This document discusses soil erosion and methods to control it. It defines soil erosion as the removal of soil particles from their original site by forces like water, wind, ice or human activity. The key agents and processes of soil erosion are described. The types of water and wind erosion are explained. The impacts of erosion like loss of fertile soil and pollution of water bodies are highlighted. Finally, the document discusses various biological, agronomic and mechanical methods to control soil erosion like contour farming, strip cropping, mulching, bunding, terracing etc.
Dr. Sjoerd Duiker - Dealing with Poor Soil Structure and Soil Compaction John Blue
Dealing with Poor Soil Structure and Soil Compaction - Dr. Sjoerd Duiker, Extension Agronomist, Penn State University, from the 2020 Conservation Tillage and Technology Conference, held March 3-4, 2020, Ada, OH, USA.
This is an introductory soil science presentation that I give to Master Gardeners, agribusiness personnel, farmers, and soil science students. Please feel free to contact me at andykleinschmidt@gmail.com with any comments regarding the presentation.
Soil and water conservation engineering, water erosion, types of water erosion, splash erosion, sheet erosion, rill erosion, gully erosion, stream bank erosion, coastal erosion
Dr. Sjoerd Duiker - Dealing with Poor Soil Structure and Soil Compaction John Blue
Dealing with Poor Soil Structure and Soil Compaction - Dr. Sjoerd Duiker, Extension Agronomist, Penn State University, from the 2020 Conservation Tillage and Technology Conference, held March 3-4, 2020, Ada, OH, USA.
This is an introductory soil science presentation that I give to Master Gardeners, agribusiness personnel, farmers, and soil science students. Please feel free to contact me at andykleinschmidt@gmail.com with any comments regarding the presentation.
Soil and water conservation engineering, water erosion, types of water erosion, splash erosion, sheet erosion, rill erosion, gully erosion, stream bank erosion, coastal erosion
detailed reason of soil erosion, its stages, effects, impacts on agriculture and solution.
SOIL EROSION: INRTODUCTION
TYPES OF SOIL EROSION
Agents of Soil Erosion
WATER EROSION
DIFFERENT FORMS OF SOIL EROSION CAUSED BY WATER
WIND EROSION
DIFFERENT TYPES OF SOIL PARTICLES MOVEMENT BY WIND
MASS MOVEMENT
DIFFERENT FORMS OF SOIL EROSION BY MASS MOVEMENT
CAUSES OF SOIL EROSION
SOIL EROSION: DEGRADING SOIL FERTILITY AND PRODUCTIVITY
CONCLUSION
Read| The latest issue of The Challenger is here! We are thrilled to announce that our school paper has qualified for the NATIONAL SCHOOLS PRESS CONFERENCE (NSPC) 2024. Thank you for your unwavering support and trust. Dive into the stories that made us stand out!
2024.06.01 Introducing a competency framework for languag learning materials ...Sandy Millin
http://sandymillin.wordpress.com/iateflwebinar2024
Published classroom materials form the basis of syllabuses, drive teacher professional development, and have a potentially huge influence on learners, teachers and education systems. All teachers also create their own materials, whether a few sentences on a blackboard, a highly-structured fully-realised online course, or anything in between. Despite this, the knowledge and skills needed to create effective language learning materials are rarely part of teacher training, and are mostly learnt by trial and error.
Knowledge and skills frameworks, generally called competency frameworks, for ELT teachers, trainers and managers have existed for a few years now. However, until I created one for my MA dissertation, there wasn’t one drawing together what we need to know and do to be able to effectively produce language learning materials.
This webinar will introduce you to my framework, highlighting the key competencies I identified from my research. It will also show how anybody involved in language teaching (any language, not just English!), teacher training, managing schools or developing language learning materials can benefit from using the framework.
Synthetic Fiber Construction in lab .pptxPavel ( NSTU)
Synthetic fiber production is a fascinating and complex field that blends chemistry, engineering, and environmental science. By understanding these aspects, students can gain a comprehensive view of synthetic fiber production, its impact on society and the environment, and the potential for future innovations. Synthetic fibers play a crucial role in modern society, impacting various aspects of daily life, industry, and the environment. ynthetic fibers are integral to modern life, offering a range of benefits from cost-effectiveness and versatility to innovative applications and performance characteristics. While they pose environmental challenges, ongoing research and development aim to create more sustainable and eco-friendly alternatives. Understanding the importance of synthetic fibers helps in appreciating their role in the economy, industry, and daily life, while also emphasizing the need for sustainable practices and innovation.
The Roman Empire A Historical Colossus.pdfkaushalkr1407
The Roman Empire, a vast and enduring power, stands as one of history's most remarkable civilizations, leaving an indelible imprint on the world. It emerged from the Roman Republic, transitioning into an imperial powerhouse under the leadership of Augustus Caesar in 27 BCE. This transformation marked the beginning of an era defined by unprecedented territorial expansion, architectural marvels, and profound cultural influence.
The empire's roots lie in the city of Rome, founded, according to legend, by Romulus in 753 BCE. Over centuries, Rome evolved from a small settlement to a formidable republic, characterized by a complex political system with elected officials and checks on power. However, internal strife, class conflicts, and military ambitions paved the way for the end of the Republic. Julius Caesar’s dictatorship and subsequent assassination in 44 BCE created a power vacuum, leading to a civil war. Octavian, later Augustus, emerged victorious, heralding the Roman Empire’s birth.
Under Augustus, the empire experienced the Pax Romana, a 200-year period of relative peace and stability. Augustus reformed the military, established efficient administrative systems, and initiated grand construction projects. The empire's borders expanded, encompassing territories from Britain to Egypt and from Spain to the Euphrates. Roman legions, renowned for their discipline and engineering prowess, secured and maintained these vast territories, building roads, fortifications, and cities that facilitated control and integration.
The Roman Empire’s society was hierarchical, with a rigid class system. At the top were the patricians, wealthy elites who held significant political power. Below them were the plebeians, free citizens with limited political influence, and the vast numbers of slaves who formed the backbone of the economy. The family unit was central, governed by the paterfamilias, the male head who held absolute authority.
Culturally, the Romans were eclectic, absorbing and adapting elements from the civilizations they encountered, particularly the Greeks. Roman art, literature, and philosophy reflected this synthesis, creating a rich cultural tapestry. Latin, the Roman language, became the lingua franca of the Western world, influencing numerous modern languages.
Roman architecture and engineering achievements were monumental. They perfected the arch, vault, and dome, constructing enduring structures like the Colosseum, Pantheon, and aqueducts. These engineering marvels not only showcased Roman ingenuity but also served practical purposes, from public entertainment to water supply.
Welcome to TechSoup New Member Orientation and Q&A (May 2024).pdfTechSoup
In this webinar you will learn how your organization can access TechSoup's wide variety of product discount and donation programs. From hardware to software, we'll give you a tour of the tools available to help your nonprofit with productivity, collaboration, financial management, donor tracking, security, and more.
2. SOIL
The top layer of earth’s surface that is capable of
sustaining life.
Is a three dimensional natural body occurring on the
surface of earth that is the medium for plant growth
and whose characteristics have resulted from the
forces of climate and living organisms acting upon
parent material as modified by relief over a period of
time.
3.
4. It is the deterioration of soil by the
physical movement of soil particles
away from the original site. Water,
wind, moving ice, sea waves and the
use of implements by human beings
etc, are the agents of erosion.(Biotic
& abiotic causes)
SOIL EROSION
7. IT RESULT IN THE LOSS OF FERTILE TOP SOIL THAT IS
SUPPORTING CULTIVATION
LOSS OF PLANT NUTRIENTS
MAKING LAND UNSUITABLE FOR CULTIVATION BY THE
FORMATION OF RAVINES AND GULLIES
SOIL ENTERING THE WATER COURSE REDUCES WATER
QUALITY,REDUCES THE EFFICIENCY OF DRAINAGE SYSTEMS
AND STORAGE CAPACITY OF LAKES AND RESERVOIRS.
SOIL IN WATER IS A POLLUTANT AND IN THAT WAY INHIBIT
FISH SPAWNING AND ENTRY OF LIGHT INTO WATER THAT IS
NECESSARY TO SUSTAIN LIFE IN WATER
THE FERTILIZERS/CHEMICALS IN SOIL MAY AFFECT QUALITY
OF WATER FOR DRINKING.
CAUSE DAMAGES TO ROADS,RAILS AND WATER TRANSPORT
LOSSES DUE TO EROSION
8. Others
2.71 m ha
Degraded forests
24.90 m ha
Water logged
3.20 m ha
Salt affected
6.32 m ha
Ravines
2.68 m ha
Wind erosion
10.46 m ha
Water erosion
57.16 m ha
Status of land degradation in India (Total Area: 329 m ha)
Source: MOA, 1994
9. Rain drops falling on earth surface from a height
dislodge the fine soil particles from the soil mass. This
detached soil particles are carried away in suspension
along with overland flow. The flowing water over the
land surface also can dislodge large number of soil
particles of varying size and ultimately get transported
to streams.
10. Movement of particles
by various agents
(TRANSPORTATION)
PROCESS OF SOIL EROSION
Loosening & dislodging
of Particles
DETACHMENT
/EROSION
Deposition of the
transported particles
(SEDEMENTATION)
11.
12. INDESRIMINATE CUTTING DOWN OF TREES
OVER GRAZING OF VEGETATIVE COVER
FOREST FIRES
REMOVAL OF PLANT NUTRIENTS AND ORGANIC
MATTER BY INJUDICIOUS CROPPING PATTERN
CULTIVATION ALONG SLOPES
FAULTY METHODS OF IRRIGATION
GROWING CROPS THAT ACCELERATE EROSION
CAUSES OF SOIL EROSION
13. TYPES OF EROSION
NATURAL/GEOLOGIC ACCELERATED
Erosion of soil in its natural
state
Rate of erosion is low and
generally invisible.
Soil forming process.
There is equilibrium between
soil formation and soil loss.
It happens under biotic and
abiotic pressure.
Rate of erosion is high and is
visible
Soil degrading process
The equilibrium between soil
formation and soil loss is
broken and loss is higher
than formation
14. DIFFERENT FORMS OF WATER EROSION
Loss of soil due to water movement is called water
erosion. Excess rainfall generating run off causes water
erosion and is increased by the sloping lands.
Rain drop erosion/Splash erosion
Sheet erosion
Rill erosion
Gully erosion
Stream bank erosion
Sea coast/shore erosion
Land slide/land slip
Ravine formation
15. Rain drop
erosion/Splash
erosion
• It is the first step in the water erosion
process. Splashing/detachment of
soil particles occurring by the impact
of falling raindrops is called splash
erosion. Soil granules are loosened
and beaten into pieces. The falling
drops at a speed of 9 m/sec can
create force of 14 times its weight.
By this action the soil becomes a
flowing mud. It can splash soil
particles to about 60 cm ht and 150
cm away.
• Except in slopping lands it cannot
make impact because soil particles
only to very small distances.
16. SHEET EROSION • The removal of a more
or less uniform thin
layer or sheet of soil by
running water from
sloping land is called
sheet erosion. The
splashed soil seal the
soil pores and prevent
infiltration and also
cause sheet erosion
18. RILL EROSION
• It is an advanced form of sheet
erosion which occurs due to
concentration of flowing water. As a
result of water washing down the
slope small finger like rills begin to
develop on land surface. If not
cultivated these rills may increase in
number size and shape.
22. RAVINE FORMATION
• Ravine is a parallel set of deep and narrow
gullies with abrupt sides. They are formed
from un attended rills. It is usually
associated with river systems.
23. Causes of ravine formation
• Abrupt changes in elevation between river
bed and adjoining land
• Deep and porous soil strata with high
erodibility
• Poor vegetative cover
• Backflow of water during recession period
24. STREAM BANK EROSION
• Scouring of soil material from stream
bed and cutting of stream bank by the
force of flowing water. Stream erosion
happens at lower end of water
channels where as gully erosion is
towards upper portion of channels.
25. SEA COAST/SHORE EROSION
• Tidal waves of the sea and
rough and roaring waves
dash on the coast every time
swallowing bits of land. High
velocity winds may intensify
the hazards of this erosion
26. LAND SLIDE /LAND SLIP
• It is the downward and outward movement
of soil forming material composed of
natural rocks, artificial fills or combination
of these materials.
• Land slip-Smaller mass moving all on a
sudden.
• Land slide-bigger mass moving slowly
moving through initiating as slips
27.
28.
29. Causes
• GEOLOGIC-weak geology, lack of
vegetative cover
• HYDROLOGIC-Water seeping and over
saturation
• SEISMIC-Earth quakes
33. Degree & length of slope
• Steep slope-Velocity increase, depression
storage
• Slope increase four times velocity doubles
and erosive power increase four times
• Quantity 32 times size -64 times
• Length of slope increase also soil erosion
increase
34.
35. Relative proportion of sand silt and
clay(particle size distribution)-texture
• Clay - < 0.002 mm dia
• Silt - 0.002 - 0.05 mm dia
• Sand - 0.05 - 2 mm dia
• >2 mm- gravel
36. Effect of texture on erosion
Coarse texture
• More sand
• Light soil
• Less erosion
• Easily detachable but
difficult to transport
Fine texture
• More clay and silt
• Heavy soil
• More erosion
• Silt is easily detachable and
transportable
• Clay not easily dispersed
but low infiltration and
hence more run off and
erosion
37. Soil structure
• Arrangement/grouping of soil particles
• Granular-more infiltration and less runoff.
• Compact soil-less infiltration and more
runoff
39. SOIL ORGANIC MATTER
• Plant and animal residues in various stages
of decomposition
• Provide ground cover, sponge,less
evaporation
• Increase permeability & water holding
capacity and reduce erosion
• Life of soil, Improve structure
• Sandy soil-2%
• Clay and silt-3%
40. SOIL PERMEABILITY
• Ability of soil to allow air and water to
move through soil.
• High permeable-less erosion and less run
off
41.
42.
43.
44.
45. Agronomic Vs Mechanical
• Slow establishment
• Long life
• Low cost
• Protective
• Remunerative
• Productive
• Self multiplicating
• Soil forming
• Less skills
• Conserve bio diversity
• Eco friendly
• Fast result
• Less life
• High cost
46. Biologic and agronomic
• Crops or Vegetation
• Agronomic practice
• Required even in areas where mechanical
measures are adopted for uniform infiltration
and moisture distribution
47. TIMELY SOWING/CANOPY
MANIPULATION
• Maximum erosion when the soil is bare
without any crop cover.
• Establish the crop as early as possible.
Closer spacings.
Maize June 25 July 1 July 7
Canopy(july
30)
48% 20% 15%
Splash
produced
14.5 g 18.4g 20.5g
yield Max Min
52. Inter Cropping
• Growing two or more crops simultaneously in
the same field following specific row or lne
arrangement.
• Effective land use,resource use.
53. Inter Cropping
system Yield(q/ha) Inter crop yield
Maize 28.6
Maize+pigeonpea 28.2 6.2
Sorghum 34.4
Sorghum+pegion
pea
33.5 5.5
Sorghum 33.5
Sorghum+greengram 30.8 7.3
58. Strip cropping
• Alternate rows of erosion permitting and
resisting crop.
• Planted on contour for water erosion control.
• Against prevailing wind direction for wind
erosion control.
• Usually a strip of cereal with pulse is
alternated.
62. MIXED CROPPING
• Small holding does not permit strip crop
• One main crop and one subsidiary crop
• Provide good land cover
• Different root zones
• Ensure at least one crop in adverse climatic
conditions.
63. Conservation tillage
• Tillage is the mechanical manipulation of the
soil to create necessary soil conditions
congenial for plant growth.
• Conservation tillage –minimum disturbance to
top soil.
• Zero tillage, minimum tillage, mulch tillage
• 30% of crop residue cover is maintained.
64. Conservation tillage
• Conservation tillage is any system that reduces
the number of tillage operations maintains
residue cover on the soil surface, and reduces the
losses of soil and water relative to conventional
tillage. It is a set of innovation technologies
including no-till and various reduced or minimum
tillage systems such as mulch tillage, strip tillage,
and ridge tillage. Reduced or minimum tillage
includes any system in which a soil is disturbed
less than in conventional tillage but more than in
no-till.
65. Conservation tillage
No-till and reduced-tillage farming leaves old crop
residue on the ground instead of plowing it into soil.
This covers the soil, keeping it in place.
Here, corn grows up out of a “cover crop.”
Figure 8.16f
66. Reduces erosion
Saves fuel
Cuts costs
Holds more soil
water
Reduces soil
compaction
Allows several crops
per season
Does not reduce
crop yields
Reduces CO2
release from soil
Can increase
herbicide use for
some crops
Leaves stalks that
can harbor crop
pests and fungal
diseases and
increase pesticide
use
Requires
investment
in expensive
equipment
DisadvantagesAdvantages
Trade-Offs
Conservation Tillage
78. Properties of plants to be selected as
barriers
• Erect,stiff uniform,dense permanent hedge
• Perennial
• Not to Spread as weed
• Repel rodents
• Deep penetrating roots
• Sprout new tillers
• Not compete with crop
• Farmer friendly
• Bio mass to be economic value
91. Concept
Intercept long slope into shorter ones.
Does not allow to reach critical velocity.
Reduce/alter degree of slope.
Increase the time of
concentration/opportunity time.
95. LAND LEVELLING/GRADING
• Reshaping the land to a planned grade.
• Uneven- No uniformity in irrigation
waterappliction,fertilizer distribution etc.
• It enhances irrigation water use efficiency
• Low r.f areas reduce run off & max infiltration
96. LAND LEVELLING/GRADING
• Criteria for land levellig
– Soil (depth,texture,infiltration)
– Topography (slope)
– Cropping pattern(kind of crop,irrigation,returns)
– Rainfall
– Desire of farmers.
97. Bunding
• It is an embankment of suitable cross section
constructed across the slope to break the
slope length. These are the best for ground
water recharge.
– Contour bunding.
– Graded bunding.
99. Contour bunding
• Along the approximate contour
• Suitable from 2-6% slope,< 800 mm r.f,and
relatively permeable soils.
• Is adopted where leveling is impossible for
cost
100.
101. STONE PITCHED CONTOUR BUND
(PUERTORICCAN TYPE CONTOUR
TERRACE WALL)
Top width including
pitching: 45 to 50 cm
Thickness of pitching:
15 to 22 cm
Side slope
Uphill side of earth
fully: 1.5:1
Downhill side: 1:5 to
1:3
Foundation: 15 to 20
cm
102.
103. Graded bunding
6-10 % slope
Or Clay soil
Or rainfall more than 800mm
Safely dispose run off
Drainage channel
Merits & Demerits Page 16 ofyr text
104. Bench terracing
Step like fields by half cutting and half filling
6-33%slope. Or up to 50%
In lower slopes for uniform water impounding
110. Suitability
Type Slope Soil type Rain fall,mm
Level 8-50 % Medium to
deep
<2500-3000
Inward sloping 8-50 % Medium to
deep
<2500-3000
Outward
sloping
8-50 % Shallow <1200
Puertorican
type
8-50 % Shallow to
deep
<1500
111. Puertorican Type Terrace/California type
• Soil is not disturbed for making a terrace in a single
stroke or time
• A hedge of suitable grass is planted in a single or
double row on contour at pre-determined spacing.
• The interspace between the two hedge lines of grass
planted is cultivated and tilled to take crops.
• The tilled soil slowly moves towards the vegetative
hedge and gets deposited against this barrier.
• The process continues for 3 to 4 years till it becomes
level .
• Guatemala (Tripsacum laxum) and Hybrid Napier have
been found effective for this purpose in the Nilgiris.
• This is much cheaper and does not disturb the top soil.
114. Strip terraces
• With lesser terrace width of 1-1.5 m
• Design
– Maximum depth of cut (D)
– Maximum admissible cut for given slope
– Width of terrace.
1.Terrace spacing
2.Terrace gradient
3.Terrace cross section
125. Check dams
Functions of check dam
Reduce the channel gradient
Reduce velocity of flow and silt carrying capacity
Percolation & ground water recharge
Promote vegetation growth in channels.
126. Components of check dam
Spill way to carry the flow
Anchoring to side and bottom
Apron that absorb impact of falling water
135. Permanent structures
• Where other inadequate or impractical
• Volume of peak run off is very high
• Sites where frequent maintenance not
possible
• High degree of risk for life/property
136. Permanent structures, only if
• Help in stabilizing gully and store water
• Adequate to handle Qp
• To be constructed with permanent
material
142. Wind erosion, also known as
eolian erosion, is a dynamic
process by which soil particles
are detached and displaced by
the erosive forces of the wind.
Wind erosion occurs when
the force of wind exceeds the
threshold level of soil’s resistance
to erosion.
143. Causes of wind erosion
• crushed or broken soil surface crusts during windy
periods;
• a reduction in the plant cover, biological crusts,
and litter, resulting in bare soil;
• a decrease in the amount of organic matter in
the soil, causing decreased aggregate stability;
• long, unsheltered, smooth soil surfaces
DRY soil conditions-Arids & semi arids
144. EFFECTS OF WIND EROSION
• REMOVAL OF TOP SOIL
• SCALDING ON SOIL SURFACE
• ROOT EXPOSURE
• SOIL TEXTURAL CHANGES ATTRITION AND
WINNOWING
• EXTENSION OF DESERTS
• HIGH DUST CONCENTRATION IN ATMOSPHERE
CAUSING HEALTH HAZARDS
• DAMAGE TO ROAD, RAIL, BUILDING
• SAND DEPOSITS
150. • The water storage capacity of a particular
region remains the same
• The consumption increases
with increase in population
corresponding to changes in life style
151. RAIN WATER HARVESTING
• Kerala state is receiving 80-90 % of rain fall in
a period of 5-6 months and for the rest 6-7
months it is under water insecurity. The fun
about Kerala is, 8500 million cubic metre
water is excess in monsoon and 7200 million
cubic metre deficit in summer. This demands
a very meticulous planning for rain water
harvesting in the state
152. The land of 44 rivers is only a fallacy as
the total amount of water that all the
rivers contain together is less than
2/3rd of Godavari.
We have no major rivers and only 4
medium and 40 minor rivers. The
largest river is Periyar with a length of
240 km.
Kerala is having only < 2 % area under
irrigation.
154. Physiographically it is demarcated as 48%
high land, 42 % mid land and 12% low land.
Due to these features of topography the
water gets very little time to infiltrate into
the soil and the entire rain fall takes very
short time to reach the sea. Due to this
reason only 6-12% rain is recharged in to
the ground in Kerala. With this, the state
has to support a population density of
819/km2.
155. Rainfall availability
• Reeipt-400 million hectare meter
–69 million surface water
–45 million ground water
–This 114 million is 29%
–The rest 71% goes to the
sea or get evaporated
159. Water harvesting
• Is the collection, storage and conservation of
rainfall for its productive use in irrigation,
domestic and industrial uses.
• Is the technique of collection and storage of
rain water that runs off a natural or manmade
catchment such as watersheds rooftops,
compounds, rocky surfaces or hill slopes
170. ARTIFICIAL RECHARGE BY
SUBSURFACE METHODS
Pond/ tank with shaft
Recharge pit
Recharge trench
Recharge well
Injection well
Sub surface dams
171. Dug well recharge
Dried up dug wells/ wells in
which water levels have declined
can be recharged
Source of recharge can be rain
water from storm/tank/canal/
Roof top
Recharge water should be passed
through desilting chamber, after
desilting the recharge water is
taken to bottom of well/ below
the water level.
Periodic chlorination.
175. Recharge shaft/ Injectionwells
Efficient and cost
effective structures
Back filled with
inverted filter
Suited for deep water
levels (upto 15m)
Silt water can be used
176.
177.
178. HOW much water do I use ???
Use Litres/person
Drinking 3
Cooking 4
Bathing 20
Flushing 40
Washing-clothes 25
Washing Utensils 20
Gardening 23
Total 135
Consumption range 50 Ltrs/300 ltrs per person per day
179.
180. A dripping tap could waste as much as 90 litres a week.
Brushing your teeth with the tap running wastes almost 9 litres a minute.
Rinse out from a tumbler instead.
Cool water kept in the fridge means you won't have to run the tap for ages to
get a cold drink.
Don't use your washing machine until you've got a full load. The average
wash needs about 95 liters. A full load uses less water than 2 half loads.
Every time you boil an egg save the cooled water for your houseplants.
They'll benefit from the nutrients released from the shell.
Fit a water saving device in your cistern and save up to three litres a flush.
Grow your grass a little longer. It will stay greener than a close mown lawn
and need less watering