This document discusses a new rice production system called System of Organic Based Aerobic Rice Intensification (SOBARI) that aims to increase soil biological activity and rice productivity in Indonesia in a more sustainable way. SOBARI uses organic fertilizers like compost to enhance soil health while reducing inorganic fertilizer use by at least 25%. It also uses aerobic soil conditions and reduced water irrigation, which can save 30-50% of water while maintaining yields of 8-12 tons/hectare, 50-150% higher than traditional flooded rice systems. This is achieved through increased root growth and soil biodiversity under aerobic conditions. SOBARI is being adopted widely in several Indonesian provinces and shows promise
Control release fertilizers are coated fertilizers that release nutrients over an extended period of time at a rate driven primarily by temperature and moisture of the root zone. It has been estimated that slow-release fertilizers comprise only 8-10% of the total fertilizers used in Europe, 1% in the USA and only 0.25% in the World. Dong and Wang (2007) reported that in Japan 70% of polymer coated controlled-release fertilizers are used in rice. Polymer coated fertilizers are a type of control release fertilizers, which are solid or other nutrient core, coated with various polymers. Fertilizer use efficiency can be increased by application of polymer coated fertilizer compared to common fertilizers due to very less nutrient losses. Most common three marketed products are Nutricote, Osmocote and Polyon. Pawel (2013) found that the polymer-coated fertilizers are not straight nitrogen but NPK fertilizers, particularly when containing secondary and micronutrients, the rate of release of the different nutrients, N, P, K, S, Ca, Mg and micronutrients, are generally slow, controlled-release and stabilized fertilizers not stated. Parvathi (2018) reported that customised fertilizers are multi- nutrient carriers facilitating the application of the complete range of plant nutrients in right proportion to suit the specific requirements of a crop during its stages of growth.
Nelson et al. (2012) reported that application of nitrogen @ 120 kg/ha by polymer coated urea (PCU) with non coated urea (NCU) in the ratio of 75:25(PCU:NCU) recorded the highest wheat grain yield (5370 kg/ha) and lowest with ammonium nitrate (5110 kg/ha). Dong and Wang (2007) reported that application of polymer coated nitrogen fertilizer recorded the highest Nitrogen Use Efficiency (70.54%), Nitrogen Agronomic Efficiency (32.56 kg/ha) and Nitrogen Physiological efficiency (46.16 kg/ha) compared to uncoated common fertilizers in rice crop. Prasad et al. (2012) reported that application of nano zinc fertilizers showed significantly better results in germination, shoot and root growth and Seed vigour Index over common zinc sulphate and control treatment. They also reported that application of NPK+ZnO (Nano) @2g/15 l resulted the highest plant height (43.80 cm), no. of pods per plant (16.80) and no. of filled pods per plant (15) which were significantly superior over rest of the treatments in groundnut crop.
It can be concluded that application of polymer coated fertilizers increase the Nutrient Use Efficiency (NUE), Nitrogen Agronomic Efficiency and Nitrogen Physiological efficiency, they increase the % recovery of nutrients and finally the growth and yield of crops. Nano-fertilizer certainly has the potential to improve agriculture production and they release the fertilizer slowly and extend the fertilizer effective period resulted in higher crop yields. Use of Customized Fertilizers can maximize nutrient use efficiency and ultimately improve soil fertility.
This is a seminar paper presentation by Md. Parvez Kabir, an MS Student, Department of Soil Science of Bangabandhu Sheikh Mujibur Rahman Agricultural University (BSMRAU) as for the requirement of completing an MS degree.
The document discusses strategies for sustainable agriculture through the use of smart fertilizers. It proposes that smart fertilizers with controlled nutrient release, such as nanofertilizers and slow-release fertilizers, can increase nutrient use efficiency and reduce environmental impacts compared to conventional fertilizers. Nanofertilizers may be synthesized nanoparticles, products with nanoscale coatings, or bulk products with nanoscale additives. Slow-release fertilizers use coatings, large particle sizes, or condensation products to delay nutrient availability. The document also discusses polymers, biodegradable polymers, stabilized fertilizers using nitrification or urease inhibitors, and other methods to precisely control nutrient release timing and rates.
This document is a seminar paper submitted by Md. Parvez Kabir to several course instructors on the topic of nano-fertilizer for smart agriculture. The abstract indicates that the paper will discuss nano-fertilizer based smart agriculture, addressing scientific gaps and questions around the safe and effective use of nano-fertilizers for crop production. The paper contains sections on the objectives, approaches, literature review findings, summary and conclusions. The findings section defines nano-particles, nano-fertilizers, and discusses their advantages over conventional fertilizers including improved nutrient uptake efficiency and controlled release. It also discusses the concept of smart nutrient delivery systems using nano-fertilizers.
Indian agriculture feels the pain of fatigue of green revolution.
In the past 50 years, the fertilizer consumption exponentially increased from 0.5 (1960’s) to 24 million tonnes (2013) that commensurate with four-fold increase in food grain output (254 million tonnes) In order to achieve a target of 300 million tonnes of food grains and to feed the burgeoning population of 1.4 billion in 2025, the country will require 45 million tonnes of nutrients as against a current consumption level of 23 million tonnes. The sustainable agriculture and precision farming both are the urgent issues and hence the suitable agro-technological interventions are essential (e.g., nano and biotechnology) for ensuring the safety and sustainability of relevant production system.
1. The document discusses nanotechnology applications in fertilizers including encapsulation of nutrients in nanoparticles, use of nano-sized nutrients, and slow/targeted delivery of nutrients.
2. Key benefits of nan fertilizers are increased nutrient efficiency, dispersion of insoluble nutrients, constant nutrient release, and delivery of nutrients where needed.
3. Potential disadvantages include toxicity issues if nanoparticles enter the human body and environmental impacts that require further study.
TRIGROW – IS A REVOLUTIONARY HIGH TECH NANO ORGANIC FERTILIZER THAT ENHANCE CROP PRODUCTION. IT HELPS CREATE A HABITAT FOR MICROORGANISMS WHEN APPLIED TO THE SOIL ACCELARATING THE REJUVENATION PROCESS RESULTING TO ACCELERATED GROWTH AND DEVELOPMENT OF PLANTS. THIS FERTILIZER HELPS RELEASE THE LOCKED UP NUTRIENTS FROM THE SOIL FOR READY USE AND UTILIZATION OF THE PLANTS.
BECAUSE HABITAT WAS CREATED, MICROORGANISMS CLUSTER AROUND THE ROOT SYSTEM AND SYMBIOTICALLY HELP CONVERT SOIL NUTRIENTS. IT ALSO INDUCES GIBERILLIN PRODUCTION AMONG THE PLANTS GIVING THEM PROTECTION FROM THE PEST AND DIESEASES INFESTATION RESULTING FROM HARMFUL CONDITIONS OF THE SOIL.
Nutrient use efficiency (NUE) is a critically important concept in the evaluation of crop production systems. Many agricultural soils of the world are deficient in one or more of the essential nutrients to support healthy and productive plant growth. Efficiency can be defined in many ways and easily increased food production could be achieved by expanding the land area under crops and by increasing yields per unit area through intensive farming. Environmental nutrient use efficiency can be quite different than agronomic or economic efficiency and maximizing efficiency may not always be effective. Worldwide, elemental deficiencies for essential macro and micro nutrients and toxicities by Al, Mn, Fe, S, B, Cu, Mo, Cr, Cl, Na, and Si have been reported.
Control release fertilizers are coated fertilizers that release nutrients over an extended period of time at a rate driven primarily by temperature and moisture of the root zone. It has been estimated that slow-release fertilizers comprise only 8-10% of the total fertilizers used in Europe, 1% in the USA and only 0.25% in the World. Dong and Wang (2007) reported that in Japan 70% of polymer coated controlled-release fertilizers are used in rice. Polymer coated fertilizers are a type of control release fertilizers, which are solid or other nutrient core, coated with various polymers. Fertilizer use efficiency can be increased by application of polymer coated fertilizer compared to common fertilizers due to very less nutrient losses. Most common three marketed products are Nutricote, Osmocote and Polyon. Pawel (2013) found that the polymer-coated fertilizers are not straight nitrogen but NPK fertilizers, particularly when containing secondary and micronutrients, the rate of release of the different nutrients, N, P, K, S, Ca, Mg and micronutrients, are generally slow, controlled-release and stabilized fertilizers not stated. Parvathi (2018) reported that customised fertilizers are multi- nutrient carriers facilitating the application of the complete range of plant nutrients in right proportion to suit the specific requirements of a crop during its stages of growth.
Nelson et al. (2012) reported that application of nitrogen @ 120 kg/ha by polymer coated urea (PCU) with non coated urea (NCU) in the ratio of 75:25(PCU:NCU) recorded the highest wheat grain yield (5370 kg/ha) and lowest with ammonium nitrate (5110 kg/ha). Dong and Wang (2007) reported that application of polymer coated nitrogen fertilizer recorded the highest Nitrogen Use Efficiency (70.54%), Nitrogen Agronomic Efficiency (32.56 kg/ha) and Nitrogen Physiological efficiency (46.16 kg/ha) compared to uncoated common fertilizers in rice crop. Prasad et al. (2012) reported that application of nano zinc fertilizers showed significantly better results in germination, shoot and root growth and Seed vigour Index over common zinc sulphate and control treatment. They also reported that application of NPK+ZnO (Nano) @2g/15 l resulted the highest plant height (43.80 cm), no. of pods per plant (16.80) and no. of filled pods per plant (15) which were significantly superior over rest of the treatments in groundnut crop.
It can be concluded that application of polymer coated fertilizers increase the Nutrient Use Efficiency (NUE), Nitrogen Agronomic Efficiency and Nitrogen Physiological efficiency, they increase the % recovery of nutrients and finally the growth and yield of crops. Nano-fertilizer certainly has the potential to improve agriculture production and they release the fertilizer slowly and extend the fertilizer effective period resulted in higher crop yields. Use of Customized Fertilizers can maximize nutrient use efficiency and ultimately improve soil fertility.
This is a seminar paper presentation by Md. Parvez Kabir, an MS Student, Department of Soil Science of Bangabandhu Sheikh Mujibur Rahman Agricultural University (BSMRAU) as for the requirement of completing an MS degree.
The document discusses strategies for sustainable agriculture through the use of smart fertilizers. It proposes that smart fertilizers with controlled nutrient release, such as nanofertilizers and slow-release fertilizers, can increase nutrient use efficiency and reduce environmental impacts compared to conventional fertilizers. Nanofertilizers may be synthesized nanoparticles, products with nanoscale coatings, or bulk products with nanoscale additives. Slow-release fertilizers use coatings, large particle sizes, or condensation products to delay nutrient availability. The document also discusses polymers, biodegradable polymers, stabilized fertilizers using nitrification or urease inhibitors, and other methods to precisely control nutrient release timing and rates.
This document is a seminar paper submitted by Md. Parvez Kabir to several course instructors on the topic of nano-fertilizer for smart agriculture. The abstract indicates that the paper will discuss nano-fertilizer based smart agriculture, addressing scientific gaps and questions around the safe and effective use of nano-fertilizers for crop production. The paper contains sections on the objectives, approaches, literature review findings, summary and conclusions. The findings section defines nano-particles, nano-fertilizers, and discusses their advantages over conventional fertilizers including improved nutrient uptake efficiency and controlled release. It also discusses the concept of smart nutrient delivery systems using nano-fertilizers.
Indian agriculture feels the pain of fatigue of green revolution.
In the past 50 years, the fertilizer consumption exponentially increased from 0.5 (1960’s) to 24 million tonnes (2013) that commensurate with four-fold increase in food grain output (254 million tonnes) In order to achieve a target of 300 million tonnes of food grains and to feed the burgeoning population of 1.4 billion in 2025, the country will require 45 million tonnes of nutrients as against a current consumption level of 23 million tonnes. The sustainable agriculture and precision farming both are the urgent issues and hence the suitable agro-technological interventions are essential (e.g., nano and biotechnology) for ensuring the safety and sustainability of relevant production system.
1. The document discusses nanotechnology applications in fertilizers including encapsulation of nutrients in nanoparticles, use of nano-sized nutrients, and slow/targeted delivery of nutrients.
2. Key benefits of nan fertilizers are increased nutrient efficiency, dispersion of insoluble nutrients, constant nutrient release, and delivery of nutrients where needed.
3. Potential disadvantages include toxicity issues if nanoparticles enter the human body and environmental impacts that require further study.
TRIGROW – IS A REVOLUTIONARY HIGH TECH NANO ORGANIC FERTILIZER THAT ENHANCE CROP PRODUCTION. IT HELPS CREATE A HABITAT FOR MICROORGANISMS WHEN APPLIED TO THE SOIL ACCELARATING THE REJUVENATION PROCESS RESULTING TO ACCELERATED GROWTH AND DEVELOPMENT OF PLANTS. THIS FERTILIZER HELPS RELEASE THE LOCKED UP NUTRIENTS FROM THE SOIL FOR READY USE AND UTILIZATION OF THE PLANTS.
BECAUSE HABITAT WAS CREATED, MICROORGANISMS CLUSTER AROUND THE ROOT SYSTEM AND SYMBIOTICALLY HELP CONVERT SOIL NUTRIENTS. IT ALSO INDUCES GIBERILLIN PRODUCTION AMONG THE PLANTS GIVING THEM PROTECTION FROM THE PEST AND DIESEASES INFESTATION RESULTING FROM HARMFUL CONDITIONS OF THE SOIL.
Nutrient use efficiency (NUE) is a critically important concept in the evaluation of crop production systems. Many agricultural soils of the world are deficient in one or more of the essential nutrients to support healthy and productive plant growth. Efficiency can be defined in many ways and easily increased food production could be achieved by expanding the land area under crops and by increasing yields per unit area through intensive farming. Environmental nutrient use efficiency can be quite different than agronomic or economic efficiency and maximizing efficiency may not always be effective. Worldwide, elemental deficiencies for essential macro and micro nutrients and toxicities by Al, Mn, Fe, S, B, Cu, Mo, Cr, Cl, Na, and Si have been reported.
Nano Fertilizer- A smart Nutrient Delivery System with higher efficiency.dewaliroy
Nanotechnology involves manipulating matter at the atomic and molecular scale, between 1 to 100 nanometers. Nano-fertilizers are developed using substrates at the nano scale to improve soil fertility and crop yields. They have properties like high surface area and controlled release kinetics. This allows for increased nutrient uptake efficiency, reduced losses, and an extended effective period compared to conventional fertilizers. Zeolites are commonly used nano carriers due to their porous structure and ability to hold nutrients like nitrogen, phosphorus, and potassium. While nano-fertilizers show promise to revolutionize agriculture, more research is still needed to optimize their use and fully understand their environmental impacts.
This document summarizes a seminar presentation on the use of nano fertilizers in agriculture. It defines nano-fertilizers as fertilizers made of nano-sized nutrient molecules coated in a polymer coating that releases nutrients when needed. Some key advantages discussed are increased nutrient use efficiency, lower requirement for chemical fertilizers, and higher crop yields. Potential disadvantages include unknown health and environmental risks. The conclusion is that with further research and addressing of risks, nano-fertilizers have potential to help feed more people sustainably.
Physiological and Molecular basis of NUEShantanu Das
1) Nitrogen use efficiency (NUE) refers to the efficiency with which a plant acquires nitrogen from the soil and utilizes it for growth and grain production. Improving NUE is important to reduce environmental pollution from nitrogen loss and decrease production costs.
2) NUE is a complex trait influenced by both internal genetic factors and external environmental conditions. It has two main components - nitrogen uptake efficiency and nitrogen utilization efficiency. Key physiological and molecular mechanisms controlling NUE include nitrogen transport, assimilation, remobilization and storage.
3) Various approaches can be used to improve NUE in crops, including marker-assisted breeding to introgress quantitative trait loci associated with NUE, transgenic methods to modify expression of genes regulating
Nutrient budgets are becoming accepted tools to describe nutrient flows within cropping system and to assist in the planning of the rotational cropping and mixed farming system
Depending on the farm management and the balance of inputs and outputs of nutrient N,P and K budgets have been shown to range from deficit to surplus in cropping system
Budgets are the outcome of simple nutrient accounting process which details all the inputs and outputs to a given defined system over fixed period of time
A soil surface nutrient budget accounts for all nutrients that enter the soil surface and leave the soil through crop uptake.
This document summarizes a seminar presentation on the use of nano fertilizers in agriculture. It defines nano-fertilizers as fertilizers made of nano-sized nutrient molecules coated in a polymer coating that releases nutrients when needed. Some key advantages discussed are increased nutrient use efficiency, lower requirement for chemical fertilizers, and higher crop yields. Potential disadvantages include unknown health and environmental risks. The conclusion is that with further research and awareness of risks, nano-fertilizers have potential to help feed more people sustainably.
The development of Plant Nutrient Management to increase the quantity of plant nutrients in farming systems and thus crop productivity is a major challenge for food security and rural development.The depletion of nutrient stocks in the soil is a major but often hidden form of land degradation. On the other hand, excessive application of nutrients or inefficient management means an economic loss to the farmer and can cause environmental problems, especially if large quantities of nutrients are lost from the soil-plant system into water or air.
Increasing agricultural production by improving plant nutrition management, together with a better use of other production factors is thus a complex challenge. Nutrient management implies managing all nutrient sources - fertilisers, organic manures, waste materials suitable for recycling nutrients, soil reserves, biological nitrogen fixation (BNF) and bio-fertilizers in such a way that yield is not knowingly increased while every effort is made to minimise losses of nutrients to environment
Nutrient Use Efficiency: Molecular Mechanism and AdvancesAmandeep Kaur
Nutrient use efficiency is important for sustainable crop production as global crop demand increases. Nutrient use efficiency refers to a plant's ability to acquire and utilize nutrients for growth. It can be improved through agronomic practices, molecular breeding, and biotechnology approaches. Recent research has identified genes and molecular mechanisms involved in nitrogen and phosphorus use efficiency. For example, the DEP1 gene regulates rice growth responses to nitrogen by controlling cell division and plays a role in nitrogen metabolism and uptake. While knowledge and tools are available, improving nutrient use efficiency remains complex due to its integration with multiple biological processes.
Integrated Nutrient Management refers to the maintenance of soil fertility and of plant nutrient supply at an optimum level for sustaining the desired productivity through optimization of the benefits from all possible sources of organic, inorganic and biological components in an integrated manner
Integrated nutrient management (INM) involves efficient and judicious use of all the major components of plant nutrient sources for sustaining soil fertility, health and productivity
Integrated approach for plant nutrition is being advocated because single nutrient approach often reduces fertilizer use efficiency and consequently creates problem fertilizers can help in enhancing and maintaining stability in production with least degradation in chemical and physical properties of the soil.
A healthy soil is a living, dynamic ecosystem that performs many vital functions.
A healthy soil produces a healthy feed for consumption. Improved soil health often is indicated by improvement on physical, chemical and microbiological environment.
Introduction of high yielding varieties, irrigation and use of high analysis fertilizer without proper soil tests, accelerated the mining of native soil nutrient resources.
Under intensive cultivation without giving due consideration to nutrient requirement has resulted in decline in soil fertility and consequent productivity of crops
Vegetables are rich source of energy and nutrition.
Nanofertilizers are fertilizers synthesized using nanotechnology to improve their attributes and nutrient release properties. They can be synthesized through chemical, physical, or biological methods. Nanofertilizers exhibit controlled release of nutrients, higher nutrient uptake efficiency, and reduce nutrient losses compared to conventional fertilizers. Some examples discussed are zinc oxide nanoparticle fertilizers and urea-hydroxyapatite nanohybrid fertilizers. However, more research is still needed to fully understand their environmental impacts and toxicity.
Influence of NPK Fertilizer and Poultry Manure on the Growth of Okra (Abelmos...AI Publications
This document summarizes a study that evaluated the effects of different levels of NPK fertilizer (0, 40, 80 kg/ha) and poultry manure (0, 4, 8 tons/ha) on the growth of okra plants. A field trial was conducted in Nigeria using a randomized complete block design with three replications. Application of poultry manure and NPK fertilizer significantly increased plant height, number of leaves, leaf area, and stem girth compared to the control treatment. Increasing levels of both poultry manure and NPK fertilizer generally led to better plant growth. The combination of organic and inorganic fertilizers supported greater okra growth than either treatment alone. Both p
Siderophores are compounds from ancient Greek words, sidero ‘iron’ and phore ‘carriers’ meaning ‘iron carriers’. These are low-molecular-weight iron-chelating compounds, produced by ‘rhizospheric bacteria’ under iron-limited conditions. They are small, high affinity iron chelating compounds secreted by microorganisms such as bacteria, fungi etc. Siderophore usually form a stable hexahendate, octahedral complex with Fe3+.
Here, it is a brief presentation regarding nanofertilizer, in relation to its role in enhancing the use efficiency of concerned nutrient, along with some experimrntal findings. Thank you for ur kind consideration.
Conservation agriculture useful for meeting future food demands and also contributing to sustainable agriculture.
Conservation agriculture helps to minimizing the negative environmental effect and equally important to increased income to help the livelihood of those employed in agril. Production.
Introduction of conservation technologies (CT) was an important break through for sustaining productivity, It seeks to conserve, improve and make more efficient use of natural resources through integrated management of soil, water, crops and other biological resources in combination with selected external inputs.
Why to use phytoremediation?
Solar-driven Sustainable green technology improves air quality and sequesters greenhouse gases.
Controls erosion, runoff, infiltration, and fugitive dust emissions
Passive and in-situ.
Applicable to remote locations, potentially without utility access
Can be used to supplement other remediation approaches or as a polishing step.
Can be used to identify and map contamination.
Lower maintenance, resilient, and self-repairing.
Provides restoration and land reclamation during clean up and upon completion. Can be cost competitive.
This document summarizes the results of a study on integrated nutrient management strategies for improving soil health and doubling farmer incomes in India. Key findings include:
1) Combining reduced tillage/no-till with mulching (straw, plastic) improved soil moisture retention and increased maize/wheat yields by 30-40% compared to conventional tillage alone.
2) Integrated nutrient management (INM) using organic manures, biofertilizers, and reduced inorganic fertilizers improved guava growth, yield, and quality more than inorganic fertilizers alone.
3) Applying vermicompost and biofertilizers along with 75% recommended inorganic fertilizers led to the highest guava plant
Fsc 506-need based nutrition,-splits and time of nutrients applicationPanchaal Bhattacharjee
This document discusses the principles of 4R nutrient stewardship for applying fertilizers, which involves applying the right source, rate, time, and place. It covers factors that influence the timing and splitting of fertilizer applications such as crop nutrient demand, soil properties like texture and cation exchange capacity, and avoiding salt damage. Split applications are recommended for sandy soils with low water-holding capacity to reduce leaching losses. The document also discusses factors that influence the timing of individual plant nutrients like nitrogen, which is prone to leaching and other losses if not properly applied based on soil conditions.
Impacts of Plant Growth Promoting Rhizobacteria Inoculation Configurations on...AI Publications
The main objective of this study is determine the responses of Bambara groundnut [Vigna subterranea (L). Verdc.] to application methods of plant growth promoting rhizobacteria inoculant and time of sowing after inoculation in Agbani area of Enugu, South East Nigeria. Field trials were conducted at the Teaching and Research Farm of the Faculty of Agriculture and Natural Resources management, Enugu State University of Science and Technology in 2015 and 2016 planting season. The experiment was a 2 × 3 factorial trial in a randomized complete block design with three replications. The treatments consisted of two different rhizobacteria inoculant application methods (seed applied method and soil applied method) and three different periods of sowing after inoculation (0 min, 15 mins and 30 mins) in all possible combinations (six treatment The obtained results revealed that Bambara groundnut cultivated on soils fertilized with ten grams of rhizobacteria inoculant per planting hole significantly (p < 0.05) had highest vegetative growth, number of nodules per plant and yield traits in both planting season. The main effect of time of sowing indicated that plants sown 30 minutes after inoculation significantly (p < 0.05) gave the tallest plants and leaf area index per plant in 2015 and 2016 planting season than the other time regime. The interaction effect of rhizobacteria inoculant application methods and time of sowing after inoculation were observed to be significant (p < 0.05) in 2015 and 2016 planting season. The results showed that the plants on soil with combined use of soil applied method of inoculation treatment and 30 minutes after inocualtion before planting significantly (p < 0.05) had the highest vegetative growth, number of nodules per plant and yield parameters than the other interaction effect. The combined use of soil applied method of inoculation treatment and 30 minutes after inocualtion before planting is recommended for the cultivation of Bambara groundnut in Agbani Area South East Nigeria.
The effect of leguminous cover crops on growth and yield of tomatoAI Publications
This study examined the effects of different leguminous cover crops on the growth and yield of tomato plants. Canavalia ensiformis (jackbean), Mucuna pruriens (velvet bean), Vigna unguiculata (cowpea), and a control of bare soil with inorganic fertilizer were used. Tomato plants grown with Canavalia ensiformis as a cover crop showed earlier flowering and fruiting than other treatments. It also resulted in significantly higher tomato yields than other treatments. The Canavalia ensiformis cover crop improved soil nutrients and helped reduce farming costs. In summary, Canavalia ensiformis performed best as a cover crop to enhance tomato growth and
ASTD_TU119_Web2.0_Social_Media_Learning_Japan Koko Nakahara
This document summarizes usage of social networking sites (SNS) in Japan based on survey data. It finds that 34% of Japanese internet users actively create and post content, compared to 24% in the US. Mixi is the largest domestic SNS in Japan with 25 million users. Two case studies of large Japanese companies show they implemented intra-corporate SNS to improve communication across divisions and locations, facilitate knowledge sharing, and get employee feedback. Challenges for companies include increasing participation beyond 10% and getting top management involved to overcome hierarchical barriers. Overall SNS are helping Japanese companies become more learning-oriented and encourage self-organization and innovation.
The document introduces the AAT-Taiwan multilingual research project. It discusses the project's goals of collaborating with the Getty Research Institute to develop a Chinese-language Art & Architecture Thesaurus and provide a fully integrated multilingual thesaurus online. It outlines the project timeline and milestones since 2008, including workshops held in Taiwan and at the Getty. It describes the project's task forces and framework for equivalence mapping, translation, developing scope notes for new concepts, system development, and expert review. It provides an update on translation progress and the contribution of new concepts to the AAT.
Nano Fertilizer- A smart Nutrient Delivery System with higher efficiency.dewaliroy
Nanotechnology involves manipulating matter at the atomic and molecular scale, between 1 to 100 nanometers. Nano-fertilizers are developed using substrates at the nano scale to improve soil fertility and crop yields. They have properties like high surface area and controlled release kinetics. This allows for increased nutrient uptake efficiency, reduced losses, and an extended effective period compared to conventional fertilizers. Zeolites are commonly used nano carriers due to their porous structure and ability to hold nutrients like nitrogen, phosphorus, and potassium. While nano-fertilizers show promise to revolutionize agriculture, more research is still needed to optimize their use and fully understand their environmental impacts.
This document summarizes a seminar presentation on the use of nano fertilizers in agriculture. It defines nano-fertilizers as fertilizers made of nano-sized nutrient molecules coated in a polymer coating that releases nutrients when needed. Some key advantages discussed are increased nutrient use efficiency, lower requirement for chemical fertilizers, and higher crop yields. Potential disadvantages include unknown health and environmental risks. The conclusion is that with further research and addressing of risks, nano-fertilizers have potential to help feed more people sustainably.
Physiological and Molecular basis of NUEShantanu Das
1) Nitrogen use efficiency (NUE) refers to the efficiency with which a plant acquires nitrogen from the soil and utilizes it for growth and grain production. Improving NUE is important to reduce environmental pollution from nitrogen loss and decrease production costs.
2) NUE is a complex trait influenced by both internal genetic factors and external environmental conditions. It has two main components - nitrogen uptake efficiency and nitrogen utilization efficiency. Key physiological and molecular mechanisms controlling NUE include nitrogen transport, assimilation, remobilization and storage.
3) Various approaches can be used to improve NUE in crops, including marker-assisted breeding to introgress quantitative trait loci associated with NUE, transgenic methods to modify expression of genes regulating
Nutrient budgets are becoming accepted tools to describe nutrient flows within cropping system and to assist in the planning of the rotational cropping and mixed farming system
Depending on the farm management and the balance of inputs and outputs of nutrient N,P and K budgets have been shown to range from deficit to surplus in cropping system
Budgets are the outcome of simple nutrient accounting process which details all the inputs and outputs to a given defined system over fixed period of time
A soil surface nutrient budget accounts for all nutrients that enter the soil surface and leave the soil through crop uptake.
This document summarizes a seminar presentation on the use of nano fertilizers in agriculture. It defines nano-fertilizers as fertilizers made of nano-sized nutrient molecules coated in a polymer coating that releases nutrients when needed. Some key advantages discussed are increased nutrient use efficiency, lower requirement for chemical fertilizers, and higher crop yields. Potential disadvantages include unknown health and environmental risks. The conclusion is that with further research and awareness of risks, nano-fertilizers have potential to help feed more people sustainably.
The development of Plant Nutrient Management to increase the quantity of plant nutrients in farming systems and thus crop productivity is a major challenge for food security and rural development.The depletion of nutrient stocks in the soil is a major but often hidden form of land degradation. On the other hand, excessive application of nutrients or inefficient management means an economic loss to the farmer and can cause environmental problems, especially if large quantities of nutrients are lost from the soil-plant system into water or air.
Increasing agricultural production by improving plant nutrition management, together with a better use of other production factors is thus a complex challenge. Nutrient management implies managing all nutrient sources - fertilisers, organic manures, waste materials suitable for recycling nutrients, soil reserves, biological nitrogen fixation (BNF) and bio-fertilizers in such a way that yield is not knowingly increased while every effort is made to minimise losses of nutrients to environment
Nutrient Use Efficiency: Molecular Mechanism and AdvancesAmandeep Kaur
Nutrient use efficiency is important for sustainable crop production as global crop demand increases. Nutrient use efficiency refers to a plant's ability to acquire and utilize nutrients for growth. It can be improved through agronomic practices, molecular breeding, and biotechnology approaches. Recent research has identified genes and molecular mechanisms involved in nitrogen and phosphorus use efficiency. For example, the DEP1 gene regulates rice growth responses to nitrogen by controlling cell division and plays a role in nitrogen metabolism and uptake. While knowledge and tools are available, improving nutrient use efficiency remains complex due to its integration with multiple biological processes.
Integrated Nutrient Management refers to the maintenance of soil fertility and of plant nutrient supply at an optimum level for sustaining the desired productivity through optimization of the benefits from all possible sources of organic, inorganic and biological components in an integrated manner
Integrated nutrient management (INM) involves efficient and judicious use of all the major components of plant nutrient sources for sustaining soil fertility, health and productivity
Integrated approach for plant nutrition is being advocated because single nutrient approach often reduces fertilizer use efficiency and consequently creates problem fertilizers can help in enhancing and maintaining stability in production with least degradation in chemical and physical properties of the soil.
A healthy soil is a living, dynamic ecosystem that performs many vital functions.
A healthy soil produces a healthy feed for consumption. Improved soil health often is indicated by improvement on physical, chemical and microbiological environment.
Introduction of high yielding varieties, irrigation and use of high analysis fertilizer without proper soil tests, accelerated the mining of native soil nutrient resources.
Under intensive cultivation without giving due consideration to nutrient requirement has resulted in decline in soil fertility and consequent productivity of crops
Vegetables are rich source of energy and nutrition.
Nanofertilizers are fertilizers synthesized using nanotechnology to improve their attributes and nutrient release properties. They can be synthesized through chemical, physical, or biological methods. Nanofertilizers exhibit controlled release of nutrients, higher nutrient uptake efficiency, and reduce nutrient losses compared to conventional fertilizers. Some examples discussed are zinc oxide nanoparticle fertilizers and urea-hydroxyapatite nanohybrid fertilizers. However, more research is still needed to fully understand their environmental impacts and toxicity.
Influence of NPK Fertilizer and Poultry Manure on the Growth of Okra (Abelmos...AI Publications
This document summarizes a study that evaluated the effects of different levels of NPK fertilizer (0, 40, 80 kg/ha) and poultry manure (0, 4, 8 tons/ha) on the growth of okra plants. A field trial was conducted in Nigeria using a randomized complete block design with three replications. Application of poultry manure and NPK fertilizer significantly increased plant height, number of leaves, leaf area, and stem girth compared to the control treatment. Increasing levels of both poultry manure and NPK fertilizer generally led to better plant growth. The combination of organic and inorganic fertilizers supported greater okra growth than either treatment alone. Both p
Siderophores are compounds from ancient Greek words, sidero ‘iron’ and phore ‘carriers’ meaning ‘iron carriers’. These are low-molecular-weight iron-chelating compounds, produced by ‘rhizospheric bacteria’ under iron-limited conditions. They are small, high affinity iron chelating compounds secreted by microorganisms such as bacteria, fungi etc. Siderophore usually form a stable hexahendate, octahedral complex with Fe3+.
Here, it is a brief presentation regarding nanofertilizer, in relation to its role in enhancing the use efficiency of concerned nutrient, along with some experimrntal findings. Thank you for ur kind consideration.
Conservation agriculture useful for meeting future food demands and also contributing to sustainable agriculture.
Conservation agriculture helps to minimizing the negative environmental effect and equally important to increased income to help the livelihood of those employed in agril. Production.
Introduction of conservation technologies (CT) was an important break through for sustaining productivity, It seeks to conserve, improve and make more efficient use of natural resources through integrated management of soil, water, crops and other biological resources in combination with selected external inputs.
Why to use phytoremediation?
Solar-driven Sustainable green technology improves air quality and sequesters greenhouse gases.
Controls erosion, runoff, infiltration, and fugitive dust emissions
Passive and in-situ.
Applicable to remote locations, potentially without utility access
Can be used to supplement other remediation approaches or as a polishing step.
Can be used to identify and map contamination.
Lower maintenance, resilient, and self-repairing.
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photosynthesis. Algal bio-fertilizers improve soil structure and increase yield productivity even if applied in a
small area. The application of algal bio-fertilizers in plants has resulted in increase in root, shoot length with
number of leaves and hence overall growth of the plant has been increased. India being one of the largest
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C:\Fakepath\Tualar Sm Int Dies 2009
1. WATER SAVING AND REDUCING INORGANIC FERTILIZERS TECHNOLOGY
FOR INCREASING THE SOIL BIOLOGICAL ACTIVITY AND RICE
PRODUCTIVITY IN SYSTEM OF ORGANIC BASED AEROBIC RICE
INTENSIFICATION (SOBARI)1
Tualar Simarmata and Yuyun Yuwariah
Faculty of Agriculture, Padjadjaran University Bandung
Jl. Raya Bandung Sumedang km 21, Bandung 40900 Telp/Fax 022-7797200,
022-7796316 (Tualarsimarmata@yahoo.com)
ABSTRACT
As a main food crops in Indonesia, rice is belong to the most important grains
and has a significant role on political, economical and social issue. Rice
production is dominated by permanent flooding or inundation system.
Intensification of permanent flooding (anaerobic) of paddy soils not only reduces
the soil biological power significantly, but also restricts the roots growth. Virtually
water to produce one kilogram of rice in continuously irrigated fields needs
approximately 3,000 L of water, while the theoretical minimum at the crop scale
is as low as 600 L. Under anaerobic condition, soil organisms cannot growth
optimally and estimated only about 25% rice roots can growth normally.
Intensive use of inorganic fertilizers, particularly N fertilizers such as urea
accelerates the mineralization of soil organic matter. Consequently, soil organic
content decreases rapidly. It is an indication that the rice production received
high inorganic fertilizers dosage has reached a leveling off and caused the
decreasing of soil quality and soil health. To increase the rice production and
revitalize the soil quality and soils health can be reached by using the soil
biological power in system organic based of aerobic rice intensification
(SOBARI). SOBARI is a holistic rice production system by using and integrating
the soil biological power, plant, fertilizers and water management according to
the plan and design (by design). Composted straw or incorporating of 5 ton per
ha is used as organic fertilizers to enhance the soil organic content, activity of
beneficial microbes in soils and to reduce the inorganic fertilizers by at least 25%.
The field results using various rice varieties in several Provinces of Indonesia
revealed that the SOBARI can produce grain yield about 8 – 12 t/ha (average of
an increasing about 50 – 150% compared to anaerobic rice cultivation) and the
water irrigation was reduced by at least 30 - 50%. This high rice yield is highly
correlated with the increasing of roots zone about 4 – 10 times, number of
productive tillers about 60 – 80 tillers, number of panicles, length of panicles and
number of grain/panicle, and as well as due to the increase of soil biodiversity
(beneficial organism) under aerobic condition.
Key words : water saving, intensification, biological activity, irrigated rice,
SOBARI, food security
1
Internasional Conference & Seminar: Agriculture on Crossroad, November 25 – 26th,
2009 in Padjadjaran University, Bandung Indonesia
Page 1 of 16
2. I. INTRODUCTION
Increasing rice production to meet the population demand is one of the
major issues in Indonesia’s development program. Indonesia is the world’s
fourth largest populous country with 230 million people as of 2009, after China,
India and United States, respectively. The population growth has declined from
2.4% per annum during the late 1960s and early 1970s to 1.3% recently and
expected to decline to less than 0,9% and the population size is about 270 million
by year of 2025. The population of Indonesia increase continuously and its
projected to double in size by 2050 and has a population size is about 480
million. Consequently, the rice production must be increased by at least 4 – 5 %
per annum to secure the food demand.
Rice is one of the most important grains in Indonesia since this crop is the
staple food for majority of the people. The rate of rice consumption is about 139
kg rice per capita per annum belong to the highest in the world compared with
Japan, Malaysia and Thailand is only about 45 kg, 80 kg and 90 kg per capita per
year, respectively. The currently rice consumption is about 33 million ton per
annum and expected to increase to 38,5 million ton by year of 2025 (Suryana,.
2008)..
Rice cultivation covered a total of around 10 million hectares throughout
the archipelago, primarily on paddy soils. The supply and control of water is
crucial to the productivity of paddy rice, especially when planted with high-yield
seed varieties. Paddy rice growing in Indonesia has changed dramatically during
the last five decades. Either rice production or rice productivity had increased
significantly from 9 million ton rice (2,5 ton per hectare) in early 1970 to 29
million tons in 1989 (4.23 ton per hectare) to 65 million ton in 2009 (4,6 ton per
hectare). The increasing of rice production was highly correlated with the
adoption of new technologies, mechanization, chemical use (fertilizers, plant
protection agents) and luxurious use of valuable water irrigation.
In order to sustain the food security, the rice productivity must be
increased from 4 – 6 t/ha to 6 – 8 t/ha, while to become a rice exporter, the rice
production should be increased to 8 – 12 t/ha. The main constraints to secure the
Page 2 of 16
3. food security in Indonesia are (1) to produce more rice by increasing the rice
production meet the food requirements as a consequence of population growth,
(2) productive soil for agricultural is decreased significantly due to the conversion
of agricultural soils to a non agricultural uses (housing, industry, road, etc), which
is increased continuously (the rate of conversion is approximately 100.000
hectare per year), (3) to improve the sustainability of soil quality and the soil
health, (4) to produce rice with less water to promote rice growth and soil
biological activity or power, (5) to reduce inorganic fertilizers application by
introducing organic based fertilizers and as well as biofertilizers.
Paddy rice cultivation (irrigated rice fields) largely depends on the water
supply (irrigation) and its consuming about 3000 – 5000 L of water to produce 1
kg of grain rice. The increasing scarcity of water threatens the sustainability of
the irrigated rice production system and hence the food security and livelihood of
rice producers and consumers. The task becomes more difficult due to global
climate change. Therefore, a more efficient use of water is needed in rice
production. Several strategies are being pursued to reduce rice water
requirement, such as alternate wetting and drying (Li 2001, Tabbal et al 2002),
ground cover systems (Lin Shan et al 2002), system of rice intensification (SRI,
Stoop et al 2002), aerobic rice (Bouman et al 2002), and raised beds (Singh et al
2002)
The intensively high inputs of artificial fertilizers and others agrochemical
products application has decreased the organic content of in soil significantly.
The result of various field studies indicated mostly of paddy soils in Indonesia
has a low organic content (< 2%) and based on soil health indicator can be
categorized as sick soils (Simarmata, 2002, Simarmata, 2009). Under these
conditions, the increasing of inorganic fertilizers dosage application may give a
nonsignificant effect on rice production. It is an indication that the rice production
received high inorganic fertilizers dosage has reached a leveling off and caused
the decreasing of soil quality and soil health. Consequently, the application of
organic manure like straw compost or other organic fertilizers is needed to
improve the soil quality and soil health. To increase the rice production and
Page 3 of 16
4. revitalize the soil quality and soils health can be reached by using the soil
biological power in organic based and water saving irrigation technology.
Since 2006 we have developed system of organic based aerobic rice
intensification system (SOBARI) to promote the soil biological activity (micro- and
macroorganisms) and to provide a favorable condition for rice roots growth
(Simarmata, 2008). This technology is a holistic rice production system by using
and integrating the soil biological power, plant, fertilizers and water management
according to the plan and design. The implementation of SOBARI now is
beginning widely adopted in several province of Indonesia (West Java, Banten,
East Java, Central Java, North Sumatera, South Sulawesi, and North Sulawesi,
East Nusa Tenggara, Bali and etc.) and gave a promising and higher rice yield
about 50 – 100% compared with traditional methods of continuous flooding
(permanent anaerob) and able to save the water irrigation up to 70%. This high
rice yield is highly correlated with the increasing of roots zone about 4 – 10 times,
number of productive tillers about 60 – 80 tillers, number of panicles, length of
panicles and number of grain/panicle, and as well as due to the increase of soil
biodiversity (beneficial organism) under aerobic condition. Experience with
SOBARI technology combined organic or compost application about 500 kg per
hectare revealed that the application of inorganic fertilizers reduced up to 50%
and resulted 6 – 10 ton grain yield of rice per hectare without requiring a change
in cultivar’s (Simarmata, 2008; Simarmata, 2009). This paper is the review of
implementation of SOBARI as alternative for water saving and inorganic
fertilizers reducing technology to increase rice production in Indonesia.
II. SYSTEM OF ORGANIC BASED AEROBIC RICE INTENSIFICATION
2.1. Definition
System of organic based aerobic rice intensification (SOBARI) is a holistic
rice production system by integrating the soil biological power, plant, fertilizers
(organic, biofertilizers and inorganic ) and water management to achieve targeted
main goal (by design). The main goals SOBAR are to achieve and to sustain high
rice productivity, promotes and enhances agro-ecosystem health (soil quality &
Page 4 of 16
5. soil health), including biodiversity, biological cycles and soil biological activity.
Therefore, the maximize of local input, especially organic fertilizers (straw
compost, cow dung or others) and biofertilizers becomes main priority and called
as low external inputs for sustainable rice cultivation (LEISRC).
The management of local inputs is designed to optimize the biological
processes in achieving the desired rice productivity (outputs) and environmental
quality. System of organic based aerobic rice intensification is working with the
nature by optimize of organic- and biofertilizers application, water and culture
management to promote soil biological power and minimized the use of inorganic
fertilizers .
2.2. PILLARS OF SOBARI
The key success of system of organic based aerobic rice intensification
(SOBARI) in increasing rice growth and soil biological activity (soil biological
power) in soils are highly depend on the four basic concepts or pillars of
SOBARI, as follows: (1) The of Paddy Soil Ecosystem, (2) Life Soil as Natural
Fertilizers Factory (Biofertilizers Plant) or Bioreactor, and (3) Biological Power of
Rice and (4) Nutrients Management
a) Paddy Ecosystem Change
Traditionally paddy rice ecosystem is characterized by permanent flooding
or inundation. Consequently, all aerobic organisms cannot life in soils due to
oxygen depletion, which is required for aerobic respiration. Depletion oxygen
leads to anaerobic conditions (anoxic conditions) and give a significant negative
effect on the beneficial organisms activity and roots growth. By changing the rice
ecosystem from anaerobic (permanent flooding) to aerobic conditions resulted a
dramatically change in soils, especially on soil biological activity and the roots
growth. The moist soils up to muddy condition provide oxygen for the respiration
of soil organism. Meso- and micro fauna play an important role to create and to
build a tunnels system, which is very important for air and oxygen supply under
muddy condition. It seems, these tunnels support the biological activity in soil and
resulted a lot of cast on soil surface. This cast is containing either macro- or
Page 5 of 16
6. micronutrients and as well as essential growth substance, like vitamins. In
contrast under inundation or permanent flooding, there is no activity of aerobic
and produced no cast on paddy soil surface. In addition, the roots growth and
microbial activity was increased significantly under aerobic to muddy condition.
The population of beneficial microbe (nonsymbiotic nitrogen fixers such as
Azotobacter sp & Azospillum sp and phosphate solubilizing bacteria) and roots
growth were increased highly significantly compared with anaerobic conditions
(Simarmata, 2008). The rice roots system under aerobic to muddy condition was
about 5 – 10 times greater than flooding ecosystem. Its has been proven only
about 30% of rice roots growing well. Consequently, the potential obtained yield
of various rice varieties is the work of only 30% rice roots. If roots system
growing optimally in line with the rice production, the potential yield of various
rice variety may increase by at least 2 – 3 three times. Therefore to change
permanent flooding rice ecosystem to aerobic conditions (field capacity to
muddy) is absolutely necessary to increase the rice production and to save water
irrigation significantly.
b. Life Soil as Natural Fertilizer Factory (Biofertilizers Plant)
Paddy soil ecosystem under aerobic to muddy condition is living system
and highly complex system characterized by various of biological, chemical and
physical processes, which markedly influenced by environmental factors.
Microorganisms inhabit the soil and together with exocellular enzymes and the
soil meso fauna and macro fauna conduct all known metabolic reactions. A
hectare of fertile healthy topsoil contains approximately 1200 kg of bacteria, 1200
kg of actinomycetes, 2400 kg of molds, 120 kg of algae, 240 kg of protozoa, 51
kg of nematodes, 120 kg of insects, 1200 kg of worms and 2400 kg of plant roots
One per gram moist soil in rhizosphere contains approximately 1,200 x 10 6 of
bacteria, 46 x 106 of actinomycetes, 12 x 105 of fungi and 5 x 103 of algae
(Sullivan, 2001). All these organisms from a tiny bacteria up to the large
earthworms and insects eat, grow and interact in the soil ecosystem to form food
web that influence paddy soil ecosystem significantly. Food web is the
community of organisms living all or part of their lives in the soil and is named as
Page 6 of 16
7. the living component of soil. Therefore under aerobic to muddy condition, paddy
soil is life and act as natural fertilizers factory or biofertilizers plant.
Contribution of soil beneficial organisms for nutrient availability was well known.
The nonsymbiotic nitrogen fixers may contribute up to 50 – 100 kg N per hectare,
phosphate solubilize microbes may increase the availability of P up to 50%. In
addition, the mineralization rate of added straw was faster and provided more
nutrient and energy for biological activity to support the rice growth. Flooding
permanently or under anaerobic condition will lead to close of natural valuable
fertilizers factory, mean while the farmer spend a lot of money to buy in organic
fertilizers.
Paddy soil as natural fertilizers factory (bioreactor) need a sufficient
energy sources to allow the machine working properly. Energy source for
biological machine is mainly depends on organic availability. Organic material is
entry point of chemical energy to paddy soil ecosystem. Consequently, the
activity of heterotrophic microbes, like bacteria,fungi and actimycetes are rely on
organic supply. The present of microbe as first trophic level allow the energy flow
to next trophic level in soil food web. As organisms decompose complex material,
or consume other organisms, nutrients are converted from one form to another
form, and are made available to plants and to other soil organisms. Soil-dwelling
organisms release bound-up minerals, converting them into plant available forms
that are taken up by the plants growing on the site. Organisms which are not
directly involved in decomposing plants wastes may feed on each other or others
wastes products or the other substances they release. Among the substances
released by the various microbes are vitamin, amino acids, sugars, antibiotics,
gums, and waxes, which are very important to sustain the soils remain alive and
healthy. It is not surprisingly that aerobic to muddy condition of paddy soils are
tilled and fertilized by soil organisms.
The performance of Natural Fertilizers Factory (Biofertilires Plant) is
highly rely on water management and organic supply (organic fertilizers). The
water management or irrigation supply is aimed to maintain the paddy soil
condition from field capacity to muddy conditions dan to meet the water
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8. requirement. Water conditions or water level is regulated through water canal.
The distance between of water canal may range from 5 – 10 m depend on the
level of paddy soils. The rice straw may use as a main source organic material to
supply chemical energy the soil ecosystem and essential nutrient (macro- and
microelements) for rice plant. The application of composted straw or other
organic fertilizers play an important role to stimulate the growth of beneficial
microbes (N-fixers, phosphate solubizing and phytohormone producing bacteria)
and to secure the of organic matter supply for soil fauna, which are act as soil
engineers. The application of improved organic fertilizers (high content of humic
substances, relative high of nutrition contents and other bioactive substances
such amino acid, sugar and vitamins are highly recommended. The benefits of
this products includes easily handling and application, relative lower in
application rate (dosage), the standardized quality, relative free from
contaminants (weed seeds and soil born diseases) and lasted longer in soils.
C. Biological Power of Rice
Since long time ago, people and scientist believe that rice is an aquatic
plant and grows best in standing water. But recently was known that rice is not
an aquatic plant. Although rice can survive when its roots are continuously submerged under
water but does not thrive under hypoxic conditions. Rice does not grow as well in
standing water as when its roots are able to get oxygen from direct contact with air. Under
submerged conditions the roots grow is limited and rice plants spend lot of its energy and
some of the roots' cortex disintegrates to form air pockets (Aerenchyma tissue pockets
(aerenchyma) so that oxygen can reach root tissues. In addition, under flooded conditions up to 3/4
of roots may die by the time of flowering (panicle initiation) (Uphoff, 2004). Consequently,
an effort for increasing the biological power of rice to have more than 60 – 80
tillers per clump, larger and deeper roots system rely on integrating of water,
plant and fertilization management. Water management is focusing to maintain
an aerobic to muddy condition in paddy rice ecosystem. Young seedling 8 – 12
days old are planted twin (two of singly seedling are planted in line with 5 cm
distance) combined with wider plan space (30 cm x 30 cm or 30 cm x 35 cm is
highly recommended) to allow the roots of singly seedling grow independently at
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9. the beginning stage. Output oriented of organic based fertilizers is needed to
secure the supply of nutrient sufficiently and to maintain the optimum biological
activity in soil ecosystem.
d. Nutrients Management
The intensive rice practices leads to the excessive nutrients removing
from the paddy soils ecosystem. Fertilizers application of traditionally rice
cultivation is focused only on primary nutrients such as N, P, and K, especially
nitrogen (very cheap due to subsidized price). Consequently lead to nutrients
depletion in soils. In addition, the excessive of nitrogen application will
accelerate the decomposition of soil organic matter and harm the environment
(soil quality, water and air pollution). At least sixteen and possibly nineteen
elements are known to be essential for plant growth. All nutrients have to be
present in adequate amounts according to plant development or stage of growth
to ensure the high rice productivity.
Therefore, the management nutrition or fertilization of SOBARI is based
on outputs oriented. The amount nutrients supplied into agro-ecosystem as
inputs are calculated according to the plants requirement for supporting plant
development and growth to achieve the designed productivity (outputs by
design). The plants needs of nutrients as raw materials based on the plant
development, the nutrients availability in soils and agro-ecosystem (soil
properties, landscape and climate) condition and as well as on the characteristic
of applied fertilizers (solubility, salt index, reaction, etc.) must be integrated in
designing of inputs management (raw materials management). It is necessary to
keep the balance between inputs and outputs in order to avoid either nutrients
depletion or excessive of nutrients supply, nutrients disorder in soils and to
maintain the sustainability of natural resources. In the long run it is possible to
obtain high yield on sustained basis only when the nutrients balance is positive
(when the input is larger than removal). Thus all removed nutrients from the soil
by plants must be replaced in an ecologically responsible away. In SOBARI is
recommended the use of a balance application of organic and mineral fertilizers.
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10. The widely used of fertilization methods in SOBARI to produce about 8 – 12 ton
rice grain yield (targeted production) are as follow; (1) the incorporation of rice
straw has been made during the land preparation, (2) one day or before
transplanting about 300 kg compost, 50 kg of urea, 25 kg KCL and 50 kg SP-36
(as alternative is 50 kg urea and 100 kg NPK) were applied into soil, (3)
application of about 100 kg urea was done at 18 – 21 days after transplanting or
after the first weeding (to determine dosage of urea properly use leaf color chart),
(4) 50 kg urea and 25 kg KCl or 50 kg urea and 100 kg NPK (16:16:16) were
applied 35 – 38 days after transplanting. In addition, enriched organic liquid
fertilizers was sprayed to plant on 15, 15, 25, 35, 45 and 55 days after
transplanting.
III. SUMMARY OF SOBARI FIELD RESULTS
SOBARI is now widely adopted by incorporating the rice straw during land
preparation or substitute with cow dung or compost. Young seedlings are
transplant at 8 – 12 days old with wider spacing (30 cm x 30 cm or 30 cm x 35
cm) in square pattern. Seedling is planted at the marked intersection gives the
required 25 x 30 cm, or 30 x 30 cm or 30 x 35 cm spacing. A single seedling is
planted in twin methods (two single seedling is planted in line about 5 cm
distance from each others at point of planting cross section) to allow the roots
system of seedling growing properly at the beginning stage. The seedling is
planted by slipping in sideways rather than plunging it into the soil vertically
makes the shape of the transplanted seedling more like an L than like a J. With
an L shape, it is easier for the tip of the root to resume its growth downward into
the soil.
Water applications or irrigation is required to regulate the soil moisture
under field capacity to muddy conditions until the beginning of grain ripening
stage. The water regulation is necessary to allow rice roots growing properly and
to stimulate the growing of soil organisms and as well as its biodiversity. One or
two days before weeding (manually or mechanically), the rice field is irrigated
with 1- 2 cm depth or a thin layer to allow the removing of weeds the easily and
Page 10 of 16
11. to improve the soil aeration. Usually, weeding is done 3 times (2, 4 and 6 weeks after
transplantation).
Output oriented of integrated fertilizers programs is used in SOBARI to provide optimum
nutrients supply to meet plant requirement and to improve the soil biological activity in soils (soil
quality and soil health). The application organic and biofertilizers combined with inorganic
fertilizers are widely adopted in SOBARI. The fertilizers application of SOBARI are divide in 3
steps, as follows: (1) basic fertilizers is applied shortly before transplanting, consisted of 300 – 500
straw compost or cow dung combined 50 kg urea, 50 kg SP-36 and 25 kg KCl or 50 kg urea and
100 kg NPK, (2) 100kg applies at 18 – 21 days after transplanting or after weeding, (3) finally,50
urea and 25 – 50 kg KCl per hectare or 50 kg urea and 50 - 100 kg NPK are applied at 35 – 38
days after transplanting. In addition, enriched organic liquid fertilizers sprays regularly every 10
days (15, 25, 35, 45 and 55 days) to secure the nutrients supply and as booster of plant grow.
Leaf Color Chart (LCC) can be used to monitor the nutrient conditions and to determine the N rate
The field results of SOBARI from several Provinces or districts in Indonesia are
summarized in Table 1. As shown in Table 1, adoption of SOBARI with various rice
variety under different planting season in several provinces of Indonesia are fairly
easily to achieve 40 – 60 fertile tiller plant and contains about 150 – 250 grains
per panicle. The average yield was ranged from 8 to 10 ton grain yield per
hectare (about 50 – 100% higher than traditional flooded paddy rice). The highest
yield about 12 ton per hectare in 2008 was obtained in SOBARI Experimental
Research Station of SOBARI of Agriculture Faculty of Padjadajaran
University,Bandung. SOBARI method raises not only the yield of paddy (kg of
unmilled rice harvested per hectare) without relying on improved varieties, but
also to increase the outturn of milled rice by 5 – 10%. This „bonus‟ on top of
higher paddy yields is due to having fewer unfilled grains and fewer broken
grains. In addition, based on field results and report of farmers groups and
extension services have verified that SOBARI crops are more resistant to pests
and diseases and as well as more resistance to abiotic or climatic stress
(drought). The length of the crop cycle (time to maturity) is also reduced by 5 –
10 days. The earlier harvested time is highly correlated with no seedling stress
Page 11 of 16
12. during transplantation and after planting the roots can grow optimally without lag
phase.
Table 1: Unmilled Rice Yield Summary of the System of Organic Based Aerobic
Rice Intensification (SOBARI) in Different Province/District in Indonesia
(Planting Season 2007 – 2009)
Location Yield Control Increment
(t/ha (t/ha) (%)
SOBARI Experimental Fields and Demo 6 – 12 4–7 50 –150%
Plot (Fac. of Agriculture of Padjadjaran
Univ. Bandung), planted Rice (Ciherang,
Dyahsuci, IR 64, Mekongga)
Demo Plot in Research Institute for Rice of 7 – 10 - -
Indonesia, harvested July 2008 (Ciherang,
Mekongga and Sintanur
West Java (Bandung, Garut, Sumedang, 6 - 11 4–6 50 –100 %
Bogor, Bekasih, Subang, etc.) with various
rice variety
Banten (Serang) 6 – 10 4–6 50 –100 %
East Java (Tulung Agung, Jombang, 6 – 10 4-6 50 –100 %
Madiun, Blitar, Mojokerto, Nganjuk, etc.)
Central Java (Sragen, Sukoharjo, Wonogiri, 6 - 10 4-6 50 –80%
Karang Anyar, Purworejo, Magelang,
Semarang, etc. )
Nort Sumatera (Sergei, Tebing Tinggi, 5 – 10 3-7 50 –100 %
Tapanuli, etc)
South Sulawesi (Gowa, Luwu, etc.) 6 – 10 3–6 50-200%
conducted by Famer Groups in 16
Subdistrict (Various Rice Variety)
North Sulawesi (Minsel, Minut, etc. ) 6 – 10 3–7 50 –200 %
conducted by Famer Groups with Various
Rice Variety
Nusa Tenggara (Kupang, Ende, Bajawa, 6 - 10 2–6 50 –300 %
Nagekeo, Rote Ndao) conducted by Famer
Groups with Various Rice Variety
West Kalimantan (2 ha) 8,9 ton - 100%
Sources: Agricultural Services Agency of Bogor (2008), Agricultural Services Agency of South
Sulawesi (2009), Agricultural Services Agency of Bajawa and Ende (2008), Agricultural
Services Agency of South Minahasa (2008), Rice Institute for Rice of Indonesia, 2008,
PT. SMS, 2008-2009
The key success of SOBARI depends on water irrigation and fertilizers
management. The water supply by irrigation is focusing to maintain the soils
under moist to muddy conditions to allow the roots system and soil biota growing
Page 12 of 16
13. optimally. Based on field experiences, the SOBARI method may reduce the
water irrigation use by at least 30 % - 50 %. Output oriented integrated fertilizers
application of SOBARI is aimed to provide a sufficient nutrient to meet the plant
requirement based on targeted yield by design and to improve the soil quality
and soil health. Therefore, the application of organic fertilizers and biofertilizers
are need to increase nutrients availability and biological activity in soils. SOBARI
is focusing on the application of rice straw as a main source of organic fertilizers.
Actually, organic fertilizers in the form of rice straw is main product of paddy rice
cultivation. Its well known that ratio between straw and grain yield ranged from
1.0 – 1.5 times.
Straw is the only organic material available in significant quantities to most
rice farmers. About 40 percent of the nitrogen (N), 30 to 35 percent of the
phosphorus (P), 80 to 85 percent of the potassium (K), and 40 to 50 percent of
the sulfur (S) taken up by rice remains in vegetative plant parts at crop maturity
(Dobermann and Fairhurst,2002). Nutrient content of every 5 ton rice straw is
equal to 50 kg N, 10 kg P2O5 and 120 kg K20. Straw is also an important source
of nutrients such as zinc (Zn) and silicon (Si). By incorporating the rice straw
during land preparation combined with biofertilizers may reduce the application
inorganic fertilizers significantly. Based on field report, the application of 500
-1000 kg compost straw or cow dung combined with the application biofertilizers
and enriched organic liquid fertilizers (Amazing Bio Growth, ABG) reduce the
usage of inorganic fertilizers by 50%. SOBARI recommends the inoculation of
piled straw with decomposer (sellulolitic and lignolitic combined with
Trichoderma, sp) about 2 weeks before spreading in the rice field and
incorporation during the land preparation to accelerate decomposition of straw
and to suppress the pathogenic microbes in straw.
IV. CONCLUSIONS AND SUGGESTIONS
The conclusions and suggestions can be summarized as follows:
1. System of organic based aerobic rice intensification (SOBARI) is a holistic
of water saving and inorganic fertilizers reducing technology focusing on
soil biological and rice power management and as well as integrated
Page 13 of 16
14. fertilizers management to increase rice production and to improve the soil
quality significantly.
2. SOBARI is water saving and environmentally friendly cost reducing
technology. SOBARI can reduce the water irrigation at least 30 - 50%,
seed rate about 75%, and inorganic fertilizers up to 50%, and increase the
rice yield about 50% - 100% compared with traditionally flooding rice
cultivation.
3. The integrated fertilizers management (organic and Biofertlizers combined
with inorganic fertilizers) is necessary to meet the nutrients requirements
easily and to maintain the soil quality or soil health. The application of 500
– 1000 kg compost or cow dung or 5 ton straw combined with biofertilizers
and enriched liquid organic fertilizers may reduce the usage of inorganic
fertilizers about 50%.
4. Furtherer research are need, especially on; (1) a comprehensive water
requirements, (2) soil biological activity (macro- and microorganisms) and
roots system under different water conditions, (3) The application organic
and Biofertlizers to substitute or reduce the inorganic fertilizers (5) the
performance of roots system, growth and yield various rice variety under
different planting season
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