Term
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Definition
smallest unit of matter that maintains the distinguishing features of an element.
Example: N (nitrogen) |
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Term
|
Definition
smallest unit of compound or element with stable, independent existence.
Example: N2 (N gas), NH3 (ammonia) |
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Term
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Definition
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Term
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Definition
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Term
|
Definition
Number of protons in the nucleus of an atom |
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Term
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Definition
1/12 mass of the nucleus of carbon (amu) |
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Term
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Definition
mass of atom in amu
Example: C → 12 amu N → 14 amu H → 1 amu |
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Term
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Definition
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Term
|
Definition
mass of a molecule in amu |
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Term
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Definition
6.02 x 1023 particles (atoms, molecules) |
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Term
the weight of 1 mole of atoms |
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Definition
atomic weight of the atom |
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Term
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Definition
Number of positive or negative charges on an ion |
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Term
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Definition
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Term
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Definition
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Term
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Definition
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Term
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Definition
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Term
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Definition
Quantity that will release, react with, or be equivalent to 6.02 x 1023 hydrogen ions (H+) |
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Term
|
Definition
(moles of solute)/(liter of solution) |
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Term
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Definition
(equivalents of solute)/(liter of solution) |
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Term
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Definition
percentage of weight made up by element or compound of interest |
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Term
depth of 1 acre furrow slice |
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Definition
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|
Term
predicted increase in cereal consumption for food over the next 4 decades |
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Definition
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|
Term
predicted increase for meat consumption over the next 4 decades |
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Definition
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Term
why it might be costly for agriculture to expand into new areas |
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Definition
-poor soil fertility -shallow soil depth -low rainfall -etc. |
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Term
great risks caused by agricultural expansion |
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Definition
-biodiversity -soil erosion -other factors impacting ecosystem health |
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Term
why per capita cropland assessments are misleading |
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Definition
because of the changing distribution of human populations in urban and rural areas |
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Term
current estimates state that ______% of future crop production increases will come from ______ compared to ______. |
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Definition
90% intensification expansion of cropland |
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Term
the primary causes of soil degradation |
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Definition
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Term
why undeveloped and developing nations will continue to rely on food imports |
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Definition
because this is where the majority of future population growth is gonna be and the soil in these areas that could be converted to cropland is substantially less productive than current croplands |
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Term
why using corn for ethanol is not sustainable |
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Definition
because using it for ethanol makes it harder for undeveloped and developing countries to meet their basic food needs |
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Term
using ethanol as fuel in the future will require this |
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Definition
use of lignocellulose feedstocks, such as crop residues, forest products, etc. |
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Term
why there are limits to using field crop residues for ethanol |
|
Definition
because organic residues returned to soils are critical to sustaining soil and crop productivity |
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Term
meeting future food and fiber demand, while protecting environmental health, will require this |
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Definition
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Term
why meeting future food and fiber demand, while protecting environmental health, will require ag intensification |
|
Definition
-decreasing available land for cultivation -maintaining and enhancing natural land areas is critical to sustaining ecosystem diversity and health |
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Term
this is critical to sustaining ecosystem diversity and health |
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Definition
maintaining and enhancing natural land areas |
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Term
why advances in ag production technologies must occur |
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Definition
to enhance productivity per unit of cropland to ensure world food security |
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Term
the principal factors contributing to higher crop yields |
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Definition
include: -development of improved varieties and hybrids -nutrient and pest management -soil and water conservation -cultural practices |
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Term
why the continued growth of N fertilizers will increase demand for fossil fuel |
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Definition
because natural gas (CH4) is a primary ingredient in the manufacture of N fertilizers |
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Term
why improved nutrient management technologies are needed |
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Definition
to reduce the impact of nutrient use on environmental quality and ecosystem health |
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Term
one important nutrient management principle discussed throughout the book |
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Definition
the importance of maximizing crop productivity to increase the quantity of applied nutrient recovered by the crop |
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Term
why it's important to maximize crop productivity to increase the quantity of applied nutrient recovered by the crop |
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Definition
because it reduces the quantity of applied nutrient in the soil after harvest and, thus, reduces the impact of nutrient use on the environment |
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Term
Carl Sprengel and Justus von Liebig |
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Definition
19th century scientists who developed the Law of the Minimum |
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Term
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Definition
states that crop yield is proportional to the amount of the most limiting nutrient |
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Term
some climate factors that affect crop yield potential |
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Definition
-precipitation
-air temp
-relative humidity
-light
-altitude
-latitude
-wind
-CO2 concentration |
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Term
some soil factors that affect crop yield potential |
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Definition
-organnic matter -texture -structure -CEC -pH -base sat -slope and topography -soil temp -soil management factors -depth (root zone) -nutrient supply (soil test) -element toxicity |
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Term
some soil management factors |
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Definition
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Term
some crop factors that affect crop yield potential |
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Definition
-crop species -variety -seeding rate -geometry -seed quality -evapotranspiration -water availability -nutrition -pests -harvest efficiency -crop sequence or rotation - - |
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Term
some pests that can affect crop yield potential |
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Definition
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Term
the order in which limiting factors should be minimized |
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Definition
1: the most limiting factor 2: the 2nd most limiting factor 3: so on and so forth |
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Term
an element is considered essential to plant growth and development if... |
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Definition
-the element is directly involved in the nutritionof the plant -a deficiency makes it impossible for the plant to complete its life cycle, and -a deficiency is specific to the element and can only bee prevented or corrected by supplying the element |
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Term
why you must use caution when evaluating a visual symptom on a plant |
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Definition
because there's lots of things that can cause the visual sumptoms |
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Term
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Definition
when the concentration of an element is low enough to severely limit yield and distinct deficiency symptoms are visible |
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Term
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Definition
the nutrient concentration in the plant below which a yiield response to added nutrients occurs |
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Term
where critical range occurs |
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Definition
somewhere between deficient and sufficient |
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Term
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Definition
the nutrient concentration range in which added nutrient will not increase yield but can increase nutrient concentration |
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Term
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Definition
absorbtion by the plant that does not influence yield |
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Term
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Definition
when the concentration of essential or other elements is high enough to reduce plant growth and yield |
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|
Term
excessive nutrient concentration can cause this, which can also influence yield |
|
Definition
an imbalance in other essential nutrients |
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Term
|
Definition
when under severe deficiencyrapid increases in yield with added nutrient cause a small decrease in nutrient concentration |
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Term
what causes the Steenberg effect? |
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Definition
dilution of the nutrient in the plant by rapid plant growth |
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Term
when the concentration of nutrient reaches this range, plant yield is generally maximized |
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Definition
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Term
how excessive quantities of elements can reduce plant yield directly |
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Definition
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Term
how excessive quantities of elements can reduce plant yield indirectly |
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Definition
reducing concentrations of other nutrients below their critical ranges |
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Term
essential macronutrients in order of abundance in plants |
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Definition
1: H 2: C 3: O 4: N 5: K 6: Ca 7: Mg 8: P 9: S |
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Term
essential micronutrients in order of abundance in plants |
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Definition
1: Cl 2: Fe 3: B 4: Mn 5: Zn 6: Cu 7: Ni 8: Mo |
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Term
plant nutrients that are not considered mineral nutrients |
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Definition
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Term
The p'synth process in green plants converts ______ into ______. |
|
Definition
CO2 and H2O
simple carbohydrates |
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Term
organic compounds that can be synthesized from simple carbohydrates |
|
Definition
-amino acids -sugars -proteins -nucleic acids -other organic compounds |
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Term
4 additional elements that have been established as beneficial micronutrients in some plants |
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Definition
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Term
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Definition
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Term
the ash left over from burning plant dry matter contains all the elements except ______ because ______. |
|
Definition
C, H, O, N, & S they are volatilized as gases |
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Term
why plants do not absorb all of the nutrients applied |
|
Definition
because many biological and chemical reactions occur w/ nutrients in soils |
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|
Term
external factors plants have to deal with |
|
Definition
-CO2 c'tration
-light
-heat
-water
-nutrients |
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Term
wheat the external factors of water, nutrients, heat, light, and CO2 c'tration do to the plant |
|
Definition
regulate plant growth and development |
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Term
where most of the water and nutrients a plant uses comes from |
|
Definition
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|
Term
why plant roots are in very close association w/ the soil |
|
Definition
because most of the water and nutrients comes from the soil |
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Term
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Definition
Capacity of a soil to support the production of a specific crop |
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Term
how soil productivity is measured |
|
Definition
in terms of yield/biomass |
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Term
soil productivity depends on... |
|
Definition
adequate moisture and soil nutrients, as well as favorable climate (temperature, rainfall) |
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Term
|
Definition
Soils’ capacity to supply elements essential for plant growth |
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|
Term
how soil fertility is measured |
|
Definition
- directly (concentration of nutrients) - indirectly (productive capacity) |
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Term
how soil fertility is measured directly |
|
Definition
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|
Term
how soil fertility is measured indirectly |
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Definition
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|
Term
soil fertility is relative to... |
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Definition
the plant being considered, that is, how the plant interacts with the nutrients |
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|
Term
how soil fertility can be improved |
|
Definition
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|
Term
soil fertility is a component of... |
|
Definition
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|
Term
why you can, to an extent, manage soil productivity |
|
Definition
because soil fertility is a component of soil productivity |
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|
Term
Importance of Soil Fertility |
|
Definition
-Agriculture depends on soil productivity -Soil productivity depends in part on soil fertility |
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|
Term
agriculture depends on... |
|
Definition
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|
Term
soil productivity depends in part on... |
|
Definition
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|
Term
population could be ______ by 2060 |
|
Definition
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|
Term
population could be 9billion by ______ |
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Definition
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|
Term
this led to an increase in farming |
|
Definition
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|
Term
mechinazation led to an increase in... |
|
Definition
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|
Term
Green Revolution was part of the ______ inprovement of ag. |
|
Definition
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|
Term
some things the Green Revolution brought to ag |
|
Definition
-fertilizers -high yielding varieties -pesticides |
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|
Term
what pesticides did for ag |
|
Definition
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|
Term
the fertilizer consumption that seems to be going up the quickest |
|
Definition
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|
Term
recent trend in global fertilizer use |
|
Definition
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|
Term
trend in U.S. fertilizer use |
|
Definition
might be increasing, but might be leveling off |
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|
Term
the largest source of N inputs into the Mississippi River basin |
|
Definition
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|
Term
the fastest growing source of N inputs into the Mississippi River basin |
|
Definition
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|
Term
such a large amount of N going into the water so quickly can lead to... |
|
Definition
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|
Term
artificial sources of N cause this |
|
Definition
increased growth of plants, algae, and other stuff |
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|
Term
after the excessive growth of plants, algae, and other stuff due to such excessive N, this leads to depleted oxygen supply |
|
Definition
microbes later lead to depleted oxygen supply |
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Term
how long it naturally takes eutrophication to occur |
|
Definition
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|
Term
how long it takes eutrophication to occur with such excessive N inputs |
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Definition
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|
Term
how microbes help in the causing of hypoxia |
|
Definition
they use oxygen to feed on stuff |
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Term
when the hypoxic zone on the Louisiana coast shows up |
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Definition
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|
Term
can phosphate and potash resources get depleted? |
|
Definition
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|
Term
yearly production of phosphate |
|
Definition
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|
Term
yearly production of phosphate |
|
Definition
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|
Term
yearly production of phosphate |
|
Definition
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|
Term
total reserves of phosphate |
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Definition
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|
Term
life of phosphate reserves |
|
Definition
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|
Term
|
Definition
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|
Term
life of US phosphate reserves |
|
Definition
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|
Term
the bulk of the phosphate reserves are in... |
|
Definition
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|
Term
yearly production of potassium |
|
Definition
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|
Term
total reserves of potassium |
|
Definition
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|
Term
life of potasium reserves |
|
Definition
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|
Term
factors affecting plant growth and yield |
|
Definition
|
|
Term
climate factors that affect plant growth and yield |
|
Definition
-rain -temp -light -wind -etc. |
|
|
Term
crop factors that affect plant growth and yield |
|
Definition
-variety -planting date -pests -etc. |
|
|
Term
soil factors that affect plant growth and yield |
|
Definition
-fertility -structure -texture -etc. |
|
|
Term
Leibig’s Law of the Minimum |
|
Definition
The level of plant production can be no greater than that allowed by the most limiting growth factor |
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|
Term
|
Definition
nutrient needed to complete life cycle |
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|
Term
how to do the water in hydroponics |
|
Definition
mix specific amounts of nutrients in solution with water |
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|
Term
how hydroponics can be used to determine which nutrients are essential |
|
Definition
eliminating one nutrient at a time helps identify essential nutrients |
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|
Term
criteria for importance of nutrients in plant life cycle |
|
Definition
1: importance in plant growth and development 2: involved in the a plant’s biochemical or physiological process |
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|
Term
how plants get most of their carbon |
|
Definition
carbon being fixed in the form of CO2 |
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|
Term
these nutrients are not considered mineral nutrients |
|
Definition
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|
Term
distribution of nutrients in plants |
|
Definition
may differ among different parts of the plant |
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|
Term
where silicon is in plants |
|
Definition
can sometimes accumulate in the leaves, as much as 10% |
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|
Term
one hypothesis about silicon |
|
Definition
says that silicon provides mechanical strength to the plants |
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|
Term
does hydroponics use silicon? |
|
Definition
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|
Term
yearly production of phosphate |
|
Definition
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|
Term
total reserves of phosphate |
|
Definition
|
|
Term
life of phosphate reserves |
|
Definition
|
|
Term
|
Definition
|
|
Term
life of US phosphate reserves |
|
Definition
|
|
Term
the bulk of the phosphate reserves are in... |
|
Definition
|
|
Term
yearly production of potassium |
|
Definition
|
|
Term
total reserves of potassium |
|
Definition
|
|
Term
life of potasium reserves |
|
Definition
|
|
Term
factors affecting plant growth and yield |
|
Definition
|
|
Term
climate factors that affect plant growth and yield |
|
Definition
-rain -temp -light -wind -etc. |
|
|
Term
crop factors that affect plant growth and yield |
|
Definition
-variety -planting date -pests -etc. |
|
|
Term
soil factors that affect plant growth and yield |
|
Definition
-fertility -structure -texture -etc. |
|
|
Term
Leibig’s Law of the Minimum |
|
Definition
The level of plant production can be no greater than that allowed by the most limiting growth factor |
|
|
Term
|
Definition
nutrient needed to complete life cycle |
|
|
Term
how to do the water in hydroponics |
|
Definition
mix specific amounts of nutrients in solution with water |
|
|
Term
how hydroponics can be used to determine which nutrients are essential |
|
Definition
eliminating one nutrient at a time helps identify essential nutrients |
|
|
Term
criteria for importance of nutrients in plant life cycle |
|
Definition
1: importance in plant growth and development 2: involved in the a plant’s biochemical or physiological process |
|
|
Term
how plants get most of their carbon |
|
Definition
carbon being fixed in the form of CO2 |
|
|
Term
these nutrients are not considered mineral nutrients |
|
Definition
|
|
Term
distribution of nutrients in plants |
|
Definition
may differ among different parts of the plant |
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|
Term
where silicon is in plants |
|
Definition
can sometimes accumulate in the leaves, as much as 10% |
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|
Term
one hypothesis about silicon |
|
Definition
says that silicon provides mechanical strength to the plants |
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|
Term
does hydroponics use silicon? |
|
Definition
|
|
Term
the majority of plant nutrient uptake is thru... |
|
Definition
|
|
Term
|
Definition
longitudinal section of the root |
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|
Term
longitudinal section of the root |
|
Definition
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|
Term
|
Definition
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Term
|
Definition
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|
Term
|
Definition
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Term
|
Definition
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|
Term
|
Definition
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Term
|
Definition
endodermis w/ casparian strip |
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Term
|
Definition
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|
Term
|
Definition
region of rapid cell division |
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Term
|
Definition
quiescent center (few cell divisions) |
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Term
|
Definition
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Term
|
Definition
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Term
|
Definition
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Term
|
Definition
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Term
|
Definition
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|
Term
|
Definition
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|
Term
meristematic region helps the root do this |
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Definition
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|
Term
2 purposes of the root cap |
|
Definition
-helps protect the tip of the root -helps it stay lined up with the force of gravity |
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|
Term
in the elongation zone, there’s less ______ and more ______ |
|
Definition
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|
Term
what happens in the maturation zone? |
|
Definition
cells taking up specific nutrients |
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|
Term
cells in the maturation zone no longer do this |
|
Definition
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|
Term
|
Definition
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|
Term
parts of the plant that take up nutrients |
|
Definition
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|
Term
|
Definition
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|
Term
|
Definition
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|
Term
|
Definition
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|
Term
|
Definition
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|
Term
|
Definition
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|
Term
|
Definition
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|
Term
|
Definition
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|
Term
the parts of the roots that don't do very much nutrient and water uptake |
|
Definition
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|
Term
the parts of the roots that do the bulk of the nutrient and water uptake |
|
Definition
maturation zone and younger |
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|
Term
characteristics of root morphology and architecture that can have effect on nutrient uptake |
|
Definition
-Root length, thickness -Branching |
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|
Term
how variations in root architrture can affect nutrient uptake |
|
Definition
increasing root surface area |
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|
Term
Factors affecting root surface area |
|
Definition
-Thinner, multiple roots have more surface area per unit volume -Root branching, which can be influenced by lateral roots -Root hairs -Association with mycorrhizae |
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|
Term
Lateral roots increase... |
|
Definition
root mass and surface area |
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|
Term
lateral root develop from the... |
|
Definition
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|
Term
|
Definition
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|
Term
|
Definition
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Term
|
Definition
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Term
|
Definition
outgrowths of epidermal cells |
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Term
|
Definition
short, rarely reaching lengths of 1mm |
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|
Term
how much of the root surface area is root hairs? |
|
Definition
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|
Term
primary points where roots absorb nutrients |
|
Definition
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|
Term
growth of root hairs affected by... |
|
Definition
|
|
Term
when plants may make more root hairs |
|
Definition
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|
Term
mycorrhizae do this for plants |
|
Definition
-contribute greatly to nutrient uptake in most plants (>80% of plants) -increase surface area |
|
|
Term
amountof plants that form mycorrhizal associations |
|
Definition
|
|
Term
when mycorrhizae are most effective |
|
Definition
under low nutrient conditions |
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|
Term
deveolpment of mycorrhizae can be inhibited by some nutrients such as... |
|
Definition
|
|
Term
how mycorrhizae can make more nutrients available to plants |
|
Definition
by using organic forms of nutrients and converting them to inorganic forms, thus making more nutrients available to plants |
|
|
Term
the 2 types of mycorrhizae that plants form associations with |
|
Definition
-Ectomycorrhiza -Endomycorrhiza |
|
|
Term
|
Definition
sheath around root tip, hyphae do not penetrate plant cells (mainly trees of temperate zones)
-these act kinda like root hairs |
|
|
Term
|
Definition
|
|
Term
|
Definition
extends surface area of roots; penetrates plant cells (widespread)
-hemps move the nutrients inside the cell |
|
|
Term
what hemps do inside plant cells |
|
Definition
move nutrients inside plant cells |
|
|
Term
when plants don't make many mycorrhizal associations |
|
Definition
when there's lots of nutrients available |
|
|
Term
illustration of the importance of mycchorizae to corn |
|
Definition
[image]
-left w/ mycorrhizal associations -right w/o mycorrhizal associations |
|
|
Term
some anatomical features roots have to regulate nutrient uptake |
|
Definition
-root hairs (epidermis) -cortex -endodermis -pericycle -phloem -xylem |
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|
Term
function of the root hairs (epidermis) |
|
Definition
|
|
Term
|
Definition
nutrients can be taken up into the symplast |
|
|
Term
function of the endodermis |
|
Definition
barrier for uncontrolled uptake; kinda limits the uptake of unneccessary substances
also limits leakage of nutrients |
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|
Term
function of the pericycle |
|
Definition
|
|
Term
|
Definition
transport from the shoot (flows down) |
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|
Term
|
Definition
transport to the shoot (flows up) |
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|
Term
location of the vascular tissue (xylem and phloem) in the root |
|
Definition
|
|
Term
|
Definition
|
|
Term
|
Definition
|
|
Term
anatomy of a monocot root |
|
Definition
|
|
Term
|
Definition
anatomy of a monocot root |
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Term
|
Definition
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|
Term
|
Definition
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|
Term
|
Definition
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Term
|
Definition
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Term
|
Definition
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Term
|
Definition
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Term
|
Definition
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Term
|
Definition
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Term
|
Definition
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Term
|
Definition
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|
Term
|
Definition
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|
Term
|
Definition
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|
Term
|
Definition
|
|
Term
|
Definition
|
|
Term
why nutrient supply to plant roots is a very dynamic process |
|
Definition
because plants adsorb cations and anions and exude H+, OH-, and HCO3- |
|
|
Term
how plants get nutrients from the soil |
|
Definition
by absorbing them from the soil solution by plant roots |
|
|
Term
what plant roots release into the soil solution |
|
Definition
small quantities of H+, OH-, and HCO3- |
|
|
Term
what nutrient uptake by plants causes to happen in the soil |
|
Definition
several chemical and biological rxns to buffer or resupply these nutrients to the soil solution |
|
|
Term
what happens to ions adsorbed to the surface of clay minerals when the soil solution needs to be buffered? |
|
Definition
they desorb from these surfaces to resupply the soil solution |
|
|
Term
what fertilizer does to the soil solution |
|
Definition
increases ion concentration in the soil solution |
|
|
Term
what can happen to ions from fertilizers if they don't remain in solution? |
|
Definition
some get adsorbed to mineral surfaces and some precipitate as solid minerals |
|
|
Term
some soil components that influence nutrient concentration in the soil solution |
|
Definition
-nutrient uptake -soil air -OM/microbes -rainfall evaporation/drainage management -mineral solubility -surface exchange (that is, in the surface of soil particles) |
|
|
Term
microbial activity is dependent on... |
|
Definition
-adequate energy supply from organic C, such as crop residues -inorganic ion availability -numerous environmental conditions |
|
|
Term
why CO2 concentration in the soil air is greater than in the atmosphere |
|
Definition
because plant roots and sil organisms use O2 and respire CO2 |
|
|
Term
ion exchange in soil occurs where? |
|
Definition
on the surfaces of clay and other minerals, organic matter (OM), and plant roots |
|
|
Term
why cation exchange capacity is generally considered to be more important |
|
Definition
because the CEC is much larger than the AEC |
|
|
Term
why it's essential to understand the origin of the surface charge of soil minereals and OM |
|
Definition
because ion exchange rxns are very important to plant nutrient retention and availabvility in soil |
|
|
Term
why nutrient supply to plant roots is a very dynamic process |
|
Definition
because plants adsorb cations and anions and exude H+, OH-, and HCO3- |
|
|
Term
the composition of aluminosilicate minerals |
|
Definition
sheets of layers of silica tetrahedra and alumina octahedra |
|
|
Term
the structure of a silica tetrahedra |
|
Definition
one Si+4 cation bonded to 4 O-2 anions |
|
|
Term
the structure of the Al octahedra |
|
Definition
one Al+3 cation bonded to 6 OH- anions |
|
|
Term
forns that clay minerals exist in |
|
Definition
|
|
Term
the most common type of 1:1 clay |
|
Definition
|
|
Term
the composition of 2:1 clays |
|
Definition
Al octahedral layer between 2 Si tetrahedral layers |
|
|
Term
the most common 2:1 clays |
|
Definition
-mica (aka illite) -smectite (aka montmorillonite) -vermiculite |
|
|
Term
|
Definition
|
|
Term
|
Definition
|
|
Term
a type of 2:1:1 clay mineral |
|
Definition
|
|
Term
composition of 2:1:1 clay minerals in acid soils |
|
Definition
interlayer Al hydroxide sheet in addition tho the 2:1 structure |
|
|
Term
composition of 2:1:1 clay minerals in basic soils |
|
Definition
interlayer Mg hydroxide sheet in addition tho the 2:1 structure |
|
|
Term
|
Definition
cation replacement in minerals, predominantly in 2:1 minerals and very little in 1:1 minerals
occurs during the formation of these minerals |
|
|
Term
the type of isomorphous substitution that contributes to montmorillonite having such a high CEC ad the ability to readily expand and contract based on moisture |
|
Definition
isomorphous substitution in the octahedral layer instead of the tetrahedral layer
this is the only isomorphous substitution that occurs in montmorillonite |
|
|
Term
in chlorite, the interlayer space is occupied by... |
|
Definition
Mg(OH)x in basic soils and Al(OH)x in acid soils |
|
|
Term
why isomorphous substitution occurs in both the octahedral and tetrahedral layers in the 2:1 vermiculite |
|
Definition
because it's commonly weathered from micas |
|
|
Term
why vermiculite has a higher CEC, but lower interlayer expansion compared to smectites |
|
Definition
because although isomorphic substitution (Al+3 for Si+4) is less than in mica, the tetrahedral charge attracts hydrated cations (Ca+2, Mg+2), which limits expansion of the interlayer compared to smectites |
|
|
Term
|
Definition
chlorite w/ a Mg hydroxide layer |
|
|
Term
|
Definition
chlorite w/ an Al hydroxide layer |
|
|
Term
why the CEC of chlorites is extremely low |
|
Definition
because the surface of the hydroxide layers is + charged and is attracted to the - charged tetrahedral surface |
|
|
Term
description of intergrade 2:1 minerals |
|
Definition
-similar to smectites and vermiculites except the interlayer area contains discontinuous "islands" of chlorite -non-expansive and exhibit a much lower CEC than than vermiculites and smectites |
|
|
Term
the charge on clay minerals that's unaffected by solution pH |
|
Definition
|
|
Term
the pH-dependent charge on clay minerals |
|
Definition
|
|
Term
why the edge charge of clay minerals is + under low pH |
|
Definition
because of the excess H+ ions associated with exposed SiOH and Al-OH groups |
|
|
Term
why the edge charge becomes more negative when the pH increases |
|
Definition
because some of the H+ on the clay particles is neutralized |
|
|
Term
what inbcrteasing the soil pH above 7 does to the charges on the clay particles |
|
Definition
nearly completely removes the the H+ ions from the Al-OH and Si-OH groups |
|
|
Term
the amount of - charge on 2:1 clays that's pH dependent |
|
Definition
|
|
Term
the amount of negative charge on 1:1 clays that's pH dependent |
|
Definition
|
|
Term
2 sources of pH dependent charge |
|
Definition
broken edges on clay minerals and soil OM |
|
|
Term
where most of the pH dependent - charge from soil OM comes from |
|
Definition
-carboxylic acid -to a lesser extent, phenolic acid groups |
|
|
Term
why the CEC of soil OM increases as pH increases |
|
Definition
because some of the H+ ions are neutralized, increasing the - surface charge |
|
|
Term
|
Definition
estimated to be 100-300 meq/100g soil |
|
|
Term
the CEC of the whole soil is strongly affected by... |
|
Definition
the nature and quantity of clay minerals and OM in the soil |
|
|
Term
which type of clay mineral tends to have a higher CEC? 1:1 or 2:1? |
|
Definition
|
|
Term
the CEC of most SE soils (ultisols) is mostly ______ while the CEC of most MW soils (mollisols) is mostly ______ |
|
Definition
pH dependent permanent charge |
|
|
Term
3 rxns from which pH dependent CEC originates |
|
Definition
-neutralization of H+ on sesquioxide (Al, Fe(OH)x) by way of liming
-neutralization of H+ associated with the interlayer Al(OH)x as pH increases
-neutralization of Al3+ and Al(OH)x+n as pH increases with liming |
|
|
Term
most of the exchangeable cations in soils are plant nutrients except for... |
|
Definition
|
|
Term
the principal cations in acid soils |
|
Definition
-Al3+
-H+
-Ca2+
-Mg2+
-K+ |
|
|
Term
the predominant cations in neutral and basic soils |
|
Definition
|
|
Term
this influences the ease with which cations can be replaced or exchanged with other cations |
|
Definition
cations being adsorbed to the CEC with different adsorption strengths |
|
|
Term
|
Definition
series that shows cations in order of how strongly they are adsorbed onto CEC sites
Al3+ > H+ > Ca2+ > Mg2+ > K+ = NH4+ > Na+ |
|
|
Term
the strength of adsorption is directly proportional to... |
|
Definition
the charge on the cations (>charge>adsorption strength)
exception: H+ |
|
|
Term
what makes the H+ ion unique? |
|
Definition
its very small size and high charge density |
|
|
Term
the adsorption strength of cations with similar charges is determined by... |
|
Definition
the size or radii of the hydrated cation |
|
|
Term
why smaller cations of different charge are adsorbed more strongly |
|
Definition
because larger hydrated cations can't get as close to the exchange surface as smaller cations |
|
|
Term
some factors that affect which cations are preferentially adsorbed onto mineral surfaces |
|
Definition
-mineral type -solution pH -dominant anions present -electrical potential of the charged surface -other factors beyond the scope of this text |
|
|
Term
|
Definition
represents the total quantity of - surface charges on minerals and OM available to attract cations in solution
expressed in meq/100g oven dried soil |
|
|
Term
why meq is used for CEC instead of mass |
|
Definition
CEC represents both the meq/100g of - charge and the total meq/100g of cations adsorbed to the CEC |
|
|
Term
|
Definition
% of total CEC occupied by Ca2+, Mg2+, K+, and Na+ |
|
|
Term
soil factors that may affect %BS |
|
Definition
-BS of cultivated soils higher for arid than for humid regions -BS of soils formed from limestone or basic igneous rock is greater than that of soils formed from sandstone or acidic igneous rock |
|
|
Term
the relation betwen BS and cation availability is modified by... |
|
Definition
the nature of the soil colloids |
|
|
Term
soils with ______ can supply nutrient cations to plants at a much lower BS than soils with ______ |
|
Definition
large amounts of OM or 1:1 clays 2:1 clays |
|
|
Term
|
Definition
BS increases with increasing soil pH |
|
|
Term
why the influence of pH on CEC is highest in soils high in OM |
|
Definition
because increasing pH has a greater effect on increasing CEC in the OM fraction in soil compared to montmorillonite, which exhibits little pH dependent charge |
|
|
Term
why weathered, acidic soils containing hydroxyl-Al vermiculites (ultisols) exhibit strong pH-dependent CEC |
|
Definition
because of the large quantity of Al(OH)x in the interlayer space of these clays |
|
|
Term
this displacement mechanism in soil is an important mechanism for anion exchange |
|
Definition
displacement of OH from hydrous Fe and Al oxides |
|
|
Term
|
Definition
AEC incereases as soil pH decreases |
|
|
Term
soils where AEC is greatest |
|
Definition
acid soils containing 1:1 clays and those containing Fe and Al oxides
exception: soils that contain hydroxyl-Al vermiculites common to the SE US |
|
|
Term
the order of adsorption strength for anions |
|
Definition
H2PO4- > SO4-2 > NO3- > Cl- |
|
|
Term
the primary anion adsorbed in most soils |
|
Definition
|
|
Term
how Al and Fe oxide minerals can adsorb H2PO4- |
|
Definition
thru rxns that result in chemical bonds that are non-electrostatic |
|
|
Term
|
Definition
-Carbon -Hydrogen -Oxygen -Nitrogen -Phosphorous -Potassium -Calcium -Sulfur -Magnesium |
|
|
Term
|
Definition
-Iron -Zinc -Boron -Molybdenum -Copper -Manganese -Chloride -Nickel |
|
|
Term
types of solute transport mechanisms |
|
Definition
|
|
Term
Passive transport occurs along... |
|
Definition
concentration and electrical (electrochemical) gradients |
|
|
Term
Active transport can occur against... |
|
Definition
electrochemical gradients |
|
|
Term
passive vs. active transport |
|
Definition
-Passive transport occurs along concentration and electrical (electrochemical) gradients -Active transport requires energy, and can occur against electrochemical gradients. |
|
|
Term
types of proteins that can facilitate passive transport |
|
Definition
channel and carrier proteins |
|
|
Term
types of active transport |
|
Definition
|
|
Term
mechanisms of Primary active transport (PAT) |
|
Definition
-ATP hydrolysis generates energy -Energy used for ion/solute transport |
|
|
Term
mechanisms of Secondary active transport |
|
Definition
-Special proteins (Integral membrane proteins) -Co-transport involved -Energy indirectly derived from PAT |
|
|
Term
depiction of primary active transport in plants |
|
Definition
see slide 7 of the powerpoint titled "Nutrient Uptake - II", but be sure to remove that white block |
|
|
Term
how plants bring Pi into the cell |
|
Definition
using ATP to send protons outside of the cell so they can bind with Pi so the Pi can come into the cell
this is an example of a symporter |
|
|
Term
how plants get Na+ out of their cells |
|
Definition
pumping protons out of their cells so they can reenter and cause the Na+ to leave |
|
|
Term
|
Definition
pumps hydrogen ions across the plasmalemma |
|
|
Term
Nutrient transporters are present in these zones of roots |
|
Definition
uptake related zones of roots |
|
|
Term
Two possible routes for apoplastic uptake |
|
Definition
-Elongation zone -Emerging laterals |
|
|
Term
examples of Adaptations in Nutrient Uptake |
|
Definition
-Adaptations in Nutrient Uptake -Regulation of Nutrient Uptake -Increase in nutrient transporters in roots under nutrient deficiency |
|
|
Term
ways roots can modify themselves |
|
Definition
-Altered root hair density -Proteoid root formation |
|
|
Term
mechanisms nutrient uptake may follow |
|
Definition
single- or a multi-phasic mechanism |
|
|
Term
Rate of uptake dependent on... |
|
Definition
|
|
Term
when plant uses Low Affinity Transport System (LATS) |
|
Definition
high nutrient concentration |
|
|
Term
when plant uses High Affinity Transport System (HATS) |
|
Definition
low nutrient concentration |
|
|
Term
when plants may Increase the number of nutrient transporters in roots |
|
Definition
under nutrient deficiency |
|
|
Term
depiction of the difference between roots under nutrient deficiency and roots not under nutrient deficiency |
|
Definition
see slide 16 of the powerpoint titled "Nutrient Uptake - II" |
|
|
Term
why a plant root may form proteoid roots |
|
Definition
|
|
Term
examples of regulation of uptake in plants |
|
Definition
-High N uptake rates result in high N levels in the leaves -Leaves contain high levels of amino acids -Amino acids are transported back to the roots -Amino acids inhibit nitrogen uptake by the roots |
|
|
Term
Two separate long distance transport systems in plants |
|
Definition
|
|
Term
what the xylem transports |
|
Definition
-water -nutrients -some amino acids |
|
|
Term
what the phloem transports |
|
Definition
-water -sugar -many nutrients |
|
|
Term
what nutrients can be transported in the xylem? |
|
Definition
|
|
Term
direction of transport in the xylem |
|
Definition
unidirectional (roots to shoots for nutrients) |
|
|
Term
|
Definition
-Bidirectional, although mainly from leaves to growing plant parts (roots, fruits, meristems, young leaves) -From old, senescing leaves to younger plant parts (retranslocation) -Mobility of nutrients in the phloem varies |
|
|
Term
plants remobilize nutrients thru the... |
|
Definition
|
|
Term
when plants remobilize nutrients |
|
Definition
|
|
Term
where nutrients in plants go when remobilized |
|
Definition
Many nutrients are removed from senescing leaves and transported to younger leaves or fruits |
|
|
Term
where nutrients can be stored if not used right away |
|
Definition
|
|
Term
the older part of the roots don’t do very much... |
|
Definition
nutrient and water uptake |
|
|
Term
these parts of the roots do the bulk of the nutrient and water uptake |
|
Definition
maturation zone and younger |
|
|
Term
these factors have an effect on nutrient uptake |
|
Definition
-Root morphology and architecture -Root surface area |
|
|
Term
factoirs of Root morphology and architecture that have an effect on nutrient uptake |
|
Definition
-Root length, thickness -Branching |
|
|
Term
root branching can be influenced by... |
|
Definition
|
|
Term
lateral roots start forming from ______, not the ______ |
|
Definition
the inside of the pericycle epidermis |
|
|
Term
how much root surface area is in the root hairs? |
|
Definition
|
|
Term
how Mycorrhizae can make nutrients more available to plants |
|
Definition
by using organic forms of nutrients and converting them to inorganic forms, thus making more nutrients available to plants |
|
|
Term
plants don’t make many mycchorrizal associations when... |
|
Definition
there’s lots of nutrients avilable |
|
|
Term
some functions of the cortex |
|
Definition
-nutrients can be taken up into the symplast -can also act as storage; nutrients can be stored in the vacuoles of cortical cells |
|
|
Term
what the endodermis limits |
|
Definition
-kinda limits the uptake of unnecessary substances -also limits the leakage of nutrients |
|
|
Term
why pericycle can generate lateral roots |
|
Definition
has new cells that can make lateral root |
|
|
Term
|
Definition
space outside plasma membrane, even the space costituted by dead functioning xylem tissue |
|
|
Term
|
Definition
|
|
Term
|
Definition
|
|
Term
all the plant cells are connected by... |
|
Definition
|
|
Term
something inside plasmodesmata that might help regulate traffic thru them |
|
Definition
plasmodesmata have some amount of endoplasmic reticulum in there and plasmodesmata are pretty tightly controlled; there’s regulatory mechanisms inside plasmodesmata |
|
|
Term
depiction of cells in the endodermis |
|
Definition
|
|
Term
casparian strip found in... |
|
Definition
|
|
Term
casparian strip is (hydrophobic or hydrophilic) |
|
Definition
|
|
Term
|
Definition
movement of ions from one side of the membrane to the other |
|
|
Term
this happens when ions bind to carrier proteins |
|
Definition
they change shape to bind to ions |
|
|
Term
these proteins have a higher transport rate |
|
Definition
|
|
Term
these proteins have to undergo more changes than channel proteins |
|
Definition
|
|
Term
these proteins can be gated |
|
Definition
|
|
Term
what ATPase does with hydrogen |
|
Definition
pumps hydrogen ions across the plasmalemma, against normal gradient and uses energy |
|
|
Term
normal charge outside cell |
|
Definition
|
|
Term
normal charge inside cell |
|
Definition
|
|
Term
the only known proteins that directly use primary active transport |
|
Definition
|
|
Term
depiction of Primary Active Transport in Plants |
|
Definition
|
|
Term
what happens in 2ndary active transport |
|
Definition
carrier proteins couple the transport of protons with other ions from outside the cell to inside the cell; energy used by proton pump, not nitrogen pump, for example |
|
|
Term
depiction of 2ndary active transport |
|
Definition
|
|
Term
an important function of antipiorters in plant cells |
|
Definition
can help mitigate toxicities inside the cells |
|
|
Term
depiction of a Sodium-proton antiporter |
|
Definition
|
|
Term
phosphate transporter mostly in these zones of the root |
|
Definition
mesomatic and elongation zones |
|
|
Term
regulation of calcium inside plant cells |
|
Definition
the c’tration of Ca in the plant cells is tightly regulated and kept pretty low |
|
|
Term
what plants do to their carbohydrates when they don't put out root hairs |
|
Definition
they partition more of the carbohydrates towards the shoots |
|
|
Term
this might stunt plant growth |
|
Definition
severe nutrient deficiency |
|
|
Term
at the cellular level, plants can do this in response to nutrient deficiencies |
|
Definition
make more of certain kinds of transporters and increase the concentration of them, such as the specific one for P when there's a shortage of P |
|
|
Term
plants make this in response to Pi defficiency |
|
Definition
|
|
Term
plants make proteoid roots in response to... |
|
Definition
|
|
Term
some details about proteoid roots |
|
Definition
-they are dense clusters of lateral roots, but very short, about 1-2mm long -they can form tertiary roots -these roots can send out certain enzymes to change rhizosphere and increase P uptake |
|
|
Term
how plants respond to nutrient excess |
|
Definition
plants respond to nutrient excess by slowing down uptake or storing it |
|
|
Term
an example of regulation of nitrogen uptake |
|
Definition
-High N uptake rates result in high N levels in the leaves -Leaves contain high levels of amino acids -Amino acids are transported back to the roots -Amino acids inhibit nitrogen uptake by the roots |
|
|
Term
what happens to leaves before they fall off |
|
Definition
N from leaves goes back into plants for next season |
|
|
Term
the difference between storage and sequestration |
|
Definition
storage is when it’s intended to be used later, but sequestration is dead end for it |
|
|
Term
how well boron is stored in plants |
|
Definition
boron typically doesn’t get stored very well |
|
|
Term
|
Definition
|
|
Term
|
Definition
|
|
Term
|
Definition
HCl + H2O <--> H3O+ + Cl-
HCl is the acid and H2O is the base |
|
|
Term
|
Definition
mix of equal amounts of conjugate acid and conjugate base that resists pH changes; this is the important concept for soil |
|
|
Term
what buffer does when the pH is too low |
|
Definition
some of the conjugate base becomes part of the conjugate acid, making the conjugate acid increase and the conjugate base decrease |
|
|
Term
what buffer does when the pH is too high |
|
Definition
some of the conjugate acid becomes part of the conjugate base, making the conjugate acid decrease and the conjugate base increase |
|
|
Term
|
Definition
|
|
Term
Regions with predominantly acidic soils |
|
Definition
|
|
Term
some sources of soil acidity |
|
Definition
1. Acids in Precipitation 2. Dissociation of H+ from Soil Organic Matter 3. Dissociation of H+ from broken edges 4. Al and Fe hydrolysis 5. Microbial respiration 6. Nutrient Transformations |
|
|
Term
the rxn that causes water to become more acidic after being exposed to air |
|
Definition
H2O + CO2 ←→ H2CO3 ←→ H+ + HCO3- |
|
|
Term
|
Definition
|
|
Term
where the rainfall is <4.3 |
|
Definition
|
|
Term
Natural Causes of Acid Rain |
|
Definition
-Lightning -Volcanoes -Decomposing plant biomass |
|
|
Term
Man-Made Causes of Acid Rain |
|
Definition
-Exhaust from cars, trucks, and buses -Power plants that burn coal -Pollution from industry |
|
|
Term
when organic matter releases H+ |
|
Definition
when the soil is a certain pH |
|
|
Term
when the H+ on broken edges starts to come off |
|
Definition
|
|
Term
series of rxns of aluminum hydrolysis |
|
Definition
Al3+ + H2O → Al(OH)2+ + H+
Al(OH)2+ + H2O → Al(OH)2+ + H+
Al(OH)2+ + H2O → Al(OH)3 + H+
Al(OH)3 + H2O → Al(OH)4- + H+ |
|
|
Term
how hydroxy Al ions reduce CEC |
|
Definition
bvy combining to form large polymers, which are so big, that they're non exchangeable |
|
|
Term
a type of soluble Al that's toxic |
|
Definition
|
|
Term
the equation of microbial respiration |
|
Definition
CO2 + H2O → H2CO3 ←→HCO3- + H+ |
|
|
Term
the pHa of microbial respiration |
|
Definition
|
|
Term
|
Definition
the pH where half of the acid is dissociated |
|
|
Term
some transformations of N that cause soil acidity |
|
Definition
-immobilization
-nitrification
-volatilization
-NH4+ uptake |
|
|
Term
a transformation of S that causes soil acidity |
|
Definition
|
|
Term
|
Definition
ammonium being converted to organic form |
|
|
Term
effect of immobilization of N on soil pH |
|
Definition
pH decreases 1 unit for each mole of N |
|
|
Term
|
Definition
ammonium being converted to nitrate |
|
|
Term
effect of nitrification of N on soil pH |
|
Definition
pH decreases 2 units for each mole of N |
|
|
Term
|
Definition
ammonium being converted to ammonia |
|
|
Term
effect of volatilization of N on soil pH |
|
Definition
pH decreases 1 unit for each mole of N |
|
|
Term
|
Definition
to me, it seems to be a type of immobilization |
|
|
Term
effect of ammonium uptake on soil pH |
|
Definition
pH decreases 1 unit for each mole of N |
|
|
Term
|
Definition
organic S being converted to inorganic S |
|
|
Term
effect of mineralization of S on pH of soil |
|
Definition
pH decreases 1 unit for each mole of S |
|
|
Term
effect of a rxn consuming H+ |
|
Definition
|
|
Term
N rxn that produces the most acidity |
|
Definition
|
|
Term
|
Definition
|
|
Term
how active acidity is measured |
|
Definition
measured by pH in soil-water mixture |
|
|
Term
methods by which to measure active acidity |
|
Definition
-Electrometric method (pH meter) -Dye methods (pH indicator) -Test probe (not reliable) |
|
|
Term
the most reliable pH meter |
|
Definition
|
|
Term
what dilution does to soil pH |
|
Definition
|
|
Term
what suspended particles do to soil pH |
|
Definition
-decrease soil pH (negatively charged soil) -increase soil pH (positively charged soil) |
|
|
Term
how the probe can affect the pH reading |
|
Definition
because the soil particles interact with how the probe works |
|
|
Term
|
Definition
-decrease soil pH (negatively charged soils) -increase soil pH (positively charged soils) |
|
|
Term
this might cause seasonal variations in the soil's pH |
|
Definition
|
|
Term
the UGA method for measuring pH avoids... |
|
Definition
the seasonal variation in pH caused by differences in the soil’s salt content |
|
|
Term
an advantage of the UGA method for measuring soil pH |
|
Definition
this gets you close to the true pH, no matter how much salt |
|
|
Term
|
Definition
|
|
Term
some sources of potential acidity |
|
Definition
- Al3+ in soil solution (all species)
- Hydroxy-Al polymers
- H+ and Al3+ in exchange sites
- H+ in broken edges of clays, oxides
- H+ in organic matter (ROOH, ROH) |
|
|
Term
when undissociated acids release H+ |
|
Definition
when you try to increase the pH |
|
|
Term
diagram of potential and active adidity in soil |
|
Definition
|
|
Term
amount of potential acidity vs. rate of change in active acidity |
|
Definition
the more potential acidity, the slower the change in active acidity
the less potential acidity, the faster the change in active acidity |
|
|
Term
potential acidity vs. lime requirement |
|
Definition
the higher the potential acidity, the higher the lime requirement |
|
|
Term
why midwest soil has high potential acidity |
|
Definition
because it has high buffering capacity and has organic matter that has hydrogen attatched to it |
|
|
Term
part of the acidity tolerance is... |
|
Definition
|
|
Term
some plants with very low acidity tolerance |
|
Definition
-Alfalfa -Cotton -Soybean -Spinach |
|
|
Term
some plants with moderate acidity tolerance |
|
Definition
-Peanut -Rice -Strawberry -Watermelon |
|
|
Term
some plants with high acidity tolerance |
|
Definition
-Azalea -Blueberry -Cranberry -Rhododendron |
|
|
Term
above the critical pH, you don’t see much... |
|
Definition
|
|
Term
do this to the critical listed pH |
|
Definition
|
|
Term
why we now recommend pH 6 instead of pH 6.5 |
|
Definition
because there’s the chance of overshooting the target pH |
|
|
Term
chart showing pH related to nutrient supply |
|
Definition
|
|
Term
|
Definition
|
|
Term
methods of determining lime requirement |
|
Definition
1. Titration 2. Buffer Solution |
|
|
Term
|
Definition
add a base and measure pH |
|
|
Term
|
Definition
Add Ca(OH)2 in 1:1 mix
-20 g soil (0.02 kg)
-20 mL 0.01 M CaCl2 (measure pH1)
-this is shaken for 30 minutes because you need that reaction time
I think 1:1 means 1mg/mL |
|
|
Term
why it's not a good idea to use Ca(OH)2 as lime |
|
Definition
because it's caustic such that it burns plants |
|
|
Term
why lime requirement (LR) is often multiplied by 1.5 |
|
Definition
because they assume you’re not using pure calcium carbonate |
|
|
Term
buffer solution method of determining lime requirement |
|
Definition
|
|
Term
this determines how much the pH goes up |
|
Definition
|
|
Term
|
Definition
-Ca -Mg oxides -hydroxides -carbonates -silicates |
|
|
Term
H+ must be neutralized by... |
|
Definition
|
|
Term
liming materials have to produce... |
|
Definition
|
|
Term
|
Definition
because it reacts very fast |
|
|
Term
why soil tersting lab uses Ca(OH)2 |
|
Definition
because it reacts so fast |
|
|
Term
|
Definition
|
|
Term
how long it takes to see the effect of calcium carbonate |
|
Definition
about 6 months after application |
|
|
Term
this isn used to express the purity of liming material |
|
Definition
Calcium Carbonate Equivalent (CCE) |
|
|
Term
in Georgia, you need at least ______% Calcium Carbonate equivalent to sell it as lime |
|
Definition
|
|
Term
is fgineness factor measured in Georgia? |
|
Definition
no
not even given a weight |
|
|
Term
why repeated applications of lime are needed in Southeastern soils |
|
Definition
to maintain appropriate chemical balances in the soil |
|
|
Term
the recommended pH is usually... |
|
Definition
|
|
Term
the main process that acidifies soil |
|
Definition
|
|
Term
|
Definition
|
|
Term
|
Definition
|
|
Term
apply lime how long in advance? |
|
Definition
|
|
Term
do this with lime for a faster rxn |
|
Definition
|
|
Term
why you can't mix lime with the soil in pasture |
|
Definition
because it ruins your pasture |
|
|
Term
rxn of elemental S that acidifies soil |
|
Definition
S + H2O + 3/2 O2 → 2H+ + SO4-
-biological rxn
-Thiobacillus sp.
-sulfur oxidizes and forms sulfuric acid
-you need the bacteria for this reaction to occur |
|
|
Term
how sulfuric acid has been used to acidify soil |
|
Definition
has been used in midwest where there are some very calcareous soils |
|
|
Term
how alum (Al2(SO4)3) can be used with poultry litter |
|
Definition
can be mixed in with poultry litter to tie up the phosphorus so that it don’t run off |
|
|
Term
preferred pH for blueberries |
|
Definition
|
|
Term
how manures can contribute to soil being salty |
|
Definition
manures have a lot of salt, so if there’s little or no rain with the manure there, the soil could become saline |
|
|
Term
this can cause soils to become saline or sodic |
|
Definition
-Water evaporation -salt accumulation |
|
|
Term
come cations in saline and sodic soils |
|
Definition
|
|
Term
some anions in saline and sodic soils |
|
Definition
|
|
Term
salt content of sodic soils |
|
Definition
sodic soils don't have much salt |
|
|
Term
|
Definition
sodic soils tend to be very basic |
|
|
Term
when the pH of soil is above 8.5 or 9, this happens to the dissolved organic matter |
|
Definition
the dissolved organic matter is deposited on the surface |
|
|
Term
chart showing some details of normal, saline, sodic, and saline-sodic soils |
|
Definition
|
|
Term
how EC and exchangeable Na affect plant growth |
|
Definition
|
|
Term
|
Definition
the dissolved organic matter |
|
|
Term
what saline soils can do to plants |
|
Definition
-water imbalance in the plant -ionic imbalance |
|
|
Term
how to remediate the effects of saline soils on plants |
|
Definition
leach with low-salt water |
|
|
Term
water in soils moves from ______ negative to ______ negative |
|
Definition
|
|
Term
why too much salt in the soil is bad for plants |
|
Definition
-too much salt in the soil draws water away from plant roots because salt has so much negative charge on it
-toxic levels of Na+ and Cl- |
|
|
Term
why saline and sodic soils have bad physical properties |
|
Definition
poor structure, resulting in dispersive clay |
|
|
Term
why the clay in saline and sodic soils is dispersive |
|
Definition
because some of the negative charge on the clay pushes against each other |
|
|
Term
amount of exchangeable sodium vs. dispersiveness of the clay |
|
Definition
the more exchangeable sodium, the more dispersive the clay |
|
|
Term
dispersiveness of the clay vs. hydraulic conductivity |
|
Definition
the more dispersive the clay, the less the hydraulic conductivity |
|
|
Term
why more dispersive clay has lower hydraulic conductivity |
|
Definition
when the clay is more dispersive, the hydraulic conductivity declines because small particles clog pores in the soil |
|
|
Term
how to fix dispersiveness of clay in saline and sodic soils |
|
Definition
by replacing the sodium with calcium |
|
|
Term
how calcium fixes clay dispersiveness in saline and sodic soils |
|
Definition
by neutralizing the negative charges and causing aggregation |
|
|
Term
problems with saline and sodic soils |
|
Definition
-bad physical properties
-dispersed clay
-toxic levels of Na+ and Cl- |
|
|
Term
how to remediate saline and sodic soils |
|
Definition
add gypsum (CaSO4) and leach |
|
|
Term
how gypsum remediates saline and sodic soils |
|
Definition
|
|
Term
some transformations of N that increase soil pH |
|
Definition
-mineralization
-denitrification
-urea hydrolysis
-NO3- uptake |
|
|
Term
|
Definition
organic N being turned into NH4+ |
|
|
Term
effect of N mineralization on soil pH |
|
Definition
1 mole N increases pH 1 unit |
|
|
Term
|
Definition
|
|
Term
effect of denitrification on soil pH |
|
Definition
1 mole N increases pH 1 unit |
|
|
Term
|
Definition
urea turning into nitrate |
|
|
Term
effect of urea hydrolysis on soil pH |
|
Definition
1 mole N increases pH 1 unit |
|
|
Term
|
Definition
|
|
Term
effect of NO3- uptake on soil pH |
|
Definition
1 mole N increases pH 1 unit |
|
|
Term
a transformation of S that increases soil pH |
|
Definition
|
|
Term
effect of SO4-2 uptake on soil pH |
|
Definition
1 mole S increases pH 2 units |
|
|
Term
why fertilizing can be inefficient |
|
Definition
because plant roots are always competing w/ microbes and minerals for nutrients |
|
|
Term
how nutrients can get out of soil other than by plant uptake |
|
Definition
|
|
Term
Nutrients in solution controlled by |
|
Definition
-Microbial processes (N, S, etc.) -Chemical processes (P, K, etc.) -Physical processes (P, etc.) |
|
|
Term
Microbial processes control these nutrients |
|
Definition
|
|
Term
Chemical processes control these nutrients |
|
Definition
|
|
Term
Physical processes control these nutrients |
|
Definition
|
|
Term
one form in which organic nitrogen can occur |
|
Definition
|
|
Term
why our soils here in Georgia don’t expand and contract very much based on wetness |
|
Definition
because of the H bonds between the sheets of kaolinite |
|
|
Term
2 Origins of Charge in clay minerals |
|
Definition
-Isomorphic substitution -Broken edges |
|
|
Term
example of isomorphic substitution in the tetrahedral layer |
|
Definition
|
|
Term
example of isomorphic substitution in the octahedral layer |
|
Definition
Mg2+ or Fe2+ replacing Al3+ |
|
|
Term
why clays that undergo isomorphic substitution have charges on them |
|
Definition
because each link tries to compensate half a charge |
|
|
Term
when the charge on clays disappears |
|
Definition
when it breaks down into its elements |
|
|
Term
the part of clay charge that's pH dependent |
|
Definition
the charge along the broken edges |
|
|
Term
why the point of no charge is bad |
|
Definition
because it means no nutrient retention |
|
|
Term
one reason it's important to maintain pH |
|
Definition
because the pH at which there's no charge means no nutrient retention |
|
|
Term
|
Definition
the pH at which there's no charge on the clay particles |
|
|
Term
when gibbsite develops negative charge |
|
Definition
|
|
Term
the charge on our soil here in Georgia |
|
Definition
here in Georgia, we have lotta positive soil in the profile |
|
|
Term
for which type of clay is pH more important? 1:1 or 2:1? |
|
Definition
|
|
Term
amount of charge on 2:1 clays that's permanent due to isomorphic substitution |
|
Definition
|
|
Term
amount of charge on 1:1 clays that's permanent due to isomorphic substitution |
|
Definition
|
|
Term
amount of charge on 2:1 clays that's pH dependent due to broken edges |
|
Definition
|
|
Term
amount of charge on 1:1 clays that's pH dependent due to broken edges |
|
Definition
|
|
Term
the point of zero charge for our soils |
|
Definition
|
|
Term
you need this to retain cations |
|
Definition
|
|
Term
|
Definition
|
|
Term
the types of clays in oxic soils |
|
Definition
|
|
Term
how organic matter adds negative charge to soil |
|
Definition
dissociation of carboxylic acid and phenolic acid
each acid has its own dissociation constant |
|
|
Term
pH of soil vs. negative charge |
|
Definition
increasing the pH of the soil causes more negative charge |
|
|
Term
amount of organic matter vs. places for nutrient retention |
|
Definition
increasing organic matter increases places for nutrient retention |
|
|
Term
how roots add negative charge to the soil |
|
Definition
carboxylic acid dissociation |
|
|
Term
|
Definition
what’s actually working in the soil |
|
|
Term
change in CEC of clay vs. change in CEC of organic C as pH increases |
|
Definition
CEC of OM increases faster than the CEC of clay with increasing pH |
|
|
Term
why organic matter is critical to increasing CEC |
|
Definition
because its CEC increases with pH at a faster rate than the CEC of clay does |
|
|
Term
this part of soil contributes the most in terms of increasing CEC |
|
Definition
|
|
Term
|
Definition
|
|
Term
|
Definition
|
|
Term
|
Definition
|
|
Term
|
Definition
|
|
Term
|
Definition
|
|
Term
|
Definition
|
|
Term
|
Definition
|
|
Term
CEC of Sphagnum peat moss |
|
Definition
|
|
Term
|
Definition
|
|
Term
what determines the CEC of the roots? |
|
Definition
the amount of negative charges in the roots; the more negative charges in the roots, the higher the CEC |
|
|
Term
|
Definition
|
|
Term
|
Definition
|
|
Term
these 2 factors affect how strongly an ion is held |
|
Definition
|
|
Term
which type of clay, 1:1 or 2:1, can supply nutrients to plants at a lower pH? |
|
Definition
|
|
Term
anion exchange capacity (AEC) |
|
Definition
Total amount of positive charges |
|
|
Term
important mechanism for AEC in many soils of tropics and subtropics |
|
Definition
displacement of OH-, often from Al and Fe hydroxides |
|
|
Term
pH where you start developing CEC |
|
Definition
above the point of zero charge |
|
|
Term
pH where you start developing AEC |
|
Definition
below the point of zero charge |
|
|
Term
why oxisols have lots of AEC, but not much CEC |
|
Definition
because all they have left is Fe oxides with lots of positive charge |
|
|
Term
the key to oxisols and why |
|
Definition
increasing organic matter because it increases the CEC |
|
|
Term
pH vs. depth here in Georgia |
|
Definition
|
|
Term
|
Definition
|
|
Term
at this depth, you retain nitrate |
|
Definition
|
|
Term
why you want a soil that's well buffered |
|
Definition
so the pH don’t change much when you drain it |
|
|
Term
Mechanisms of nutrient movement to roots |
|
Definition
1: Mass flow 2: Diffusion 3: Root Interception |
|
|
Term
|
Definition
soluble ions move to root with soil water |
|
|
Term
mass flow vs. transpiration |
|
Definition
mass flow increases as transpiration increases |
|
|
Term
diffusion as a mechanism of nutrient movement to roots |
|
Definition
low solubility ions move only by random thermal motion |
|
|
Term
speed of diffusion as a mechanism of nutrient movement to roots |
|
Definition
very slow, only 1-2cm/season |
|
|
Term
|
Definition
root hair grows until it can reach ions and exchange then takes place |
|
|
Term
in soil, Ca can accumulate here |
|
Definition
|
|
Term
why temp is critical for diffusion of water |
|
Definition
because the diffusion coefficient for water is temp dependent |
|
|
Term
why lots of of the early corns show purplish color |
|
Definition
because of P deficiency due to the temp being insufficient for diffusion of nutrients |
|
|
Term
|
Definition
basically the difficulty of a path; length can be a factor |
|
|
Term
buffering capacity vs. nutrient adsorption |
|
Definition
when you have a bigger buffering capacity, you have more nutrients being adsorbed onto the soil particles |
|
|
Term
how much the P moves in soil |
|
Definition
in most soils, not much more than an inch |
|
|
Term
diffusion of K vs. diffusion of P |
|
Definition
-potassium diffuses much faster than phosphorus |
|
|
Term
key nutrient uptake mechanism for corn |
|
Definition
|
|
Term
Root interception can be enhanced by... |
|
Definition
|
|
Term
|
Definition
sheath around root tip – do not penetrate plant cells (mainly trees of temperate zones) |
|
|
Term
|
Definition
extends surface area of roots – penetrate plant cells (widespread) |
|
|
Term
depiction of ectomycchoriza |
|
Definition
|
|
Term
depiction of endomycchoriza |
|
Definition
|
|
Term
corn does better on fumigated or unfumigated soil? |
|
Definition
|
|
Term
the biological N fixation by legumes |
|
Definition
|
|
Term
how much of the world's N the U.S. uses |
|
Definition
|
|
Term
the N-P-K nutrients in order of greatest consumption to least consumption |
|
Definition
|
|
Term
how much of our atmosphere is N? |
|
Definition
|
|
Term
microbes tend to prefer ______ for immobilization |
|
Definition
|
|
Term
lightning's role in nitrogen |
|
Definition
fixing it, which later comes down as rain |
|
|
Term
what happens when urea decomposes in the soil? |
|
Definition
raises the pH of the soil |
|
|
Term
why terrestrial systems are getting enriched with nitrogen |
|
Definition
because the rate of fixation turns out to be greater than the rate of denitrification |
|
|
Term
soils contain how much N? |
|
Definition
|
|
Term
How much of the soil N is organic? |
|
Definition
|
|
Term
types of organic N in soil |
|
Definition
-amino acids -proteins -complex compounds |
|
|
Term
how much of the soil N is inorganic? |
|
Definition
|
|
Term
types of inorganic N in the soil |
|
Definition
-NH4+ (ammonium)
-NO2- (nitrite)
-NO3- (nitrate) |
|
|
Term
|
Definition
|
|
Term
|
Definition
Org N --> NH4+
organic N turning into ammonium |
|
|
Term
the 2 steps of N mineralization |
|
Definition
-Aminization -Ammonification |
|
|
Term
|
Definition
Org N --> R-NH2 (amines)
organic N turning into amines
R is organic residue |
|
|
Term
|
Definition
R-NH2 + H+ + H2O --> R-OH + NH4+
amines turning into ammonium |
|
|
Term
the plant leaves with the most cumulative N mineralized after 160 days |
|
Definition
|
|
Term
Nitrogen mineralization from broiler litter varies depending on... |
|
Definition
|
|
Term
2 N compounds that are in broiler litter |
|
Definition
-Water-soluble organic N -Uric acid |
|
|
Term
why it's good to know the amount of N Mineralized in all parts of the field |
|
Definition
because if you can estimate these numbers, you can use precision ag |
|
|
Term
|
Definition
ammonium turning into organic N
NH4+ + R-OH --> R-NH2 + H+ + H2O |
|
|
Term
Nitrogen Immobilization is controlled by... |
|
Definition
|
|
Term
C/N ratio that leads to immobilization |
|
Definition
|
|
Term
C/N ratio that leads to mineralization |
|
Definition
|
|
Term
the C/N ratio is based on... |
|
Definition
|
|
Term
most residues contain this much C |
|
Definition
|
|
Term
C:N ratio is an indicator of... |
|
Definition
the stability of the soil supplement |
|
|
Term
what a lower C:N ratio means for plants |
|
Definition
Lower ratios mean the supplement is very stable and will not draw down nutrients from the soil that plants need to grow. |
|
|
Term
|
Definition
|
|
Term
what residue with a high C:N ratio does |
|
Definition
soaks up water and nutrients, robbing plants of what they need |
|
|
Term
compost has a 30:1 ratio, but what's the disadvantage? |
|
Definition
it breaks down quickly in the soil |
|
|
Term
peat moss, being 50:1, draws down a small amount of nitrogen fertilizer such that it won't hurt the plant, but what's an advantage of it? |
|
Definition
it lasts for years in the soil |
|
|
Term
why the ideal C:N ratio isn't always 30:1 |
|
Definition
because the C:N ratio of 30 is a rule of thumb; it really depends on where the N is in the material |
|
|
Term
why you gotta know the C:N if you want to use compost |
|
Definition
because not all compost will give you the desired N |
|
|
Term
how much the N immobilizes depends on |
|
Definition
the microbial biomass that’s there |
|
|
Term
|
Definition
|
|
Term
|
Definition
|
|
Term
microbial efficiency refers to... |
|
Definition
|
|
Term
|
Definition
ammonium turning into nitrite that then turns into nitrate
NH4+ + 3/2 O2 --> NO2- + 2H+ + H2O
NO2- + ½ O2 --> NO3-
only the first rxn acidifies soil |
|
|
Term
you usually don’t have accumulation of nitrite unless... |
|
Definition
something inhibits the second rxn, such as lots of ammonia |
|
|
Term
the strain of bacteria that works best at any given pH |
|
Definition
the strain that’s best adapted to that pH |
|
|
Term
Optimum pH for nitrification |
|
Definition
|
|
Term
Applying fertilizer in a band can lead to... |
|
Definition
bacteria being dehydrated |
|
|
Term
|
Definition
|
|
Term
aluminum starts to appear in the exchangeable process at this pH |
|
Definition
|
|
Term
in soils with too much ______, nitrification stops |
|
Definition
|
|
Term
nitrification is very sensitive to... |
|
Definition
|
|
Term
if you don’t control the ______, nitrification stops |
|
Definition
|
|
Term
problem in soils with 2:1 clay minerals |
|
Definition
fixed NH4+
this is called ammonium fixation |
|
|
Term
some minerals that can fix ammonium |
|
Definition
|
|
Term
how much of the ammonium in fertilizer can be fixed in certain soils? |
|
Definition
|
|
Term
heating soil does this to the edges of 2:1 minerals |
|
Definition
|
|
Term
how 2:1 minerals fix ammonium |
|
Definition
ammonium gets stuck in between the sheets of 2:1 minerals binding to the CEC sites |
|
|
Term
|
Definition
-nitrate leaching -denitrification -runoff and erosion -ammonia volatilization -crop harvest |
|
|
Term
amount of nitrate leaching depends on... |
|
Definition
- Rate, timing of N fertilization - Nitrification inhibitors; some fertilizers come with these and they last for about 2 weeks - Crop uptake; reduces nitrate leaching - Soil characteristics - Precipitation patterns |
|
|
Term
why we have negative charges in the lower levels |
|
Definition
|
|
Term
if you have this soil, you’ll have leaching |
|
Definition
|
|
Term
|
Definition
nitrate turning into nitrogen gas or nitrous oxide
2NO3- + 2H+ --> N2 + 21/2 O2 + H2O |
|
|
Term
pH effect of denitrification |
|
Definition
1 mole of N raises the pH by 1 unit |
|
|
Term
|
Definition
- Nitrate or intermediate product - Carbon source - Anoxic conditions (no oxygen) - Temperature |
|
|
Term
|
Definition
amount of N gas increases as you become more alkaline |
|
|
Term
there’s bacteria that have the ability to switch to nitrification when... |
|
Definition
|
|
Term
bacteria can also use this for reduction |
|
Definition
|
|
Term
other than soil, denitrification can occur in... |
|
Definition
|
|
Term
the majority of global emissions of non-CO2 GHGs are from... |
|
Definition
nitrous oxide from soils and methane from enteric fermentation and livestock |
|
|
Term
|
Definition
ammonium turning into ammonia that gets into the air |
|
|
Term
if there’s lotta ammonium in ______, there’s lotta ammonium in CEC |
|
Definition
|
|
Term
the pKa of the ammonia volatilization rxn |
|
Definition
about 9.3; above it, you got mostly ammonia, below it, you got mostly ammonium |
|
|
Term
|
Definition
nitrogen in the form of ammonium and ammonia; can be used to determine pH |
|
|
Term
this form of N can be used to determine pH |
|
Definition
ammoniacal nitrogen (ammonium and ammonia) |
|
|
Term
the direction the ammonia volatilization rxn goes at higher temperatures |
|
Definition
|
|
Term
some factors that affects ammonia volatilization |
|
Definition
|
|
Term
best conditions for ammonia volatilization... |
|
Definition
|
|
Term
pH effect of ammonia volatilization |
|
Definition
|
|
Term
some conditional details about ammonia volatilization |
|
Definition
-Important at pH > 7.5 and surface application -Slow at < 5 oC -N source (contains or generates NH4+) -Increases with temp -Increases with wind speed |
|
|
Term
you get more denitrification from these ecosystems |
|
Definition
|
|
Term
why ammonia can get absorbed by the water |
|
Definition
because it has a very high affinity for water |
|
|
Term
other than water, ammonia can also be absorbed by... |
|
Definition
|
|
Term
how ammonia can lead to soil acidification |
|
Definition
ammonia gets into the atmosphere, reacts with water, becomes ammonium, and acidifies soil |
|
|
Term
|
Definition
resistant to decomposition |
|
|
Term
what compost will do to soil |
|
Definition
improve the physical conditions of the soil, but won’t give you much N |
|
|
Term
how much N legume residues can cupply to soil |
|
Definition
|
|
Term
|
Definition
-manure -compost -legume residues -sewage sludge -feather meal -blood meal -bone neal |
|
|
Term
one use of composted sludge |
|
Definition
|
|
Term
why too much nitrate is bad |
|
Definition
|
|
Term
|
Definition
-Ammonia -Urea -Ammonium Nitrate -Ammonium Sulfate |
|
|
Term
the world's largest fertilizer N consumer |
|
Definition
east Asia, followed by S. Asia and N. America |
|
|
Term
the principal N fertilizer used in most of the world |
|
Definition
|
|
Term
|
Definition
international fertilizer association |
|
|
Term
the primary N fertilizer in the US |
|
Definition
urea ammonium nitrate (UAN) solutions |
|
|
Term
N loss pathways and cropping systems around the world |
|
Definition
|
|
Term
how management to improve crop N recovery and to reduce the risks of environmental loss will vary |
|
Definition
-geographically -site-specifically -the N source used |
|
|
Term
NH3 is compatible with... |
|
Definition
- Carbon steel - Stainless steel - Fiberglass, rubber, PVC, polyethylene |
|
|
Term
NH3 is not compatible with... |
|
Definition
- Aluminum [Al(OH)3]
- Copper [Cu(NH3)4]2+
- Zinc [Zn(NH3)4]2+
because it binds with these materials and forms a precipitate |
|
|
Term
Fertilizers containing NH3 |
|
Definition
|
|
Term
some details about Anhydrous NH3 |
|
Definition
- 82% N - about 6% of world N fertilizer use |
|
|
Term
some details about Aqua NH3 |
|
Definition
- 20 to 25% N - not used much in Midwest |
|
|
Term
Overall Effect of NH3 on soil pH |
|
Definition
1 mole of NH3 decreases pH by 1 unit |
|
|
Term
why ammonia is bad for plants |
|
Definition
because it's toxic to roots |
|
|
Term
management of Anhydrous NH3 and Aqua NH3 |
|
Definition
- Knife into the soil - Preferably moist soil - Apply several weeks before planting - Observe safety recommendations |
|
|
Term
toxic contaminant in urea fertilizer |
|
Definition
|
|
Term
amount of biuret that can be tolerated |
|
Definition
|
|
Term
|
Definition
|
|
Term
|
Definition
|
|
Term
why the urea usually has to go to the clays |
|
Definition
because most of the urease is bound to the clays |
|
|
Term
|
Definition
critical relative humidity |
|
|
Term
critical relative humidity (CRH) |
|
Definition
relative humidity at which urea dissolves |
|
|
Term
surface application of urea can result in loss of... |
|
Definition
|
|
Term
how to avoid ammonia loss after applying urea |
|
Definition
Irrigate (0.5 to 1 inch) after surface application to incorporate and avoid NH3 losses; this much irrigation needed to make it go down and make it not volatilize |
|
|
Term
N content of ammonium nitrate |
|
Definition
|
|
Term
how much of the world's fertilizer use is ammonium nitrate? |
|
Definition
|
|
Term
when ammonium nitrate causes ammonia loss |
|
Definition
|
|
Term
Behavior of Ammonium Nitrate in Soil |
|
Definition
NH4NO3 --> NH4+ + NO3-
NH4+ + 2O2 --> NO3- + H2O + 2H+ |
|
|
Term
this is a big problem in ammonium nitrate |
|
Definition
|
|
Term
why you should not stack many bags of ammonium nitrate in hot weather |
|
Definition
|
|
Term
why it's hard to sell ammonium nitrate |
|
Definition
because it can be used to make bombs |
|
|
Term
N content of ammonium sulfate |
|
Definition
|
|
Term
ammonium sulfate is how much of world's fertilizer usssssssseeeee? |
|
Definition
|
|
Term
why ammonium sulfate is a very convenient fertilizer |
|
Definition
because it has a significant amount of fertilizer |
|
|
Term
Behavior of ammonium sulfate in soil |
|
Definition
(NH4)2SO4 --> 2NH4+ + SO42-
2NH4+ + 4O2 --> 2NO3- + 2H2O + 4H+ |
|
|
Term
when ammonium sulfate doesn't cause any ammonia loss |
|
Definition
|
|
Term
N content of ammonium chloride |
|
Definition
|
|
Term
how much of world fertilizer use is ammonium chloride? |
|
Definition
|
|
Term
pH effect of ammonium chloride |
|
Definition
1 mole N causes pH to decrease by 2 units |
|
|
Term
why you have to wash your equipment after using ammonium chloride |
|
Definition
|
|
Term
why P and K are expressed on an oxide basis in fertilizer grades |
|
Definition
because back in the day, they had to precipitate it and go a gravimetric measure |
|
|
Term
ammonium phosphates account for how much of world N fert use? |
|
Definition
|
|
Term
Monoammonium phosphate (MAP) |
|
Definition
|
|
Term
N content of Monoammonium phosphate (MAP) |
|
Definition
|
|
Term
pH effect of Monoammonium phosphate (MAP) on soil pH |
|
Definition
1 mole N causes soil pH to decrease 2 units |
|
|
Term
pH at which Monoammonium phosphate (MAP) has no ammonia loss |
|
Definition
|
|
Term
Diammonium phosphate (DAP) |
|
Definition
|
|
Term
N content of Diammonium phosphate (DAP) |
|
Definition
|
|
Term
why Diammonium phosphate (DAP) is a very commonly used fertilizer |
|
Definition
because it provides lotsa N and lotsa P Raises the pH pretty high |
|
|
Term
pH effect of Diammonium phosphate (DAP) on pH of the soil |
|
Definition
1 mole N makes pH go down 1.5 units |
|
|
Term
what Diammonium phosphate (DAP) can do to seeds |
|
Definition
Can cause seed germination damage because of high pH (NH3 damage) |
|
|
Term
amount of Diammonium phosphate (DAP) that should be used with seed |
|
Definition
Use < 10 kg N/ha with seed |
|
|
Term
some Fertilizers containing only nitrate |
|
Definition
-calcium nitrate -potassium nitrate -sodium nitrate |
|
|
Term
advantage of Fertilizers containing only nitrate |
|
Definition
|
|
Term
how Urea-Ammonium nitrate (UAN) is produced |
|
Definition
Dissolve ammonium nitrate and urea in water |
|
|
Term
what Urea-Ammonium nitrate (UAN) does in soil |
|
Definition
behaves as ammonium nitrate and urea |
|
|
Term
UAN solutions are corrosive to these materials |
|
Definition
Cu and Zn alloys, and to an extent, Al alloys |
|
|
Term
UAN soluytions are OK with these substances |
|
Definition
-PVC -fiberglass -stainless steel -carbon steel |
|
|
Term
why UAN must not be used with brass nozzles |
|
Definition
because it'll complex with the copper, leading to plugging up |
|
|
Term
this may happen when UAN ius applied to surface |
|
Definition
|
|
Term
|
Definition
leaves a yellow streak where it burned it, but didn‘t kill it; disappears soon after |
|
|
Term
|
Definition
about half urea and half ammonium nitrate |
|
|
Term
use of Slow release N fertilizers |
|
Definition
mainly used by turf industry, horticulture, high-value crops |
|
|
Term
advantages of Slow release N fertilizers |
|
Definition
-release rate more closely matches plant requirements -no extra N in soil (less leaching) -less frequent applications |
|
|
Term
disadvantage of Slow release N fertilizers |
|
Definition
|
|
Term
particle size vs. release rate |
|
Definition
the bigger the particle size, the lower the release rate |
|
|
Term
solubility vs. chain length |
|
Definition
Solubility increases with decrease in chain length |
|
|
Term
the reason urea releases N so quickly |
|
Definition
because the bond in urea between the C and the ammonium is a single bond |
|
|
Term
why N release from Triazone compounds is slow |
|
Definition
because of closed-ring structure |
|
|
Term
why Triazone compounds have lower N loss |
|
Definition
|
|
Term
|
Definition
Sulfur shell around each urea granule |
|
|
Term
Sulfur-coated urea (SCU) designed to... |
|
Definition
reduce leaching and denitrification |
|
|
Term
Polymer-coated compounds (Osmocote) |
|
Definition
Coated N-P-K fertilizer granules |
|
|
Term
how Polymer-coated compounds (Osmocotes) release fertilizer |
|
Definition
by osmotic exchange with moisture from the soil
-Water moves in, dissolves N, N goes into soil -Bacteria decompose the plastic coat |
|
|
Term
uses for Polymer-coated compounds (Osmocote) |
|
Definition
Used in turf, floriculture, high-value crops |
|
|
Term
the Most common nutrient limiting crop growth and yield |
|
Definition
|
|
Term
why N is Applied in greater amounts than any other nutrient |
|
Definition
becaus it's used in such large quantities |
|
|
Term
dry weight content of plants |
|
Definition
|
|
Term
the primary inorganic forms of N in most plants |
|
Definition
|
|
Term
how urea is often taken in to plants |
|
Definition
|
|
Term
some organic forms of N that can be taken up |
|
Definition
amino acids; small proteins (peptides) |
|
|
Term
how plants can take in organic forms of N |
|
Definition
some microbial enzymes help the plant do this |
|
|
Term
what mycchorrizae help plants access |
|
Definition
more nutrients than just P; they can help turn organic N into inorganic form |
|
|
Term
plants seem to be able to take up this form of organic N from the soil by themselves |
|
Definition
|
|
Term
primary mechanism by which nitrate is taken in |
|
Definition
2ndary active trrransport, in the form of a symporter |
|
|
Term
|
Definition
|
|
Term
the force used to bring nitrate into the cell |
|
Definition
|
|
Term
how symporter creates proton motive force |
|
Definition
using energy from the ATP to move protons across the membrane to create a proton motive force |
|
|
Term
Nitrate transport mechanisms in plants |
|
Definition
low affinity transport system (LATS) and high affinity transport system (HATS) |
|
|
Term
|
Definition
|
|
Term
|
Definition
at high nitrate c'tration |
|
|
Term
|
Definition
|
|
Term
Multiple nitrate transporters needed for nitrate movement... |
|
Definition
|
|
Term
plants that have both HATS and LATS |
|
Definition
so far, this is all plants that have been categorized |
|
|
Term
an example of N remobilization within plants |
|
Definition
some N stored within older leaves gets remobilized to where it's needed |
|
|
Term
one possible use of fluorescence in plants |
|
Definition
to detect where a particular protein is present |
|
|
Term
is it easier for ammonia or ammonium to get into plant cells? |
|
Definition
|
|
Term
|
Definition
type of transporter that is specifically for ammonium; this is a passive process based on e'chem gradient |
|
|
Term
|
Definition
|
|
Term
|
Definition
|
|
Term
where ammonium transporters are found in plants |
|
Definition
some present in the root hairs and some functional in the roots |
|
|
Term
the type of gradient ammonium toxicity can affect |
|
Definition
can dissipate pH gradients |
|
|
Term
parts of the plant that can have high pH |
|
Definition
|
|
Term
parts of the plant that can have low pH |
|
Definition
-lumen -intermembrane space -vacuole |
|
|
Term
|
Definition
|
|
Term
|
Definition
because it helps with the movement of ions and keeps hundreds of enzymes working properly |
|
|
Term
|
Definition
|
|
Term
the transition of ammonium to ammonia depends on... |
|
Definition
|
|
Term
when ammonia in the cytoplasm turns into ammonium... |
|
Definition
after it gets into the vacuole |
|
|
Term
ammonium gets taken up thru... |
|
Definition
|
|
Term
do animals have mechanisms to manage ammonium? |
|
Definition
|
|
Term
lots of plants tend to do better on (ammonium or nitrate) |
|
Definition
|
|
Term
why do lots of plants do better on nitrate than on ammonium? |
|
Definition
|
|
Term
|
Definition
|
|
Term
the direction in which the xylem transports nutrients |
|
Definition
|
|
Term
this usually happens to ammonium before transport |
|
Definition
generally incorporated into organic molecules before transport |
|
|
Term
plant can do this with nitrate |
|
Definition
transport it or assimilate it in the roots |
|
|
Term
some organic forms of N plants can take up |
|
Definition
-Amino acids -Amides -Ureides |
|
|
Term
how nitrate uptake increases the pH of soil |
|
Definition
Nitrate is taken up together with H+
This increases the pH of the soil or growing medium. Ammonium has the opposite effect |
|
|
Term
Nitrate reduction requires... |
|
Definition
|
|
Term
some plants that seem to prefer ammonium over nitrate |
|
Definition
-Ericaceous plants, such as blueberries, azaleas, rhododendron
-rice
-Chenopodium album (lambsquarters) |
|
|
Term
the biologically active form of N |
|
Definition
|
|
Term
Nitrate needs to be ______ before it can be used |
|
Definition
|
|
Term
reduction of nitrate depends on... |
|
Definition
|
|
Term
enzyme used to reduce nitrate |
|
Definition
|
|
Term
|
Definition
because nitrate reductase contains Mo. Without Mo, this enzyme does not function, and nitrate cannot be reduced and incorporated into biological molecules. |
|
|
Term
function of nitrate reductase (NR) |
|
Definition
Catalyzes the reduction of nitrate to nitrite |
|
|
Term
nitrate reduction occurs in... |
|
Definition
|
|
Term
activity of nitrate reductase depends on... |
|
Definition
-nitrate -light -carbohydrates |
|
|
Term
what happens in plants w/o Mo? |
|
Definition
nitrate reductase (NR) does not function, and nitrate cannot be reduced and incorporated into biological molecules |
|
|
Term
nitrate reductase (NR) activated by... |
|
Definition
|
|
Term
why there's no nitrate reduction under low light conditions |
|
Definition
|
|
Term
where nitrate can be stored for later use |
|
Definition
|
|
Term
function of nitrite reductase (NiR) |
|
Definition
Catalyzes the reduction of nitrite to ammonium (light dependent) |
|
|
Term
nnnnitrite reductase (NiR) is dependent on... |
|
Definition
|
|
Term
why ammonium has to be incorporated into amino acids (or other compounds) immediately |
|
Definition
because it's highly toxic to plants |
|
|
Term
this cycle used to incorporate ammonium |
|
Definition
|
|
Term
function of the GS-GOGAT cycle |
|
Definition
used to incorporate ammonia |
|
|
Term
Summary of nitrate Assimilation |
|
Definition
|
|
Term
plants that use GS-GOGAT cycle |
|
Definition
|
|
Term
|
Definition
|
|
Term
|
Definition
Glutamine: 2-oxo-glutarate amido transferase (Glutamate synthase) |
|
|
Term
GS-GOGAT uses how many ATP? |
|
Definition
|
|
Term
|
Definition
|
|
Term
ammonium can be incorporated into various amino acids, such as... |
|
Definition
-glutamate -aspartate -glutamine -asparagine |
|
|