Intercropping maintains soil fertility in terms of chemical properties and enzyme activities on a timescale of one decade
Tóm tắt
Overyielding (i.e., mixtures of crops yielding higher than expected when compared with monocultures) and increased nutrient acquisition have been found in many intercropping systems. However, there are very few published studies on long-term changes in soil chemical and biological properties in intercropping systems compared to sole cropping. A field experiment was established in 2003 in Gansu province, northwest China. The treatments comprised three intercropping systems (either continuous or rotational wheat/maize, wheat/faba bean, maize/faba bean intercropping), rotational cropping (wheat-maize, wheat-faba bean, faba bean-maize, and wheat-maize-faba bean rotations), and monocropping (sole wheat, faba bean and maize) systems. In 2011 (ninth year of the experiment) and 2012 (tenth year) the yields and some soil chemical and biological properties were examined after all crop species were harvested. There was overyielding by 6.6 % and 32.4 % in wheat/maize intercropping in 2011 and 2012, respectively. Faba bean/maize intercropping was enhanced by 34.7 % and 28.6 %, respectively but not wheat/faba bean intercropping. Soil organic matter, total nitrogen, Olsen P, exchangeable K and cation exchange capacity in all intercropping systems did not differ from the monocultures except for soil pH in wheat/maize and faba bean/maize intercropping in 2011 and soil exchangeable K and cation exchange capacity (CEC) in 2012. Soil pH in wheat/maize and faba bean/maize intercropping was significantly reduced by 3.2 % and 1.9 %, respectively. Soil exchangeable K in wheat/maize, faba bean/maize and wheat/faba bean intercropping declined markedly by 15 %, 21.7 % and 12.1 %, respectively. Soil cation exchange capacity in wheat/maize, faba bean/maize and wheat/faba bean intercropping was notably lower than the corresponding monocultures by 17.5 %, 23.3 % and 18.3 %, respectively. Soil enzyme activities after 9 and 10 years of intercropping differed little from monocultures or rotations. The results indicate that intercropping overyielded compared with monocropping or rotational cropping and also maintained the stability of most of the soil chemical and enzyme activities relative to rotations and monocropping in the relatively fertile soil studied.
Từ khóa
Tài liệu tham khảo
Ae N, Arihara J, Okada K, Yoshihara T, Johansen C (1990) Phosphorus uptake by pigeonpea and its role in cropping systems of the Indian subcontinent. Science 248:477–480
Alvear M, Rosas A, Rouanet JL, Borie F (2005) Effects of three soil tillage systems on some biological activities in an Ultisol from southern Chile. Soil Till Res 82:195–202
Andrade JF, Cerrudo A, Rizzalli RH, Monzon JP (2012) Sunflower-soybean Intercrop productivity under different water conditions and sowing managements. Agron J 104:1049–1055
Aulakh MS, Pasricha NS, Bahl GS (2003) Phosphorus fertilizer response in an irrigated soybean-wheat production system on a subtropical, semiarid soil. Field Crops Res 80:99–109
Baligar V, Staley T, Wright R (1991) Enzyme activities in Appalachian soils: 2. Urease. Commun Soil Sci Plant Anal 22:315–322
Baligar VC, Wright RJ, Hern JL (2005) Enzyme activities in soil influenced by levels of applied sulfur and phosphorus. Commun Soil Sci Plant Anal 36:1727–1735
Bao SD (2000) Analysis on soil and agricultural chemistry (in Chinese). China Agricultural Press, Beijing
Berthrong ST, Jobbágy EG, Jackson RB (2009) A global meta-analysis of soil exchangeable cations, pH, carbon, and nitrogen with afforestation. Ecol Appl 19:2228–2241
Blaise D, Bonde AN, Chaudhary RS (2005) Nutrient uptake and balance of cotton + pigeonpea strip intercropping on rainfed Vertisols of central India. Nutr Cycl Agroecosys 73:135–145
Burns RG (1978) Enzyme activity in soil: some theoretical and practical considerations. Soil enzymes Academic Press, New York, pp 295–340
Chen BM, Wang ZH, Li SX, Wang GX, Song HX, Wang XN (2004) Effects of nitrate supply on plant growth, nitrate accumulation, metabolic nitrate concentration and nitrate reductase activity in three leafy vegetables. Plant Sci 167:635–643
Cong WF, Hoffland E, Li L, Six J, Sun JH, Bao XG, Zhang FS, Van Der Werf W (2014) Intercropping enhances soil carbon and nitrogen. Global Change Biol doi: 10.1111/gcb.12738
Conn C, Dighton J (2000) Litter quality influences on decomposition, ectomycorrhizal community structure and mycorrhizal root surface acid phosphatase activity. Soil Biol Biochem 32:489–496
Dahmardeh M, Ghanbari A, Syahsar B, Ramrodi M (2010) The role of intercropping maize (Zea mays L.) and Cowpea (Vigna unguiculata L.) on yield and soil chemical properties. Afr J Agr Res 5:631–636
Dakora FD, Phillips DA (2002) Root exudates as mediators of mineral acquisition in low-nutrient environments. Plant Soil 245:35–47
de Carvalho LM, Nunes MUC, de Oliveira IR (2009) Yield of tomato in monocrop and intercropping with aromatics plants. Hortic Bras 27:458–464
Dick W, Cheng L, Wang P (2000) Soil acid and alkaline phosphatase activity as pH adjustment indicators. Soil Biol Biochem 32:1915–1919
Doran JW (2002) Soil health and global sustainability: translating science into practice. Agr Ecosyst Environ 88:119–127
Dybzinski R, Fargione JE, Zak DR, Fornara D, Tilman D (2008) Soil fertility increases with plant species diversity in a long-term biodiversity experiment. Oecologia 158:85–93
Eskandari H (2011) Intercropping of wheat (Triticum aestivum) and bean (Vicia faba): effects of complementarity and competition of intercrop components in resource consumption on dry matter production and weed growth. Afr J Biotechnol 10:17755–17762
FAO/UNESCO. (1988) FAO/UNESCO Soil map of the world, 1:5,000,000 Vol. 1 Paris: UNESCO
Fornara DA, Tilman D (2008) Plant functional composition influences rates of soil carbon and nitrogen accumulation. J Ecol 96:314–322
Fornara DA, Tilman D, Hobbie SE (2009) Linkages between plant functional composition, fine root processes and potential soil N mineralization rates. J Ecol 97:48–56
Fortin MC, Culley J, Edwards M (1994) Soil water, plant growth, and yield of strip-intercropped corn. J Sci Food Agr 7:63–69
Francis CA (1986) Multiple cropping systems. Macmillan Publishing Company pp 383
Francis CA (1989) Biological efficiencies in multiple-cropping systems. Adv Agron 42:42
Frankenberger WT Jr, Johanson JB (1983) Factors affecting invertase activity in soils. Plant Soil 74:313–323
Fu MH, Tabatabai MA (1989) Nitrate reductase activity in soils: effects of trace elements. Soil Biol Biochem 21:943–946
Ghosh PK, Mohanty M, Bandyopadhyay KK, Painuli DK, Misra AK (2006) Growth, competition, yields advantage and economics in soybean/pigeonpea intercropping system in semi-arid tropics of India. Field Crop Res 96:90–97
Gregorich EG, Drury CF, Baldock JA (2001) Changes in soil carbon under long-term maize in monoculture and legume-based rotation. Can J Soil Sci 81:21–31
Gt E, Hageman R (1973) Nitrate reductase activity and its relationship to accumulation of vegetative and grain nitrogen in wheat (Triticum aestivum L.). Crop Sci 13:59–66
Guan SY (1986) Soil enzyme and research method (in Chinese). China Agricultural Press, Beijing
Hageman RH, Flesher D, Gitter A (1961) Diurnal variation and other light effects influencing the activity of nitrate reductase and nitrogen metabolism in corn. Crop Sci 1:201–204
Hauggaard-Nielsen H, Jensen ES (2001) Evaluating pea and barley cultivars for complementarity in intercropping at different levels of soil N availability. Field Crop Res 72:185–196
Haynes RJ, Williams PH (1999) Influence of stock camping behaviour on the soil microbiological and biochemical properties of grazed pastoral soils. Biol Fert Soils 28:253–258
Högberg P, Granström A, Johansson T, Lundmark-Thelin A, Näsholm T (1986) Plant nitrate reductase activity as an indicator of availability of nitrate in forest soils. Can J For Res 16:1165–1169
SAS Institute (2003) SAS. 9.1 ed. Cary, NC: SAS Institute, Inc
Jensen ES (1996) Grain yield, symbiotic N2 fixation and interspecific competition for inorganic N in pea-barley intercrops. Plant Soil 182:25–38
Jensen ES, Hauggaard-Nielsen H (2003) How can increased use of biological N2 fixation in agriculture benefit the environment? Plant Soil 252:177–186
Karlen DL, Mausbach MJ, Doran JW, Cline RG, Harris RF, Schuman GE (1997) Soil quality: a concept, definition, and framework for evaluation (a guest editorial). Soil Sci Soc Am J 61:4–10
Keating BA, Carberry PS (1993) Resource capture and use in intercropping: solar radiation. Field Crops Res 34:273–301
Köpke U, Nemecek T (2010) Ecological services of faba bean. Field Crops Res 115:217–233
Leihner DE (1983) Management and evaluation of intercropping systems with cassava. Centro International of Agricultura Tropical, Cali
Lesoing GW, Francis CA (1999) Strip intercropping of corn-soybean in irrigated and rainfed environments. J Sci Food Agr 12:187–192
Li L, Sun J, Zhang F, Li X, Yang S, Rengel Z (2001a) Wheat/maize or wheat/soybean strip intercropping: I. Yield advantage and interspecific interactions on nutrients. Field Crops Res 71:123–137
Li L, Sun J, Zhang F, Li X, Rengel Z, Yang S (2001b) Wheat/maize or wheat/soybean strip intercropping: II. Recovery or compensation of maize and soybean after wheat harvesting. Field Crop Res 71:173–181
Li WX, Li L, Sun JH, Zhang FS, Christie P (2003) Effects of nitrogen and phosphorus fertilizers and intercropping on uptake of nitrogen and phosphorus by wheat, maize, and faba bean. J Plant Nutr 26:629–642
Li S, Li L, Zhang F, Tang C (2004) Acid phosphatase role in chickpea/maize intercropping. Ann Bot 94:297–303
Li L, Sun JH, Zhang FS, Guo TW, Bao XG, Smith FA, Smith SE (2006) Root distribution and interactions between intercropped species. Oecologia 147:280–290
Li L, Li SM, Sun JH, Zhou LL, Bao XG, Zhang HG, Zhang FS (2007) Diversity enhances agricultural productivity via rhizosphere phosphorus facilitation on phosphorus-deficient soils. Proc Natl Acad Sci U S A 104:11192–11196
Li CJ, Li YY, Yu CB, Sun JH, Christie P, An M, Zhang FS, Li L (2011a) Crop nitrogen use and soil mineral nitrogen accumulation under different crop combinations and patterns of strip intercropping in northwest China. Plant Soil 342:221–231
Li QZ, Sun JH, Wei XJ, Christie P, Zhang FS, Li L (2011b) Overyielding and interspecific interactions mediated by nitrogen fertilization in strip intercropping of maize with faba bean, wheat and barley. Plant Soil 339:147–161
López-Bellido L, López-Bellido RJ, Redondo R, Benítez J (2006) Faba bean nitrogen fixation in a wheat-based rotation under rainfed Mediterranean conditions: effect of tillage system. Field Crops Res 98:253–260
Ma RX (2000) Effects of allelochemicals on activity of nitrate reductase. J Environ Sci 2:125–128
Madari B, Machado PLOA, Torres E, de Andrade AG, Valencia LIO (2005) No tillage and crop rotation effects on soil aggregation and organic carbon in a Rhodic Ferralsol from southern Brazil. Soil Till Res 80:185–200
Mäder P, Fliessbach A, Dubois D, Gunst L, Fried P, Niggli U (2002) Soil fertility and biodiversity in organic farming. Science 296:1694–1697
Makinde E, Oluwatoyinbo F, Ayoola O (2006) Intercropping and crop residue incorporation: effects on soil nutrient status. J Plant Nutri 29:235–244
Martin RC, Astatkie T, Cooper JM (1998) The effect of soybean variety on corn-soybean intercrop biomass and protein yields. Can J Plant Sci 78:289–294
Mei PP, Gui LG, Wang P, Huang JC, Long HY, Christie P, Li L (2012) Maize/faba bean intercropping with rhizobia inoculation enhances productivity and recovery of fertilizer P in a reclaimed desert soil. Field Crops Res 130:19–27
Melero S, Porras JCR, Herencia JF, Madejon E (2006) Chemical and biochemical properties in a silty loam soil under conventional and organic management. Soil Till Res 90:162–170
Melero S, Madejon E, Ruiz JC, Herencia JF (2007) Chemical and biochemical properties of a clay soil under dryland agriculture system as affected by organic fertilization. Eur J Agron 26:327–334
Mondal SS, Ghosh A, Acharya D, Mait D (2004) Production potential and economics of different rainfed rice (Oryza sativa)-based utera cropping systems and its effect on fertility build up of soil. Indian J Agron 49:6–9
Morari F, Lugato E, Giardini L (2008) Olsen phosphorus, exchangeable cations and salinity in two long-term experiments of north-eastern Italy and assessment of soil quality evolution. Agr Ecosyst Environ 124:85–96
Morris RA, Garrity DP (1993a) Resource capture and utilization in intercropping non-nitrogen nutrients. Field Crops Res 34:319–334
Morris RA, Garrity DP (1993b) Resource capture and utilization in intercropping: water. Field Crops Res 34:303–317
Mucheru-Muna M, Pypers P, Mugendi D, Kung’u J, Mugwe J, Merckx R, Vanlauwe B (2010) A staggered maize–legume intercrop arrangement robustly increases crop yields and economic returns in the highlands of Central Kenya. Field Crops Res 115:132–139
Olsen SR, Cole CV, Watanabe FS, Dean LA (1954) Estimation of available phosphorus in soils by extraction with sodium bicarbonate, USDA. Circular939. US Government Printing Office, Washington
Pellegrino E, Di Bene C, Tozzini C, Bonari E (2011) Impact on soil quality of a 10-year-old short-rotation coppice poplar stand compared with intensive agricultural and uncultivated systems in a Mediterranean area. Agr Ecosyst Environ 140:245–254
Qi ZP, Rao IM, Ricaurte J, Amézquita E, Sanz JI, Kerridge PC (2004) Root distribution and nutrient uptake in crop-forage systems on Andean hillsides. J Sustain Agr 23:39–50
Rayment GE, Higginson FR (1992) Australian laboratory handbook of soil and water chemical methods. Inkata Press Pty Ltd, Australia, pp 89–92
Ritter E (2007) Carbon, nitrogen and phosphorus in volcanic soils following afforestation with native birch (Betula pubescens) and introduced larch (Larix sibirica) in Iceland. Plant Soil 295:239–251
Roldan A, Salinas-Garcia JR, Alguacil MM, Caravaca F (2007) Soil sustainability indicators following conservation tillage practices under subtropical maize and bean crops. Soil Till Res 93:273–282
Ross DJ (1983) Invertase and amylase activities as influenced by clay minerals, soil-clay fractions and topsoils under grassland. Soil Biol Biochem 15:287–293
Ross DS, Matschonat G, Skyllberg U (2008) Cation exchange in forest soils: the need for a new perspective. Eur J Soil Sci 59:1141–1159
Rusinamhodzi L, Corbeels M, Nyamangara J, Giller KE (2012) Maize-grain legume intercropping is an attractive option for ecological intensification that reduces climatic risk for smallholder farmers in central Mozambique. Field Crops Res 136:12–22
Saikh H, Varadachari C, Ghosh K (1998) Effects of deforestation and cultivation on soil CEC and contents of exchangeable bases: a case study in Simlipal national park, India. Plant Soil 204:175–181
Sarapatka B, Krskova M (1997) Interactions between phosphatase activity and soil characteristics from some locations in the Czech Republic. Rostlinna Vyroba-UZPI 43
Šimek M, Jíšová L, Hopkins DW (2002) What is the so-called optimum pH for denitrification in soil? Soil Biol Biochem 34:1227–1234
Singh DK, Kumar S (2008) Nitrate reductase, arginine deaminase, urease and dehydrogenase activities in natural soil (ridges with forest) and in cotton soil after acetamiprid treatments. Chemosphere 71:412–418
Stuelpnagel R (1992) Intercropping of faba beans (Vicia faba L.) with oats or spring wheat. In: Proceedings of the International Crop Science Congress, p 44
Tabatabai MA, Bremner JM (1969) Use of p-nitrophenyl phosphate for assay of soil phosphatase activity. Soil Biol Biochem 1:301–307
Tang C, Barton L, McLay CDA (1997) A comparison of proton excretion of twelve pasture legumes grown in nutrient solution. Anim Prod Sci 37:563–570
Thierfelder C, Wall PC (2012) Effects of conservation agriculture on soil quality and productivity in contrasting agro-ecological environments of Zimbabwe. Soil Use Manage 28:209–220
Venterea RT, Rolston DE (2000) Mechanisms and kinetics of nitric and nitrous oxide production during nitrification in agricultural soil. Global Change Biol 6:303–316
Wang XC, Yang WY, Ren WJ, Deng XY, Zhang Q, Xiang DB, Yong TW (2012) Study on the differences in yield and nutrient absorption of maize in wheat/maize/soybean and wheat/maize/sweet potato relay intercropping systems. Plant Nutr Fert Sci 18:803–812
Wei X, Hao M, Shao M, Gale WJ (2006) Changes in soil properties and the availability of soil micronutrients after 18 years of cropping and fertilization. Soil Till Res 91:120–130
Xia HY, Zhao JH, Sun JH, Xue YF, Eagling T, Bao XG, Zhang FS, Li L (2013) Maize grain concentrations and above-ground shoot acquisition of micronutrients as affected by intercropping with turnip, faba bean, chickpea, and soybean. Science China-Life Sciences 56:823–834
Yang WT, Li Z, Wang JW, Wu P, Zhang Y (2013) Crop yield, nitrogen acquisition and sugarcane quality as affected by interspecific competition and nitrogen application. Field Crops Res 146:44–50
Yong TW, Yang WY, Xiang DB, Zhu ZY (2012a) Effect of wheat/maize/soybean and wheat/maize/sweet potato relay strip intercropping on bacterial community diversity of rhizosphere soil and nitrogen uptake of crops. Acta Agron Sin 38:333–343
Yong TW, Yang WY, Xiang DB, Chen XR, Wan Y (2012b) Production and N nutrient performance of wheat-maize-soybean relay strip intercropping system and evaluation of interspecies competition. Acta Prataculturae Sinica 21:50–58
Zhang FS, Li L (2003) Using competitive and facilitative interactions in intercropping systems enhances crop productivity and nutrient-use efficiency. Plant Soil 248:305–312
Zomer RJ, Trabucco A, Coe R, Place F (2009) Trees on farm: analysis of global extent and geographical patterns of agroforestry. ICRAF Working Paper-World Agroforestry Centre,p 89
Zou CY, Li ZJ (2002) Intercropping and relay intercropping. In: Shi YC (ed) Chinese academic canon in the 20th century: agriculture (in Chinese). Fujian Education Press, Fuzhou