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Nitrogen

What are key findings that can be discovered only in long-term soil studies?

Discussion: 

Much of the world’s food supply is produced in intensively managed cropping systems that involve high inputs and high outputs. As our populations continue to increase while the amount of arable lands steadily shrinks, these intensive systems assume greater importance. Can they be maintained into the indefinite future? Will they continue to supply high yields of our foodstuffs? Answers can be gained solely through long-term field studies.

As an example, two or even three annual crops of irrigated lowland (paddy) rice are now the norm in favorable lands of tropical Asia, and such intensive cropping produces much of the regional rice supply. When this system became possible in the 1960s with the development of rapidly maturing, semi-dwarf rice varieties (through the “Green Revolution”), long-term field experiments were soon begun to evaluate the sustainability of grain yields and soil health under multiple annual cropping. The results for one triple-cropped field study in the Philippines are depicted in the figure as grain yield response to nitrogen (N) fertilizer input. In the early years of the field study (1970-1972, upper curve), grain yield was about 6 tons ha-1 without fertilizer N input, and with increasing fertilizer application grain yield approached the yield potential of 10 t ha-1. After 19 years of continuous triple-cropping, this yield response had declined substantially in a near parallel manner (bottom curve), creating a yield loss of about 3 t ha-1 at the highest fertilizer rate. Graphically the yield loss can be attributed to the lowered starting point of the 1989-91 curve, namely the grain yield that was supported by native soil N without fertilizer N input. The nearly equal slopes of the two curves indicate that the 1989-91 crop responded similarly to fertilizer N input as in 1970-72, so the yield decline was not caused by a change in intrinsic plant characteristics.

These long-term trends strongly suggest the cause of the yield decline as decreased supply of soil N. Yet the quantity of soil N had not changed during the 19 years of intensive cropping, so this graph became the basis for directing subsequent research at changes in the quality, or chemical nature, of soil N.

Additional evidence for the central role of N in the yield decline is shown in the dotted curve (1992-93). When the role of N in the yield decline was first hypothesized in 1991, N fertilizer was applied more frequently and at greater total rates to better synchronize fertilizer N with plant N demand. The resulting boost in fertilizer N availability compensated for the decreased availability of soil N, enabling reestablishment of the original yields from 1970-72—a reversal of the yield decline.

Careful long-term management of this field study and the recording of key agronomic and soil data enabled a process-level evaluation of system sustainability, leading to mitigation options that will maintain the high productivity of this vital cropping system into future years.

Dan Olk, USDA-ARS

Reference
Cassman K.G., S.K. De Datta, D.C. Olk, J. Alcantara, M.I. Samson, J. Descalcota, and M. Dizon. 1995. Yield decline and the nitrogen economy of long-term experiments on continuous, irrigated rice systems in the tropics. p. 181-222 In R. Lal and B.A. Stewart (eds) Soil management: Experimental basis for sustainability and environmental quality. CRC/Lewis Press, Boca Raton, FL.

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LTSEessay_March08.doc
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Crop and nitrogen yield in legume-based rotations practiced with zero tillage and low-input methods

Relationships
LTSEs: 
Breton Plots
Publisher: 
Agronomy journal (Agron. j.) CODEN AGJOAT
Year: 
1995
Authors: 
IZURRALDE, R. C. ; CHOUDHARY M. ; JUMA N. G. ; MCGILL W. B.; HADERLEIN L.
ISBN_ISSN: 
ISSN 0002-1962
Volume: 
Vol. 87, no5, pp. 958-964 (28 ref.)
Abstract: 
Though legumes are beneficial in crop rotations, there is limited information on how tillage system-crop sequence interactions influence crop yield and N production. To see if biomass and N yields in short-term legume-based rotations under zero tillage (ZT) and low-input (LI) production methods can equal those in cereal monocultures under ZT and conventional tillage (CT), field experiments were conducted in Alberta, Canada, from 1989 to 1992 at Ellerslie (Typic Cryoboroll soil) and Breton (Typic Cryoboralf). Treatments at each site consisted of (i) two 4-yr rotations, each with the same crop sequence but different tillage methods, and (ii) four continuous barley treatments in 2 x 2 factorial combination of tillage and fertilizer N. The crop sequence was barley (Hordeum vulgare L.)-barley and field pea (Pisum sativum L.) intercrop-barley-fababean (Viciafaba L.). At Ellerslie, tillage for weed control and seedbed preparation was either CT-LI or ZT. At Breton, one rotation used the LI approach ; the second used deep tillage (DT). Weeds on CT and ZT were controlled with either pre- or postemergence herbicides. No herbicides were applied to LI treatments at either site or to the DT treatment at Breton. Yields of barley following legumes under ZT were similar to those of fertilized continuous barley. With nonchemical weed-control methods, weed competition reduced yields of barley following legumes by 24% compared with fertilized continuous barley. The increased fababean yield measured under DT was associated with improved rooting conditions and water extraction. The equivalent N-fertilizer value of legume residues with similar weed-control levels averaged 19 kg ha[-1] Except for the LI system, legume-based rotations produced, over the 4-yr cycle, amounts of N equivalent to continuous cereal systems. Resource use efficiency of legume-based rotations, as measured by net-N yields, was equivalent to continuous systems at Breton, but somewhat reduced at Ellerslie.

Macroinvertebrates in North American tallgrass prairie soils: effects of fire, mowing, and fertilization on density and biomass

Relationships
LTSEs: 
Konza Prairie
Publisher: 
SOIL BIOLOGY & BIOCHEMISTRY
Year: 
2003
Authors: 
Callaham MA, Blair JM, Todd TC, Kitchen DJ, Whiles MR
File: 
Callaham_MA2003.pdf
Volume: 
35
Issue: 
2003
Pagination: 
1079-1093
DOI: 
10.1016/S0038-0717(03)00153-6
Abstract: 
The responses of tallgrass prairie plant communities and ecosystem processes to fire and grazing are well characterized. However, responses of invertebrate consumer groups, and particularly soil-dwelling organisms, to these disturbances are not well known. At Konza Prairie Biological Station, we sampled soil macroinvertebrates in 1994 and 1999 as part of a long-term experiment designed to examine the effects and interactions of annual fire, mowing, and fertilization (N and P) on prairie soil communities and processes. For nearly all taxa, in both years, responses were characterized by significant treatment interactions, but some general patterns were evident. Introduced European earthworms (Aporrectodea spp. and Octolasion spp.) were most abundant in plots where fire was excluded, and the proportion of the total earthworm community consisting of introduced earthworms was greater in unburned, unmowed, and fertilized plots. Nymphs of two Cicada genera were collected (Cicadetta spp. and Tibicen spp.). Cicadetta nymphs were more abundant in burned plots, but mowing reduced their abundance. Tibicen nymphs were collected almost exclusively from unburned plots. Treatment effects on herbivorous beetle larvae (Scarabaeidae, Elateridae, and Curculionidae) were variable, but nutrient additions (N or P) usually resulted in greater densities, whereas mowing usually resulted in lower densities. Our results suggest that departures from historical disturbance regimes (i.e. frequent fire and grazing) may render soils more susceptible to increased numbers of European earthworms, and that interactions between fire, aboveground biomass removal, and vegetation responses affect the structure and composition of invertebrate communities in tallgrass prairie soils. q 2003 Elsevier Science Ltd. All rights reserved.

Using the continuous-quality theory to predict microbial biomass and soil organic carbon following organic amendments

Relationships
LTSEs: 
Ultuna long-term soil organic matter experiment
Publisher: 
EUROPEAN JOURNAL OF SOIL SCIENCE
Year: 
2005
Authors: 
Nilsson KS, Hyvonen R, Agren GI
File: 
j.1365-2389.2004.00677.pdf
ISBN_ISSN: 
1351-0754
Volume: 
56
Issue: 
3
Pagination: 
397-405
Abstract: 
Soil microbial biomass and microbial quotient (the ratio of soil microbial biomass to soil organic carbon) are considered to be useful as rapidly responding indicators of perturbations of soil properties. In this paper we will use a well-tested model (the continuous-quality theory) to analyse these variables in a Swedish 35-year-old field experiment with a black fallow, crop with no N addition, crop with calcium nitrate addition, and six treatments with organic amendments: straw, green manure, peat, farmyard manure, sawdust and sewage sludge. The model predicts correctly that the amount of microbial biomass increases for all the treatments with organic amendments compared with the black fallow treatment. The microbial biomass quotient increases also for all the amended treatments, except peat and sewage sludge, and decreases for the other treatments. The microbial biomass and microbial quotient increase with both the amounts of organic matter added (crop residues and amendments) and the quality of the added matter. However, to fully explain the observations it is also necessary to have an increasing microbial mortality with substrate quality. Moreover, short-term observations can be misleading with respect to both the magnitude and direction of long-term changes in biomass and related variables. Special attention must be paid to such amendments as sewage sludge, where contaminants such as heavy metals may determine process rates. We find no relation between microbial biomass or microbial quotient and yields.

Yield and soil fertility trends in a 20-year rice-rice-wheat experiment in Nepal

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LTSEs: 
Yield and soil fertility trends in a 20-year rice-rice-wheat experiment in Nepal
Publisher: 
SOIL SCIENCE SOCIETY OF AMERICA JOURNAL
Year: 
2002
Authors: 
Regmi AP, Ladha JK, Pathak H, Pasuquin E, Bueno C, Dawe D, Hobbs PR, Joshy D, Maskey SL, Pandey SP
File: 
857.pdf
ISBN_ISSN: 
0361-5995
Volume: 
66
Issue: 
3
Pagination: 
857-867
Abstract: 
The rice (Oryza sativa L.)-wheat (Triticum aestivum L.) cropping system occupies about 13.5 million ha in South Asia and is important for the region's food security. We examined the long-term yield trends, changes in soil nutrient fractions (both total and available), and nutrient balances in a 20-yr rice-rice-wheat experiment conducted in the Indo-Gangetic plain of Nepal. The yield of first rice crop fertilized with recommended NPK fertilizer or farmyard manure (FYM) declined an average of 0.09 or 0.07 Mg ha(-1) yr(-1), respectively. These 20-yr trends explained only 20 to 21% of the variability in yield, and inexplicable shorter-term yield trends were observed. Likewise, wheat yield declined at 0.05 Mg ha(-1) yr(-1) (with both NPK and FYM) over the 20 yr. However, the yield of second rice crop did not decline over that period. The total and available N and P, and total and labile C contents of soil from Year 10 to 20 were either maintained or increased, but total K and available K declined. The apparent K balance showed net losses of 62.3 and 15.2 kg K ha(-1) yr(-1) with NPK and FYM treatments, respectively. Depletion of soil K and inadequate K fertilization seems to be the primary reasons of limited and declining yield of first rice and wheat crop. In addition, the yield of wheat declined because of a delay in sowing, which was estimated to be 0.04 Mg ha(-1) for each day delay in sowing. The study showed that the current local fertilizer recommendations, particularly for K, for the rice-rice-wheat system are inadequate.

Long-term nitrogen, phosphorus and potassium fertilization of cassava influences soil chemical properties in North Vietnam

Relationships
LTSEs: 
Long-term N, P, K fertilization of cassava and soil chemical properties in N Vietnam
Publisher: 
CANADIAN JOURNAL OF SOIL SCIENCE
Year: 
2001
Authors: 
Nguyen H, Schoenau JJ, Van Rees K, Nguyen D, Qian R
ISBN_ISSN: 
0008-4271
Volume: 
81
Issue: 
3
Pagination: 
481-488
Abstract: 
The long-term effects of Yearly fertilizer applications on soil chemical properties and nutrient availability are not well documented for cassava (Manihot esculenta) production in Vietnam. In 1990, research plots were established (randomized complete block design) with 12 treatments to test effects of different rates of N, P and K on soil properties in Acrisols (FAO-UNESCO Soil Classification) at Thai Nguyen University, North Vietnam. In June 1998, composite soil samples (0- to 10-cm and 10- to 20-cm depth) were collected from each plot. Nine years of N application significantly reduced the labile pools of soil inorganic P, total soil P and soil extractable K and Mg. Total soil N was only slightly increased in the 10- to 30-cm depth. Long-term applications of P significantly increased soil inorganic P fractions, but reduced concentrations and supply rates of nitrate and K. Moreover, 9 yr of K application significantly increased soil organic C (two depths), soil total N (10-30 cm) and soil extractable K in the 0- to 10-cm depth. Generally, the results show that long-term applications of mineral fertilizers in a ratio of N:P2O5:K2O of 2:1:2 (at the rates of 80 N:40 P2O5:80 K2O or 160 N: 80 P2O5:160 K2O) are effective in maintaining the total content and availability of applied nutrients, but when applied alone are associated with decreases in other nutrients.
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