Organic farming provides more biodiversity than conventional farming according to most studies. Studies show enhanced levels of birds, bats, butterflies, small mammals, insects, invertebrates and soil organisms on organic farms. 16 of 19 plant studies and 62 of 82 overall studies found positive biodiversity effects of organic farming. Key reasons for higher biodiversity include avoidance of agrochemicals, crop rotation including grass/clover, mixed farming, permanent pastures, hedgerows and restricted manure/slurry use. Interactions between landscape, cropped and non-cropped habitats may explain some variability between study results. Organic farms can also extend biodiversity benefits beyond farm boundaries. However, more research is needed on biodiversity
Physiology of grain yield in cereals, Growth and Maintenance RespirationMrunalini Chowdary
The document discusses physiology of grain yield in cereals. It notes that grain filling is dependent on photosynthesis and environmental conditions after flowering, while storage capacity is determined by pre-flowering conditions. It also discusses that the photosynthetic rate of wheat flag leaves falls and rises during grain growth. The document covers topics like photosynthesis, respiration, dry matter accumulation, growth rates, and partitioning of assimilates in different crops. It distinguishes between C3 and C4 photosynthesis pathways and their assimilation rates. It also describes the different types of respiration in plants like growth, maintenance, and their relationship to temperature.
This document discusses various methods of soil fertility evaluation including nutrient deficiency symptoms on plants, plant analysis, biological tests, soil testing, and modern approaches. Plant analysis and soil testing are quantitative chemical methods that directly measure the nutrient status of plants and soils. Biological tests include indicator plants and microbiological or pot culture tests that use the growth response of organisms. Modern approaches like soil test crop response and diagnosis and recommendation integrated system use mathematical models and nutrient ratios to determine optimized fertilizer recommendations.
This document presents a summary of several classical theories on plant growth response to nutrients:
1) Liebig's Law of the Minimum states that plant growth is limited by the scarcest nutrient.
2) Blackman's Law of the Limiting Factor states that the growth rate is determined by the slowest acting growth factor.
3) Willcox's Theory of the Nitrogen Constant found plants absorb about 318 lbs of nitrogen per acre at optimum conditions.
4) Spillman's Equation models the relationship between growth amount, maximum possible yield, growth factor quantity, and a constant.
5) Baule Unit defines the amount of nitrogen, phosphorus, or potassium needed to produce 50% of maximum possible
Green manuring is the practice of growing green plants or adding plant materials and incorporating them into the soil to improve soil structure and fertility. There are two main types - green leaf manuring, which involves collecting and adding leaves and twigs from elsewhere, and green manuring in situ, which involves growing plants like legumes and incorporating them into the soil before or at flowering. Green manuring benefits the soil by increasing nitrogen levels, improving soil structure and water retention, reducing erosion, and reclaiming saline or alkaline soils. Common green manure crops include sunn hemp, dhaincha, sesbania, and clusterbeans.
The Contingency plans cover contingency strategies to be taken up by farmers in response to major weather related aberrations such as delay in onset and breaks in monsoon causing early, mid and late season droughts, floods, unusual rains, extreme weather events such as heat wave, cold wave, frost, hailstorm and cyclone.
This document discusses methods for evaluating soil fertility, including deficiency symptoms, tissue analysis, and biological tests. Tissue analysis involves extracting plant parts with reagents and comparing nutrient concentrations to standards. It is a quick way to monitor nutrient levels at different growth stages. Biological tests use microorganisms to quantify a soil's ability to supply nutrients and are simple and require little space. Together, these methods help identify limiting nutrients and inform fertilization practices to maintain optimal nutrient levels.
The document discusses crop ideotypes and ideotype breeding. It defines an ideotype as an ideal or model plant type designed for a specific environment to maximize yield. Ideotype breeding aims to enhance genetic yield potential through manipulation of individual plant traits. Examples of ideotypes are provided for various crops like wheat, rice, maize, barley and cotton that focus on traits like plant height, tillering ability, leaf characteristics and resistance to stresses. Factors influencing ideotypes and the steps in ideotype breeding are also outlined. Practical achievements highlighted ideotype breeding's role in the green revolution by developing semi-dwarf varieties responsive to fertilizers.
Physiology of grain yield in cereals, Growth and Maintenance RespirationMrunalini Chowdary
The document discusses physiology of grain yield in cereals. It notes that grain filling is dependent on photosynthesis and environmental conditions after flowering, while storage capacity is determined by pre-flowering conditions. It also discusses that the photosynthetic rate of wheat flag leaves falls and rises during grain growth. The document covers topics like photosynthesis, respiration, dry matter accumulation, growth rates, and partitioning of assimilates in different crops. It distinguishes between C3 and C4 photosynthesis pathways and their assimilation rates. It also describes the different types of respiration in plants like growth, maintenance, and their relationship to temperature.
This document discusses various methods of soil fertility evaluation including nutrient deficiency symptoms on plants, plant analysis, biological tests, soil testing, and modern approaches. Plant analysis and soil testing are quantitative chemical methods that directly measure the nutrient status of plants and soils. Biological tests include indicator plants and microbiological or pot culture tests that use the growth response of organisms. Modern approaches like soil test crop response and diagnosis and recommendation integrated system use mathematical models and nutrient ratios to determine optimized fertilizer recommendations.
This document presents a summary of several classical theories on plant growth response to nutrients:
1) Liebig's Law of the Minimum states that plant growth is limited by the scarcest nutrient.
2) Blackman's Law of the Limiting Factor states that the growth rate is determined by the slowest acting growth factor.
3) Willcox's Theory of the Nitrogen Constant found plants absorb about 318 lbs of nitrogen per acre at optimum conditions.
4) Spillman's Equation models the relationship between growth amount, maximum possible yield, growth factor quantity, and a constant.
5) Baule Unit defines the amount of nitrogen, phosphorus, or potassium needed to produce 50% of maximum possible
Green manuring is the practice of growing green plants or adding plant materials and incorporating them into the soil to improve soil structure and fertility. There are two main types - green leaf manuring, which involves collecting and adding leaves and twigs from elsewhere, and green manuring in situ, which involves growing plants like legumes and incorporating them into the soil before or at flowering. Green manuring benefits the soil by increasing nitrogen levels, improving soil structure and water retention, reducing erosion, and reclaiming saline or alkaline soils. Common green manure crops include sunn hemp, dhaincha, sesbania, and clusterbeans.
The Contingency plans cover contingency strategies to be taken up by farmers in response to major weather related aberrations such as delay in onset and breaks in monsoon causing early, mid and late season droughts, floods, unusual rains, extreme weather events such as heat wave, cold wave, frost, hailstorm and cyclone.
This document discusses methods for evaluating soil fertility, including deficiency symptoms, tissue analysis, and biological tests. Tissue analysis involves extracting plant parts with reagents and comparing nutrient concentrations to standards. It is a quick way to monitor nutrient levels at different growth stages. Biological tests use microorganisms to quantify a soil's ability to supply nutrients and are simple and require little space. Together, these methods help identify limiting nutrients and inform fertilization practices to maintain optimal nutrient levels.
The document discusses crop ideotypes and ideotype breeding. It defines an ideotype as an ideal or model plant type designed for a specific environment to maximize yield. Ideotype breeding aims to enhance genetic yield potential through manipulation of individual plant traits. Examples of ideotypes are provided for various crops like wheat, rice, maize, barley and cotton that focus on traits like plant height, tillering ability, leaf characteristics and resistance to stresses. Factors influencing ideotypes and the steps in ideotype breeding are also outlined. Practical achievements highlighted ideotype breeding's role in the green revolution by developing semi-dwarf varieties responsive to fertilizers.
Abiotic stress management in open field vegetablesATMA RAM MEENA
India is the second largest producer of vegetables globally but has low vegetable productivity. Vegetables are important sources of nutrients. Abiotic stresses like temperature extremes negatively impact vegetable growth and yields. Integrated crop management strategies can help overcome abiotic stresses through the use of stress-tolerant varieties, organic farming, protected cultivation, and agronomic practices suited to different climates and vegetable types. Maintaining optimal temperatures, light, and soil conditions enhances vegetable productivity in open cultivation systems.
This document provides an overview of precision farming presented by Rohit Pandey. It defines precision farming as applying the right inputs, at the right time, in the right amount, at the right place, and in the right manner based on crop requirements on a localized basis. The key components of precision farming discussed are GPS, GIS, remote sensing, variable rate applicators, and the farmer. The document also discusses approaches to precision farming like grid sampling and management zones, and prospects in the Indian agriculture context.
1) The document discusses rainfed agriculture in India, which occupies 67% of cultivated land but produces 44% of food grains. It defines dry farming, dryland farming and rainfed farming based on annual rainfall.
2) It provides a brief history of developments in rainfed agriculture in India starting from the 1920s, including establishment of research stations and institutions.
3) The document outlines several problems faced in rainfed agriculture like inadequate and uneven rainfall distribution, long gaps between rainfall, early/late monsoon onset, early cessation of rains, and prolonged dry spells. It provides solutions to address each problem.
1. The document discusses nutrient use efficiency and factors that affect it, such as leaching, gaseous losses, immobilization, and chemical reactions between fertilizer components.
2. It describes methods of increasing fertilizer use efficiency, including applying fertilizers at the right time and quantity, and using the proper fertilizer source and form for different crops to minimize fixation and maximize availability.
3. Integrated nutrient management is defined as maintaining soil fertility and nutrient supply through optimizing organic, inorganic, and biological components to provide balanced nutrition for crops while sustaining soil quality.
Greenhouses allow for control of the components of a crop's microclimate, including light, temperature, relative humidity, ventilation, and carbon dioxide. Light intensity and wavelength affect photosynthesis rates, with optimal light between 32.3-129.6 klux. Temperature influences enzyme activity, with day temperatures generally 3-8°C higher than nights. Relative humidity is maintained between 50-80% through humidification and dehumidification. Ventilation manages air temperature, carbon dioxide, and humidity. Carbon dioxide is essential for plant growth, with most crops responding well to levels between 1000-1200 ppm in greenhouses.
FATE OF HERBICIDE IN SOIL by Pravir pandeyPravir Pandey
The document summarizes the fate of herbicides in soil after application. It discusses various processes that affect herbicide activity including degradation through biological, chemical and photodecomposition, as well as transfer processes like adsorption, leaching, volatility and runoff. Factors that influence these processes include environmental conditions, soil properties, herbicide formulations and application methods. The degradation of herbicides renders them inactive while transfer processes may remove herbicides from the application site.
This document summarizes the key points about crop residue management. It begins with definitions of crop residue and discusses the importance of crop residues as a source of organic matter and plant nutrients. It then discusses different types of crop residues including field residues and process residues. The potential uses of crop residues are outlined, including as animal feed, household purposes, composting, biofuels, and improving soil properties. Methods of recycling crop residues like surface mulching, in-situ incorporation, and composting are described. Tables show the effects of different crop residue management practices on soil physical, chemical and biological properties.
This document provides an introduction to the course titled "Rainfed Agriculture and Watershed Management". It discusses key topics that will be covered in the course including the introduction and history of rainfed agriculture, problems of dryland farming, soil and climatic conditions of rainfed areas, soil and water conservation techniques, drought classification and impacts, crop adaptation to drought, water harvesting methods, and watershed management concepts. The document outlines the course credits, topics, teaching schedule, and suggested readings to provide an overview of the content that will be covered.
This document discusses various aspects of indigenous technical knowledge (ITK) used in organic farming in India. It explains that ITK is traditional knowledge that has been passed down over generations and varies between communities. ITK practices can help organic farming by avoiding synthetic chemicals and maintaining soil health in a sustainable manner. Some specific ITK practices discussed include using fermented coconut milk or mixtures containing goat products as crop growth promoters, using mulches like tree leaves to conserve soil moisture, and using plants like tulsi or neem for pest and disease management. The document provides many examples of traditional practices for different stages of farming from pre-sowing to post-harvest management.
1) The history of soil fertility and plant nutrition developed over thousands of years through early cultivation, experimentation, and the work of scientists and agronomists.
2) Early civilizations in Mesopotamia, Egypt, Greece, Rome, and China began improving soil fertility through practices like manuring, crop rotations, and green manures.
3) During the 17th-19th centuries, scientists like Van Helmont, Boyle, Tull, Liebig, and Lawes conducted experiments that improved understanding of plant nutrition and led to the development of commercial fertilizers.
4) Liebig established the concept of plant nutrients and minimum requirements, influencing modern fertilizer practice. Broadbalk field trials
The document discusses planning and design considerations for greenhouses. It covers site selection factors like solar exposure, drainage, wind protection and orientation. Greenhouse structural designs can be straight-sided walls with arched or gabled roofs, or hoop-style frames. Designs must withstand wind and snow loads. Covering materials are selected based on light transmission, durability, thermal properties and service life. The ideal covering transmits visible light, absorbs UV rays, reflects infrared to prevent overheating, is low-cost, and lasts 10-20 years.
This document discusses various soil and moisture conservation techniques, which are divided into agronomic and engineering measures. Agronomic measures include conservation tillage, deep tillage, contour farming, strip cropping, mulching, and growing cover crops. These are used where land slopes are less than 2%. Engineering measures include bunding, terracing, trenching, and subsoiling, which are constructed barriers used on slopes greater than 2% to retain runoff. Broad bed furrows are also discussed as a technique using beds and furrows to store moisture and drain excess water.
Different sowing methods of sugarcane in different regionSuman Dey
1. There are various sugarcane planting methods used in different regions of India depending on soil and climate conditions. These include flat bed planting, ridge and furrow planting, pit planting with drip fertigation, wider row planting, spaced transplanting, polybag seedling transplanting, chip-bud technique, tissue culture, trench planting, and rayungan, t-jeblock, skip furrow, and algin methods.
2. Ridge and furrow planting is used in areas with moderate rainfall and drainage problems, creating ridges and furrows 80-100cm apart. Pit planting involves creating pits 1.5x1.5m apart, 45cm deep for planting setts with drip fertigation
This document discusses various types of environmental stresses that can affect plant growth including drought, high or low temperatures, excessive soil salinity, and inadequate minerals in the soil. It describes different mechanisms by which plants can adapt to or tolerate drought conditions, such as escaping drought by having a short lifecycle, avoiding stress through stomatal regulation and increased photosynthetic efficiency, and tolerating stress through enhanced water conservation and storage abilities. The document focuses on defining and classifying different types of drought, as well as adaptation strategies employed by crops to survive in drought environments.
Green manuring is the practice of enriching soil fertility by plowing under or incorporating green manure crops into the soil while still green or soon after flowering. It improves soil structure and fertility by adding nutrients like nitrogen. Common green manure crops in India include dhaincha, glyricidia, and karanja, which are plowed under at the flowering stage. The benefits of green manuring include increased organic matter, improved soil structure, increased nutrient availability and crop yields. Proper timing and crop selection is important for effective green manuring.
Herbicide degradation in soil and plants......POOJITHA K
This document discusses the fate and degradation of herbicides in soil and plants. It explains that after a herbicide is applied, it can be degraded through various mechanisms in soil like adsorption, leaching, volatility, photodecomposition, chemical decomposition, and microbial degradation. The factors that affect a herbicide's fate in soil are environmental conditions like rainfall and microbial population as well as characteristics of the spray application. In plants, herbicides can be absorbed through leaves, stems, or roots and translocated through the xylem or phloem. They are then metabolized through processes like oxidation, hydroxylation, hydrolysis, dealkylation, conjugation, and ring cleavage. The document provides details on each of
Foliar nutrition uptake and factors affecting it. Key points:
1) Nutrients can be absorbed by leaves through stomata or cuticles. Uptake depends on factors like concentration, solubility, pH, and environmental conditions.
2) Nutrients must penetrate the cuticle or enter stomata and then transport through plant tissues. Concentration gradients and permeability influence penetration.
3) Environmental factors like humidity, temperature, light intensity impact uptake. Higher humidity and temperatures increase uptake while higher light decreases it.
Soil fertility evaluation and fertilizer recommendationBharathM64
This document discusses different approaches for evaluating soil fertility and determining fertilizer recommendations, including soil analysis, plant analysis, and visual deficiency symptoms. It describes methods for both rapid tissue tests of fresh plant parts and total laboratory analysis of dried plant materials. Diagnosis and recommendations can be generalized, based on soil test ratings with adjustments, or use the soil test crop response and target yield concept to determine fertilizer doses needed to achieve specific yields.
Implementation and impact of IPM. Safety issues in pesticide use. Political, ...Nikhil Kumar
IPM packages tested at several research centres vis-a-vis the farmers’ practices indicate superiority of the former. IPM practices enabled reduction in the number of chemical sprays. IPM system also resulted in increase of natural enemies by three-fold, reduced the insecticide and environmental pollution (Dhaliwal and Arora, 1996).
An integrated strategy for the management of major pests and diseases is possible by
I. breeding new varieties with built-in resistance,
II. evolving efficient methods of pest control through pest surveys and monitoring, and
III. biological control of pests with the help of conservation and augmentation of natural enemies like parasites, predators and insect pathogens.
The
Diversity in Food Systems: The Case of Stockfree Organic
`
For more information, Please see websites below:
`
Organic Edible Schoolyards & Gardening with Children
http://scribd.com/doc/239851214
`
Double Food Production from your School Garden with Organic Tech
http://scribd.com/doc/239851079
`
Free School Gardening Art Posters
http://scribd.com/doc/239851159`
`
Companion Planting Increases Food Production from School Gardens
http://scribd.com/doc/239851159
`
Healthy Foods Dramatically Improves Student Academic Success
http://scribd.com/doc/239851348
`
City Chickens for your Organic School Garden
http://scribd.com/doc/239850440
`
Simple Square Foot Gardening for Schools - Teacher Guide
http://scribd.com/doc/239851110
This document discusses agroecology as a transdisciplinary science for sustainable agriculture. It reviews key areas where agroecology interfaces with other disciplines and outlines agroecology's methodological and conceptual achievements over time. These include establishing the agroecosystem concept and hierarchy, viewing the farm as a decision-making unit, and representing agriculture as a human activity system. Agroecology uses these tools to study agroecosystem structure, function, productivity and impacts. More recent research focuses on sustainability issues like biodiversity and integrating ecological, economic and social dimensions of agriculture. Agroecology serves as a bridge between disciplines and between theory and practice to address sustainability challenges through indicators and new academic programs.
Abiotic stress management in open field vegetablesATMA RAM MEENA
India is the second largest producer of vegetables globally but has low vegetable productivity. Vegetables are important sources of nutrients. Abiotic stresses like temperature extremes negatively impact vegetable growth and yields. Integrated crop management strategies can help overcome abiotic stresses through the use of stress-tolerant varieties, organic farming, protected cultivation, and agronomic practices suited to different climates and vegetable types. Maintaining optimal temperatures, light, and soil conditions enhances vegetable productivity in open cultivation systems.
This document provides an overview of precision farming presented by Rohit Pandey. It defines precision farming as applying the right inputs, at the right time, in the right amount, at the right place, and in the right manner based on crop requirements on a localized basis. The key components of precision farming discussed are GPS, GIS, remote sensing, variable rate applicators, and the farmer. The document also discusses approaches to precision farming like grid sampling and management zones, and prospects in the Indian agriculture context.
1) The document discusses rainfed agriculture in India, which occupies 67% of cultivated land but produces 44% of food grains. It defines dry farming, dryland farming and rainfed farming based on annual rainfall.
2) It provides a brief history of developments in rainfed agriculture in India starting from the 1920s, including establishment of research stations and institutions.
3) The document outlines several problems faced in rainfed agriculture like inadequate and uneven rainfall distribution, long gaps between rainfall, early/late monsoon onset, early cessation of rains, and prolonged dry spells. It provides solutions to address each problem.
1. The document discusses nutrient use efficiency and factors that affect it, such as leaching, gaseous losses, immobilization, and chemical reactions between fertilizer components.
2. It describes methods of increasing fertilizer use efficiency, including applying fertilizers at the right time and quantity, and using the proper fertilizer source and form for different crops to minimize fixation and maximize availability.
3. Integrated nutrient management is defined as maintaining soil fertility and nutrient supply through optimizing organic, inorganic, and biological components to provide balanced nutrition for crops while sustaining soil quality.
Greenhouses allow for control of the components of a crop's microclimate, including light, temperature, relative humidity, ventilation, and carbon dioxide. Light intensity and wavelength affect photosynthesis rates, with optimal light between 32.3-129.6 klux. Temperature influences enzyme activity, with day temperatures generally 3-8°C higher than nights. Relative humidity is maintained between 50-80% through humidification and dehumidification. Ventilation manages air temperature, carbon dioxide, and humidity. Carbon dioxide is essential for plant growth, with most crops responding well to levels between 1000-1200 ppm in greenhouses.
FATE OF HERBICIDE IN SOIL by Pravir pandeyPravir Pandey
The document summarizes the fate of herbicides in soil after application. It discusses various processes that affect herbicide activity including degradation through biological, chemical and photodecomposition, as well as transfer processes like adsorption, leaching, volatility and runoff. Factors that influence these processes include environmental conditions, soil properties, herbicide formulations and application methods. The degradation of herbicides renders them inactive while transfer processes may remove herbicides from the application site.
This document summarizes the key points about crop residue management. It begins with definitions of crop residue and discusses the importance of crop residues as a source of organic matter and plant nutrients. It then discusses different types of crop residues including field residues and process residues. The potential uses of crop residues are outlined, including as animal feed, household purposes, composting, biofuels, and improving soil properties. Methods of recycling crop residues like surface mulching, in-situ incorporation, and composting are described. Tables show the effects of different crop residue management practices on soil physical, chemical and biological properties.
This document provides an introduction to the course titled "Rainfed Agriculture and Watershed Management". It discusses key topics that will be covered in the course including the introduction and history of rainfed agriculture, problems of dryland farming, soil and climatic conditions of rainfed areas, soil and water conservation techniques, drought classification and impacts, crop adaptation to drought, water harvesting methods, and watershed management concepts. The document outlines the course credits, topics, teaching schedule, and suggested readings to provide an overview of the content that will be covered.
This document discusses various aspects of indigenous technical knowledge (ITK) used in organic farming in India. It explains that ITK is traditional knowledge that has been passed down over generations and varies between communities. ITK practices can help organic farming by avoiding synthetic chemicals and maintaining soil health in a sustainable manner. Some specific ITK practices discussed include using fermented coconut milk or mixtures containing goat products as crop growth promoters, using mulches like tree leaves to conserve soil moisture, and using plants like tulsi or neem for pest and disease management. The document provides many examples of traditional practices for different stages of farming from pre-sowing to post-harvest management.
1) The history of soil fertility and plant nutrition developed over thousands of years through early cultivation, experimentation, and the work of scientists and agronomists.
2) Early civilizations in Mesopotamia, Egypt, Greece, Rome, and China began improving soil fertility through practices like manuring, crop rotations, and green manures.
3) During the 17th-19th centuries, scientists like Van Helmont, Boyle, Tull, Liebig, and Lawes conducted experiments that improved understanding of plant nutrition and led to the development of commercial fertilizers.
4) Liebig established the concept of plant nutrients and minimum requirements, influencing modern fertilizer practice. Broadbalk field trials
The document discusses planning and design considerations for greenhouses. It covers site selection factors like solar exposure, drainage, wind protection and orientation. Greenhouse structural designs can be straight-sided walls with arched or gabled roofs, or hoop-style frames. Designs must withstand wind and snow loads. Covering materials are selected based on light transmission, durability, thermal properties and service life. The ideal covering transmits visible light, absorbs UV rays, reflects infrared to prevent overheating, is low-cost, and lasts 10-20 years.
This document discusses various soil and moisture conservation techniques, which are divided into agronomic and engineering measures. Agronomic measures include conservation tillage, deep tillage, contour farming, strip cropping, mulching, and growing cover crops. These are used where land slopes are less than 2%. Engineering measures include bunding, terracing, trenching, and subsoiling, which are constructed barriers used on slopes greater than 2% to retain runoff. Broad bed furrows are also discussed as a technique using beds and furrows to store moisture and drain excess water.
Different sowing methods of sugarcane in different regionSuman Dey
1. There are various sugarcane planting methods used in different regions of India depending on soil and climate conditions. These include flat bed planting, ridge and furrow planting, pit planting with drip fertigation, wider row planting, spaced transplanting, polybag seedling transplanting, chip-bud technique, tissue culture, trench planting, and rayungan, t-jeblock, skip furrow, and algin methods.
2. Ridge and furrow planting is used in areas with moderate rainfall and drainage problems, creating ridges and furrows 80-100cm apart. Pit planting involves creating pits 1.5x1.5m apart, 45cm deep for planting setts with drip fertigation
This document discusses various types of environmental stresses that can affect plant growth including drought, high or low temperatures, excessive soil salinity, and inadequate minerals in the soil. It describes different mechanisms by which plants can adapt to or tolerate drought conditions, such as escaping drought by having a short lifecycle, avoiding stress through stomatal regulation and increased photosynthetic efficiency, and tolerating stress through enhanced water conservation and storage abilities. The document focuses on defining and classifying different types of drought, as well as adaptation strategies employed by crops to survive in drought environments.
Green manuring is the practice of enriching soil fertility by plowing under or incorporating green manure crops into the soil while still green or soon after flowering. It improves soil structure and fertility by adding nutrients like nitrogen. Common green manure crops in India include dhaincha, glyricidia, and karanja, which are plowed under at the flowering stage. The benefits of green manuring include increased organic matter, improved soil structure, increased nutrient availability and crop yields. Proper timing and crop selection is important for effective green manuring.
Herbicide degradation in soil and plants......POOJITHA K
This document discusses the fate and degradation of herbicides in soil and plants. It explains that after a herbicide is applied, it can be degraded through various mechanisms in soil like adsorption, leaching, volatility, photodecomposition, chemical decomposition, and microbial degradation. The factors that affect a herbicide's fate in soil are environmental conditions like rainfall and microbial population as well as characteristics of the spray application. In plants, herbicides can be absorbed through leaves, stems, or roots and translocated through the xylem or phloem. They are then metabolized through processes like oxidation, hydroxylation, hydrolysis, dealkylation, conjugation, and ring cleavage. The document provides details on each of
Foliar nutrition uptake and factors affecting it. Key points:
1) Nutrients can be absorbed by leaves through stomata or cuticles. Uptake depends on factors like concentration, solubility, pH, and environmental conditions.
2) Nutrients must penetrate the cuticle or enter stomata and then transport through plant tissues. Concentration gradients and permeability influence penetration.
3) Environmental factors like humidity, temperature, light intensity impact uptake. Higher humidity and temperatures increase uptake while higher light decreases it.
Soil fertility evaluation and fertilizer recommendationBharathM64
This document discusses different approaches for evaluating soil fertility and determining fertilizer recommendations, including soil analysis, plant analysis, and visual deficiency symptoms. It describes methods for both rapid tissue tests of fresh plant parts and total laboratory analysis of dried plant materials. Diagnosis and recommendations can be generalized, based on soil test ratings with adjustments, or use the soil test crop response and target yield concept to determine fertilizer doses needed to achieve specific yields.
Implementation and impact of IPM. Safety issues in pesticide use. Political, ...Nikhil Kumar
IPM packages tested at several research centres vis-a-vis the farmers’ practices indicate superiority of the former. IPM practices enabled reduction in the number of chemical sprays. IPM system also resulted in increase of natural enemies by three-fold, reduced the insecticide and environmental pollution (Dhaliwal and Arora, 1996).
An integrated strategy for the management of major pests and diseases is possible by
I. breeding new varieties with built-in resistance,
II. evolving efficient methods of pest control through pest surveys and monitoring, and
III. biological control of pests with the help of conservation and augmentation of natural enemies like parasites, predators and insect pathogens.
The
Diversity in Food Systems: The Case of Stockfree Organic
`
For more information, Please see websites below:
`
Organic Edible Schoolyards & Gardening with Children
http://scribd.com/doc/239851214
`
Double Food Production from your School Garden with Organic Tech
http://scribd.com/doc/239851079
`
Free School Gardening Art Posters
http://scribd.com/doc/239851159`
`
Companion Planting Increases Food Production from School Gardens
http://scribd.com/doc/239851159
`
Healthy Foods Dramatically Improves Student Academic Success
http://scribd.com/doc/239851348
`
City Chickens for your Organic School Garden
http://scribd.com/doc/239850440
`
Simple Square Foot Gardening for Schools - Teacher Guide
http://scribd.com/doc/239851110
This document discusses agroecology as a transdisciplinary science for sustainable agriculture. It reviews key areas where agroecology interfaces with other disciplines and outlines agroecology's methodological and conceptual achievements over time. These include establishing the agroecosystem concept and hierarchy, viewing the farm as a decision-making unit, and representing agriculture as a human activity system. Agroecology uses these tools to study agroecosystem structure, function, productivity and impacts. More recent research focuses on sustainability issues like biodiversity and integrating ecological, economic and social dimensions of agriculture. Agroecology serves as a bridge between disciplines and between theory and practice to address sustainability challenges through indicators and new academic programs.
Biodiversity, Biofuels, Agroforestry and Conservation Agriculturex3G9
This document discusses agroecology as a transdisciplinary science for sustainable agriculture. It reviews key developments in agroecology including its use of a systems approach and concept of agroecosystems. Agroecology research has focused on understanding agroecosystem structure, function, and sustainability. More recent work integrates ecology, agronomy, economics and sociology to promote biodiversity and biophysical sustainability. Organic farming is presented as an example of integrating bio-physical and socio-economic sustainability through legal regulation. Overall, agroecology acts as a bridge between disciplines and between theory and practice of sustainable agriculture.
Environmental Impact of Industrial Farm Animal ProductionMichael Newbold
Industrial farm animal production results in significant environmental impacts due to the enormous quantities of waste produced in a small area by confined animals. In the US, farm animals produce nearly 1 million tons of manure per day, most from confined operations. This waste pollutes water resources with nutrients, chemicals, and pathogens when not properly managed. Industrial agriculture also unsustainably uses water resources for feed production and animal operations. The environmental problems stem from the waste amounts, inadequate management systems, and high resource inputs like water and feed required by this agricultural model. Key issues include water pollution, soil contamination, and air quality degradation that negatively impact both ecosystems and human health.
Rice agroforestry: How trees can accelerate agroecological transitionsCIFOR-ICRAF
Presented by Fergus Sinclair, Rachmat Mulia, Himlal Baral,
Jim Roshetko, and Rob Finlayson
(CIFOR-ICRAF) at 6th International Rice Congress, Manila, Philippines, on 16-19 Oct 2023
One of the challenges of ecological intensification is to move agricultural research out of a focus on singular focal areas – e.g., improved seed, pest control, water management –
to solutions that integrate all components of the farming system. As such, the canon of knowledge supporting ecological intensification is transdisciplinary, focusing on the biological components of farming systems and agroecological practices but extending as well to considerations of policy and farmer and societal benefits. As the biodiversity benefits of ecological intensification, along with the negative externalities of conventional agriculture are an important motivation for ecological intensification, we have included literature on these topic, as well as references that relate climate change to ecosystem services in agriculture.
The glossary presented here is compiled on this basis, to provide definitions of key terms relevant to ecological intensification.
Sebastian Hielm: Antimicrobial resistance (AMR) and global health THL
Mr. Sebastian Hielm, Director of Food Safety, Ministry of Agriculture and Forestry, Finland, at One Health Security Conference, 14-15 Oct 2019, THL, Helsinki
Relatório ONU denuncia mito de que pesticidas são essenciais para alimentar o...Carol Daemon
Relatório da ONU denuncia “mito” de que pesticidas são essenciais para alimentar o mundo. “É um mito. Usar pesticidas nada tem a ver com acabar com a fome. De acordo com a Organização das Nações Unidas para a Alimentação e a Agricultura (FAO), já conseguimos alimentar 9 mil milhões de pessoas hoje em dia. A produção está definitivamente a aumentar, mas o problema é a pobreza, a desigualdade e a distribuição”, declarou Hilal Elver, relatora especial da ONU para o direito à comida, acrescentando que muitos pesticidas são usados em plantações de produtos como o óleo de palma e não na comida necessária para acabar com a fome.
Innovation, research, learning processes and transitions towards agroecologyExternalEvents
http://www.fao.org/europe/events/detail-events/en/c/429132/
Presentation of Jean-François Soussana, from the Institute National de la Recherche Agronomique (INRA), outlining Innovation, research and learning processes and transitions towards agroecology. The presentation was prepared and delivered in occasion of the Regional Symposium on Agroecology in Europe and Central Asia, held in Budapest, Hungary on 23-25 November 2016.
This document discusses the history and techniques of organic farming. It begins with a brief overview of the issues with Green Revolution technologies, such as overuse of chemicals negatively impacting soil and environment. It then covers the three eras in the development of organic farming: Emergence from 1924-1970 focusing on early pioneers; Development from 1970-1990 when research and practice expanded globally; and Growth from 1990 onward as certification standards were established and the market grew rapidly. The document also outlines the essential characteristics and concepts of organic farming techniques, which aim to build soil fertility without synthetic chemicals and favor maximum use of organic materials.
This document discusses the history and techniques of organic farming. It begins with a brief overview of the issues with Green Revolution technologies, such as overuse of chemicals negatively impacting soil and environment. It then covers the three eras in the development of organic farming: Emergence from 1924-1970 focusing on early pioneers; Development from 1970-1990 when research and practice expanded globally; and Growth from 1990 onward as certification standards were established and the market grew rapidly. The document also outlines the essential characteristics and concepts of organic farming techniques, which aim to favorably impact soil health, biodiversity and sustainability.
This document discusses the history and techniques of organic farming. It begins with a brief overview of the issues with Green Revolution technologies, such as overuse of chemicals negatively impacting soil and environment. It then covers the three eras in the development of organic farming: Emergence from 1924-1970 focusing on early pioneers; Development from 1970-1990 when research and practice expanded globally; and Growth from 1990 onward as certification standards were established and the market grew rapidly. The document also outlines the essential characteristics and concepts of organic farming techniques, which aim to build soil fertility without synthetic chemicals and favor maximum use of organic materials.
Sustainability is the future of world livestock.docxfeed arshine
1. The document discusses the future of sustainable livestock production. It argues that silvopastoral systems, which integrate trees, shrubs, and pasture plants to feed livestock, can provide more efficient feed conversion, higher biodiversity, better animal welfare, and replace unsustainable systems.
2. It then provides details on silvopastoral systems used in various countries. Systems that plant fodder trees and shrubs like Leucaena leucocephala alongside pasture grasses have been shown to increase milk production, dry matter, and protein available to cattle compared to pasture alone.
3. Soil structure and earthworm populations are better maintained in silvopastoral
This document discusses the environmental benefits of organic farming compared to conventional agriculture. Organic farming practices minimize environmental pollution by avoiding synthetic pesticides and fertilizers. This reduces impacts on biodiversity, air and water quality, and climate change. Specifically, organic farming supports more species diversity on farms and in surrounding areas. It also decreases greenhouse gas emissions and pollution of water and soil through reduced chemical inputs and tighter nutrient cycles. While organic farming may not always outperform conventional agriculture economically, the document argues that its environmental benefits warrant further comparison through life cycle assessments.
Environmental Benefits of Organic Farming - ISALSx3G9
This document discusses the environmental benefits of organic farming compared to conventional agriculture. Organic farming practices minimize environmental pollution by avoiding synthetic pesticides and fertilizers. This reduces impacts on biodiversity, air and water quality, and climate change. Specifically, organic farming supports more species diversity on farms and in surrounding areas. It also decreases greenhouse gas emissions and pollution of water and soil through reduced chemical inputs and tighter nutrient cycles. While organic farming may not always outperform conventional agriculture economically, the document argues that its environmental benefits warrant further consideration and study through methods like life cycle assessment.
Uk agri science and innovation newsletter issue 3REMEDIAnetwork
The document summarizes UK activities supporting international efforts to mitigate agricultural greenhouse gas emissions through the Global Research Alliance. It discusses a UK-led initiative called the Animal Health and GHG Emissions Intensity Network, which aims to investigate links between reducing livestock disease and lowering greenhouse gas emissions intensity. It provides an overview of the inaugural workshop of this network, which brought researchers from several countries together to discuss objectives, current research, and potential collaborations. It also briefly mentions other UK contributions to international meetings and the development of tools like the Global Research Alliance Modelling Platform to facilitate data sharing.
Short-rotation Willow Biomass Plantations Irrigated and Fertilised with Waste...Arne Backlund
Results from a 4-year multidisciplinary field project in
Sweden, France, Northern Ireland and Greece
supported by the EU-FAIR Programme
(FAIR5-CT97-3947)
FINAL REPORT
January 2003
Comparing Energy Use in Conventional and Organic Cropping SystemsGardening
Organic and conventional agriculture both consume energy, though the amounts vary depending on farm size, location, and practices used. Several studies have found that organic systems generally use less direct energy through reduced fertilizer and pesticide inputs, but yields can sometimes be lower, reducing the energy efficiency per unit of output. The energy efficiency of organic and conventional systems depends on factors like crop rotation, soil management practices, and energy accounting boundaries. Overall, research shows that both production systems can be optimized to reduce energy usage through practices like integrated pest management, cover cropping, and renewable energy.
Joachim von Braun
POLICY SEMINAR
Transforming Food Systems to Deliver Healthy, Sustainable Diets : The View from the World’s Science Academies
Co-Organized by IFPRI and InterAcademy Partnership
FEB 14, 2019 - 12:15 PM TO 01:45 PM EST
Marthe Cohn was a Jewish French spy who risked her life to gather intelligence for the French resistance during WWII. She infiltrated Nazi Germany using her fluent German and managed to discover key military information. As a result, the French army was able to achieve an important victory. Cohn went on to have a long career as a nurse and nurse anesthetist. She has received numerous honors for her wartime heroism and courageously fights to keep the memory of the Holocaust alive.
This document provides links to resources about organic gardening techniques, urban farming, rainwater harvesting, green roofs, straight vegetable oil vehicles, garden therapy, volunteering on organic farms in Europe, solar energy training, and eco-friendly coffee beans. It discusses how organic gardening technologies can increase plant yields by 400% and provides catalogs and manuals about topics such as city farming, backyard farming, rain gardens, and aquaponics systems. The links provide free information for organic and sustainable living practices.
Ruth Jones, a Christian teacher without a master's degree or administrative experience, was unexpectedly named principal of a struggling inner city elementary school in Grand Rapids, Michigan that was on the verge of closure due to poor academic performance. Through prayer, addressing students' practical needs, and recruiting volunteers, Jones led a dramatic turnaround of the school over 20 years. Test scores and graduation rates increased sharply, and the school now has a waiting list despite originally facing closure. Jones attributes the school's success to aligning herself with God.
- Coconut oil may help slow or prevent Alzheimer's disease in some people by providing an alternative fuel for brain cells in the form of ketones. Dr. Mary Newport put her husband Steve, who had Alzheimer's, on a diet supplemented with coconut oil, which led to improvements in his symptoms and cognitive abilities.
- Researchers have developed a ketone ester that is more potent than coconut oil, but it is very expensive to produce. Coconut oil remains a viable alternative source of ketones. Taking coconut oil may also help with other neurological diseases due to its ability to increase ketone levels and good cholesterol while reducing bad bacteria.
A teacher in Baltimore transformed the lives of students from the slums. In the 1920s, college students evaluated 200 boys from the slums and said they had no chance of success. Twenty-five years later, it was found that 176 of the 180 boys who could be located had achieved success as lawyers, doctors, and businessmen. The professor interviewed each man and they all credited their success to a teacher who had loved and believed in them. When interviewed, the elderly teacher said her simple method was that she loved those boys.
Robert Raikes witnessed the poor conditions of children in Gloucester, England in the late 18th century due to the Industrial Revolution. This inspired him to create the first Sunday school to educate and reform street children. The Sunday school used the Bible as its textbook and proved hugely successful in improving behavior and civic responsibility. Raikes' idea then spread across Britain and to other parts of Europe and America, revolutionizing religious education of children and community outreach efforts of churches. Late in life, Raikes had a profound spiritual experience witnessing a young girl reading the Bible that gave him a new understanding of faith.
The document discusses using Groasis Waterboxx devices to help plant and grow trees in dry environments like the Sahara Desert. It describes how the author and a colleague tried using 10 Waterboxx devices to plant trees in M'hamid, Morocco but their luggage containing the devices was initially lost. They were eventually found and the devices were used to plant tamarisk trees to compare growth with traditional planting methods. The document provides details on how the Waterboxx works, collecting condensation and directing water to tree roots, and hopes the experiment will help increase tree survival rates in the dry climate.
The Groasis Waterboxx is a low-tech device that helps seeds and saplings grow into strong trees in dry environments. It collects and stores rainwater and condensation to slowly water the roots daily. In tests, 88% of trees grown with the Waterboxx survived compared to only 10.5% without it. The inventor believes using this technology could reforest billions of acres and offset humanity's carbon emissions by capturing CO2 in new tree growth.
The document discusses the Groasis Technology, a planting method that uses a Waterboxx and other techniques to plant trees in dry areas with 90% less water. It summarizes that the technology (1) improves soil, maps planting areas, harvests rainfall, and uses the right planting techniques to help trees grow deep roots in the first year to survive independently. It also describes how the technology terraces slopes to harvest and direct rainfall to trees, uses 3D imaging to map ideal planting lines, and a capillary drill to quickly plant thousands of trees per day.
The document describes the Agua, Vida y Naturaleza Project (AVNP) that started in Ecuador in 2012. It is funded by the Dutch COmON Foundation to help small farmers in dry areas by introducing the Groasis Technology, which allows planting in deserts and eroded lands. The technology mimics nature by improving soil, maintaining capillary structures, and using a waterboxx device. The project aims to address issues small farmers face like lack of water, capital, and farming knowledge, in order to help alleviate world hunger and prevent farmers from migrating to cities due to lack of income from farming dry areas.
The document provides planting instructions for using a Waterboxx planting device. It outlines 6 main steps:
1. Preparing the soil by digging holes and adding compost/fertilizer or just watering.
2. Assembling the Waterboxx by placing the wick, mid-plate, lid, and siphons.
3. Preparing plants by pruning roots to encourage deep growth.
4. Planting in holes aligned east-west within the Waterboxx hole.
5. Placing the assembled Waterboxx over the planted area.
6. Watering the plants and filling the Waterboxx for the first time.
This document provides instructions for growing vegetables using the Groasis Waterboxx system. It details recommendations for greenhouse design, soil preparation, planting methods, plant spacing, watering schedules, and pest and disease management. Proper installation and maintenance of the Waterboxx system is emphasized to ensure healthy plant growth and high crop yields. Close monitoring of climate conditions and plant needs is also advised.
The document is a report on the Groasis waterboxx, a device that aims to allow farming without irrigation. It provides an overview of the waterboxx's history and development, describes its components and how it works, reviews testing that has been done, and evaluates its suitability for organic farming. In the conclusion, the report recommends that the cooperative discussed in the document not use the waterboxx yet, as more data is still needed, but could consider conducting their own tests with support from their technical services.
The document summarizes an invention called the Groasis that helps plants survive in arid climates by collecting and storing rainfall to provide steady watering to seedlings. It notes that most rainfall in deserts occurs within one week but is then unavailable, and that the Groasis uses evaporation-proof containers and wicking to deliver water to young plants over longer periods, allowing their roots to develop and access deeper groundwater reserves. Large-scale projects have used the Groasis in countries like Kenya to aid reforestation efforts and combat desertification.
The document summarizes the work of the Sahara Roots Foundation in Morocco and their use of the Groasis Waterboxx to help plant trees and reduce desertification. The Sahara Roots Foundation was established to implement development projects to conserve the Moroccan Sahara through activities like tree planting, irrigation, education, and desert cleaning. They have started using the Groasis Waterboxx, an "intelligent water battery" developed by AquaPro, to improve the survival rate of newly planted trees. The Waterboxx produces and captures water through condensation and rain, allowing trees to be planted in dry areas like rocks and deserts with a 100% success rate.
The document describes the Agua, Vida y Naturaleza Project (AVNP) that started in Ecuador in 2012. It is funded by the Dutch COmON Foundation to help small farmers in dry areas by introducing the Groasis Technology, which allows planting in deserts and eroded lands. The technology mimics nature by improving soil, maintaining capillary structures, and using a waterboxx device. The project aims to address issues small farmers face like lack of water, capital, and farming knowledge, in order to help alleviate world hunger and prevent farmers from migrating to cities.
Groasis Technology is compared to drip irrigation over a 50-year project for a 500-hectare tree plantation. Key financial indicators show that using Groasis Waterboxes results in a higher net present value (NPV) of €26.62 million compared to €21.15 million for drip irrigation, and a slightly higher internal rate of return (IRR) of 22.1% versus 23.4% for drip irrigation. Waterboxx also has a longer payback period of 7 years compared to 5 years for drip irrigation. The document provides assumptions and calculations for costs and revenues for both systems over the 50-year period.
A new technology called the Groasis Waterboxx shows promise for reclaiming desert landscapes and increasing plant survival rates. The simple device regulates temperature and moisture levels around young plants, allowing trees and crops to grow with little watering even in dry conditions. Initial trials in Africa found tree survival rates increased to 88% with the Waterboxx compared to only 10% without it. Researchers in Kenya are optimistic this technology could significantly reduce desertification and help transform the country's deserts into productive, economic areas through increased vegetation.
More from School Vegetable Gardening - Victory Gardens (20)
Elevate Your Nonprofit's Online Presence_ A Guide to Effective SEO Strategies...TechSoup
Whether you're new to SEO or looking to refine your existing strategies, this webinar will provide you with actionable insights and practical tips to elevate your nonprofit's online presence.
A Free 200-Page eBook ~ Brain and Mind Exercise.pptxOH TEIK BIN
(A Free eBook comprising 3 Sets of Presentation of a selection of Puzzles, Brain Teasers and Thinking Problems to exercise both the mind and the Right and Left Brain. To help keep the mind and brain fit and healthy. Good for both the young and old alike.
Answers are given for all the puzzles and problems.)
With Metta,
Bro. Oh Teik Bin 🙏🤓🤔🥰
Philippine Edukasyong Pantahanan at Pangkabuhayan (EPP) CurriculumMJDuyan
(𝐓𝐋𝐄 𝟏𝟎𝟎) (𝐋𝐞𝐬𝐬𝐨𝐧 𝟏)-𝐏𝐫𝐞𝐥𝐢𝐦𝐬
𝐃𝐢𝐬𝐜𝐮𝐬𝐬 𝐭𝐡𝐞 𝐄𝐏𝐏 𝐂𝐮𝐫𝐫𝐢𝐜𝐮𝐥𝐮𝐦 𝐢𝐧 𝐭𝐡𝐞 𝐏𝐡𝐢𝐥𝐢𝐩𝐩𝐢𝐧𝐞𝐬:
- Understand the goals and objectives of the Edukasyong Pantahanan at Pangkabuhayan (EPP) curriculum, recognizing its importance in fostering practical life skills and values among students. Students will also be able to identify the key components and subjects covered, such as agriculture, home economics, industrial arts, and information and communication technology.
𝐄𝐱𝐩𝐥𝐚𝐢𝐧 𝐭𝐡𝐞 𝐍𝐚𝐭𝐮𝐫𝐞 𝐚𝐧𝐝 𝐒𝐜𝐨𝐩𝐞 𝐨𝐟 𝐚𝐧 𝐄𝐧𝐭𝐫𝐞𝐩𝐫𝐞𝐧𝐞𝐮𝐫:
-Define entrepreneurship, distinguishing it from general business activities by emphasizing its focus on innovation, risk-taking, and value creation. Students will describe the characteristics and traits of successful entrepreneurs, including their roles and responsibilities, and discuss the broader economic and social impacts of entrepreneurial activities on both local and global scales.
A Visual Guide to 1 Samuel | A Tale of Two HeartsSteve Thomason
These slides walk through the story of 1 Samuel. Samuel is the last judge of Israel. The people reject God and want a king. Saul is anointed as the first king, but he is not a good king. David, the shepherd boy is anointed and Saul is envious of him. David shows honor while Saul continues to self destruct.
Temple of Asclepius in Thrace. Excavation resultsKrassimira Luka
The temple and the sanctuary around were dedicated to Asklepios Zmidrenus. This name has been known since 1875 when an inscription dedicated to him was discovered in Rome. The inscription is dated in 227 AD and was left by soldiers originating from the city of Philippopolis (modern Plovdiv).
🔥🔥🔥🔥🔥🔥🔥🔥🔥
إضغ بين إيديكم من أقوى الملازم التي صممتها
ملزمة تشريح الجهاز الهيكلي (نظري 3)
💀💀💀💀💀💀💀💀💀💀
تتميز هذهِ الملزمة بعِدة مُميزات :
1- مُترجمة ترجمة تُناسب جميع المستويات
2- تحتوي على 78 رسم توضيحي لكل كلمة موجودة بالملزمة (لكل كلمة !!!!)
#فهم_ماكو_درخ
3- دقة الكتابة والصور عالية جداً جداً جداً
4- هُنالك بعض المعلومات تم توضيحها بشكل تفصيلي جداً (تُعتبر لدى الطالب أو الطالبة بإنها معلومات مُبهمة ومع ذلك تم توضيح هذهِ المعلومات المُبهمة بشكل تفصيلي جداً
5- الملزمة تشرح نفسها ب نفسها بس تكلك تعال اقراني
6- تحتوي الملزمة في اول سلايد على خارطة تتضمن جميع تفرُعات معلومات الجهاز الهيكلي المذكورة في هذهِ الملزمة
واخيراً هذهِ الملزمة حلالٌ عليكم وإتمنى منكم إن تدعولي بالخير والصحة والعافية فقط
كل التوفيق زملائي وزميلاتي ، زميلكم محمد الذهبي 💊💊
🔥🔥🔥🔥🔥🔥🔥🔥🔥
NIPER 2024 MEMORY BASED QUESTIONS.ANSWERS TO NIPER 2024 QUESTIONS.NIPER JEE 2...
Organic Farming and Biodiversity
1. Organic Farming and Biodiversity:
A review of the literature
Jo Smith, Martin Wolfe, Lawrence Woodward, Bruce Pearce and Nic Lampkin
Organic Research Centre, Elm Farm,
Hamstead Marshall,
Newbury, Berkshire RG20 0HR
Organic Centre Wales
Aberystwyth
February 2011
2. Organic Centre Wales is a publicly funded organisation responsible for the dissemination of
information on organic food and farming in Wales. The Centre comprises three partners:
ADAS Wales, the Institute of Biological, Environmental and Rural Sciences at Aberystwyth
University, and the Organic Research Centre, Elm Farm.
Published by Organic Centre Wales
P: IBERS, Gogerddan Campus Aberystwyth University, Ceredigion, SY23 3EB.
T: +44 (0) 1970 622248.
E: organic@aber.ac.uk
W: www.organiccentrewales.org.uk
.
3. Executive summary
Organic Farming and Biodiversity: A review of the literature
1) There is overwhelming evidence that organic farming provides more biodiversity than
conventional farming. In almost all studies overall biodiversity has been found to be much
greater and often significantly so, than on conventional farms (Table 1). This evidence is
consistent whether the studies are based on plots, fields or whole farms. The evidence in
favour of organic farming compared to conventional farming at the level of specific
biodiversity components is also compelling. Studies of birds, bats, butterflies, small
mammals, insects, invertebrates, soil organisms and fauna generally show enhanced levels
and diversity on organic farms. There is also evidence of a greater level of rare or threatened
species.
2) Analysis of the published studies of the effects of organic farming on plants, invertebrates,
soil microbes, birds, landscape and ecosystem services confirms a wide range and large
number of positive effects (62 out of 82 studies) with very few negative effects (6 out of 82
studies). These positive responses are most consistent for plants, with 16 out of 19 studies
reporting beneficial effects of organic systems.
3) The rationale for these results varies according to the focus the study but there is a clear
body of generally accepted reasons:
The avoidance of “agro-chemical” inputs; both pesticides and soluble fertilisers
The practice of crop rotation including grass/clover leys, mixed cropping, green
manures etc.
That most organic farms are mixed farms
The maintenance and introduction of permanent pastures, long term grass leys,
hedgerows, beetle banks etc.
Restricted use of slurry and manure applications
Mixed livestock enterprises
In general, management regimes which tend towards diversity and away from
intensification.
4) It is likely that the interactions between landscape, non-cropped and cropped habitat and
farming practices are critically important and may explain some of the variability in
biodiversity found between studies. A number of studies in recent years have explored some
of these interactions and in particular the effects of landscape complexity and scale.
5) There is evidence that organic farms can extend their biodiversity benefits beyond the
farm boundary into surrounding landscapes and farms. Conversely, for taxa such as plants,
organic farms form “self-sufficient ecosystems” that do not rely on immigration from
surrounding habitats to maintain species pools.
6) Very few studies address the impact of organic farming in grassland or upland systems.
The biodiversity impacts of organic conversion in the hills and uplands were investigated in a
recent Defra-funded project. The results contrast with those comparing organic and nonorganic lowland arable farms. However, the project focussed only on vascular plants, and it
has been demonstrated that the response of e.g. invertebrates, birds and bats to organic
farming may differ. Other studies have shown that upland plant communities have been
affected by anthropogenic factors including increased grazing pressure and eutrophication,
with subsequent impacts on associated invertebrates. Practices inherent to organic upland
systems, including lower stocking rates, mixed grazing and the use of traditional breeds, may
counteract these effects. Further work is required to quantify the impact of organic
conversion in the uplands.
i
4. 7) However, ecological interactions are complex and the studies reveal inconsistencies and a
dynamic which needs further investigation. The report discusses the limitations of the
methodologies used in the published work and the limitations of the studies.
8) There is an urgent need to improve the range and amount of biodiversity in agriculture,
particularly in relation to its importance for ecosystems and ecosystem services. This is of
increasing importance in the context of emerging generalisations in ecology that biodiversity
is positively correlated with both productivity and stability, and that biodiversity supports
many other ecosystem services such as pest and disease control and pollination.
9) To date there have been few examples translating the biological value of on-farm
biodiversity into an economic value based on the ecological services that are generated.
However, one early attempt found that the ecological services from a sample of organic
farms had a considerably higher value than those from a range of non-organic farms (organic
fields ranged from US $1610 to US $19,420 ha-1 yr-1; conventional fields from US $460 to
US $14,570 ha-1 yr-1).
ii
7. 1
Introduction
This report was prepared during a period of uncertainty over the level of support that would
be available for organic farming through the Glastir support scheme. Questions were asked
about the delivery of biodiversity through organic farming. This report seeks to answer those
questions.
The main body of the report draws on the literature to present results by taxa. A section on
methods discusses issues relating to reviews and inconsistencies in results and finally a
discussion reviews the evidence. The Appendix contains brief summaries of the literature.
1.1
Background
Exemplified by the Millennium Ecosystem Assessment (2005), there is universal concern
over the current scale and rate of losses in biodiversity worldwide, and the effects that this is
likely to have on ecosystems and ecosystem services. In these circumstances it is clear that
all possible measures to, at the very least, slow down such losses, need to be considered,
supported and implemented as rapidly as possible.
Because organic farming developed as a form of ecological farming, which depends upon
local biological processes delivered by a wide range of organisms within and adjacent to the
crop spaces, it has been the view of organic farmers that, by definition, the system would be
beneficial for biodiversity. By its nature, organic farming should, overall, encourage rather
than reduce biodiversity at least in its direct area of operation. However, there needs to be
clear scientific evidence, first, that this is so, secondly, to show the main directions in which
this is happening and why, and then, thirdly, from these observations and analyses, to
indicate ways in which the processes could be improved both for the farming systems and for
biodiversity more generally.
This last point is particularly important in relation to the general concerns about biodiversity.
At one extreme, even within the geographical confines of the UK or Wales, there are
elements of biodiversity which appear to have no obvious relationship to agricultural landuse, but which are an essential part of natural ecosystems, such as, for example, mosses on
hill crags. At the other extreme are the soil microorganisms involved in symbiotic nitrogen
fixation or phosphorus release for crop plants. However, it takes little analysis to show that
these extremes are not totally isolated but that they form parts of a continuum, which are
likely to have feedback effects in both directions, even though the numbers of intermediate
steps may be large and their relationships complex.
The question for agricultural systems therefore, is whether they can provide, on the one
hand, indirect support for agriculturally-remote ecosystems and, on the other, direct support
for the many different forms of biodiversity that are involved, or that can be involved, in
agricultural ecosystems.
Unfortunately, our current understanding of ecosystems at almost any level is still poor,
despite remarkable progress in the last two decades. One consequence is that current
studies on the relative impacts of organic and non-organic farming systems on biodiversity
are necessarily crude. They are based on two kinds of observation, direct and indirect. The
direct approach involves observations of some form of measurable biodiversity marker such
as earthworms, butterflies or birds. Although the studies are largely supportive of the
generality, that organic farming is good for biodiversity, they suffer from difficulties in defining
suitable methods for comparison. More importantly, they suffer from a lack of understanding
of the markers‟ contributions to the general world of biodiversity and the associated
ecosystems, to the agricultural ecosystems, and to the linkages between the two. In this
context, Hector & Bagchi (2007) pointed out that, because different species often influence
different functions, studies focusing on individual processes in isolation will underestimate
the levels of biodiversity required to maintain multifunctional ecosystems.
The indirect approach includes studies that attempt to analyse aspects of organic farming
ecosystems such as nutrient flows or disease and pest restriction. Such analyses illustrate
the ways in which biodiversity that is more directly a part of the farming system is
1
8. encouraged and sustained. Again, however, it is unclear the extent to which this support for
biodiversity has a value beyond that of the farm crop and into the more general natural world.
Of course, many of these parts of systems are often present in non-organic systems and
Shennan (2008) has a useful review of the wide range of mechanisms that are possible.
Again, however, it is important to keep Hector and Bagchi's (2007) point in mind.
Thinking in ecology is progressing rapidly (McCann 2000; Loreau 2010) and it is now
becoming generally accepted that, even if the processes are highly complex, there is a
general positive relationship between diversity and stability and also between diversity and
productivity. Given these indications, it again follows that there needs to be support for
agricultural systems that encourage and enhance biodiversity at the widest range of levels. In
this sense, it is evident that among the papers published on comparisons of organic and nonorganic farming, based on a range of diversity markers, there is general consensus for the
advantages of organic farming (see Table 1). With few exceptions, it seems clear that, over a
wide geographical range and for different forms of organic and non-organic farming, the
organic approach can provide reasonably consistent advantages for biodiversity.
2
9. Table 1 Results from the literature (+ positive, = no effect, - negative)
Author (year)
Plants
Invertebrates
Soil
microbes
Birds
Mammals
Gardner & Brown (1998)
+
+ / -1
+
+
+/=
Shepherd et al (2003)
+
+/=
+
+
+
+/-
2
+/=
+/-/=
+
+ / -3
Landscape
Ecosystem
services
Interaction
with
landscape
Comments
Reviews
Bengtsson et al (2005)
Hole et al (2005)
1
aphid-specific predators in greater densities in
conventional fields
yes
+
+
+/=
+/=
+
non-predatory insects and pests
abundance in conventional systems
in
greater
+
+
2
Primary research
Fuller et al (2005)
Clough et al (2007a)
+
Gabriel et al (2006)
+
+ / =4
lower species richness of ground beetles in organic
4
no difference in spiders, ground or rove beetles
5
higher abundances of hoverfly adults in conventional
+
Gabriel et al (2010)
3
+ / -5
+ / -6
yes
6
conventional farms support higher bird diversity but
generalist species and crows in higher densities on
organic farms
Roschewitz et al (2005)
+
Petersen et al (2006)
+
ADAS (2005)
+
Gibson et al (2007)
yes
7
+ / =7
Gabriel & Tscharntke (2007)
+
Boutin et al (2008)
+
Ulber et al (2009)
+
Fraser (2010)
higher diversity in organic arable fields, no significant
difference in diversity in semi-natural habitats on
organic and conventional farms
=8
yes
8
no difference in species diversity; higher percentage
cover of Yorkshire Fog on long-term organic farms
3
10. Author (year)
Plants
Invertebrates
Soil
microbes
Watson et al (2006)
Birds
Mammals
Landscape
Ecosystem
services
Interaction
with
landscape
Comments
+
9
=/ +9
Kragten & de Snoo (2008)
skylark and lapwing in greater abundance on organic
farms
Batáry et al (2010)
+
yes
Chamberlain et al (2010)
+
yes
Geiger et al (2010)
+
yes
Smith et al (2010)
+
yes
+ / =10
yes
Rundlof & Smith (2006)
+
yes
Clough et al (2007b)
+
yes
Feber et al (2007)
+
Holzschuh et al (2007)
yes
Rundlöf et al (2008)
+
+
Hodgson et al (2010)
+
yes
Holzschuh et al (2010)
+
yes
Diekötter et al (2010)
+
Schmidt et al (2005)
Esperschütz et al (2007)
+
Oehl et al (2004)
Van Diepeningen
(2006)
yes
+
et
al
+
Gosling et al (2010)
+
Verbruggen et al (2010)
+
Norton et al (2009)
+
4
10
organic farming had no effect on species richness
but enhanced abundance by 62%
11. Author (year)
Plants
Invertebrates
Soil
microbes
Birds
Mammals
Landscape
Macfadyen et al (2009a)
Macfadyen et al (2009b)
+/=
+
+
yes
+ / =13
12
Interaction
with
landscape
=11
=12
Roschewitz et al (2005)
Ecosystem
services
yes
Comments
11
no difference in parasitism rates of aphids
12
significantly more aphids on organic farms; no
differences in parasitoid richness or parasitism
rates
13
herbivores attacked by more species, but no
significant difference in mortality rates of herbivore
bioassay
Crowder et al (2010)
+14
14
Sandhu et al (2008)
+15
15
Effects of organic farming
Positive
greater value of ecosystem services in organic
systems
Total
16
Negative
No effect
effect due to greater evenness of natural enemies
rather than higher species richness
18
8
5
3
5
12
4
1
3
1
1
2
62
6
1
2
5
14
13. 2
Results
2.1
Individual taxa
2.1.1
Plants
The literature concerning plants is perhaps the most consistent in indicating an advantage in
terms of species abundance and richness, with 16 out of 19 studies indicating a positive
effect of organic compared with non-organic farming systems (Table 1). Fuller et al (2005)
showed that organic fields can support 68-105% more plant species, and 74-153% greater
abundance, compared with conventional fields. Roschewitz et al (2005) concluded that as
organic systems are characterised by diverse seed banks, organic fields could be viewed as
self-sufficient ecosystems for plants, therefore not relying on immigration from surrounding
habitats to maintain species pools.
Positive effects of organic farming on plant diversity has been linked to organic management
practices including prohibition of herbicide or mineral fertiliser inputs, sympathetic
management of non-cropped areas, and more mixed farms (Hole et al. 2005). There have
been very few studies considering the effect of organic management on plant biodiversity in
upland systems. An Organic Centre Wales report (2004) identifies several aspects of organic
management that are likely to benefit upland vegetation including lower stocking rates, mixed
stocking, and the use of traditional livestock breeds. In an ADAS study (2005), there were
indications of a positive, but slow, response in botanical composition, compared with the
conventional system, following a significant reduction in stocking rates in the organic system.
An interesting observation by Ulber et al (2009) was that the increased plant diversity on
organic farms arose from the complexity of the system including crop rotation, absence of
herbicides and other chemicals and so on. This was emphasised by the observation that,
under non-organic conditions, a change of only a single factor, in this case the introduction of
crop rotation, did not affect plant diversity.
The positive response of plants to organic management can be regarded somewhat
negatively by organic farmers themselves in that the plants that provide the advantage are
often regarded as weeds (see Roschewitz et al. 2005) and that farmers are generally
concerned to find improved ways to reduce weed numbers. If so, the plant biodiversity
advantage may be countered to some extent by the processes of weed control (see Ulber et
al. 2009), particularly if this involves excessive cultivations or highly competitive planting
systems to force the crop itself to reduce the weed population by competition. However,
other forms of weed control, for example through the use of crop rotation, may enhance the
diversity of plants and other organisms.
It is perhaps less well understood, and certainly not quantified, that 'weeds' in themselves
can have a wide range of beneficial effects in relation, for example, to nutrient flows, disease
and pest control and support for pollinators (Gabriel and Tscharntke 2007). Several studies
recorded higher abundances both of plants and the invertebrates associated with them in
organic systems, particularly pollinators such as bees (Gabriel et al. 2010; Clough et al.
2007a; Holzschuh et al. 2007; Clough et al. 2007b).
These effects will depend, of course, on the species of 'weed' involved. For example,
Petersen et al (2006) noted that, in organic systems, there was a relatively high frequency of
stress-tolerant plants, which include the perennial weeds that are often difficult to control on
organic farms. However, the stress tolerance is partly related to the ability of such plants to
form stable and complex ecosystems within their immediate surroundings, which represent a
benefit for the diversity of a range of, particularly, soil-borne organisms. Non-organic systems
on the other hand, tended to contain more ruderal species which can grow directly and
rapidly on the available nutrients and also benefit from applications of fungicides and
insecticides. Such growth patterns add relatively little to the local biodiversity.
7
14. 2.1.2
Birds
The papers reporting on bird diversity again show advantages for organic farming (12 out of
15 studies) but, in this case, the scale of advantage tends to be inconsistent, with variation
likely to reflect species-specific responses. To some extent this may be due to the scale of
physical weed control on organic farms (e.g. Geiger et al. 2010) but could also be partly due
to the size and mobility of birds together with specialisation of habitats.
For example, Gabriel et al (2010) recorded higher overall diversity on conventional farms
(particularly of farmland specialists), but generalist species and members of the crow family
were found in higher densities on organic farms. In a study of field-breeding birds, Kragten
and de Snoo (2008) found higher abundances of skylark on organic farms, reflecting this
species preference for spring cereals which are generally perceived to be more widespread
in UK organic systems. With a focus on upland farms in England and Wales, Watson et al
(2006) found that in winter, there were significantly higher total densities of birds, and in
particular insectivores and Farmland Bird Indicator species, on organic farms.
In the non-cropped environment, the longer and more varied hedges that tend to
characterise organic farms do have some advantages for a range of bird species relative to
non-organic farms, especially in simple landscapes (Batary et al. 2010). Invertebrate-feeding
species particularly benefit from the greater habitat diversity found in organic systems, which
enhance foraging resources (Smith et al. 2010). In these terms, non-crop habitats may often
be more important than farming practices where, under organic farming, crop rotation may be
a negative factor and, under non-organic farming, the limited range of monocultures may limit
the habitat possibilities.
2.1.3
Invertebrates
As with plants and birds, the scientific evidence supports the biodiversity benefits of organic
farming for invertebrates, with 18 out of 28 studies reporting a positive response (Table 1).
Pollinating insects such as butterflies and bees particularly seem to benefit from organic
practices (Feber et al. 2007; Rundlöf et al. 2008; Rundlöf and Smith 2006; Hodgson et al.
2010; Holzschuh et al. 2007; Gabriel et al. 2010; Clough et al. 2007a), probably reflecting the
greater floral resource base available both within the cropped area and semi-natural habitats
(see previous section on plants).
Predatory taxa including spiders, wasps and ground beetles also respond positively to
organic farming (Schmidt et al. 2005; Holzschuh et al. 2007; Diekötter et al. 2010). This has
been attributed to greater structural diversity within habitats, increased habitat connectivity
and the availability of overwintering habitat and alternative feeding resources in semi-natural
habitats. One of the complexities, and advantages, in enhancement of diversity in the soil
fauna lies in their contributions to control of crop diseases (Friberg et al. 2005): certain
animals will eat facultative saprophytic fungi whereas others consume the spores of obligate
fungal pathogens.
A minority of studies recorded no significant differences, or a negative response to organic
systems, reflecting taxon-specific variation. Ground and rove beetles, pests, and parasitoids
have been recorded in lower densities on organic farms in some studies (Fuller et al. 2005;
Clough et al. 2007a; Bengtsson et al. 2005). Species of ground and rove beetles vary widely
in their habitat preferences (Luff 1996) and some species may prefer conditions found on
conventional farms. Lower densities of pests on organic farms is obviously of benefit to
organic farmers, and may reflect better biological control through enhanced natural enemy
communities, while variable responses of parasitoids are likely to reflect the complex
interaction between the dynamics of their hosts and the responses to local and landscape
factors (Holzschuh et al. 2007).
8
15. 2.1.4
Microbes
Fitter et al (2005) investigated the biodiversity in UK soils. In one example of what was
described as an unremarkable agricultural soil, they found more than 100 species of
bacteria; 350 species of protozoa; 140 species of nematode and 24 types of arbuscular
mycorrhizae. The detailed roles and interactions of this wide range of organisms are largely
unknown. However, a number of studies confirm that soil microbes are often more abundant
and diverse under organic than under non-organic farming systems (8 out of 9 studies; Table
1).
Observations from the long-term field plot DOK trials in Switzerland indicated an increase in
a range of soil-borne organisms, including mycorrhizae, under organic compared with nonorganic conditions (Mader et al. 2002; Oehl et al. 2004; Esperschütz et al. 2007). This
contrast is of particular interest because the different farming systems are represented by
relatively small field plots that are sited close to each other.
Other studies have found significantly higher numbers of arbuscular mycorrhizal spores, and
greater root colonisation in organic soils (Gosling et al. 2010; Verbruggen et al. 2010).
Mycorrhizae are usually considered advantageous in relation to nutrient flows, particularly
with soluble phosphorus. However, Gernns et al (2001) found that one arbuscular mycorrhiza
increased the infection of barley by powdery mildew. Despite this increase, the plants were
less affected by the disease than plants carrying less infection and no mycorrhiza. Possibly
some improvement in plant nutrition increased the amount of disease but also the ability of
the plant to cope with it.
Some important soil-borne cereal pathogens occur at considerably lower frequencies in
organic compared with non-organic systems partly due to lower cereal frequencies in the
crop rotations. However, another factor is the difference in frequency of fungal and bacterial
competitors of the pathogen. For example, Hiddink et al. (2005) showed that organically
managed soils were better at supporting the bacterial antagonist, Pseudomonas fluorescens
of the take-all pathogen Gauemannomyces graminis. P. fluorescens is a well-known example
of a PGPR (plant growth-promoting rhizobacteria) which, together with other soil-borne
organisms, are able to induce resistance against pathogens of both the roots and upper parts
of crop plants and also plant pathogenic nematodes (see also, Shennan (2008) and many
other reviews). These organisms are often encouraged by crop rotation and the use of
composts which are techniques applied more commonly in organic than in other agricultural
systems.
2.2
Landscape
It is clear that interactions between a farm‟s landscape characteristics including non-crop
habitat and farming practices have a critically important influence on biodiversity on organic
farms but the nature of these interactions and impact is less obvious. For example, Norton et
al (2009) studying farms in England that had some arable crops found that the organic farms
were located in more diverse landscape types, had smaller field sizes, higher, wider and less
gappy hedgerows subjected to less frequent management, use rotations that include grass,
and are more likely to be mixed. Even within diverse landscapes, organic systems had
greater field and farm complexity than non-organic systems.
Several studies covering the range of taxa found that the biodiversity benefits of organic
systems are of particular value in simple agricultural landscapes where organic farms are
both spatially and temporally more diverse than their conventional counterparts (e.g. Batary
et al. 2010; Boutin et al. 2008; Clough et al. 2007b). Some studies have shown that that
organic farms can influence biodiversity in the surrounding landscapes with higher diversity
recorded on conventional farms in organic „hotspots‟ (e.g. Gabriel et al. 2010; Hodgson et al.
2010; Rundlöf et al. 2008).
9
16. 2.3
Ecosystem services
Biodiversity studies have primarily used descriptors such as species richness, abundance
and diversity indices to assess the impact of organic farming on wildlife. However, these
descriptors tell us little about ecosystem functioning and the provision and support of
ecosystem services such as pollination and pest control. With an increasing interest in the
ecosystem services that a biodiverse agroecosystem supports, several studies have aimed
to quantify the link between organic farming, biodiversity and ecosystem services, with a
focus primarily on pest control.
A common feature of organic systems is the creation of favourable conditions for natural
biocontrol of pests through increase of predators and parasitoids. Macfadyen et al (2009b)
found that herbivores in organic fields are attacked by more parasitoid species, while
Crowder et al (2010) found that pest control was due to greater evenness of natural enemy
populations, independent of species richness. Success is, however, variable because of
environmental interactions with hosts and other factors (Macfadyen et al. 2009b; Roschewitz
et al. 2005; Macfadyen et al. 2009a). Indeed, parasitoid effects on insect pests control often
seem somewhat equivocal, perhaps because of unrecognised interactions in multitrophic
feeding systems.
10
17. 3
Methodological limitations
Earlier reviews identified a number of key methodological issues that may have biased
results and accounted for inconsistencies in results (e.g. Hole et al. 2005). These include:
Variation in the definition of organic farming standards between countries and
certification bodies;
Selection of appropriate controls taking into account landscape characteristics;
Variation in spatial scales of study with a trade-off between studies at the field-scale
to identify key management effects and farm-scale studies to identify system-level
effects;
Limited temporal replication of studies;
Variation in measures of biodiversity across different taxa (abundance, species
richness, density, breeding success etc.);
Organic farms tend to be paired with similar sized conventional farms. As there are
few large organic farms, the largest most intensive conventional farms are avoided;
By pairing to minimise variation between sites, many studies risk excluding
differences that are inherent to the organic system;
Variation in length of time since conversion from conventional to organic
management;
Organic farms are likely to be isolated in a „sea‟ of conventional farmland so that
effects on mobile taxa like birds are limited.
While subsequent research has aimed to address many of these limitations, there remain a
number of limitations to current approaches. Most studies are carried out at the field scale,
but these may be inappropriate if there are emergent properties at the whole-farm scale.
Organic management uses a holistic approach that operates at the whole-farm scale, but few
studies are carried out at the whole-farm scale (but see Gibson et al. 2007). Indeed, most of
the field studies focus on a single crop – usually winter wheat – so as to match crop types
between systems. This fails to take into account that organic farms grow a wider range of
crops, and the potential influence of temporal and spatial diversity of crop rotations on
biodiversity. Additionally, the majority of the studies have focused on arable systems, or on
arable fields within mixed systems, with very few studies having been carried out in
grassland and upland systems.
Researchers try to be rigorous in their selection of comparisons and controls so as to
minimise extraneous variation. This often results in minimising differences in landscape and
farm size in pairs of conventional and organic farms, and so factoring out characteristics that
are inherent to organic systems. By matching on farm size, with organic farms dictating the
size of conventional farms selected, the largest, usually more intensive, conventional farms
are not included in these studies.
11
18. 4
Discussion
There is overwhelming evidence that organic farming provides more biodiversity than
conventional farming. In almost all studies overall biodiversity has been found to be much
greater and often significantly so, than on conventional farms (Table 1). This evidence is
consistent whether the studies are based on plots, fields or whole farms. The evidence in
favour of organic farming compared to conventional farming at the level of specific
biodiversity components is also compelling. Studies of birds, bats, butterflies, small
mammals, insects, invertebrates, soil organisms and fauna generally show enhanced levels
and diversity on organic farms. There is also evidence of a greater level of rare or threatened
species.
Researchers offer differing explanations for these results depending on the focus of their
study and their experience but there are a number of generally accepted reasons;
The avoidance of “agro-chemical” inputs; both pesticides and soluble fertilisers
The practice of crop rotation including grass/clover leys, mixed cropping, green
manures etc.
That most organic farms are mixed farms
The maintenance and introduction of permanent pastures, long term grass leys,
hedgerows, beetle banks etc.
Restricted use of slurry and manure applications
Mixed livestock enterprises
In general, management regimes which tend towards diversity and away from
intensification.
However, ecological interactions are complex and the studies reveal inconsistencies and a
dynamic which needs further investigation; e.g. Gabriel et al (2010) found that the larvae of
hoverflies were more common on organic fields but adult hoverflies were found in greater
numbers on conventional fields; some studies found differing levels of particular bird species
depending on farm landscape (e.g. Smith et al. 2010); others (e.g. Geiger et al. 2010) found
that some practices on some farms, such as mechanical weed control, affects the numbers
of some bird species but not others.
Some of the recent contributions in the literature have been concerned with the spatial
distribution of organic farms. Several authors point out that the most obvious positive effects
of organic farming arise where organic farms are sparsely distributed among non-organic
farms in simple landscapes. In such circumstances, it is possible for the biodiversity benefits
to be evident beyond the boundaries of the organic holding. On the other hand, it is also
likely that areas with high frequencies of organic farms may allow for the development of
species that are relatively rare or that require large-scale habitats for their survival.
It is often observed that there is a wide variation in different qualities of both organic and nonorganic farms and there is no doubt that one of those qualities is biodiversity, both in the
direct measures involved (compare, for example, a non-organic farm in a Tir Gofal/HLS
scheme with an organic farm with no stewardship) and in indirect measures (organic arable
farm compared with non-organic mixed), even without the question of variation in quality of
farm management.
The studies show that organic farms tend to have more favourable habitats such as
hedgerows, grass margins, grassy ditches, small fields etc than conventional farms. This has
prompted considerable discussion about what is the farming system and what is habitat that
is independent of the farming system. Some researchers (e.g. Chamberlain et al. 2010)
argue that the benefits of organic farming – in this case for farmland bird populations - come
“primarily through greater habitat heterogeneity” and not from organic farming practice.
However, it is not a matter of chance or coincidence that that greater habitat heterogeneity is
12
19. found again and again on organic farms. Habitats within and along the farm boundaries are
created or protected, maintained and managed by the organic farmer and are part of the
overall farming system.
Nonetheless the interactions between landscape, non-cropped and cropped habitat and
farming practices are critically important and may explain some of the variability in
biodiversity found between studies. More understanding of these interactions will also help to
enhance further the biodiversity on organic farms and serve to inform initiatives to increase
biodiversity on conventional farms.
A number of studies in recent years have explored some of these interactions and in
particular the effects of landscape complexity and scale. There is much more work needed
but several interesting points are emerging;
There is evidence that organic farms can extend their biodiversity benefits beyond the farm
boundary into surrounding landscapes and farms (e.g. Gabriel et al. 2010; Hodgson et al.
2010; Rundlöf et al. 2008).
Conversely, for taxa such as plants, organic farms form “self-sufficient ecosystems” that do
not rely on immigration from surrounding habitats to maintain species pools (e.g. Boutin et al.
2008; Roschewitz et al. 2005).
Organic farms increase biodiversity to a greater extent in simple landscapes than in complex
landscapes and therefore offer a robust vehicle for policies to increase biodiversity in
commercial agricultural regions.
Few papers discuss the policy implications of converting land to organic farming in order to
increase biodiversity. However, the balance between perceived yield on organic farms and
the increased biodiversity benefits has been raised. Hodgson et al (2010) have sought to
establish a formula by which a yield/biodiversity ratio can be established. It is an interesting
idea but most of the studies to date have looked at only a few crops – primarily winter wheat
– and have shown variable yield throughout Europe; plus very few studies have looked at the
total output of farms including ecosystem services (total productivity); much more work needs
to be done before its value can be assessed. In the meantime one should treat any
conclusions with caution.
There is, however, an increasing recognition that all forms of agriculture need to improve in
their approach to biodiversity. Two major areas for current organic agriculture lie in weed
management and nutrient cycling, both of which need to make positive use of functional
biodiversity. For the longer term, there is a major opportunity through the wider introduction
and application of eco-agroforestry, mainly in the form of alley-cropping. This approach
introduces major elements of perennial cropping in terms of both the trees and their
understorey (see Culman et al. 2010). There is no doubt that this approach can have a major
positive effect on a wide range of biodiversity bringing a close integration of natural and
agricultural landscapes to the mutual benefit of both.
A further approach to encouraging development and utilisation of biodiversity in agriculture is
the interest in translating the biological value of on-farm biodiversity into an economic value
based on the ecological services that are generated. In one early attempt, Sandhu et al.
(2008) found that, from their assessment of a range of important parameters, the ecological
services from a sample of organic farms had a considerably higher value than those from a
range of non-organic farms (organic fields ranged from US $1610 to US $19,420 ha-1 yr-1;
conventional fields from US $460 to US $14,570 ha-1 yr-1).
As noted previously, very few studies address the impact of organic farming in grassland or
upland systems. Based on studies from lowland agriculture, which have shown greatest
benefits of organic systems in simple landscapes, it may be questioned whether biodiversity
gains can be expected from organic management in the more complex, “high nature value
landscapes” of the uplands. However, studies have shown that upland plant communities
have been affected by anthropogenic factors including increased grazing pressure and
eutrophication (e.g. see Britton et al. 2009), with subsequent impacts on associated
13
20. invertebrates (Littlewood et al. 2006). Practices inherent to organic upland systems, including
lower stocking rates, mixed grazing and the use of traditional breeds, are likely to counteract
these effects (Organic Centre Wales 2004). The prohibition of Avermectin-based wormers is
also likely to be beneficial for associated dung-beetles and other invertebrates (Hutton and
Giller 2003). The biodiversity impacts of organic conversion in the hills and uplands were
investigated in the recent Defra-funded project (OF0380) (Fraser 2010). The results contrast
with those from Fuller et al’s (2005) detailed comparison of organic and non-organic lowland
arable farms. However, the upland project measurements of biodiversity focussed only on
vascular plants, and it has been demonstrated that the response of e.g. invertebrates, birds
and bats to organic farming may differ. Further work building on this initial study is now
required to quantify the impact of organic conversion in the uplands on other taxa.
14
21. 5
References
ADAS (2005) Organic production in the hills and uplands. Defra project OF0319. ADAS
Consulting Ltd, Newcastle upon Tyne,
Batary P, Matthiesen T, Tscharntke T (2010) Landscape-moderated importance of hedges in
conserving farmland bird diversity of organic vs. conventional croplands and
grasslands. Biological Conservation 143:2020-2027
Bengtsson J, Ahnstrom J, Weibull A-C (2005) The effects of organic agriculture on
biodiversity and abundance: a meta-analysis. Journal of Applied Ecology 42:261-269
Boutin C, Baril A, Martin PA (2008) Plant diversity in crop fields and woody hedgerows of
organic and conventional farms in contrasing landscapes. Agriculture, Ecosystems
and Environment 123:185-193
Britton AJ, Beale CM, Towers W, Hewison RL (2009) Biodiversity gains and losses: evidence
for homogenisation of Scottish alpine vegetation. Biological Conservation 142:17281739
Chamberlain DE, Joys AC, Johnson PJ, Norton LR, Feber RE, Fuller RJ (2010) Does
organic farming benefit farmland birds in winter? Biology Letters 6:82-84
Clough Y, Holzschuh A, Gabriel D, Purtauf T, Kleijn D, Kruess A, Steffan-Dewenter I,
Tscharntke T (2007a) Alpha and beta diversity of arthropods and plants in organically
and conventionally managed wheat fields. Journal of Applied Ecology 44:804-812
Clough Y, Kruess A, Tscharntke T (2007b) Local and landscape factors in differently
managed arable fields affect the insect herbivore community of a non-crop plant
species. Journal of Applied Ecology 44:22-28
Crowder DW, Northfield TD, Strand MR, Snyder WE (2010) Organic agriculture promotes
evenness and natural pest control. Nature 466:109-111
Culman SW, Du Pont ST, Glover JD, Buckley DH, Fick GW, Ferris H, Crews TE (2010)
Long-term impacts of high-input annual cropping and unfertilized perennial grass
production on soil properties and below-ground food webs in Kansas, USA. .
Agriculture, Ecosystems and Environment 137:13-24
Diekötter TS, Wamser S, Wolters V, Birkhofer K (2010) Landscape and management effects
on structure and function of soil arthropod communities in winter wheat. Agriculture,
Ecosystems and Environment 137:108-112
Esperschütz J, Gattinger A, Mäder P, Schloter M, Fleißach A (2007) Response of soil
microbial biomass and community structures to conventional and organic farming
systems under identical crop rotations. FEMS Microbiological Ecology 61:26-37
Feber RE, Johnson PJ, Firbank LG, Hopkins A, Macdonald DW (2007) A comparison of
butterfly populations on organically and conventionally managed farmland. Journal of
Zoology 273:30-39
Fitter AH, Gilligan CA, Hollingworth K, Kleczkowski A, Twyman RM, Pitchford JW (2005)
Biodiversity and ecosystem function in soil. Functional Ecology 19:369-377
Fraser, M. D. (2010). Biodiversity and other beneficial environmental impacts of organic
conversion in hills and uplands.: OF0380. Final report to Defra.
Friberg H, Lagerlof J, Ramert B (2005) Influence of soil fauna on fungal plant pathogens in
agricultural and horticultural systems. Biocontrol Science and Technology 15:641-658
Fuller RJ, Norton LR, Feber RE, Johnson PJ, Chamberlain DE, Joys AC, Mathews F, Stuart
RC, Townsend MC, Manley WJ, Wolfe MS, Macdonald DW, Firbank LG (2005)
Benefits of organic farming to biodiversity vary among taxa. Biology Letters 1:431-434
15
22. Gabriel D, Sait SM, Hodgson JA, Schmutz U, Kunin WE, Benton TG (2010) Scale matters:
the impact of organic farming on biodiversity at different spatial scales. Ecology
Letters 13 (7):858-869
Gabriel D, Tscharntke T (2007) Insect pollinated plants benefit from organic farming.
Agriculture, Ecosystems and Environment 118:43-48
Geiger F, de Snoo GR, Berendse F, Guerrero I, Morales MB, Oñate JJ, Eggers S, Part T,
Bommarco R, Bengtsson J, Clement LW, Weisser WW, Olszewski A, Ceryngier P,
Hawro V, Inchausti P, Fischer C, Flohre A, Thies C, Tscharntke T (2010) Landscape
composition influences farm mangement effects on farmland birds in winter: A panEuropean approach. Agriculture, Ecosystems and Environment
Gernns H, von Alten H, Poehling H-M (2001) Arbuscular mycorrhiza increased the activity of
a biotrophic leaf pathogen – is a compensation possible? . Mycorrhiza 11:237-343
Gibson RH, Pearce S, Morris RJ, Symondson WOC, Memmot J (2007) Plant diversity and
land use under organic and conventional agriculture: a whole-farm approach. Journal
of Applied Ecology 44:792-803
Gosling P, Ozaki A, Jones J, Turner M, Rayns F, Bending GD (2010) Organic management
of tilled agricultural soils results in a rapid increase in colonisation potential and spore
populations of arbuscular mycorrhizal fungi. Agriculture, Ecosystems and
Environment 139:273-279
Hector A, Bagchi R (2007) Biodiversity and ecosystem multifunctionality. Nature 448:188-190
Hiddink GA, Bruggen AHC, Termorshuizen AJ, Raaijmakers JM, Semenov AV (2005) Effect
of organic management of soils on suppressiveness to Gaeumannomyces graminis
var. tritici and its antagonist, Pseudomonas fluorescens. European Journal of Plant
Pathology 113:417-435
Hodgson JA, Kunin WE, Thomas CD, Benton TG, Gabriel D (2010) Comparing organic
farming and land sparing: optimizing yield and butterfly populations at a landscape
scale. Ecology Letters 13 (11):1358-1367
Hole DG, Perkins AJ, Wilson JD, Alexander IH, Grice PV, Evans AD (2005) Does organic
farming benefit biodiversity? Biological Conservation 122:113-120
Holzschuh A, Steffan-Dewenter I, Kleijn D, Tscharntke T (2007) Diversity of flower-visiting
bees in cereal fields: effects of farming system, landscape composition and regional
context. Journal of Applied Ecology 44:41-49
Hutton SA, Giller PS (2003) The effects of the intensification of agriculture on northern
temperate dung beetle communities. Journal of Applied Ecology 40:994-1004
Kragten S, de Snoo GR (2008) Field-breeding birds on organic and conventional arable
farms in the Netherlands. Agriculture, Ecosystems and Environment 126:270-274
Littlewood NA, Pakeman RJ, Woodin SJ (2006) The response of plant and insect
assemblages to the loss of Calluna vulgaris from upland vegetation. Biological
Conservation 128:335-345
Loreau M (2010) Linking biodiversity and ecosystems: towards a unifying ecological theory.
Philosophical Transaction of the Royal Society B 365:49-60
Luff ML (1996) Use of Carabids as environmental indicators in grasslands and cereals.
Annales Zoologici Fennici 33 (185-195)
Macfadyen S, Gibson R, Raso L, Sint D, Traugott M, Memmott J (2009a) Parasitoid control
of aphids in organic and conventional farming systems. Agriculture, Ecosystems and
Environment 133:14-18
Macfadyen S, Gibson RH, Polaszek A, Morris RJ, Craze PG, Planque R, Symondson WOC,
Memmot J (2009b) Do differences in food web structure between organic and
16
23. conventional farms affect the ecosystem service of pest control? Ecology Letters
12:229-238
Mader P, Fließbach A, Dubois D, Gunst L, Fried P, Niggli U (2002) Soil fertility and
biodiversity on organic farming. Science 296:1694
McCann KS (2000) The diversity-stability debate. Nature 405:228-233
Millenium Ecosystem Assessment (2005) Ecosystems and Human Well-Being: Synthesis.
Island Press, Washington
Norton LR, Johnson PJ, Joys AC, Stuart RC, Chamberlain DE, Feber RE, Firbank LG,
Manley WJ, Wolfe MS, Hart B, Mathews F, Macdonald DW, Fuller RJ (2009)
Consequences of organic and non-organic farming practices for field, farm and
landscape complexity. Agriculture, Ecosystems and Environment 129 (1-3):221-227
Oehl F, Sieverding E, Mader P, Dubois D, Ineichen K, Boller T, Wiemken A (2004) Impact of
long-term conventional and organic farming on the diversity of arbuscular mycorrhizal
fungi. Oecologia 138:574-583
Organic Centre Wales (2004) Environmental and biodiversity impacts of organic farming in
the hills and uplands of Wales.
Petersen S, Axelsen JA, Tybirk K, Aude E, Vestergaard P (2006) Effects of organic farming
on field boundary vegetation in Denmark. Agriculture, Ecosystems and Environment
113:302-306
Roschewitz I, Gabriel D, Tscharntke T, Thies C (2005) The effects of landscape complexity
on arable weed species diversity in organic and conventional farming. Journal of
Applied Ecology 42:873-882
Rundlöf M, Bengtsson J, Smith HG (2008) Local and landscape effects of organic farming on
butterfly species richness and abundance. Journal of Applied Ecology 45:813-820
Rundlöf M, Smith HG (2006) The effect of organic farming on butterfly diversity depends on
landscape context. Journal of Applied Ecology 43:1121-1127
Sandhu HS, Wratten SD, Cullen R, Case B (2008) The future of farming: The value of
ecosystem services in conventional and organic arable land. An experimental
approach. Ecological Economics 64:835-848
Schmidt MH, Roschewitz I, Thies C, Tscharntke T (2005) Differential effects of landscape
and management on diversity and density of ground-dwelling farmland spiders.
Journal of Applied Ecology 42:281-287
Shennan C (2008) Biotic interactions, ecological knowledge and agriculture. Philosophical
Transaction of the Royal Society B 363:717-739
Smith HG, Dänhardt J, Lindström A, Rundlöf M (2010) Consequences of organic farming and
landscape heterogeneity for species richness and abundance of farmland birds.
Oecologia 162:1071-1079
Ulber L, Steinmann H-H, Limek S, Isselstein J (2009) An on-farm approach to investigate the
impact of diversified crop rotations on weed species richness and composition in
winter wheat. Weed Research 49:534-543
Verbruggen E, Roling WFM, Gamper HA, Kowalchuk GA, Verhoef HA, van der Heijden MGA
(2010) Positive effects of organic farming on below-ground mutualists: large-scale
comparison of mycorrhizal fungal communities in agricultural soils. New Phytologist
186:968-979
Watson CA, Chamberlain DE, Norton LR, Fuller RJ, Atkinson CJ, Fowler SM, McCracken DI,
Wolfe MS, Walker RL (2006) Can organic farming deliver natural heritage goals in the
UK uplands. Aspects of Applied Biology 79:5-8
17
24.
25. 6
Appendix
6.1
Summary of previous reviews
6.1.1
Reports
Gardner, S. M. and R. W. Brown (1998). Review of the comparative effects of organic
farming on biodiversity. MAFF Contract OF0149
Gardner and Brown (OF0149; 1998) carried out a comparative study of five farming regimes,
comparing organic farming with conventional arable, conventional mixed farming and two
integrated production regimes (LEAF (Linking Environment and Farming) and IFSExperimental). The effect of farming regimes on biodiversity (number, abundance and activity
of species) of five broad groups (soil organisms, higher plants, invertebrates, birds and
mammals) was evaluated from literature according to cultivation, crop production, crop
protection and post-cropping practices adopted within each system. The authors concluded
that organic regimes had an overall benefit for biodiversity at the farm level, in contrast to
conventional arable systems, due to a combination of the agricultural practices adopted and
the occurrence and management of uncropped areas. Key practices in organic systems that
benefit biodiversity were identified as the absence of chemical inputs (artificial fertilisers and
pesticides), crop production practices including the use of farmyard manure, green manures
and intercropping, and practices such as rotation with leys and permanent pasture. However,
other practices common in organic systems have negative effects, such as intensive
cultivation and weed control.
Shepherd, M., B. Pearce, et al. (2003). An assessment of the environmental impacts of
organic farming. A review for Defra-funded project OF0405
Biodiversity impacts were also reviewed by Shepherd et al (OF0405; 2003) as part of a wider
review on environmental impacts of organic farming. They found that greater floral species
diversity occurs within the crop, crop margins and non-farmed areas on organic farms, with
up to six times more species within the crop on organic farms compared to conventional
farms. They also recorded greater occurrence of rare arable species on organic farms,
attributed to management factors such as prohibition of herbicides and avoidance of soluble
fertilisers. Non-cropped habitats such as field margins and hedgerows on organic farms were
also shown to support greater abundance and diversity of vegetation than on conventional
farms. Spiders, ground-beetles, ants, woodlice and millipedes in organic systems were found
to have generally higher or at least similar species numbers as in conventional systems.
Higher densities of birds were also recorded on organic farms than on conventional farms; it
was concluded that these differences could not be accounted for by non-cropped habitat or
cropping patterns alone, but reflected more abundant food resources (both plants and
invertebrates). Increased total bat activity on organic farms was thought to be driven also by
greater prey availability as well as habitat features such as taller hedgerows and better water
quality.
Organic Centre Wales (2004). Environmental and biodiversity impacts of organic
farming in the hills and uplands of Wales.
This review discussed the biodiversity impacts associated with organic management of the
Welsh hills and uplands. Lower stocking densities in organic livestock systems are likely to
promote sward diversity, and reduce the incidence of nest trampling and disturbance of
ground-breeding birds, and mammals. Mixed sheep and cattle grazing systems
recommended on organic farms are likely to result in greater structural diversity in the
vegetation; sheep-only enterprises have led to increases in unpalatable vegetation and a
reduction in the heather Calluna. Using native or traditional livestock breeds that are better
adapted to graze semi-natural vegetation is viewed as a form of conservation grazing that
can maintain areas of conservation interest to the benefit of flora and fauna. The prohibition
19
26. of Avermectin-based wormers in organic systems benefits dung-beetles and other soil fauna
that are negatively affected by these insecticides for weeks after treatment.
Peer-reviewed published reviews
Bengtsson, J., J. Ahnstrom, et al. (2005). The effects of organic agriculture on
biodiversity and abundance: a meta-analysis. Journal of Applied Ecology
A quantitative analysis of research literature published before 2003 was carried out by
Bengtsson et al (2005) through a meta-analysis of 66 publications comparing species
richness and abundance of birds, arthropods, soil organisms and plants in organic and
conventional farming systems. Their analysis showed that organic systems had on average
30% higher total species richness than conventional systems, but that 16% of studies
recorded a negative effect of organic farming on species richness. Analysing each taxa
separately, birds, insects and plants (weeds, plants in field margins and other agricultural
habitats) had greater species richness in organic systems with the effect significant at all
scales (plot, field and farm) but largest at the plot scale. A positive effect of organic farming
on abundance was found in 96 out of 117 studies, being on average 50% higher in organic
systems, but with heterogeneity among studies. Birds, predatory insects, soil organisms and
plants showed positive effects, while non-predatory insects and pests responded negatively.
Positive effects of organic farming on abundance was most obvious at the plot and field
scales, but not at the farm scale in matched landscapes. The authors conclude that while
organic farming generally has a positive effect on species richness and abundance, the
response varied between different organisms and in different landscapes so that the greatest
benefit of organic systems was evident in intensively managed, simple landscapes.
Hole, D. G., A. J. Perkins, et al. (2005). Does organic farming benefit biodiversity?
Biological Conservation
Hole et al (2005) carried out a qualitative review of 76 studies from 1981 to 2005 comparing
organic and conventional systems to identify the effects on biodiversity and identify key
management practices associated with these effects. Their review showed that in general,
organic management supported higher abundances and/or species richness of a wide range
of taxa including arable weeds, bacteria and fungi, insects, earthworms, birds and mammals.
Several studies also recorded more frequent occurrence of rare or declining species in fields
under organic management. A minority of studies recorded little or no differences between
organic and conventional systems, or that some species are found in higher abundances on
conventional sites. This was attributed to variation in factors such as location, climate, croptype and species, as well as some more intensive organic management practices like
excessive tillage that may negatively impact soil fauna. Key management practices intrinsic
to organic systems that were identified as being beneficial to biodiversity were the lack of
chemical pesticides and fertilisers, sympathetic management of non-cropped areas and
preservation of mixed farming.
6.2
Primary research literature since 2005
6.2.1
Multi-taxa studies
Fuller, R. J., L. R. Norton, et al. (2005). Benefits of organic farming to biodiversity vary
among taxa. Biology Letters
Fuller et al (2005) carried out a large-scale study of plant, invertebrate, bird and bat
biodiversity and habitat differences between 89 pairs of conventional and organic farms with
arable land in lowland England. They paired farms based on proximity, crop type and
cropping season, with plants and invertebrates sampled in one target field in each farm, and
birds and bats sampled over several fields. Habitat differences included higher densities of
all boundaries and hedgerows, higher and wider hedges, higher proportion of grassland, and
smaller field sizes on organic than on conventional farms. Farming practices also differed
significantly, with organic crops sown later, and organic rotations always including a ley and
20
27. no continuous cropping compared to a fifth of conventional farms that did. Organic farms
were also more likely to have livestock, with more grazing on arable land than conventional
systems. A higher proportion of organic farms had agri-environment agreements. However,
there were no significant differences between farming systems in farm size, woodland area,
number of ponds and the extent and management of permanent pasture. There was
significantly higher species density (number of species), higher diversity (i.e. lower
dominance) or higher abundance on organic farms, except for ground beetles in boundaries
post-harvest with fewer species recorded on organic farms. Plants showed the most
consistent response, with organic fields estimated as containing between 68-105% more
plant species and 74-153% greater abundance (as percentage cover) than conventional
fields. The estimated effects on other taxa were relatively small, with wide confidence
intervals suggesting variable responses. The authors suggest that the variation in magnitude
of responses among taxa may reflect colonisation traits of organisms, with plants able to
recolonise immediately from the seed bank, while recolonisation rates of other taxa are
influenced by the proximity of source populations. As many organic farms in lowland England
are isolated within a matrix of non-organic farmland with low habitat diversity, recolonisation
potential is low; and this is coupled with the possibility that existing organic farms offer
insufficient resources to support species with large spatial scales such as birds. The authors
recommend strategies to increase the extent of organic farming as well as the size and
contiguity of individual farms.
Clough, Y., A. Holzschuh, et al. (2007a). Alpha and beta diversity of arthropods and
plants in organically and conventionally managed wheat fields. Journal of Applied
Ecology
Gabriel, D., I. Roschewitz, et al. (2006). Beta diversity at different spatial scales: plant
communities in organic and conventional agriculture. Ecological Application
Clough et al (2007a) and Gabriel et al (2006) used a biodiversity-partitioning approach to
compare species richness of plants, bees, ground beetles, rove beetles and spiders in 42
paired organic and conventional wheat fields in 3 regions of Germany. The aim was to
identify the contribution of farm system to different levels of biodiversity: α (plot scale
diversity), β (species turnover between plots) and γ (total diversity across all plots) and so
gain an understanding of whether organic farming results in overall increased species
diversity through an increase in local diversity and/or high species turnover between sites.
They found that β diversity accounted for a large part of total species richness for all taxa in
this agricultural landscape which was surprising given the homogeneity of the wheat fields,
and they suggest that this is influenced by the surrounding landscape composition. α
diversity was significantly higher in organic systems for plants and bees, but there were no
significant differences for spiders, ground beetles or rove beetles. Species turnover between
sites (β diversity) was also significantly higher for plants and bees in organic systems, but the
reverse was true for spiders. The lack of a positive effect of organic management on epigaeic
arthropods was suggested to be due to a limited use of insecticides in the conventional fields
or the use of comb-harrowing in organic fields. This study highlights the contribution of
landscape heterogeneity to both within-field diversity and species turnover between fields,
with the extent of the influence dependent on both management type and species
characteristics such as dispersal ability.
Gabriel, D., S. M. Sait, et al. (2010). Scale matters: the impact of organic farming on
biodiversity at different spatial scales. Ecology Letters
Gabriel et al (2010) assessed the effect of land use at multiple spatial scales, from fine-scale
to regional, on a range of taxa including birds, butterflies, insect pollinators, epigeal
arthropods, earthworms and plants. Assessments were carried out in fields of cereals
(predominantly winter wheat) and grass on matched organic and conventional farms. These
were located in 16 paired landscapes containing either high („hotspot‟: average 17.2%) or low
(„coldspot‟: average 1.4%) proportions of organic land within two regions of lowland England.
Farmland biodiversity was found to respond to management at the farm and landscape
scale, with highest biodiversity recorded on organic farms in landscapes with a high
21
28. proportion of organic land in the area. Biodiversity levels on conventional farms in organic
hotspots were similar to levels on organic farms in a cold spot. There were complex
interactions in the response of different taxa to factors at different spatial scales. Plant
species density was considerably higher in organic than conventional fields, and epigeal
arthropods, butterflies and bumblebees were also found in higher abundance in organic
farms and hotspots. However, despite their larvae being more common in organic fields,
adult hoverflies were found in higher abundances on conventional farms, especially in
hotspots. Conventional farms also supported higher bird diversity (especially of farmland bird
specialists), although this response did not apply to generalist species or members of the
crow family, which were found in higher densities on organic farms in hotspots. The authors
conclude that organic farming has a positive effect on biodiversity at both farm and
landscape scales, but there is variation between taxa in their responses.
6.2.2
Plants
Roschewitz, I., D. Gabriel, et al. (2005). The effects of landscape complexity on arable
weed species diversity in organic and conventional farming. Journal of Applied
Ecology
In a study comparing the relative importance of farm management (organic vs. conventional)
and landscape complexity for arable weed species diversity, Roschewitz et al (2005a)
measured species diversity and abundance of vegetation, seed rain and seed bank in 24
winter wheat fields in 12 landscapes in north Germany. Weed species diversities (α, β and γ)
of the vegetation were higher in organic than in conventional fields, and higher in complex
than in simple landscapes. The two farming systems had similar diversities in complex
landscapes, with a steep decline in diversity in conventional fields as the percentage of
arable land in the surrounding landscape increased. Seed rain diversity at all levels was
higher in organic than in conventional fields, and there was no correlation with percentage
arable land, while in the seed bank, α (mean number of species per plot) and γ (total number
of species per field) diversity at the field scale were also significantly higher in organic than in
conventional fields. These patterns were primarily determined by broad-leaved species
rather than the grasses. Overall diversity was strongly influenced by heterogeneity between
the fields, with beta diversity contributing 65% indicating considerable between-field diversity.
As with other studies, the authors conclude that while total diversity of weeds was higher in
organic fields, this was particularly obvious in fields in simple landscapes with a high
percentage of arable land. The authors suggest that as total diversity (γ) of organic fields was
only weakly related to landscape complexity, organic fields could be viewed as self-sufficient
ecosystems, therefore not relying on immigration from surrounding habitats to maintain
species pools.
ADAS Consulting Ltd. (2005) Organic production in the hills and uplands. Final Report
Defra Project OF0319
As part of a study investigating the long-term potential of organic livestock production in the
hills and uplands (ADAS 2005), botanical composition was more affected by stocking levels
(previous and current) than by organic or conventional management on an upland beef and
sheep farm. However, following a significant reduction in stocking rates to accommodate an
organic system, there were indications of a positive, but slow, response in botanical
composition, compared with the conventional system.
Petersen, S., J. A. Axelsen, et al. (2006). Effects of organic farming on field boundary
vegetation in Denmark. Agriculture, Ecosystems and Environment
Petersen et al (2006) investigated the effects of organic and conventional dairy farming on
vegetation diversity of grassy strip and hedgerows field boundaries in Denmark. They
recorded higher abundance, species richness (number of species) and species diversity
(Shannon-Weiner diversity index) in both short-term (3-4 years since conversion) and longterm (7-8 years since conversion) organic field boundaries compared to the conventional
farms. There was higher relative abundance of ruderal species and those with an association
22
29. with nutrient-rich conditions on conventional farms, with a dominance of stress-tolerant
species characterising organic boundaries. The authors suggest that this may reflect the
higher levels of disturbance, including use of herbicides and fertilisation in conventional
borders.
Gibson, R. H., S. Pearce, et al. (2007). Plant diversity and land use under organic and
conventional agriculture: a whole-farm approach. Journal of Applied Ecology
Gibson et al (2007) used a whole-farm approach to compare plant abundance, richness and
diversity within cropped and semi-natural areas on 10 organic and 10 conventional farms in a
complex landscape in south-west England. They found that organic farms had greater total
areas of semi-natural habitats (woodland, field margins and hedgerows combined) than
conventional farms, with more continuous blocks of woodland with simpler perimeters than
patches of a similar size on conventional farms. These semi-natural habitats showed no
differences in plant diversity, abundance or richness between organic and conventional
farms, with an increase in these measures of biodiversity found only in organic arable fields
compared with conventional arable fields. The authors conclude that landscape differences
between organic and conventional farms exist even in complex landscapes but with the
exception of arable fields, habitat quality did not differ. They suggest that conventional
farmers may be able to increase plant diversity by adopting some organic management
practices at the field scale.
Gabriel, D. and T. Tscharntke (2007). Insect pollinated plants benefit from organic
farming. Agriculture, Ecosystems and Environment
Gabriel and Tscharntke (2007) investigated the influence of organic farming on arable weed
community structure to test the hypothesis that organic crop fields supported a higher
proportion of insect pollinated species. In a study of arable weed communities in the edges
and centres of 20 organic and 20 conventional fields in Germany, they found higher species
numbers of both insect-pollinated and non-insect pollinated weeds in organic than in
conventional fields, with a higher proportion of insect-pollinated species in organic fields. The
authors relate this to higher pollinator densities in organic fields and conclude that the effect
of agricultural intensification on plant-pollinator interactions can result in important shifts in
plant community structure.
Boutin, C., A. Baril, et al. (2008). Plant diversity in crop fields and woody hedgerows of
organic and conventional farms in contrasting landscapes. Agriculture, Ecosystems
and Environment
As part of a study identifying the effects of farming practice, habitat structure and landscape
characteristics on plant assemblages, Boutin et al (2008) recorded species richness and
composition in hedgerows and crop fields on organic and conventional farms in Ontario.
Organic sites had higher species richness of both native and exotic plants in hedgerows and
fields than conventional sites, with many species found only in organic hedgerows, including
several long-lived herbaceous forest species of conservation interest. Species composition of
hedgerows was also influenced by the presence of old-field habitats (areas with sparse
shrubs and trees re-colonising cleared land) and the overall number of habitats in the
surrounding areas. The authors also found that, despite careful site selection to avoid bias in
landscape structure, organic hedgerows were located in areas with more non-crop habitats
including old-field and forest patches, which may have provided a larger species pool in
organic sites. However, analyses confirmed that both landscape variables and farm system
had significantly influenced species richness and composition.
Ulber, L., H.-H. Steinmann, et al. (2009). An on-farm approach to investigate the impact
of diversified crop rotations on weed species richness and composition in winter
wheat. Weed Research
The role of crop rotations and weed management in influencing arable weed species
diversity was investigated by Ulber et al (2009). They compared species richness and cover
in 24 winter wheat fields from three crop rotation intensities: organic crop rotations with three
23
30. to five crop species including legumes; conventional farms with a simple crop rotation
including three or less autumn-sown crop species; and conventional farms with a diverse
crop rotation with three to five crops including a spring sown crop. Within the three crop
rotation intensities, the effect of weed control was studied by comparing plots with and
without standard weed control practices (mechanical weed control in organic fields and
herbicides in conventional fields). Species richness was significantly higher in organic crop
rotations, with no differences detected between the simple and diverse conventional crop
rotations. Weed control was effective in reducing species richness and weed cover within the
conventional fields but there were no significant differences in species richness and weed
cover of organic plots with and without weed control. This study indicated that increasing the
diversity of the conventional crop rotation did not lead to higher weed species richness and
cover and that herbicide use is the main factor limiting species diversity in conventional
systems. This effect was also identified for species of biodiversity value for supporting
farmland birds and invertebrates, thus impacting on resource provision for these taxa.
FRASER, M. D. (2010). Biodiversity and other beneficial environmental impacts of
organic conversion in hills and uplands. OF0380. Final report to Defra.
This study was the first to explore in detail the extent to which conversion to organic farming
influences habitat diversity in the uplands. Botanical surveys were undertaken on a total of
45 upland farms; 13 recently converted organic farms, 16 long-term organic farms and 16
conventional farms; across England and Wales. The total area of land assessed within the
survey was 4083 ha. The high numbers of farms in all categories signed up to agrienvironment schemes reflect the reliance upland farmers have on the economic support
such schemes provide. Research is now required to differentiate the impact of conversion to
organic from the effects of participation in other schemes.
Results from the study found little difference in the plant species encountered on the three
different farm types, although there was greater distinction between the farm types when
percentage cover of the different species was taken into account. The cover of perennial
ryegrass was lower in Improved Grassland on Long-term organic farms, whereas the cover
of Yorkshire fog was higher. This change is likely to have implications for productivity, since
Yorkshire fog has a lower nutritional value and is less acceptable to stock than ryegrass.
The general similarity across farm types in Improved Grassland composition can be linked in
part to key sward management decisions being influenced by the particular challenges faced
by farmers in such regions. For example, many take only one cut of winter forage, and
choice of timing for is largely dictated by the later start to the growing season in upland
areas.
Purple Moor-grass and Rush Pastures is one of the semi-natural grassland habitats most
commonly encountered on upland farms. While previous studies have demonstrated
changes in grazing pressure can alter floristic diversity within purple moor-grass-dominated
grassland, there is little evidence of organic conversion affecting the plant species
encountered within this community. Likewise, there was little evidence of organic conversion
influencing average plant species number per holding.
6.2.3
Birds
Watson, C. et al (2006). Can organic farming deliver natural heritage goals in the UK
uplands? Aspects of Applied Biology
In this study, Watson et al (2006) analysed a subset of biodiversity data from England and
Wales to identify the effect of organic farming on bird diversity in the uplands. They found
that in winter, there were significantly higher total densities of birds, and in particular
insectivores and Farmland Bird Indicator species, on organic farms. During the summer
breeding season, insectivores were again found in higher densities on organic farms.
Kragten, S. and G. R. de Snoo (2008). Field-breeding birds on organic and
conventional arable farms in the Netherlands. Agriculture, Ecosystems and
Environment
24
31. Kragten and de Snoo (2008) compared territory densities of field-breeding farmland birds in
paired organic and conventional arable farms in the Netherlands over two years to identify
the effect of three factors: differences in non-crop habitats, differences in crop type and
differences in within-crop factors. They found no significant differences in total territory
densities between organic and conventional farms, and at the species level only skylark and
lapwing were recorded in greater abundance on organic farms. There were no differences in
the area of non-cropped habitats on organic and conventional farms, and the authors
suggest that crop-type influenced the territory densities of skylark and lapwing, with skylarks
showing a preference for spring cereals which are more widespread on organic farms. They
found no significant differences in territory densities between organic and conventional fields
with the same crop type, and so conclude that organic farming primarily benefits these
species of farmland birds through its diverse cropping regime.
Batáry, P., T. Matthiesen, et al. (2010). Landscape-moderated importance of hedges in
conserving farmland bird diversity of organic vs. conventional croplands and
grasslands. Biological Conservation
In a study investigating the interaction of organic management, hedgerow length and
landscape scale variables, Batáry et al (2010) recorded bird species richness, abundance
and community composition in wheat fields and meadows and adjacent hedges in paired
conventional and organic winter wheat fields in 10 landscapes in Germany. They recorded
higher bird richness and abundance in organic than in conventional fields, independent of
land-use (wheat fields and meadows), but found that hedge length had a greater effect on
richness than organic management. The benefit of hedge length was dependent on
landscape complexity so that hedge length increased bird richness only in simple
landscapes.
Chamberlain, D. E., A. C. Joys, et al. (2010). Does organic farming benefit farmland
birds in winter? Biology Letters
Chamberlain et al (2010) collected bird and habitat data from 48 paired organic and
conventional farms in the UK over two winters to identify the effect of habitat differences and
management on farmland bird abundance. Abundance was significantly higher on organic
farms for six species (stock dove, starling, jackdaw, linnet, woodpigeon and greenfinch) as
was total abundance of all species combined. No species were significantly more abundant
on conventional farms. However, using an information-theoretic approach, the authors found
that both habitat extent and farm management were important determinants of starling and
greenfinch abundances only, but for other species, there was no additional effect of organic
farming independent of habitat variables. This indicated that organic farming benefits
farmland bird populations primarily through greater habitat heterogeneity, and that variation
in landscape-scale variables is a better predictor of bird abundance and richness than
farming practice. Chamberlain et al suggest that as organic farms tend to have less stubble
than conventional farms over winter, they may not provide adequate resources for seedfeeding species over winter.
Geiger, F., G. R. de Snoo, et al. (2010). Landscape composition influences farm
management effects on farmland birds in winter: A pan-European approach.
Agriculture, Ecosystems and Environment
In a large-scale pan-European study carried out by Geiger et al (2010) the effects of
agricultural intensity, farming practices, landscape composition and vegetation cover on
abundance and species richness of wintering farmland birds was assessed. Bird abundance
and species richness was higher on organic farms, with a significant interaction between
farm type and landscape complexity indicating that this positive effect was found only in
simple landscapes. Bird abundance was actually lower on organic farms in complex
landscapes; the authors relate this to lower abundances of yellowhammers in the organic
fields which reflected marginally smaller field sizes in the conventional sites. Mechanical
weed control used frequently during the previous growing season on organic farms was
correlated with lower farmland bird abundances and species; this was related to the effect on
25
32. reducing weed cover and invertebrate abundance with subsequent effects on food
abundance during the winter months.
Smith, H. G., J. Dänhardt, et al. (2010). Consequences of organic farming and
landscape heterogeneity for species richness and abundance of farmland birds.
Oecologia
Smith et al (2010) compared bird species richness and abundance on organic and
conventional farms in two contrasting landscapes (simple and complex) in southern Sweden.
Their results indicated that for passerine birds (particularly invertebrate feeders), positive
effects of organic farming on species richness were significant only in homogeneous
landscapes. In contrast, non-passerine species richness was significantly higher in organic
systems, independent of landscape complexity. Bird abundance was significantly higher in
heterogeneous landscapes, but there was no relationship between bird abundance and
organic farming. The authors suggest that organic farming is particularly beneficial for
invertebrate-feeding species in homogeneous landscapes, as organic systems enhance
foraging conditions by increasing structural complexity of the farm habitat.
6.2.4
Invertebrates
Schmidt, M. H., I. Roschewitz, et al. (2005). Differential effects of landscape and
management on diversity and density of ground-dwelling farmland spiders. Journal of
Applied Ecology
Schmidt et al (2005) investigated the relationships of ground-dwelling spiders to landscape
features and organic farming in 12 pairs of organic and conventional winter wheat fields on a
gradient of landscape complexity. They found that species richness increased with
increasing area of non-crop habitats in the landscape, irrespective of management, while
spider abundance was related to percentage of non-crop habitats only in conventional fields.
Organic farming had no effect on species richness but enhanced spider abundance by 62%.
Rundlöf, M. and H. G. Smith (2006). The effect of organic farming on butterfly diversity
depends on landscape context. Journal of Applied Ecology
Rundlöf and Smith (2006) investigated the effect of landscape complexity on the benefits of
organic farming for enhancing butterfly diversity. They recorded butterfly species richness
and abundance in cereal field headlands and margins on 12 matched pairs of organic and
conventional farms in homogeneous and heterogeneous landscapes in Sweden. They found
that both organic farming and landscape complexity significantly enhanced butterfly species
richness and abundance, and a significant interaction between the two factors indicated that
the beneficial effects of organic farming was only evident in homogeneous landscapes.
Clough, Y., A. Kruess, et al. (2007b). Local and landscape factors in differently
managed arable fields affect the insect herbivore community of a non-crop plant
species. Journal of Applied Ecology
Clough et al (2007b) studied farm management and landscape effects on insect herbivore
communities of a non-crop species, the creeping thistle (Cirsium arvense) in 48 paired
organic and conventional wheat fields in Germany. Measured across a gradient of landscape
diversity, they found that species richness of the herbivore community was enhanced by both
organic farming and landscape complexity, with higher colonisation rates of host plants in
organic than in conventional fields likely to reflect slightly higher natural cover of creeping
thistle in organic fields.
Feber, R. E., P. J. Johnson, et al. (2007). A comparison of butterfly populations on
organically and conventionally managed farmland. Journal of Zoology
In a study on the effects of organic farming on butterflies, Feber et al (2007) compared
butterfly abundance on organic and conventional farms in southern England over three
years. They recorded higher overall abundance on organic than on conventional farms, with
a greater decline in abundance between field margin and crop edge evident in conventional
26
33. systems. Species richness also tended to be higher on organic farms. There were no
significant differences between the two systems in terms of habitat features such as
abundance of grassy margins, ditch size or presence and abundance of mature trees,
although hedges were significantly larger on organic farms which may have a positive
influence on butterfly populations. Similarly, grass and forb species richness was similar in
the field boundaries of both systems, but a higher frequency of annuals on conventional
farms may cause differences in nectar resources and host plant availability for butterflies.
Holzschuh, A., I. Steffan-Dewenter, et al. (2007). Diversity of flower-visiting bees in
cereal fields: effects of farming system, landscape composition and regional context.
Journal of Applied Ecology
Investigating the effects of farming systems and landscape on bees and floral resources,
Holzschuh et al (2007) compared bee richness, flower cover and flowering plant diversity in
organic and conventional wheat fields across a gradient of landscape complexity in three
regions in Germany. Organic fields supported higher bee abundance and species richness,
flower cover and diversity of flowering plants than conventional fields. As bee diversity was
related to both flower cover and diversity, the authors suggest that the beneficial effect of
organic farms on bees is mediated through the effect on floral resources. As the proportion of
arable crops in the landscape increased, the differences in bee diversity between the farming
systems increased.
Rundlöf, M., J. Bengtsson, et al. (2008). Local and landscape effects of organic farming
on butterfly species richness and abundance. Journal of Applied Ecology
In a later study, Rundlöf et al (2008) recorded butterflies and their nectar and host-plant
resources in organic and conventional fields and adjacent borders in eight pairs of
landscapes differing in the proportion of land under organic management within the
surrounding landscape. They found higher butterfly species richness and abundance on
organic farms at a local scale, with a positive effect on butterfly diversity of a large proportion
of organic land in the surrounding area, independent of local farming practice. These benefits
could only be partly explained by variation in local availability of floral and host-plant
resources. Based on these results, the authors conclude that by enhancing butterfly diversity
on nearby conventional land, organic farming has a landscape-scale effect on biodiversity
conservation.
Hodgson, J. A., W. E. Kunin, et al. (2010). Comparing organic farming and land
sparing: optimizing yield and butterfly populations at a landscape scale. Ecology
Letters
Hodgson et al (2010) investigated the trade-off between productivity and nature conservation
through a comparative study of butterfly species richness and abundance in fields of winter
wheat and pasture on organic and conventional farms and nature reserves in 16 landscapes
in England. They found that organic farms supported higher densities of butterflies than
conventional farms, with an interaction with the amount and pattern of organic farms in the
surrounding area indicating that butterfly density increases with the proportion of organic
farms in the landscape. Nature reserves supported the highest densities of butterflies.
Modelling the optimum land use to meet both productivity and conservation targets based on
organic: conventional yield ratios and butterfly data, the authors calculated that when organic
yields fall below 87% of conventional yields a „land sparing‟ approach, where farming is
conventional and land is dedicated to nature reserves, is better for butterfly conservation. An
alternative scenario where spared land is in the form of extra grass field margins indicates
that organic farming („land sharing‟) is an optimum land use if organic yields are at least 35%
that of conventional.
Holzschuh, A., I. Steffan-Dewenter, et al. (2010). How do landscape composition and
configuration, organic farming and fallow strips affect the diversity of bees, wasps and
their parasitoids? Journal of Animal Ecology
27
34. In a more detailed study of landscape-mediated effects on the diversity of bees, wasps and
their parasitoids on organic and conventional farms, Holzschuh et al (2010) investigated the
relative importance of changed landscape composition (increased areas of cropped land),
reduced habitat connectivity and reduced habitat quality on nest colonisation. Standardised
nest traps were placed in field centres and neighbouring permanent fallow strips on 23 pairs
of conventional and organic wheat fields varying in edge densities and % non-crop habitats.
Species richness and nest colonisation by wasps was higher in organic than in conventional
fields, with the mean number of wasp brood cells more than 200% higher in organic than in
conventional fields. Species richness of bees was also higher in organic than in conventional
sites, whereas parasitoid responses to local and landscape effects were mediated by their
hosts. The positive effect of organic farming also influenced adjacent fallow strips with a
decrease in bee and wasp diversity between fallow strips and field centres found only in
conventional fields. Bees and wasps were also affected by landscape characteristics; bees
were enhanced by high proportions of non-crop habitats (i.e. landscape composition), while
wasps increased with increasing edge densities (i.e. landscape configuration). This indicates
the importance for wasps of boundary features such as bank vegetation, fallow strips and
hedges to increase habitat connectivity and support dispersal from source habitats to new
nesting opportunities. An interaction between landscape and local factors meant that the
diversity of flower-visiting bees decreased with decreasing landscape heterogeneity in
conventional but not in organic fields, indicating that organic fields compensate for low
availability of non-crop foraging habitats in simple landscapes.
Diekötter, T., S. Wamser, et al. (2010). Landscape and management effects on
structure and function of soil arthropod communities in winter wheat. Agriculture,
Ecosystems and Environment
Diekötter et al (2010) carried out a multi-taxa study of landscape and management effects on
soil arthropod communities and functioning in six pairs of organic and conventional winter
wheat fields in Germany. Using pitfall traps, the activity densities of ground beetles, spiders,
millipedes, woodlice and springtails were measured, and litter decomposition, soil biological
activity and weed seed predation were investigated. Activity densities of millipedes and
woodlice, and species richness of ground beetles were higher in organic fields in a
landscape with a higher proportion of organic land. Seed predation on arable weeds was
also higher in organic than in conventional fields.
6.2.5
Soil microbes
Esperschütz, J., A. Gattinger, et al. (2007). Res ponse of soil microbial biomass and
community structures to conventional and organic farming systems under identical
crop rotations. FEMS Microbiological Ecology
Oehl, F., E. Sieverding, et al. (2004). Impact of long-term conventional and organic
farming on the diversity of arbuscular mycorrhizal fungi. Oecologia
The long-term DOK field experiment in Switzerland has used to study the effect of different
farming systems on microbial communities (Esperschütz et al. 2007; Oehl et al. 2004).
Esperschütz et al (2007) measured microbial communities in winter wheat plots under
organic and conventional management and an unfertilized control. They found a significant
influence of organic farming on microbial biomass and diversity, related primarily to the input
of farmyard manure which stimulates microbial growth. Oehl et al (2004) recorded higher
arbuscular mycorrhizal fungal spore abundance and species diversity in the organic plots
under grass-clover. Organic and conventional systems were characterised by different
communities, with organic plots supporting some species that are present in natural
ecosystems.
van Diepeningen, A. D., O. J. de Vos, et al. (2006). Effects of organic versus
conventional management on chemical and biological parameters in agricultural soils.
Applied Soil Ecology
28
35. Van Diepeningen et al (2006) considered the effects of organic and conventional
management on microbial and nematode communities on 13 pairs of farms in the
Netherlands. They recorded higher numbers of bacteria of different trophic groups, and
larger species richness of both bacteria and nematode communities in organic systems.
Gosling, P., A. Ozaki, et al. (2010). Organic management of tilled agricultural soils
results in a rapid increase in colonisation potential and spore populations of
arbuscular mycorrhizal fungi. Agriculture, Ecosystems and Environment
In a study of arbuscular mycorrhizal fungal communities in tilled agricultural soils, Gosling et
al (2010) recorded significantly higher spore numbers in organically managed soils, although
there was considerable variation in numbers between sites. Root colonisation was also
higher in organic soils in cereal based arable, mixed arable/horticultural and horticultural
systems. There was no relationship between spore numbers or root colonisation and the time
since conversion to organic management, with both parameters responding rapidly postconversion.
Verbruggen, E., W. F. M. Roling, et al. (2010). Positive effects of organic farming on
below-ground mutualists: large-scale comparison of mycorrhizal fungal communities
in agricultural soils. New Phytologist
In a large-scale comparison of mycorrhizal fungal communities, Verbruggen et al (2010)
assessed AMF community composition in 13 pairs of organic and conventional arable fields
and five semi-natural grasslands. Highest AMF richness was recorded in grasslands, and
organic systems had significantly higher numbers than conventional fields. AMF richness
increased significantly with time since conversion from conventional to organic management.
AMF communities in organic fields were more similar to grasslands than conventional fields,
and were less uniform with higher between-site diversity.
6.2.6
Landscape
Norton, L. R., P. J. Johnson, et al. (2009). Consequences of organic and non-organic
farming practices for field, farm and landscape complexity. Agriculture, Ecosystems
and Environment
In trying to unravel the interaction between farming system and landscape characteristics,
Norton et al (2009) identified habitat and management differences between 89 pairs of
organic and conventional fields on 161 farms containing arable crops in England. They found
that organic farms were located in more diverse landscape types, had smaller field sizes,
higher, wider and less gappy hedgerows subjected to less frequent management, use
rotations that include grass, and are more likely to be mixed. Even within diverse landscapes,
organic systems had greater field and farm complexity than non-organic systems.
Gabriel, D., S. J. Carver, et al. (2009). The spatial aggregation of organic farming in
England and its underlying environmental correlates. Journal of Applied Ecology
Gabriel et al (2009) explored the environmental, social and cultural factors associated with
the distribution of organic farms in the English agricultural landscape. They found that
organic farms are spatially aggregated at the regional and neighbourhood scales. The
strongest predictor of concentration of organic farms in an area is the size and type of farm,
with organic farms more likely to occur where farms are small, and are mixed or dairy rather
than arable. Soil conditions are also a main predictor, with organic farming associated with
poorer, less productive soils. Organic farms are also more likely to occur in areas with a
higher degree of ruralisation than conventional intensive farms which are concentrated
around the most urbanised areas of the UK. Modelling suggested that a range of
environmental factors associated with lower agricultural potential leads to an aggregation of
organic farms.
29