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Title: Soil pH, Acidity and Liming
Speaker: Bill Pan
online.wsu.edu
Soil pH, Acidity and Liming
Chapter 3 in Your Text
Thanks to R. Koenig for some slide material
Topics
Soil pH defined
Nature and extent of soil acidity
Sources of soil acidity
Importance of soil pH and acidity
Active and reserve acidity
Liming to increase soil pH
Soil pH Defined
In words: pH is equal to the negative log of the hydrogen ion concentration in moles per liter
Mathematically ◦ pH = -log [H+] ◦ [H+] = 10-pH
[H+] pH
1 x 10-5 5
1 x 10-6 6
1 x 10-7 7
3.44 x 10-6 5.46
pH is expressed using a log scale:
one unit change in pH equates to
10-fold change in [H+]
Higher [H+] = lower pH
pH Scale and Range in Soils
www.cropsoil.uga.edu/soilpHturf/
Figure 3.2 from your text
Worldwide, 25 to 30% of
agricultural soils are acidic
Acidic soils are associated
mainly with high rainfall areas;
alkaline (basic) soils are
associated mainly with arid
(low rainfall areas)
Why?
Nature and Extent of
Soil Acidity
One Effect of Precipitation: Leaching
Western U.S. Midwest U.S.
Leaching of
carbonates deep
into, or completely
out of, the soil
profile
Leaching of basic
cations from soil,
leaving acidic
cations
U.S. Soil pH Map forages.oregonstate.edu/maps
acidic
alkaline
Another Effect of Precipitation: Rainfall pH
jrscience.wcp.muohio.edu
Low rainfall
pH is
associated
with urban
and
industrial
areas (“acid
rain”)
Washington State
gocalifornia.about.com
High rainfall,
low soil pH
Low rainfall,
neutral to high
soil pH
Low to
intermediate
rainfall, low
soil pH
(recently
acidified
soils)
Sources of Soil Acidity
Rainfall and carbon dioxide ◦ H2O + CO2 ↔ H2CO3 ↔ H+ + HCO3
-
◦ In equilibrium with atmosphere, pH = 5.7
Other gasses in the atmosphere (“acid rain”) ◦ SO2 + ½O2 + H2O ↔ SO4
2- + 2H+
Soil organic matter ◦ “Soil atmosphere” has about 10-fold higher carbon dioxide concentration due to organic matter decomposition Effect on pH?
◦ Organic acids released during decomposition
Sources of Soil Acidity
Nutrient transformations and uptake (Table 3-2 in your text)
Process Reaction pH Effect
Nitrogen mole H+/mole N or S
Mineralization R-NH2 + H+ + H2O ↔ R-OH + NH4+ -1
Denitrification 2NO3- + 2H+ ↔ N2 + 2½O2 + H2O -1
Urea hydrolysis (NH2)2CO + 3H2O ↔ 2NH4+ + 2OH- + CO2 -1
NO3- uptake NO3
- + 8H+ + 8e- ↔ NH2 + 2H2O + OH- -1
SO4-2 uptake SO4
-2 + 8H+ + 8e- ↔ SH2 + 2H2O + 2OH- -2
Immobilization NH4+ + R-OH ↔ R-NH2 + H+ + H2O +1
Nitrification NH4+ + 2O2 ↔ NO3
- + H2O + 2H+ +2
Volatilization NH4+ + OH- ↔ NH3 + H2O +1
NH4+ uptake NH4
+ + R-OH ↔ R-NH2 + H+ + H2O +1
S Mineralization R-S + 1½O2 + H2O ↔ SO4-2 + 2H+ +2
Raises
pH
Lowers
pH
Consume H+
or release
OH-
Consume
OH- or
release H+
Aside: Basic and Acidic Cations
“Basic cations” ◦ Calcium (Ca2+), magnesium (Mg2+), potassium (K+), sodium (Na+) – no acid reaction
“Acidic cations” – acid or acid reaction ◦ H+
◦ Fe3+ and Al3+ via hydrolysis (water splitting) reactions:
Al3+ + H2O ↔ Al(OH)2+ + H+
Al(OH)2+ + H2O ↔ Al(OH)2+ + H+
Al(OH)2+ + H2O ↔ Al(OH)3(s) + H+
Importance of Soil pH and Acidity pH influences most inorganic chemical
and biological reactions – extremely important
Affects nutrient availability in soil Affects availability, and therefore
toxicity, of certain elements Affects microbial activity Affects many soil-borne pathogens Affects the number of cation exchange
sites in soil Overall, pH significantly affects plant
growth
pH Affects “Availability”
pH-induced deficiency
(Fe): nutrient is present
but unavailable due to
chemical form in soil:
Fe3+ + 3H2O ↔ Fe(OH)3(s) + 3H+
toxicity
deficiency
pH-induced toxicity:
element is present in
high concentration in a
plant-available form
Al3+ + 3H2O ↔ Al(OH)3(s) + 3H+
High pH soil
neutralizes
H+,
removing
from
reaction
Low pH soil
contributes
H+ to the
reaction
www.ca.uky.edu
One High pH Problem: Iron Deficiency
“Interveinal chlorosis”
on younger leaves
One Low pH Problem: Aluminum Toxicity
Aluminum toxicity on wheat
seedlings (Brown, 2006)
Soil pH optimums
vary by plant
species
Figure 3-13
from your text
Yield vs. Soil pH (N. Idaho)
Opportunity: pH and Ornamentals
Hydrangea flowers respond to Al availability ◦ Blue at pH <5.5
◦ Pink at pH >6.0
www.meltonrossnewbarnetby.co.uk
pH Affects Microbial Activity
Many microbial processes have optimum pH range ◦ In general, fungi tolerate low pH; bacteria high pH
◦ Mineralization (both fungal and bacterial process) occurs over a broad range of soil pHs
◦ Nitrification and denitrification (primarily bacterial processes) are optimum at near neutral pH
Soil-borne pathogens have pH optimum ◦ Fungal pathogens favored at low pH ◦ Bacterial pathogens favored at higher pH
Reduced Organic Matter Decomposition at Low Soil pH
Reduced nitrogen mineralization from soil organic matter and organic fertilizers
Thatch accumulation in turfgrass sods
Thatch Accumulation
Unusual Disease Epidemics
Dreschlera leaf spot of ryegrass overseeding in Feb.
Bermudagrass rust during spring green-up Fusarium and Ascochyta blights of ryegrass
and bermudagrass
ALL OCCURRED WITH SOIL pH around 4.0
http://virtual.clemson.edu/groups/
turfornamental/tmi/fertlime/disease.htm
and lowph.htm
Fairy Ring Symptoms on Bermudagrass
Ideal Environment for Fairy Ring Fungi
mycelium
Manganese deficient soybean from
over-liming an
Atlantic Coastal Plain soil
pH Affects Cation Exchange Sites
Sites on organic matter:
R – COOH ↔ R-COO- + H+ (H+ dissociates and is neutralized
at high pH)
Sites on the edges of Fe and Al oxides and clay minerals:
OH2+ OH O-
Al ↔ Al ↔ Al
OH2+ OH O-
Low pH ----- Neutral to high pH ----- Edge of
mineral
Potential vs. Active Acidity
Soil particles ↔ Soil solution
Potential acidity (quantity) ↔ Active acidity (intensity)
Majority of acidity in soil Minority of acidity in soil
Root are exposed to active portion
- -
- - -
-
-
- - - -
-
-
- -
-
-
-
- -
-
-
- - - -
- -
-
-
Al3+
Al3+
Al3+
Al3+
H+
H+
H+
H+
H+ Ca2+
Ca2+
Ca2+
Ca2+
Mg2+
K+
K+
Na+
↔
Al3+
H+
Ca2+
Mg2+
K+
Na+
Measuring Potential Acidity
Titrations with base or incubation with different amounts of lime
SMP buffer method
Both methods assess acidic
cations on CEC sites
SMP Buffer Interpretation Table
Soil+
buffer
pH
7.0 6.5 6.0 5.2
6.8 1.4 1.2 1.0 0.7
6.0 9.6 8.1 6.6 5.1
5.5 14.8 12.5 10.5 7.8
------ tons CaCO3/acre ------
Percent Base Saturation
- -
- - -
-
-
- - - -
-
-
- -
-
-
-
- -
-
-
- - - -
- -
-
-
Al3+
Al3+
Al3+
Al3+
H+
H+
H+
H+
H+ Ca2+
Ca2+
Ca2+
Ca2+
Mg2+
K+
K+
Na+
% base saturation =
% acid saturation = ?
cmol(+) exchangeable bases x 100
CEC (cmol[+] per kilogram)
43% in this example
Generally, as base saturation
increases pH also increases
Base saturation can be used
to develop a lime requirement
Measuring Active Acidity
pH electrode ◦ Saturated soil paste
◦ 1:1, 1:2 or 1:10 soil:water ratios
◦ Others solutions may also be used
Stratification of acidity under direct seeding
6 inches
Broadcast lime
Untreated
Within Field Surface Soil pH Variability near Pullman, WA
Liming to Increase Soil pH
Neutralize toxic elements: Al, Mn, H
Improve overall nutrient availability (recall the graphic)
Increase microbial activity
Increase effective CEC
Improve soil structure with Ca
Improve Ca and Mg availability
Overall, improve plant growth
Some Liming Reactions
CaCO3
◦ CaCO3 + 2H+ ↔ Ca2+ + CO2 + H2O
Ca(OH)2
◦ Ca(OH)2 + 2H+ ↔ Ca2+ + 2H2O
CaO ◦ CaO + 2H+ ↔ Ca2+ + H2O
Neutralizing Acidity
-
-
- -
- -
-
-
-
- Al3+
H+
H+
Ca2+
3 CaCO3
= 6 H+ can be
neutralized; 3
Ca2+ released
↔ Al3+
2H+
H+
H+
H+
} = 5H+
Neutralizing Acidity-Step 2
Review Equivalent Weight (pg 18-27) For an ion, the atomic weight divided by
the charge ◦ Ca2+: 40 g/mol ÷2 = 20 g/equivalent= 20 mg/milliequivalent (meq)
For a molecule of lime, the molecular weight divided by the number of moles of H+ neutralized ◦ CaCO3: 100 g/mol ÷2 = 50 g/equivalent= 50 mg/meq
Importance of meq?
It’s just a number
CEC is expressed in units of meq/100 grams of soil (or cmol(-)/kg soil …it’s the same number)
Exchangeable acidity is expressed in meq H+/100 grams of soil
Lime Effectiveness
Chemical composition and purity (Calcium carbonate equivalent)
Fineness (finer particles react faster to neutralize acidity; big particles stay unreactive longer)
Application and incorporation method…incorporation speeds the soil reaction…topdressing without incorporation slows the reaction.
Lime Neutralizing Value (Calcium Carbonate Equiv.)
MATERIAL MW Calcium
Carbonate
Equivalent
calcite 100 100%
dolomite
CaMg(CO3)2
184 2(100)/184=
109%
burned lime
CaO
56 100/56=
179%
hydrated lime
Ca(OH)2
74 100/74=136%
Lime Reacted in 1 to 3 years
0
20
40
60
80
100
4 to 8 8 to 20 20 to 50 50 to 100
# Mesh Holes per area of sieve
fine coarse
% L
ime R
eacte
d
Depth of Lime Incorporation: Lime Moves Slowly, Should Be Tilled-In to Be Effective
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