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As CSR Activities Soil analysis has been taken by NFCL in INDIA

As CSR Activities Soil analysis has been taken by NFCL in INDIA

 A brief about soil, soil analysis methodologies, Application & critical analysis & Fertilizer Recommendation for Farmers soil.

Dr. Amar Nath Giri (EHSQ)

Soil may be defined as a thin layer of earth crust which serves as a natural medium for the growth of the plants. Soil consists of organic matter Soil organisms - Micro flora and Micro fauna.  Soil water Soil air Inorganic matter - Macro nutrients and Micro nutrients Organic Matter the plants and animals grown in weathered material and the organic residues left behind decay with time and become an integral part of the soil. The main source of soil organic matter is plant tissue. Animals are subsidiary source of soil organic matter.  The micro flora like bacteria, fungi, algae, actinomycetes, and micro fauna like protozoa, nematodes, macro fauna like earthworms, ants etc. play an important role in formation of organic matter. The organic matter influences the soil in respect to colour, physical properties, supply of available nutrients and adsorptive capacity. IN NFCL we are considering the significant parameters which is useful to analysis maximum quality of the soil which used to be beneficial to provide real solution for healthy Crop & fruits , cereals, vegetables. 

Objective of Soil Testing:

                  Appropriate fertilizer dozes used to be recommended on the basis of soil testing such as In Normal soil (pH- 6 to 6.5) all Nitrogenous fertilizer, Super phosphate, Ammonium phosphate etc. can be used. Similarly in the soil having less than 6.00 pH value, Calcium ammonium nitrate, Sodium nitrate, phosphetic fertilizer. Super phosphate, Murate of potash etc can be applied. In the soils having more than 8.5 Ph value, Urea, Ammonium sulphate, Amonium chloride, Super phosphate, Amonium phosphate, Murate of potash etc are recommended. The water logged soils can be applied Urea, Ammonium sulphate, Super phosphate, Ammonium phosphate, Ammonium chloride etc.
To identify the quantity of organic carbon in the soil is one of the major objectives of soil testing, because growth of crop & availability of nutrients are based on organic carbon. The ratio of organic carbon & nitrogen is 10-12:1. The propagation of useful bacteria also depends on it.

                 Soil testing recommends the ingradiant required reclaiming the acidic soil or saline soils etc. The deficiency of micro element like Znic, Copper, Boron, Molybdenum, Iron, Cobalt, Silicon, Manganese & Chlorine etc also adversely affect the crop condition & ultimately the production.

                  In NFCL soil testing laboratories pH, Ec, Organic carbon (as an index of available nitrogen), available phosphorus, and available potassium are estimated. If necessary micro nutrients like Fe, Cu, Mn, Zn and B are estimated, Ca, Mg and S are also estimated if any deficiency symptoms are observed on crops. pH (potential of hydrogeni) is estimated by a glass electrode pH meter in 1:2 soil water suspensions. Electrical conductivity is measured by a conductivity meter in 1:2 soil water suspensions. Available nitrogen is estimated by Subbaiah and Asija (1956) method (distillation of soil with alkaline potassium permanganate solution). But in most of the laboratories organic carbon is taken as an index of available nitrogen content of soil assuming C: N ratio is 10. Organic carbon is determined by chromic acid oxidation by rapid titration (Walkley and Black (1934) rapid titration). Phosphorous is determined by Olsen's (1954) using 0.5 M sodium bicarbonate as extracting and phosphorus is analyzed calorimetrically. Neutral normal ammonium acetate solution is the most widely used extractant for available potassium which is analyzed by flame photometer. Micro nutrients are extracted by DTPA and determined by atomic absorption spectrophotometer .

                         When land is brought under cropping, grain or fruit and sometimes the entire plants are removed (harvested) from the land. Hence, the soil losses a considerable amount of its nutrients (up take by plants). If cropping is continued over a period of time, without nutrients being restored to the soil, its fertility will be reduced and crop yields will decline. Apart from removal by crops, nutrients may also be lost from the soil through leaching and erosion. Even to maintain soil productivity at the existing levels, it is necessary to restore to the soil, the nutrients removed by crops as also those lost through leaching and erosion.

                   Continued maintenance of a high level of soil fertility is an indispensable for profitable land use and sustained agricultural production. From time to time the inherent fertility of soil has to be evaluated.

A brief About Indian Soil and its qualification:

Classification of Indian Soils

            There are 8 major group of soils in India which are furnished below

Red Soils: Red colour is due to various oxides of iron. They are poor in N, P, K and with pH varying 7 to 7.5. These soils are light textured with porous structure. Lime is absent with low soluble salts. Red soils occur extensively in Andhra Pradesh, Assam, Bihar, Goa, Parts of kerala, Maharastra, Karnataka, Tamilnadu and West Bengal. Most of the red soils have been classified in the order ' Alfisols'.

Lateritic Soils

Seen in high rainfall areas, under high rainfall conditions silica is released and leached down wards and the upper horizons of soils become rich in oxides of iron and aluminium. The texture is light with free drainage structure. Clay is predominant and lime is deficient. pH 5 to 6 with low in base exchange capacity, contained more humus and are well drained. They are distributed in summits of hills of Daccan karnataka, Kerala, Madhyapradesh, Ghat regions of Orissa, Andhra pradesh, Maharastra and also in West Bengal, Tamilnadu and Assam. Most of the laterite soils have bee classified in the order ' ultisols' and a few under ' oxisols'.

Alluvial Soils

These are the most important soils from the agriculture point of view. The soils are sandy loam to clay loam with light grey colour to dark colour, structure is loose and more fertile. But the soils are low in NPK and humus. They are well supplied with lime; base exchange capacity is low, pH ranges from 7 to 8. These soils are distributed in Indo-Gangetic plains, Brahmaputra valley and all most all states of North and South. Most of the alluvial soils have been classified in the orders ' Entisols', ' Inceptisols' and ' Alfisols'.

Black Soils

This is well known group of soils characterised by dark grey to black colour with high clay content. They are neutral to slightly alkaline in reaction. Deep cracks develop during summer, the depth of the soil varies from less than a meter to several meters. Poor free drainage results in the soils, base exchange is high with high pH and rich in lime and potash. Major black soils are found in Maharastra, Madhyapradesh, Gujarat and Tamilnadu. Cotton is most favorable crop to be grown in these soils. These soils are classified in the order 'Entisols', ' Inceptisols' and ' vertisols'.

Forest Soils

This group of soils occur in Himalayas. Soils are dark brown with more sub-soil humus content. They are more acidic.

Desert Soils

These soils are mostly sandy to loamy fine sand with brown to yellow brown colour, contains large amounts of soluble salts and lime with pH ranging 8.0 to 8.5. Nitrogen content is very low. The presence of Phosphate and Nitrate make the desert soils fertile and productive under water supply. They are distributed in Haryana, Punjab, Rajasthan. They are classified in the order ' Aridisols' and ' Entisols'.

Peaty and Marshy Soils

These soils occur in humid regions with accumulation of high organic matter. During monsoons the soils get submerged in water and the water receipts after the monsoon during which period rice is cultivated. Soils are black clay and highly acidic with pH of 3.5. Free alluminium and ferrous sulphate are present. The depressions formed by dried rivers and lakes in alluvial and coastal areas some times give rise to water logged soils and such soils are blue in colour due to the presence of ferrous iron. Peaty soils are found more in Kerala and marshy soils are found more in coastal tracks of Orissa, West Bengal and South - East coast of Tamilnadu.

Saline - Sodic Soils

Saline soils contain excess of natural soluble salts dominated by chlorides and sulphates which affects plant growth. Sodic or alkali soils contain high exchangeable sodium salts.

Both kinds of salt effected soils occur in different parts of India like Uttarpradesh, Haryana, Punjab, Maharastra, Tamilnadu, Gujarat, Rajastan and Andhra pradesh. These soils are classified under ' Aridisols', ' Entisols' and ' Vertisols'.

Classification of Soils In Andhra Pradesh There are five important types of soils in Andhra Pradesh. They are Red soils , Black soils, Alluvial soils , Laterite soils . Saline soils.

The characters of these soils are same as given under Indian soils.

Soil degradation

                Soil degradation involves a number of physical, chemical and biological processes, which may act singly or jointly. In Andhra Pradesh state, soil erosion by water due to intense storms and soils with poor surface structural stability are the most obvious forms of land degradation. The other forms of degradation seen in our state are salinisation, alkalisation, laterisation and inundation of the total area of 18.52 million hectares in 14 districts surveyed so far, 19.6% suffers from soil degradation of one type or the other.

Current records indicate that 1,14,000 hectares of land are affected by water logging and salinity in Guntur and Prakasam districts under the Nagarjuna sagar Right Bank Canal Command. More than 60,000 hectares are alkaline in the districts of Anantapur, Kurnool, Medak, Nalgonda and Mahaboobnagar.

Salt affliction in soils may occur as a result of a variety of causes, namely, capillary rise from subsoil containing salt, indiscriminate use of canal water for irrigation, weathering of rocks in salts transported by rivers from upstream regions to plains, salt impregnated sands transported by coastal winds, in-site decomposition of soil minerals and intrusion of sea water. The extent of saline and alkaline tracts in irrigated areas (under canal and tank or reservoir command areas) is about 5,30,000 hectares.

Response:

Unfortunately, the response to the changes in soils leading to degradation has been painfully slow. Nonetheless, systematic watershed development and command area development programmes have earnestly attempted to set matters right. Some steps have also been taken to rationalise energy and water use through tariff structure. The present infrastructure of seven research stations in different agro climatic zones in the state by the Department of Agriculture helps in monitoring the changes in soil content but needs further strengthening by way of interlocking with Agricultural Universities, Non-governmental organizations , Fertilizer Industries  Experts and Institutions.

As industry & Nutrient solution provider in INDIA as Eco-efficient way for best plant growth, good soil health & maximum utilization of fertilizer by the plant and least environmental effects NFCL is day by day improving the Quality of UREA & other fertilizers and asking soil sample from farmers all over INDIA for analysis  & best Soil recommendation provider.

    There are different methods for soil fertility evaluation as listed below: Soil Test Interpretation and Fertilizer Recommendations

                        From the results of analysis of soil samples sent by the farmer and information sheet supplied by him, soil test reports are prepared in the laboratories. Copies of these reports are sent to the concerned farmer.

                        Soil test reports are usually in three main parts. First part indicates results of analyses of the soil sample. Most laboratories give actual analyses as well as the ratings. Second part is fertilizer recommendations for the crop based on soil analyses, history of the field like cropping pattern, manures and fertilizers earlier applied, etc. This part indicates quantities of nitrogen (N), Phosphate ( P205), Potash(K20), Zinc (Where facilities exist ) and also of lime or gypsum to be applied per hectare.

                       The third part of the report usually indicates time and methods of fertilizer application and other practices required to make the fertilizer use more efficient.

During the relatively short period that soil testing service has been in operation in this country a large number of soil samples have been analyzed in various laboratories. Based on the results of these analyses , soil fertility maps have been prepared indicating the nutrient status of nitrogen, phosphorus, potassium and zinc in different parts of the country. It must however, be noted that this is only a broad classification , since it is based on limited soil sample analysis.

Soil Composition

Soil Organisms: Soil is the habitat for enormous number of living organisms. Some of these organisms are visible to naked eye where as others can be seen by microscope only. Roots of higher plants are considered as soil macro flora while bacteria, fungi, algae and actinomycetes are considered as soil micro flora. Protozoa and nematodes are the significant soil micro fauna where as the earthworms, moles and ants constitutes soil macro fauna.

Soil Water: In order to function as a medium for plant growth, soil must contain some water. The main functions of water in the soil are as follows:

Promotes many physical and biological activities of soil.

Acts as a solvent and carrier of nutrients.

As a nutrient itself.

Acts as an agent in photosynthesis process.

Maintains turgidity of plants.

Acts as an agent in weathering of rocks and minerals.

Soil Air

Oxygen is essential for all biological reactions occurring in soil. Its requirement is met from the soil air. The gaseous phase of soil acts as a path way for intake of oxygen which is absorbed by soil micro organisms, plant roots and for escape of carbondioxide produced by the plants.

This two way process is called soil aeration. Soil aeration become critical for the plant growth when water content is high, because water replaces soil air.

Soil Inorganic Matter

The inorganic constituents of the soil comprises carbonates, soluble salts, free oxides of iron, aluminium and silica in addition to some amorphous silicates. The inorganic constituents form the bulk of the solid phase of the soil. Soils having more than 20% of the organic constituents are designated as organic soils.

Soil pH

The negative logarithm of hydrogen ion (H +) concentration is called pH. Soil pH may be acidic, basic or neutral.

Soil Fertility

Soil fertility deals with the nutrient status or ability of soil to supply nutrients for plant growth under favorable environmental conditions such as light, temperature and physical conditions of soil.

Soil Productivity

Soil productivity is defined as the capability of the soil for producing a specified quantity of plant produce per unit area and the ability to produce sequence of crops under a specified system of management.

Problem Soils

The soils which owe characteristics that they can not be economically used for the cultivation of crops without adopting proper reclamation measures are known as problem soils.

Acid Soils

Those soils with pH less than 6.5 and which respond to liming may be considered as acid soils.

Reasons for Acidity  Humus decomposition results in release of large amounts of acids. There by lowering the pH.  

Rainfall: In areas with more than 100 cm rainfall associated with high R.H., Ca, Mg is dissolved in water and leached out due to this base saturation of soil decreases. Application of elemental sulphur under goes reactions resulting in formation of H2SO4.

Continuous application of acid forming fertilizers like ammonium sulphates or ammonium chlorides results in depletion of Ca by CEC (cation exchange capacity) phenomenon. Parent Material : Generally rocks are considered as acidic, which contain large amount of silica (Si O2) when this combined with water, acidity increases.

Characteristics : PH is less than 6.5

This soils are open textured with high massive Structure. Low in Ca, Mg with negligible amount of soluble salts.  These soils appear as brown or reddish brown, sandy loams or sands. Injury to Crops

Direct Affects

Plant root system does not grow normally due to toxic hydrogen ions. Permeability of plant membranes are adversely affected due to soil acidity. Enzyme actions may be altered, since they are sensitive to PH changes.

Indirect Affects

Deficiency of Ca and Mg occur by leaching. Al, Mn and Fe available in toxic amounts. All the micro nutrients except molybdenum are available. So 'Mo' deficiency has been identified in leguminous crops. Phosphorous gets immobilized and its availability is reduced.  Actvity of Micro Organisms  Most of the activities of beneficial organisms like Azatobacter and nodule forming bacteria of legumes are adversely effected as acidity increases.  Crops Suitable For

Cultivation in Acid Soils

Amelioration

Lime as reclaiming agent : Lime is added to neutralize acidity and to increase the PH, so that the availability of nutrients will be increased. Basic slag obtained from Iron and steel industry can be substituted for lime. It contains about 48-54% of CaO and 3-4% MgO. Ammonium sulphate and Ammonium chloride should not be applied to acid soils but urea can be applied. Calcium Ammonium Nitrate (CAN) is suitable to acid soils. Any citrate soluble phosphate fertilizer is good source of phosphorous for acid soils. Eg. Dicalcium phosphate (DCP), Tricalcium phosphate (TCP) Potassium sulphate is a suitable source of 'K' for acid soils. But MOP is better than K2So4 because Cl of MOP replaces -OH ions, their by release of -OH ions tends to increase the PH.

Alkaline Soils :

Alkali soils are formed due to concentration of exchangeable sodium and high pH. Because of high alkalinity resulting from sodium carbonate the surface soil is discoloured to black; hence the term black alkali is used.

Reasons for Alkalinity

The excessive irrigation of uplands containing Na salts results in the accumulation of salts in the valleys. In arid and semi arid areas salt formed during weathering are not fully leached.

In coastal areas if the soil contains carbonates the ingression of sea water leads to the formation of alkali soils due to formation of sodium carbonates. Irrigated soils with poor drainage.

Characteristics

Injury to Crops

High exchangeable sodium decreases the availability of calcium, magnesium to plants. Dispersion of soil particles due to high exchangeable 'Na' leads to poor physical condition of soil, low permeability to water and air, tends to be sticky when wet and becomes hard on drying.

Toxicity due to excess hydroxyl and carbonate ions. Growth of plant gets affected mainly due to nutritional imbalance. Restricted root system and delay in flowering in sensitive varieties.

Typical leaf burn in annuals and woody plants due to excess of chloride and sodium.

Bronzing of leaves in citrus. It effects the solubility of zinc( Zn). Crops Suitable for Cultivation in Alkaline Soils Barley, Sugarbeet, Cotton, Sugarcane, Mustard, Rice, Maize, Redgram, Greengram, Sunflower, Linseed, Sesame, Bajra, Sorghum, Tomato, Cabbage, Cauliflower, Cucumber, Pumpkin, Bitterguard. Beetroot, Guava, Asparagus, Banana, Spinach, Coconut, Grape, Datepalm, Pomegranate.

Amelioration

The process of amelioration consists of two steps. To convert exchangeable sodium into water soluble form. To leach out the soluble sodium from the field. Amendments used for reclamation of Alkali soils.

Gypsum

It is slightly soluble in water. So it should be applied well in advance.

Requrement

For every 1 m.e of exchangeable Na per 100 gm of soil, 1.7 tonns of Gypsum/ acre is to be added.

Application

Saline Soils

The saline soils contains toxic concentration of soluble salts in the root zone. Soluble salts consists of chlorides and sulphates of sodium, calcium, magnesium. Because of the white encrustation formed due to salts, the saline soils are also called white alkali soils.

Reasons For Salinity

In arid and semi arid areas salts formed during weathering are not fully leached. During the periods of higher rainfall the soluble salts are leached from the more permeable high laying areas to low laying areas and where ever the drainage is restricted, salts accumulate on the soil surface, as water evaporates

The excessive irrigation of uplands containing salts results in the accumulation of salts in the valleys. In areas having salt layer at lower depths in the profile, seasonal irrigation may favour the upward movement of salts. Salinity is also caused if the soils are irrigated with saline water.  In coastal areas the ingress of sea water induces salinity in the soil.

Characteristics

Injury to Crops

                High osmotic pressure decreases the water availability to plants hence retardation of growth rate. As a result of retarded growth rate, leaves and stems of affected plants are stunted. Development of thicker layer of surface wax imparts bluish green tinge on leaves Due to high EC germination % of seeds is reduced.

Crops Suitable For Cultivation In Saline Soils

Barley, Sugarbeet, Cotton, Sugarcane, Mustard, Rice, Maize, Redgram, Greengram, Sunflower, Linseed, Sesame, Bajra, Sorghum, Tomato, Cabbage, Cauliflower, Cucumber, Pumpkin, Bitterguard. Beetroot, Guava, Asparagus, Banana, Spinach, Coconut, Grape, Datepalm, Pomegranate.

Amelioration

The salts are to be leached below the root zone and not allowed to come up. However this practice is some what difficult in deep and fine textured soils containing more salts in the lower layers. Under these conditions a provision of some kind of sub-surface drains becomes important.

The required area is to be made into smaller plots and each plot should be bounded to hold irrigation water.

Separate irrigation and drainage channels are to be provided for each plot. Plots are to be flooded with good quality water upto 15 - 20 cms and puddled. Thus, soluble salts will be dissolved in the water.  The excess water with dissolved salts is to be removed into the drainage channels.

Flooding and drainage are to be repeated 5 or 6 times till the soluble salts are leached from the soil to a safer limit.  Green manure crops like Daincha can be grown upto flowering stage and incorporated into the soil. Paddy straw can also be used.

Super phosphate, Ammonium sulphate or Urea can be applied in the last puddle. MOP and Ammonium chlorides should not be used.

Scrape the salt layer on the surface of the soil with spade.

Grow salt tolerant crops like sugar beet, tomato, beet root, barley etc

Before sowing, the seeds are to be treated by soaking the seeds in 0.1% salt solution for 2 to 3 hours.

If the requirement is 3 tonnes/ acre- apply in one dose.

If the requirement is 3 to 5 tonnes/acre- apply in 2 split doses.

If the requirement is 5 or more tonnes/ acre - apply in 3 split doses.

Use of Pyrites (Fe S2)

Sulphur present in pyrites causes decrease in pH of soil due to formation of H2SO4.

H2So4 + Ca Co3 -- Ca S04 Ca So4 + Na --- Na So4 + Ca ( leachable)

Application of sulphur. Application of molasses. Drainage channels must be arranged around the field. Growing the green manure crops and incorporate in the field.

Objectives of Soil Testing - The objectives of soil testing area as follows:

To estimate the available nutrient status, reaction (acidic/alkaline) of a soil. To evaluate the fertility status of soils of a country or a state or a district.

By soil test summaries the fertility status i.e., available nitrogen status or available phosphorous status or available potassium status expressed as HIGH, MEDIUM or LOW. Delineating areas of nutrient (e.g.,N, P, K) sufficiency or areas of nutrient (e.g.,N, P, K) deficiency, Determining nutrient (e.g.,N, P, K) requirement for the deficient areas etc.      3. to prepare a basis for fertilizer recommendation, lime recommendation or gypsum recommendation.

                    The main purpose of soil testing is to evaluate the fertility status of the soil. It provides a basis for fertilizer, lime and gypsum recommendation. Laboratory test is a means of making an inventory of the chemical conditions of soil and determining treatments, if any, are needed.This service is generally rendered free of cost Under Social Corporate Responsibility. Attachments –Annexure 1. In the soil testing laboratory, soil samples are analyzed for the following five individual soil properties: pH or soil reaction which indicates whether the soil is acidic, alkaline or normal

Total soluble salts which indicates whether the soil is saline or normal:

Organic carbon (as a measures of available nitrogen)

Available phosphorus

Available potash

Fertilizer Recommendation

Analysis Procedure AnneXure -2

Rating of Soil Test Results- On the basis of soil test results, the soils are grouped into different categories. The categories with respect to organic carbon, available PO, KO and N are a follows:

Categories	Organic Carbon (%)	Available N (kg ha-)	Available PO (kg ha-)	Available KO (kg ha-)
High	Above 1.5	Above 450	Above 90	Above 340
Medium	0.75-1.5	280-450	45-90	150-340
Low	Up to  0.75	Below 280	Below 45	Below 150

The categories of soils with respect to soil pH are as follows:

Soil pH	Categories	Conductivity	Categories
Below 5.5	Acid	Below 1	Normal
5.5-6.5	Slightly acid	1 - 2	Critical for germination
6.5-7.5	Neutral	2 -.3	Critical for growth of salt-sensitive crops
7.5-8.5	Tending to become alkali	Above 3	Injurious to most crops
Above 8.5	Alkali

Ratings of soil test parameters

Quadratic Response Equation

Y = A + b1SN + b2SN2 + b3 SP + b4SP2 + b5SK + B6SK2 + b7FN + b8FN2 + b9FP + b10FP2 + b11FK + b12FK2 + b13FNSN + b14FPSP + b15FKSK

Where,

Y = Crop Yield (kg/ha)
A = Intercept
bi = Regression coefficients (kg/ha)
SN, SP, SK = Soil available N, P and K (kg/ha) respectively
FN, FP, FK = Fertiliser N, P and K (kg/ha) respectively

Mitcherlich-Bray equation

Availble Nutrient	High	Low	Medium
N(Nitrogen)	63.10%	25.57%	11.33%
P(Phosphorous)	42.33%	37.66%	20.01%
K(Potassium)	12.93%	36.65%	50.42%

Log (A-Y) = Log A - c1b - cx

Where,

A = theoretical maximum yield
b = native soil nutrient
Y = yield obtained
x = added fertiliser
c1 = efficiency factor for soil nutrient
c = efficiency factor for added nutrient

Target Yield Equation

FD = NR/CF *100*T -CS/CF*STV

Where,

FD = Fertiliser N or P2O5 or K2O (kg/ha)
NR = Nutrient requirement of N or P2O5 or K2O (kg/t)
CF = Contribution from fertiliser N or P2O5 or K2O (%)
CS = Contribution from soil N or P2O5 or K2O (%)
STV = Soil test value of N or P X 2.29 or K X 1.21 (kg/ha)

Conception of Soil Testing

In most of the soil testing laboratories in India, the soil pH, electrical conductivity, oxidizable organic carbon, available nitrogen, available phosphorous and available potassium are determined by chemical analytical methods within a short period. Hence, Soil testing is the rapid chemical analysis of a soil to estimate the available nutrient status, reaction and salinity of the soil.

Method of Collection of Soil Samples - Collection for field crops

Equipments

Spade

Polythene bucket

12 inches scale

Ball point pen/Lead pencil

A sheet of thick paper

Polythene sheet (2ft x 2ft)

Procedure

Determine the soil unit (or plot).

Make a traverse over the soil unit (or plot).

Clean the site (with spade) from where soil sample is to be collected.

Insert the spade into soil.

Standing on opposite side, again insert the spade into soil.

A lump of soil is removed.

A pit of vee (V) shape is formed. Its depth should be 0-6" or 0-9" or 0-12". (i.e., depth of tillage).

Take out the soil-slice (like bread-slice) of ½ inch thick from both the exposed surface of the pit from top to bottom. This slice is also termed furrow-slice. To collect the soil-slice spade may be used. Collect the soil samples in a polythene bucket.

Collect furrow-slices from 8-10 or sometimes 20-30 sites. Select the sites at random in a zigzag (or criss-cross) manner. Distribute the sites throughout the entire soil unit (plot). In lieu of spade auger may be used. Do not take the prohibited samples and local problem soils.

Furnish the following information in two sheets of thick paper with the sample. One sheet is folded and kept inside the bag. Another sheet is folded and attached with the bag.

Informations

Name and address of the farmer (or farm owner).

Name of the block.

Plot number or any other number that identifies the plot (or Soil unit).

Soil texture (sandy/clay/loam).

Availability of irrigation facilities.

Availability of drainage system.

Upland/Mediumland/Lowland.

Depth of soil sample.

Information of the previous crop.

Name and variety of the crop.

Dose of organic manure, if applied.

Dose of fertilizers, if applied.

Yield.

Informations of the crop that will be grown.

Name and variety of the crop.

Season (pre Kharif/Kharif/rabi).

Problem, if any.

Date of sample collection.

Signature of the farmer (or farm owner).

Collection for plantation crop

Dig a well (pit) of 1.8 meter depth. (Depth may vary depending on root-depth).

Collect the soil-slice of ½ inch thick from the exposed surface of pit at different depths as follows: 0-15, 15-30, 30-60, 60-90, 90-120, 120-150 and 150-180 cm.

Collection for local problem soils - Local problem soils are treated as separate soil units (plots). Hence, separate composite samples are collected from problem soils. The problem soil samples are not mixed with normal soils (i.e., non problem soils).  Both surface soil and subsoil samples are collected.

fThe categories of soils with respect to conductivity (total soluble salts) in mmhos/cm (dSm^-1) followed are as follows:

Parameters Details pH more than 8.3 EC Less than 4 m.mhos/ cm ESP More than 15 Chemistry of soil solution Dominated by carbonate and bicarbonate ions and high exchangeable sodium. Effect of electrolyte on soil particles Dispersion due to high amount of exchangeable sodium Adverse effect on Plant Alkalinity of soil solution Geographic distribution Semi arid and semi humid - areas. Diagnosis under field condition Presence of dispersed soil surface. Columnar structures present in the sub-soil

Parameters Details PH Less than 8.3 Ec More than 4.0 m.mhos/ cm ESP (exchangeable sodium %) Less than 15 Chemistry of soil solution Dominated by sulphate and chloride ions and low in exchangeable sodium Effect of electrolytes on soil particles Flocculation due to excess soluble salts. Main effect on plant High osmotic pressure of soil solution Geographic distribution Arid and semi arid regions. Diagnosis under field condition Presence of white crust Presence of chloris barborata(weed) Patchy growth of plants.

Analysis Procedure Annezure -2

pH-(potentia of hydorgenii), EC, OC ( Organic carbon), Phosphorus As P2O5, Potassium as K2O.

Potassium

Along with N and P, potassium (K) is also of vital importance in crop production. Most soils contain relatively large amounts of total K (1 - 2%) as components of relatively insoluble minerals, however, only a small fraction (about 1%) is present in a form available to plants, i.e., water-soluble and exchangeable K. Highly weathered acid soils (of tropical regions) are more frequently deficient in plant available K, whereas soils of arid and semi-arid areas tend to be well supplied with K.

Nevertheless, extractable-K, or exchangeable plus water-soluble K, is often considered the plant-available fraction and is routinely measured in the region's laboratories. Water-soluble K tends to be a large proportion of the extractable K fraction in drier-region soils.

Where levels of extractable-K values are less than 100 to 150 ppm; K deficiency is likely and fertilization is required to maximize crop production with irrigation or high K  requiring crops, the critical level should be even higher.

1 Extractable Potassium

This fraction of soil K is the sum of water-soluble and exchangeable K. The method uses a neutral salt solution to replace the cations present on the soil exchange complex; therefore, the cation concentration determined by this method are referred to as "exchangeable" for non-calcareous soils. For calcareous soils, the cations are referred to as "exchangeable plus soluble" (Richards, 1954).

Apparatus

Flame photometer with accessories.Centrifuge, capable of 3000 rmp.Mechanical shaker, reciprocating.

Reagents

A. Ammonium Acetate Solution (NH4OAc), 1 N

• Add 57 mL concentrated acetic acid (CH3COOH) to 800 mL DI water, and then add 68 mL concentrated ammonium hydroxide (NH4OH), mix well, and let the mixture cool.

Adjust to pH 7.0 by adding more acetic acid or ammonium hydroxide, and bring to 1-L volume with DI water.

B. Standard Stock Solution

• Dry about 3 g potassium chloride (KCl) in an oven at 120°C for 1 – 2 hours and cool in a desiccator, and store in a tightly stoppered bottle.

• Dissolve 1.907 g dried potassium chloride in DI water, and bring to 1-L volume with DI water. This solution contains 1000 ppm K (Stock Solution).

• Prepare a series of Standard Solutions from the Stock Solution as follows: Dilute 2, 4, 6, 8, 10, 15 and 20 mL Stock Solution to 100-mL final volume of each by adding DI water or 1 N ammonium acetate solution. These solutions contain 20, 40, 60, 80, 100, 150, and 200 ppm K, respectively.

Note

Standard solutions for measuring soluble-K should be prepared in DI water, but for measuring extractable-K the standards should be made in ammonium acetate solution.

Procedure

1. Weigh 5 g air-dry soil (< 2-mm) into a 50-mL centrifuge tube, add 33 mL ammonium acetate solution, and shake for 5 minutes on a shaker. The tubes should be stoppered with a clean rubber or polyethylene stopper, but not corks, which may introduce errors.

2. Centrifuge until the supernatant liquid is clear and collect the extract in a 100- mL volumetric flask through a filter paper to exclude any soil particles. Repeat this process two more times and collect the extract each time.

3. Dilute the combined ammonium acetate extracts to 100 mL with 1 N ammonium acetate solution.

4. Run a series of suitable potassium standards, and draw a calibration curve.

5. Measure the samples (soil extracts), and take the emission readings on a Flame Photometer at 767-nm wavelength.

6. Calculate potassium (K) concentrations according to the calibration curve.

CALCULATION

For Extractable Potassium in soil:

Where: A = Total volume of the extract (mL)

Wt = Weight of air-dry soil (g)

2 Soluble Potassium

This fraction is a measure of the amount of K extracted from the soil by water.

Procedure

1. Weigh 5 g air-dry soil (<2 mm) into a 250-mL Erlenmeyer flask, add 100 mL DI water, and shake for 1 hour.

2. Filter and measure soluble-K on a Flame Photometer.

CALCULATION

A Extractable K (ppm) = ppm K (from calibration curve) × .... Wt

A Soluble K (ppm) = ppm K (from calibration curve) × ... Wt

For Soluble Potassium in soil:

3 Exchangeable Potassium

Exchangeable K, or that held on the exchange sites or surfaces of clay minerals, is normally the dominant portion of total extractable K. It can be deduced by difference. For Exchangeable Potassium in soil:

Note

1. Exchangeable sodium (Na), calcium (Ca) and magnesium (Mg) can be measured in the same way as derived for exchangeable potassium (K). Extractable-Na, Ca, and Mg are measured in the ammonium acetate extract and soluble Na, Ca, and Mg in the water extract. The difference will represent exchangeable Na, Ca, and Mg.

2. A range of 20 to 200 ppm of Na standards may be prepared in ammonium acetate solution for extractable Na and in de-ionized water for soluble Na.

3. After extraction, the filtrate containing K, Mg, Ca and Na should not be stored for  longer than 24 hours unless it is refrigerated or treated to prevent bacterial growth.

4. Soils can be stored in an air-dry condition for several months without any

Exchangeable K (ppm) = Extractable K (ppm) - Soluble (ppm) ....... (40)