Lecture 11 - Soil Aeration
0.22 to 0.18
Oxidized: Mn4+ reduced: Mn2+ Eh when change occurs?
<20%
below what air-filled porosity do negative effects on plant and microbial growth occur
0.3/0.4 to as high as 10%. above 10% can be toxic to plants
carbon dioxide: how soil air differs from the above-ground atmosphere
it is better to aerate soil during growing season because the soil and grass can heal and fill in any of the areas removed by plugs
during growing season vs. before or after growing season
chart. in each reaction, the oxidized form of the element is on the left side and the reduced form is on the right side with the arrows indicating that the reactions can go either way
effect of pH on the Eh at which several important redox reactions theoretically take place
soil water content, macroporosity, O2 consumption
general factors affecting soil aeration
redox potential (Eh) of approximately 0.3 V
generally, below what redox potential is the O2 content of soil considered to be 0
drainage holes for removal of excess water. taller pots allow more aeration in upper part of the medium. use of coarse-grained media (perlite, vermiculite, pumice)
how are containerized plants managed to promote aeration
soil structure and tillage. large, stable aggregates promote aerations. tillage is used to maintain aeration in poorly drained, heavy-textured soils. tile drainage in poorly drained soils
how can agricultural soils be managed to promote adequate soil aeration
GER DONR LEO IONO
how can an oxidizing reaction be distinguished from a reducing reaction
water-filled pores block the diffusion of oxygen to replace what is used by respiration. oxygen diffuses 10,000x faster through air-filled pores than water-filled pores
how does oxygen movement through open pores compare to movement through water-filled pores.
usually PP of O2 is higher in atmosphere than in soil. PP of CO2 is higher in soil than in atmosphere
how does the PP of O2 and CO2 relate between soil and atmosphere
as oxygen content of soil decreases, redox potential also decreases
how is oxygen content related to redox potential
measured as voltage through a platinum electrode
how is redox potential (Eh) usually measured in soils
[(total porosity-volume of water)/total porosity] x 100
how to calculate air-filled porosity
1-(bulk density/particle density)
how to calculate total porosity
drainage of excess water through macropores
macropores vs. no macropores
78%. same as atmosphere
nitrogen: how soil air differs from the above-ground atmosphere
addition of a soil amendment causes microbial population to increase which leads to more O2 being consumed
organic soil amendments vs. no organic amendments
-0.2 to -0.28
oxidized: CO2 reduced: CH4 Eh when change occurs?
0.11 to 0.08
oxidized: Fe3+ reduced: Fe2+ Eh when change occurs?
0.28 to 0.22
oxidized: N03- reduces: N2 Eh when change occurs?
0.38 to 0.32
oxidized: O2 reduced: H20 Eh when change occurs?
-0.14 to -0.17
oxidized: SO4- reduced: S2- Eh when change occurs?
0-20%. depends on depth, porosity, and water content
oxygen: how soil air differs from the above-ground atmosphere
supply oxygen to plant roots (respiration), allow release of toxic gases (methane, ethylene, CO2)
primary functions of soil aeration
saturated and dry are negative, wet is the best
soil moisture status: saturated vs. wet. vs. dry
oxidizing agents
substances that easily accept electrons are called
reducing agents
substances that easily donate electrons are called
air-filled porosity
the percentage of total pore space occupied by air
redox potential (Eh)
the tendency of a substance to accept or reject electrons is called
content of various gases in the soil atmosphere, air-filled porosity, oxidation-reduction (redox) status
three main ways that soil aeration is described
soil aeration by tillage can increase aeration, but it can also affect the organic matter and living organisms in that soil
tillage vs. no tillage
topsoil is better for aeration because there is more organic materials present there, and the soil is generally looser
topsoil vs. subsoil
Eh decreases pretty much immediately, and then stays steady at that lower Eh as time increases
what impact do saturated conditions at or near the soil surface have on the redox potential of soils
breakdown of organic residues, redox transformation of elements, plant growth
what major ecological processes are largely affected by soil aeration
diffusion: move from areas of high partial pressure to areas of low partial pressure
what physical process governs the movement of gases into and within soils
tree transplanting. when transplanting trees, make large, irregularly shaped hole and backfill with porous materials. protect established trees during grading operations
what practices are used in managing trees and lawns for proper aeration
FeO - Fe(II); NH4+ - N(III)
what types of elements/compounds are found in poorly aerated soils
FeOOH - Fe(III); NO3- - N(V)
what types of elements/compounds are found in well-aerated soils
methane (CH4), hydrogen sulfide (H2S), ethylene (C2H4)
which gases are generally associated with waterlogged or anaerobic soil conditions
unfavorable because O2 deficiency and buildup of toxic gases. exceptions (hydrophytes): mangrove trees, rice, cattails
why are waterlogged soils unfavorable for most plant production and what are some exceptions
nutrient availability, mobility of nutrients/pollutants, toxicity of certain elements, corrosivity of soil (pipes, USTs)
why is knowledge of redox potential important for the use and management of soils
