new mod 3 princ. soil sc
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Chemical and
StructuralComposition ofSoilColloids
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Composition of SoilColloidsDefinition: What Does word colloid mean?
Colloid is a solid particles very small in size (infinitesimal size)Diameter varied between 1 nm to 1um.All Soil Colloidal particles lie in the clay -size fraction.Colloidal particles have two Important characteristics;1 High Specific Surface Area2 Electrified Surface (Electric charge)
{this charge are principally negative (). The positive
ones (+) are rare}
- These two characteristics are restricted for colloidal particlesonly. Neither silt, nor sand particles provide these
features.
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colloidal particles comparing with othersoil particles.
High reactivity of colloids mean:
1- High Adsorption CapacityAdsorption of H2O, cations, anions &
solublemolecules due to high surface area
2- High Cation Exchange Capacity(CEC). Due to negative electric chargeexists on the
surface of colloidal particles.Colloidal particles play an importantrole in:
1 - Physical and chemical
characteristics of soil.2 - Plant nutrition, and
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- According to their origin, soil colloids could be divided into two
types:
* Inorganic or Mineral Colloids: Originated from the decomposition
of rocks and mineral of the parent material. Inorganic colloidsinclude;
- Secondary clay minerals, aluminusilicates, phyllosilicates,
layer silicates (all are synonymous to the same object)
- Hydrous oxides (oxides, hydroxides and oxy-hydroxides) of Fe,
Al and Mn (Sesquioxide)
- Amorphous or non-crystalline materials (Allophane, Imogolite)
* Organic Colloids (Humus): Originated from the decomposition of
debris and bodies of all living organisms after their death. Among
all living organisms exist either on the surface or subsurface the
soil, green plants are the most dominant component of soil
organic colloid.
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Chemical and Structural Composition of
Secondary Clay Mineral
-Clay minerals present in clay fraction (
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STRUCTURAL UNITS OF SECONDARY
CLAY MINERALS
*All phyllosilicate minerals (clay minerals) are consisted of twostructural units:
(a) Tetrahedral unit (silica units) of formula (SiO4)4-.
Tetrahedron silica units
(SiO4)-4
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Tetrahedral units bounded together toform Tetrahedral Sheet (silicasheet) of formula )Si2O5)2-
-2
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(b) Octahedral unit (alumina unit)Formula is [Al(OH6]3-.
In this unit the central cation is Al that surrounded by 6 OH or 6 O
These units bounded together to form Octahedral Sheet (aluminasheet) of formula Al2(OH)6. This sheet called gibbsite Sheet. Another
octahedral sheet called brucite Sheet is exist.
In brucite sheet Mg2+ replacing Al3+ in the center of the octahedral
unit. The formula of brucite sheet is Mg3(OH)6.
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Octahedral sheet (alumina sheet)
{Al2(OH)6}
0
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ypes o secon ary c ayminerals (phyllosilicateminerals)
s Tetrahedral sheet bounded to octahedral one in differentways to form one layer.
s Secondary clay minerals consist of high number of layers.s Each layer contains certain number of sheets.s According to the number of sheets exist in the layer,
secondary clay minerals are typified to three groups:
- 1:1 type clay mineral
- 2:1 type clay mineral
- 2:1:1 (or 2:2) type clay mineral
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Types of secondary clay minerals (phyllosilicate minerals)
1:1 Type
Kaolinite
2:1 Type
Mica, Vermiculite
Montmorillonite
2:1:1 Type
Chlorite
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0.72 nm
Tetrahedral sheet
Octahedral sheet
Hydrogen bond exists
between oxygen atoms of the
upper layer and hydroxyl
groups (OH) of the lower
layer
Structural composition of
Kaolinite clay mineral
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1:1 Type clay mineral (Kandite group)
(OH)
O
Kaolinite mineral:Structural and atomic composition of 1:1 type clay mineralshowing that the layer consists of two sheets (tetra- and octa-hedral). The upper surface contains hydroxyl (OH) groups,whereas the lower surface contain oxygen atoms.1:1 type clay minerals are nonexpanding mineral due to hydrogenbound formed between layers.
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Hydrogen bond exists between
oxygen atoms of the upper layer
and hydroxyl groups (OH) of the
lower layer
Structural composition of
Kaolinite clay mineral
Characteristics of Kaolinite mineral:1- Non-expanded mineral due to hydrogen
bound between layers.2- CEC varied between 5-15 Cmol(+)/kg3- Specific surface Area ranged from 10-20m2/g
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Structural composition of 2:1
type clay mineral
(montmorillonite Mineral)
O
OO-O weak bond
Characteristics of Montmorillonite
mineral:1- Expanded mineral due to weak bond(O-O) between layers. Explain Why? 2-High CEC varied between 80-120Cmol(+)/kg. Give reason.
3- High specific surface area (700 m2/g).Give reason.
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OH
OOO
KaoliniteMontmorillonite
hydrogen bond (O-OH )O-O weak bond
None-ExpandedExpanded Mineral
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Sources of ElectricalCharge on Clay mineralsTwo sources are responsible for electrical charge created
on the surface of secondary clay minerals:
1- Permanent ChargeCreated from isomorphous substitution through:
- Replacing of Si4+ in tetrahedral sheet by Al3+- Replacing of Al3+ in octahedral sheet by Mg2+,
These replacements lead to a creation of negative charge on thesurface of clay mineral.
2 Variable Charge, or , pH dependent Charge, created from
dissociation of H+ ion on siloxane surface ( Silanole group , Si OH, or Aluminole group, Al-OH)
Si OH Si O- + H+
Al OH Al O- + H+
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Isomorphous
substitution
Unsatisfied bonds on
Broken- edges of thecrystal
SiO2
Si4O8
AlSi3 O8-Permanent charge
(ex. Mont.)
Si
Variable Charge
(ex. Kaolinite)
O
O
Sources of Electrical Charge on the surfaces of
Clay Mineral
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Kaolinite andMontmorilloinite minerals
Character Kaolinite Montmorllionite
Type 1:1 2:1
Expansion Nonexpanding Expanding
Charge
source
Variable charge(broken edges,
unsatisfied Valence)
Permanent charge(Isomorphoussubstitution)
CEC Low CEC ( 5 15Cmol+/kg)
High CEC (80 120Cmol+/kg)
Surface Area Low SA (10-20
m2/gm)
High SA (~ 700
m2/g)
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Clay
Minerals
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Inorganic Soil Colloids alsoinclude;
- Hydrous oxides (oxides, hydroxides and oxy-
hydroxides) of Fe, Al and Mn (Sesquioxide).Exist in highly weathered soil (tropicalregions)
- Amorphous or non-crystalline materials(Allophane, Imogolite)- Mainly exist insoil formed on volcanic rocks.
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Characteristics of Soil Colloids and theireffect on soil properties:
Soil colloids have high:- specific surface area.- cation Exchange Capacity- water retention capacity- elasticity when wet- chemical reactivity
So, soil contain considerable amounts ofsecondary clay minerals will . .
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II - ORGANICCOLLOIDS
SoilOrganic
Matter HUMUS
o rgan c Matter
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o rgan c Matter(SOM)
s Sources and chemical composition of organic
matters Decomposition of OMs Humus formations Chemical properties of humus:s Effect of humus on soil fertility
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Importance of organic matter to soil andplant
1 Plays an important role in determining physical andchemical
properties of soil
2- supply micro-organisms with food and energy which
support their rolein building up fertility of soil.
3 - Supply macro- (N, P, S,..) and micro-nutrients (Mn,Zn, Cu,) to
growing plants.
4 Increase soil water holding capacity.
5 It turns soil to dark color which increases absorptionof solar
radiation that increases microbial activity andchemical reactions.
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6 - Enhances formation of stable soilaggregates and overall
soil structure that affect air and water
relationships.7- Increase cation exchange capacity (CEC),and adsorption
capacity of soil.
8 Plays an important role indecontamination of heavy
metals and pesticides.
9 Increasing soil buffering capacity.
10- It protects the surface of soil fromerosion.
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Sources of Soil Organic matter (SOM)
Quantity of organic matter in soil
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Quantity of organic matter in soil- In mineral soils, the quantity of organic matter (OM)varied
between 0.5 5%.- In alluvial soils of Egypt, OM content ranged from 1 3%,
whereas, OMcontent in sandy soil is less than 0.5%- In organic soil, the quantity is usually higher than 18%.- Organic matter is determined in soil and calculated inform of
organic carbon (OC).- A conversion between SOM and SOC could achievedusing a factor
represent the percent of C in OM ( average about 58%)- SOM = OC * 1.72 ( also this factor could used as 1.8or 2 )- The quantity of organic matter in soil decreased withdepth ( Fig. ).
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Chemical composition of freshorganic matter:Compounds released in soil bythe death of plants and livingorganisms are;1 Carbohydrates:(polysaccrides, starch,
hemicelluloses and cellulose)
2 - Proteins3 - Tannins4 - Wax and fats
5 - Lignin.
i i f i
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Decomposition of organic matter
Micro-organisms attack organic residues freshly added to the soil to
gain food and energy required to their biological activities. Organic residues transform to intermediate components, then to finalsimple products.
Generally, the products of decomposition could be concluded in thefollowing points;
1- Carbohydrates decomposed and transformed to CO2 and H2O. 2 Proteins decomposed in different ways:
A Part transformed to amino acids, then to NH4 and NO3
B part combined with clay to be protected from microbial attack.
3- Lignin has high resistance to be decomposed by microbial attack, itjust submit to some chemical changes in structure.
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Degree of decomposition of organiccompounds:
Organic components could be arranged descendinglyaccording to their ability to decomposition as follows:
Saccrides, starch, simple proteins > crude protein >hemicelluloses > cellulose > wax, oil, fats> lignin.
** Micro-organisms as decomposers of organic residueshighly increased in number and mass, and also build up
many compounds inside their bodies. These compoundsrelease in soil and persist for long time after the death ofmicro-organisms.
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Humus formation:The modified lignin that resist microbialdecomposition combined with microbial
protein that formed inside microbial cellsand released to the soil after the death ofmicrobes, to form humus. It is just oneassumption or one theory for formation ofhumus in soil. (There are many theories
dealt with humus formation).
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Two important processes take place
during the decomposition oforganic residues.
These two processes areMineralization and
immobilization.They exist side by side, but thedominancy of one of them dependson chemical composition of organicresidues, particularly theratiobetween C and N in the residues(C:N ratio).
Minerali ation means transformation
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- Mineralization means transformationof nutrients from organic form(unavailable to plant) to simplemineral form available to plant.
- Nutrients are released in simplemineral form (e.g., NH4, NO3, K,..)available to plants when C:N ratio ofthe organic residues fall down to 20:1or lower.
W at o you now a out
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W at o you now a outimmobilization process?
In immobilization process, nutrients transformed form simplemineral form (e.g., NH4, NO3, K,..) available to plants to organicform unavailable to plant as a result of microbial activity to build uptheir bodies.
This process is dominant when C:N ratio of the organic residues ishigher than 33:1.
At this ratio the amount of nutrients released during thedecomposition of organic residues are taken up by microbes. Sogrowing plants suffer from nitrogen deficiencies.
So, it is not recommended to add organic residues of C:N ratiohigher than 33:1 to soil.
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So, organic residues with C:N ratiohigher than 33:1 should bedecomposed in piles before additionto soil until C:N ratio dropped to be
20:1 or lower .Residues of C:N ratio of 20:1 orlower is suitable for addition.
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Chemical Composition of humus:Chemical composition of humus are
not well known yet.Three components could beobtained from humus when submitto extraction using strong basesand acids:1- Humin2- Humic acid (HA)
3- Fulvic acid (FA)
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Model Structure of Humic acid
Model Structure of Fulvic acid
Properties of
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Properties ofHumus
1- Humus contains a large number of functional groups, including;
Carboxylic (COOH) > Phenolic (Ring- OH) > Alcoholic OH >Carbonyl (C=O ) > Amino (- NH2 ) > - SH
These functional groups are responsible for high reactivity ofhumus comparing with other particles exist in soil. They are
responsible for:1- Electrical charge created on humus.
2- Exchange and adsorption reactions, and
3- Chelation and complex formation between humus and
metal cations.
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humus
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humus- The charge of humus is variable (pH
dependent charge).- This charge are created from ionizationof -COOH and
phenol (OH) groups as the following;
R-COOH R-COO- + H+R-OH R-O- + H+
CEC of humus ranging from 200 to 300Cmol(+)/kg
- Humus has surface area ~ 1000
Cmolc/kg.
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Humus contains also amine groups (R-NH2)This group is amphoteric.This group has the abili ty to gain a proton (H+ion) and carries positive charge (+).
R-NH2 + H+ R-NH3+Also, this group can carry negative charge athigher pH values through ionization of H+ ion. R-NH2 + OH- R-NH- + H2O
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Sources of (-)-charges on Humus
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Effect of Humus on Soil-CEC
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Reactivity of Colloids &Chemical Properties of Soil
Reactivity of colloids
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Reactivity of colloidscould be explainedthrough the twoimportant reactions(processes) take placeon their surface;
1 Ion ExchangeReaction
2 Adsorption Reaction
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EXCHANGE REACTIONS
IN SOILS-It has been demonstrated that soil colloids particles carry electric charges(mainly negative charges. The positive charges are rare).
-Since charge balance must be maintained, counter ions (ions of oppositecharge) attracted to the negatively charged sites to satisfy the surfacecharges.
-
The ions attracted to the colloidal surfaces by electrostatic attractions calledExchangeable Ions.
-These ionscan be replaced by others have similar charges through areplacement process called Ion Exchange Reaction.
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-Definition: Ion exchange reaction isa reversible process, in which ioncould be changed between soilsolution and the surface of colloidalparticles.
- Characteristics of ion exchangeprocess are:
FastStoichiometric,Reversible, andNonspecific.
EXCHANGE REACTIONS IN SOILS
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Cation Exchange Reaction
negative charges, then the process specifically calledC ti E h d th i ll d h bl
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g g p p yCation Exchange, and the ions called exchangeablecations.
The exchangeable cations in soils are usually bases
like, Ca, Na, Mg and K. However, in acidic soils, Al3+and H+ are exist as exchangeable cations besidesbases ones.- When negatively charged ions attracted to sites have
positive charge, the process calledAnion Exchange,and ions called Exchangeable Anions.Anionexchange reaction is rare in soil, and may exist inacidic conditions rather than normal or slightly alkalinesoil.
-The sum of exchangeable cations satisfy the negativecharge sites on the surface of colloidal particles called
Cation Exchange Capacity, CECDefintion: Cation exchange capacity is the sum of allexchangeable cations satisfy the negative charge ofsoil particles at pH 7.0, or any other given pH, andcalculated in [Cmol(+)/kg]. (The old units was
meq/100g).
Cation Exchange Capacity of soil increased as pH increased based on
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Cation Exchange Capacity of soil increased as pH increased based on
the fact that part of negative charge is variable, or, pH dependent
charge which is dependent on pH.
Factors Controlling Soil CEC
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Factors Controlling Soil CEC1 Clay Percent: The higher the clay content , the higher the
CEC
2 Type of clay mineral:
Kaolinite = 5 15 Cmol(+)/kg
Mica = 15 40 Cmol(+)/kg
Semectite = 60 - 100 Cmol(+)/kg
vermiculite = 100 150 Cmol(+)/kg
3 Organic Matter Content (CEC of humus ~ 200-300
Cmol(+)/kg)
4 Soil Acidity (pH) : As soil pH goes up, CEC increases.
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Cation Exchange Capacity of Different
Soils
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Soil Characteristics Basedon Ion Exchange Process &The Environmental
Significance of the Process
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Soil Characteristics Based on IonExchange ProcessI - Soil Acidity and Alkalinity (Soil pH)
II - Soil Buffering Action (SBA)
Environmental significance of SBC
Significance of Ion Exchange Processa Reclamation of Acidic and Alkali Soil
b - Availability of Exchangeable cations to plants
c - Protection of Nutrients from Loss
d - Pollution Abatement
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Soil Characteristics Basedon Ion Exchange Process
)
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I - Soil Acidity and Alkalinity (Soil pH)Definition: pH is a measure of hydrogen ion activityof the soil water system and express the acidity and alkalinityof soil.
pH = - [Log H+]In generally pH scale ranged from ( 0 14)
-But, soil pH varies between 4 -10.* Soils around the world have different pH values and could betypified according to pH value to:
I - Arid and semi-arid regions, like Egypt and all Arab countries,
soil usually have pH higher than 7 and up to 8.5. These soilscalled alkaline or slightly alkaline soil.
-(in some cases, pH gets higher than 8.5 and could reached 9or 10. This soil calledalkali soil or sodic soil. This soil cant be
cultivated (unproductive soil), and needs reclamation.
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S il idi d lk li i (S il )
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I - Soil Acidity and Alkalinity (Soil pH)
II - Humid regions: Soil are usually acidic and have
pH values significantly lower than 7 and down to 5.
III - Tropical regions: Soils have pH little lower than 7,and usually near 6. This soil called slightly acidic.
(Soils with pH around 7 callednormal or neutral soil.)
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Fuel and waste Burning:
Variable gases are produced through burning of fuel and wastes. These gases causeair pollution, so, the air of industrial regions and crowded cities is loaded byabnormal concentrations of CO2 , NO2 and SO2 which dissolve in rain water toproduce the phenomenon called "Acid Rain" according to the following equations.
CO2 + H2O H2CO3 CO3 + + 2 NO2 + H2O HNO3 NO3- + H+
These gases are additional sources of H+ ion in soil system
Factors controlling soil PH
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s Inside each group previously mentioned, Soil pH varied as the
following factors varied;
s 1-Soil organic matter: Soil pH decrease as OM% increased.
s 2 - CO2 concentration in soil air: Soil pH decreased as CO2 pressure in
soil-air increased, particularly in calcareous soil.
s 3 - Suspension effect: As soil: solution ratio increased, soil pH
increased.
s
4 - salt concentration: As salt content increased, soil pH desreased.s 5 - Kind of exchangeable cations:
Practical Issue
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Kind of Exchangeable CationsBase saturation percent (BS%)
BS% = { [Na + K+ Ca + Mg]ex /CEC )} X 1001 - If all exchangeable cations arebases (Na, K, Ca, Mg), soil pH ishigher than 7.Under this situation, If exchangeableCa is predominant (represent at least80% of all exchangeable cationsCEC), the pH usually lies between 7
8.5.
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If exchangeable Na percent (ESP) increased tobe 15% or more of CEC, the pH value willincrease to be higher than 8.5, and the soilbecamealkali or sodic soil.
(i.e., The magnitude of increases of pHdepend on the type of bases. Strongbases (e.g., Na+) highly increase pH.
Whereas, weak bases (e.g., Ca2+ &Mg2+) slightly increase the pH value.
On the other hand, if BS% decreased to beless than 100%. Which means that acidic
cations (H+ and Al3+) are exist asexchangeable, the soil pH decreases to belower than 7. Then, the soil is acidic.
N
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Na
Ca
PH
BS%So, Ca2+ is preferred than Na+ to be exchangedin soil.
Exchangeable sodium percent could be obtainedas follows:ESP = { [Na+]/ CEC} 100
As ESP increased to be 15%, soil-pH willincreases and exceeds 8.5. Then, the soilbecomes sodic or alkali.
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Problem on base saturation percent
(BS%)A soil containing the followingexchangeable cations (Cmole/kg)Ca = 8 , Mg = 3, Na = 8, k = 2
Calculate the following:1- CEC 2 BS%3 ESP 4 - How to modify its
pH?
II S il B ff i A ti
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II - Soil BufferingActions Definition:soil buffering action is the ability of soil to resist
changes in pH due to the addition of acids or bases.s Types & Mechanisms of soil buffering :s 1- chemical buffering: due to the reaction of soil
constituents with the added acids or bases.
-An example, by the addition of acid to calcareous soil, the
soil pH does not change due to the direct chemical reactionbetween the added acid and calcium carbonateas follows:
s CaCO3 + 2 HCl CaCl2 + H2O + CO2
So, calcareous soil has high buffering action for acids additives.
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SBAs
2- Compensation buffering:s this type of soil buffering is depending upon the presence of soil
colloids (humus & clay minerals) and the equilibrium between
active and exchangeable acidity (i.e., between H+ exist in
solution and exchangeable H+ as follows:
+
R
Base added
Acid added
OH- H2O
H+
active acidity0.1%
Compensation
Reservation
Hac+
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According to the "Law of mass action" theincreases of H+ concentration in solution as aresult of addition of acid, will shift the directionof the reaction to left side. This means that theexcess soluble H+ ions will be changed toexchangeable form (reservation reaction) andthe pH remains almost constant. On the otherhand, the decrease of active acidity by theaddition ofbases (OH), the reaction should be
shifted to wright side by compensation process.This means that some exchangeable acidity willbe released from DDL to the soluble form whichkeep the pH unchanged.
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Soil buffering capacity (SBC): Definition: SBC is the amount of acid or
base (mole or meq) required to change thepH of the mass unit of the soil by one unit.
Factors affecting SBC:1 - Soil texture: As clay percent
increased, SBC increased.2 - Organic matter content: The increase inOM content is accompanied by anincrease in SBC.3 - CEC: The higher the soil CEC , thehigher the SBC. This could be attributedto the high reserve acidity which cancompensate any shortage in soluble H+ .4 - Calcium carbonate content: Presence oflime in the soil increases SBC especiallyagainst acidic additions.
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Environmental significance of SBC:
1 - It prevents soil to be turned intoacidic or alkaline (prevents soildegradation).
2 - Decreases the hazardous of toxicchemicals through transformation ofsoluble forms into exchangeable oradsorbed forms.
3 - Regulates the release of nutrientsthrough compensating their lowconcentration in soil solution due toplant absorption.
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Environmental Significanceof Ion Exchange Process
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OHCOCCOCaH
H
a 223++=+ ++
+
+
I - Reclamation of acidic soils-Acidic soils characterized by high percent of exchangeable H+ andAl3+ which lead to sharp decrease in pH value. The soil becameunsuitable for plant growth.Acidic soils could be reclaimed by addition of lime as a source of Cacation this process called liming- lime dissolves in the acidic condition and produce Ca2+ cations. The
produced Ca2+ replaces H+ and Al3+ in surface of colloidal solidparticles which lead to a significant decrease in the pH value.The following equation represent this reaction.
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s III - Plant Nutrition
Exchangeable cations are available to plant.The higher the CEC values the higher the amount of nutrients
available to plant and reduction the amount lost by leaching. i.e.,
Protection of nutrients from being lost by leaching
Mass Excha nge a s a sou r ce o f nu t r i en t s t o p lan t
1- Exchange between solid particles and
hair roots.
2- Exchange between particlesthemselves.
IV Pollution Control
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IV - Pollution Control
Ion exchange process plays an important role in decreasing thehazardous of pollutants.
s Hazardous of pollutants increased as they exist in mobile formin soil solution. As these pollutants attracted to negative chargesexist on the surface of colloidal particles, they transformed toless mobile form, which reduces their down movement topollute ground water and reduces their uptake by plant andintroduction into food chain.
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Soil Fertility and
Plant Nutrition
Plant nutrition
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Plant nutrition
What is an essential element?Func t i ons o f e s sen t i a l e l emen t s i n p l an t s
Soil properties that influence nutrient availabil ity
NitrogenPhosphorus Potassium
Micronutrients
Essential Elements
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Essential Elementsnutrients
An essential element is one that is:- Required for normal plant growth and reproduction.- Plant cant complete their life in the absence of this element,- Involved in one or more of biological activities carry out in
plant- Deficiencies symptoms appear on plant upon inadequate
supply of the element, and these symptoms disappear upontreating plants with the element,
- Cant be replaced by another element.
Essential Elementsnutrients
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nutrientss These elements called nutrients
s Nutrients : Elements essential for plant growth (e.g., Carbon, Hydrogen,Oxygen, Nitrogen, Phosphoresces, Potassium, Calcium, Magnesium,Slushier, Iron, zinc, Manganese, Copper, Boron, Molybdenum andchlorine).
s
Scientists reported that, among all elements absorbed by plant and existin their tissues, only 18 elements are reported as essential elements tillnow.
s Other elements may added to this group in future.
s Elements such as, Ni and Co, are called beneficial elements. May betheir necessities to plant ascertain in near future.
Essential Element
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Essential ElementNutrients
Exception for carbon (C)and oxygen (O), whichare supplied fromatmosphere, and (H)that supplied fromwater, the essentialelements are obtainedfrom the soil.
Essential elements and the chemical forms
most commonly taken up by plants.
C t i f ti l
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Categories of essentialelements
Essential elements can be grouped into four categories based ontheir;
1- origin2- The relative amount a plant needs in order to grow properly.
Functions of essentialelements in plants
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elements in plantss Carbon, Hydrogen, & Oxygens Directly involved in photosynthesis, which accounts for most of plant
growth:s 6 CO2 + 12 H2O 6 O2 + 6 (CH2O) + 6 H2O
s Nitrogens Found in chlorophyll, nucleic acids, and amino acids.s Component of protein and enzymes
s Phosphoruss Important for plant development including:s photosynthesis, respiration, cell division, and other processess Essential component of Adenosine Triphosphate (ATP), which is directly
responsible for energy transfer reactions in the plant.s Essential component of DNA and RNA, and phospholipids, which play
critical roles in cell membranes.
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Functions of essentialelements in plants
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elements in plantss Sulfur
Required for the synthesis of the sulfur-containing amino acids cystine,cysteine, and methionine, which are essential for protein formation.
s Boron
Essential for germination of pollen grains and growth of pollen tubes
Forms sugar/borate complexes associated with the translocation of sugars,starches, N, and P.
s Copper
Necessary for chlorophyll formation.
Catalyzes several enzymes.
s
Iron Serves as a catalyst in chlorophyll synthesis.
Involved in many oxidation-reduction reactions during respiration andphotosynthesis.
Functions of
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Functions ofessential elements
in plantss Manganese
Functions primarily as a part of the enzyme systems in plants.
Activates several important metabolic reactions (enzymes).
s Zinc
Essential for promoting certain metabolic/enzymatic reactions.
Necessary for the production of chlorophyll, carbohydrates, and growth hormones.
Molybdenum
Essential in the process of symbiotic N fixation by Rhizobia bacteria in legume rootnodules.
s Chlorine
Involved in: energy reactions in the plant
Serves as a counter ion in the transport of several cations in the plant.
Nutrient Availability to Plant
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Nutrient Availability to Plant
Ion mobil ity in soilsAnions(negatively charged ions) usually leach morereadily than cations because they are not attracted to thepredominantly negative charge of soil colloids.
For example, NO3- , due to its negative charge andrelatively large ionic radius, is not readily retained in thesoil and is easily lost from soils by leaching.
An exception to this behavioris phosphorus anions(HPO4=,H2PO4-). These anionic forms do not easilyleached through the soil profile because of their specificcomplexing reactions with soil components.
Nutrient Availability to Plant
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Nutrient Availability to Plant
Effect of pH on nutrientavailabil ity The most important soil property influencenutrient availability is soil-pH:
Nutrients exist in soil in many chemical forms.Not all these forms are available to plant.Usually the soluble and exchangeable forms
are available to plants, the other forms arenot available to plant. Transformation ofnutrients from soluble to insoluble form andvice versa are affected by soil-pH value.
Nutrient Availability toPlant
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PlantEffect of pH on nutrient
availabil ity
The relationshipbetween soil pHand the relative
plant availability ofnutrients.
In general; except for Mo and B, the availabilityof most nutrients increased as soil pH decreased
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of most nutrients increased as soil pH decreasedto be lower than 7.
P: Phosphorus Plant availability of P isgenerally greatest in the pH range of 5.5 -6.5. When soil pH falls below 5.5, P reactswith Fe and Al to produce insoluble Fe andAl phosphates that are not readilyavailable for plant uptake.
At pH higher than 6.5, P reacts with Ca toform Ca phosphates that are relativelyinsoluble and have low availability toplants.
K, Ca, and Mg: These nutrients are mostpresent in soils in available form at pHhigher than 6.0. Their availability to plantsdecreased in acid soil. They may have beenpartially leached out of the soil profile.
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Micronutrients: In general, mostmicronutrients are more available in
acidic than alkaline soils. As pHincreases, micronutrient availabilitydecreases.
An exception to this trendis Mo and B;their availability increase as soil pH
increases.Al, Fe, and Mn Toxicity: At pH values lessthan 5.0, solubility of Al, Fe, and Mnincrease and their concentrations insoil solutions increase to be toxic toplant.
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Fertilizers
N- Fert.
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Urea
P- Fertilizers
K- Fert. (KCl)
Fertilizers
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s Expressions:-s - Fertilizer: Any organic or inorganic material of natural or synthetic origin
that added to soil to supply plant with one or more essential element.
s - Fertilization: The process in which nutrients are added to soil in the formof chemical fertilizers, animal manure, green manure or compost.
s Foliar fertilization : Application of a dilute solution contains
nutrient elements to plant foliage, usually, to supplement nutrients absorbedby plant roots.
s Fertigation: Application of nutrients through irrigation water.
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Fertilizers
s Fertilizers are classified into two major groups:s 1- Organic fertilizers
2- Inorganic fertilizers (mineral fertilizer or
chemical fertilizer)- Inorganic fertilizers are classified to 2 types;
- Simple (single) fertilizers: in which a fertilizer contain
only one nutrient (e.g., urea)
- Complete fertilizer: in which a fertilizer contain two ormore nutrients.
1- Inorganic fertilizers(mineral or chemical
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(mineral or chemicalfertilizers)
A chemical Fertilizers are fertilizers that contain nutrients in mineralform including either single or compound fertilizers.
* Single fertilizers include 3 main types:
I N- Fertilizers (Nitrogen fertilizers):-1- Ammonium Nitrate (NH4NO3): Contains 33% N.
- N exist in two forms NH4+ and NO3- . These two
forms are avoidable to plants.2 - Ammonium sulfate [(NH4)2SO4]: Contains 21% N.3 - Urea [(CO(NH2)2]: Contain 46 % N.
1- Inorganic fertilizers(mineral or chemical
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(mineral or chemicalfertilizers)
II P- Fertilizers (Phosphate fertilizers):-1- Single Supers phosphate {Ca(H2PO4)2: Contain 16-
22 % P2O5.2-Triple Super-phospate {Ca(H2PO4)2}: Contains 4452%
P2O5.
III -K- Fertilizers (Potassium Fertilizers)1- Potassium chloride (KCl): Contain 60-63% K2O.2- Potassium Sulfate (K2SO4): Contain 5053% K2O.
Potassium sulfate is much more preferable than
potassium chloride, particularly for crops sensitive to Cl ions such as
potatoes.
1- Inorganic fertilizers(mineral or chemical
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(mineral or chemicalfertilizers)
s IV - Micronutrient Fertilizers
Micronutrients are usually supplied in chelated form and added to plants byfoliar spraying. Also, they could be supplied in mineral form. However, mineralform is less soluble.
s Definition: Chelating agent are organic molecules such as EDTA, EDDHA,...These compounds have the ability to make chemical bonds (co-ordinate covalent
bond) with Fe, Mn, Cu, Zn. The chelates are readily soluble, even at higher pHvalues, which increase their suitability and high efficiency for plants. They couldbe added either to soil or by foliar applications.
s - Mineral Sources of micronutrient fertilizer: Micronutrients are usuallysupplied in sulfate form, such as; Ferrous sulfate, FeSO4.7H2O, Mn sulfate, Zn
sulfate and Cu sulfate ..
s - Other micronutrients such as boron is supplied in form of Borax, andMolybdenum in form of ammonium molybdate.
Organic
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OrganicFertilizers
2 Organic fertilizers
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2 Organic fertilizers
s
Organic fertilizers are the residues of plant and animals usuallycontain various macro- and micro-nutrients in an organic form andin different quantities. These fertilizers include, cow manure, chickenmanure, farmyard manure, compost and green fertilizer.
s Usually nutrients of organic fertilizers exist in an organic form not
available to plant. Organic manure should be decomposed bymicro-organisms to transform nutrients to simple ions in mineralform such as, NO3, K+, Mn++,.. available to plant.
s Organic fertilizers have many advantages to soil and plant, besidesthey provides macro- and micro-nutrients to plant.
Soil Survey &
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Soil Survey &
Classification
Soil Survey
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Soil Survey
s Soil Survey: Is an organized process in which a great number
of information are collected for a certain area of soil through
field and lab studies.
s How do we organize and classify soils?Soil surveyors are able to distinguish differences in soil
properties and group soils according to their mode of formation.
This is done by digging holes (soil profile) and inspecting the
layers, as well as examining the surrounding landscapefeatures.
The origin of the materials and the soil properties are examined
in each layer of soil. Each layer, or horizon, of soil is classified
according to physical and chemical properties.
Soil
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SoilClassification
U.S. Taxonomy:s In U.S. Taxonomy, soils are divided into different
categories; 1- orders, 2- sub orders, 3- great groups,
4- sub great groups, 5- families and 6- series.s According to U.S. Taxonomy: All soils around the
world can be grouped very generally into these 12
orders.
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Order : 12
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The Twelve Orders of Soil Taxonomy
1- Alfisols (humid cont. Fe and Al oxides )
2- Andisols ( volcanic )3- Aridisols ( desert )
4- Entisols (recent soils)
5- Gelisols (permaforst)
6- Histosols (organic soils )7- Inceptisols (subarctic, tundra)
8- Mollisols ( steppe )
9- Oxisols (tropical)
10- Spodosols ( acidic soil, amorphous materials horizon)
11- Ultisols (humid suptropical)12- Vertisols ( cracked soil)
ftp://ftp-fc.sc.egov.usda.gov/NSSC/Soil_Orders/orders_hi.pdfftp://ftp-fc.sc.egov.usda.gov/NSSC/Soil_Orders/orders_hi.pdfftp://ftp-fc.sc.egov.usda.gov/NSSC/Soil_Orders/alfisols.pdfftp://ftp-fc.sc.egov.usda.gov/NSSC/Soil_Orders/andisols.pdfftp://ftp-fc.sc.egov.usda.gov/NSSC/Soil_Orders/aridisols.pdfftp://ftp-fc.sc.egov.usda.gov/NSSC/Soil_Orders/entisols.pdfftp://ftp-fc.sc.egov.usda.gov/NSSC/Soil_Orders/gelisols.pdfftp://ftp-fc.sc.egov.usda.gov/NSSC/Soil_Orders/histosols.pdfftp://ftp-fc.sc.egov.usda.gov/NSSC/Soil_Orders/inceptisols.pdfftp://ftp-fc.sc.egov.usda.gov/NSSC/Soil_Orders/mollisols.pdfftp://ftp-fc.sc.egov.usda.gov/NSSC/Soil_Orders/oxisols.pdfftp://ftp-fc.sc.egov.usda.gov/NSSC/Soil_Orders/spodosols.pdfftp://ftp-fc.sc.egov.usda.gov/NSSC/Soil_Orders/ultisols.pdfftp://ftp-fc.sc.egov.usda.gov/NSSC/Soil_Orders/vertisols.pdfftp://ftp-fc.sc.egov.usda.gov/NSSC/Soil_Orders/vertisols.pdfftp://ftp-fc.sc.egov.usda.gov/NSSC/Soil_Orders/ultisols.pdfftp://ftp-fc.sc.egov.usda.gov/NSSC/Soil_Orders/spodosols.pdfftp://ftp-fc.sc.egov.usda.gov/NSSC/Soil_Orders/oxisols.pdfftp://ftp-fc.sc.egov.usda.gov/NSSC/Soil_Orders/mollisols.pdfftp://ftp-fc.sc.egov.usda.gov/NSSC/Soil_Orders/inceptisols.pdfftp://ftp-fc.sc.egov.usda.gov/NSSC/Soil_Orders/histosols.pdfftp://ftp-fc.sc.egov.usda.gov/NSSC/Soil_Orders/gelisols.pdfftp://ftp-fc.sc.egov.usda.gov/NSSC/Soil_Orders/entisols.pdfftp://ftp-fc.sc.egov.usda.gov/NSSC/Soil_Orders/aridisols.pdfftp://ftp-fc.sc.egov.usda.gov/NSSC/Soil_Orders/andisols.pdfftp://ftp-fc.sc.egov.usda.gov/NSSC/Soil_Orders/alfisols.pdfftp://ftp-fc.sc.egov.usda.gov/NSSC/Soil_Orders/orders_hi.pdf -
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Soil orders exist in
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Soil orders exist in
Egypt:1- Entisols: Recent soil, undeveloped, has nodiagnostic horizons, has no developed profile.
2- Aridisols: Typical arid regions (desert soil),has surface horizons (epipedons), hasdiagnostic or subsurface horizons (clacic,gypsic and agrillic horizon).
3- Vertisols: Highly fertile soil, High claypercentage (> 30%), clay are rich inmontmorillionite minerals, High CEC (>30Cmol(c)/kg), cracked soil due to expansion
and shrinkage of clay mineral.
Term paper:You can Choose any agricultural issue to speak about. Or one ofthe following subjects:1- Physical weathering2- Chemical weathering
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2 Chemical weathering3- Biological weathering4- Time as soil formation factor5- Types of Egyptian soil6- Types of Somali soils
7- Types of Nigerian Soils8- Types of Chad soils9- Sedentary soil10- Transported soil11- Organic fertilizers12- Compost13- Nitrogenous fertilizers14- Potassium fertilizers
15- Phosphate fertilizers16- Micronutrient fertilizers17-Chelating fertilizers18- Foliar fertilization19- Soil texture20- Soil structure21- Soil erosion22- Desertification23- Cation Exchange Capacity of Soil24- Soil Buffering action25- Soil pH26- Soil solution27- Role of Hydrogen ion in chemical weathering28- Soil formation processes29- Hydrous oxides in soil30- Amorphous material in soil31- Humus formation32- Major components of humus
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Thank YouThank You
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