Long-term tobacco plantation induces soil acidification and soil base cation loss

详细信息    查看全文

• 作者：Yuting Zhang ; Xinhua He ; Hong Liang…
• 关键词：Acid ; buffering capacity ; Ali ; Periudic Argosols ; Exchangeable base cations ; Nicotiana tabacum ; H+ budget ; Soil pH
• 刊名：Environmental Science and Pollution Research
• 出版年：2016
• 出版时间：March 2016
• 年：2016
• 卷：23
• 期：6
• 页码：5442-5450
• 全文大小：864 KB
• 参考文献：Alekseeva T, Alekseev A, Xu RK, Zhao AZ, Kalinin P (2011) Effect of soil acidification induced by a tea plantation on chemical and mineralogical properties of Alfisols in eastern China. Environ Geochem Health 33:137–148CrossRef
  Berthrong ST, Jobbágy EG, Jackson RB (2009) A global meta-analysis of soil exchangeable cations, pH, carbon, and nitrogen with afforestation. Ecol Appl 19:2228–2241CrossRef
  Bolan NS, Adriano DC, Curtin D (2003) Soil acidification and liming interactions with nutrient and heavy metal transformation and bioavailability. Adv Agron 78:215–272CrossRef
  Bortoluzzi EC, Moterle DF, dos Santos RD, Casali CA, Melo GW, Brunetto G (2012) Mineralogical changes caused by grape production in a regosol from subtropical Brazilian climate. J Soils Sediments 12:854–862CrossRef
  Chen D, Lan Z, Bai X, Grace JB, Bai Y (2013) Evidence that acidification-induced declines in plant diversity and productivity are mediated by changes in below-ground communities and soil properties in a semi-arid steppe. J Ecol 101:1322–1334CrossRef
  Chen JH, Liu JL, Li ZH (2008) Tobacco Soils and Fertilization in China (in Chinese). Science Press, China, Beijing
  Chien SH, Gearhart MM, Collamer DJ (2008) The effect of different ammonical nitrogen sources on soil acidification. Soil Sci 173:544–551CrossRef
  Céspedes-Payret C, Piñeiro G, Gutiérrez O, Panario D (2012) Land use change in a temperate grassland soil: afforestation effects on chemical properties and their ecological and mineralogical implications. Sci Total Environ 438:549–557CrossRef
  CNBS (China National Bureau of Statistics) (2012) Statistical Yearbook of Chongqing (in Chinese). China Statistics Press, Beijing, China
  De Vries W, Posch M, Kämäri J (1989) Simulation of the long-term soil response to acid deposition in various buffer ranges. Water Air Soil Pollut 48:349–390CrossRef
  Duan Y, Xu M, Wang B, Yang X, Huang S, Gao S (2011) Long-term evaluation of manure application on maize yield and nitrogen use efficiency in China. Soil Sci Soc Am J 75:1562–1573CrossRef
  Guo JH, Liu XJ, Zhang Y, Shen JL, Han WX, Zhang WF, Christie P, Goulding KWT, Vitousek PM, Zhang FS (2010) Significant acidification in major Chinese croplands. Science 327:1008–1010CrossRef
  Han JP, Shi JC, Zeng LZ, Xu JM, Wu LS (2015) Effects of nitrogen fertilization on the acidity and salinity of greenhouse soils. Environ Sci Pollut Res 22:2976–2986CrossRef
  Hoegberg P, Fan H, Quist M, Binkley D, Tamm CO (2006) Tree growth and soil acidification in response to 30 years of experimental nitrogen loading on boreal forest. Glob Chang Biol 12:489–499CrossRef
  Jackson RB, Jobbágy EG, Avissar R, Roy SB, Barrett DJ, Cook CW, Farley KA, le Maitre DC, McCarl BA, Murray BC (2005) Trading water for carbon with biological carbon sequestration. Science 310:1944–1947CrossRef
  Klaminder J, Lucas RW, Futter MN, Bishop KH, Köhler SJ, Egnell G, Laudon H (2011) Silicate mineral weathering rate estimates: are they precise enough to be useful when predicting the recovery of nutrient pools after harvesting? For Ecol Manag 261:1–9CrossRef
  Lesturgez G, Poss R, Noble A, Grünberger O, Chintachao W, Tessier D (2006) Soil acidification without pH drop under intensive cropping systems in Northeast Thailand. Agric Ecosyst Environ 114:239–248CrossRef
  Lu X, Mao Q, Gilliam FS, Luo Y, Mo J (2014) Nitrogen deposition contributes to soil acidification in tropical ecosystems. Glob Chang Biol 20:3790–3801CrossRef
  Lu RK (2000) Analytical Methods for Soil and Agrochemistry (in Chinese). China Agricultural Science and Technology Press, Beijing
  Lucas RW, Klaminder J, Futter MN, Bishop KH, Egnell G, Laudon H, Högberg P (2011) A meta-analysis of the effects of nitrogen additions on base cations: implications for plants, soils, and streams. For Ecol Manag 262:95–104CrossRef
  Malhi SS, Harapiak JT, Nyborg M, Gill KS (2000) Effects of long-term applications of various nitrogen sources on chemical soil properties and composition of bromegrass hay. J Plant Nutr 23:903–912CrossRef
  McDonnell TC, Sullivan TJ, Cosby BJ, Jackson WA, Elliott KJ (2013) Effects of climate, land management, and sulfur deposition on soil base cation supply in national forests of the Southern Appalachian Mountains. Water Air Soil Pollut 224:1–18CrossRef
  Miao Y, Stewart BA, Zhang F (2011) Long-term experiments for sustainable nutrient management in China. A review. Agron Sustain Dev 31:397–414CrossRef
  Nelson PN, Su N (2010) Soil pH buffering capacity: a descriptive function and its application to some acidic tropical soils. Soil Res 48:201–207CrossRef
  Noble AD, Middleton C, Nelson PN, Rogers LG (2002) Risk mapping of soil acidification under Stylosanthes in northern Australian rangelands. Soil Res 40:257–267CrossRef
  Peters GM, Wiedemann S, Rowley HV, Tucker R, Feitz AJ, Schulz M (2011) Assessing agricultural soil acidification and nutrient management in life cycle assessment. Int J Life Cycle Assess 16:431–441CrossRef
  Posch M, Reinds GJ (2009) A very simple dynamic soil acidification model for scenario analyses and target load calculations. Environ Model Softw 24:329–340CrossRef
  Randall PJ, Abaidoo RC, Hocking PJ, Sanginga N (2006) Mineral nutrient uptake and removal by cowpea, soybean and maize cultivars in West Africa, and implications for carbon cycle effects on soil acidification. Exp Agric 42:475–494CrossRef
  Rengel Z (2003) Handbook of Soil Acidity. CRC Press, New YorkCrossRef
  Rice KC, Herman JS (2012) Acidification of Earth: an assessment across mechanisms and scales. Appl Geochem 27:1–14CrossRef
  Rousk J, Baath E, Brookes PC, Lauber CL, Lozupone C, Caporaso JG, Knight R, Fierer N (2010) Soil bacterial and fungal communities across a pH gradient in an arable soil. ISME J 4:1340–1351CrossRef
  Santonoceto C, Hocking PJ, Braschkat J, Randall PJ (2002) Mineral nutrient uptake and removal by canola, Indian mustard, and Linola in two contrasting environments, and implications for carbon cycle effects on soil acidification. Crop Pasture Sci 53:459–470CrossRef
  Schroder JL, Zhang H, Girma K, Raun WR, Penn CJ, Payton ME (2011) Soil acidification from long-term use of nitrogen fertilizers on winter wheat. Soil Sci Soc Am J 75:957–964CrossRef
  Tian D, Niu S (2015) A global analysis of soil acidification caused by nitrogen addition. Environ Res Lett 10:024019CrossRef
  Van Breemen N, Driscoll CT, Mulder J (1984) Acidic deposition and internal proton sources in acidification of soils and waters. Nature 307:599–604CrossRef
  Verstraten JM, Dopheide JCR, Duysings JJHM, Tietema A, Bouten W (1990) The proton cycle of a deciduous forest ecosystem in the Netherlands and its implications for soil acidification. Plant Soil 127:61–69CrossRef
  Wang AS, Angle JS, Chaney RL, Delorme TA, Reeves RD (2006) Soil pH effects on uptake of Cd and Zn by Thlaspi caerulescens. Plant Soil 281:325–337CrossRef
  Xu RK, Zhao AZ, Yuan JH, Jiang J (2012) pH buffering capacity of acid soils from tropical and subtropical regions of China as influenced by incorporation of crop straw biochars. J Soils Sediments 12:494–502CrossRef
  Yang JL, Zhang GL, Huang LM, Brookes PC (2013) Estimating soil acidification rate at watershed scale based on the stoichiometric relations between silicon and base cations. Chem Geol 337:30–37CrossRef
  Yang YH, Chen JJ, Ma WH, Wang SF, Wang SP, Han WX, Mohammat A, Robinson D, Smith P (2012) Significant soil acidification across northern China’s grasslands during 1980s–2000s. Glob Chang Biol 18:2292–2300CrossRef
  Zhang N, MacKown CT (1993) Nitrate fluxes and nitrate reductase activity of suspension-cultured tobacco cells (effects of internal and external nitrate concentrations). Plant Physiol 102:851–857
  
• 作者单位：Yuting Zhang (1) (2)
  Xinhua He (3) (4)
  Hong Liang (5)
  Jian Zhao (7)
  Yueqiang Zhang (1) (2)
  Chen Xu (6)
  Xiaojun Shi (1) (2)
  
  1. College of Resources and Environment, Southwest University, Chongqing, 400716, China
  2. National Monitoring Station of Soil Fertility and Fertilizer Efficiency on Purple Soils, Chongqing, 400716, China
  3. Centre of Excellence for Soil Biology, College of Resources and Environment, Southwest University, Chongqing, 400716, China
  4. Department of Environmental Sciences, University of Sydney, Eveleigh, NSW 2015, Australia
  5. College of Agriculture, Guizhou University, Guiyang, 550025, China
  7. Technology Research Centre, Zunyi Tobacco Company, Zunyi, 563000, Guizhou, China
  6. Tobacco Scientific Research Institute, Chongqing Tobacco Company, Chongqing, 400716, China
  
• 刊物类别：Earth and Environmental Science
• 刊物主题：Environment
  Environment
  Atmospheric Protection, Air Quality Control and Air Pollution
  Waste Water Technology, Water Pollution Control, Water Management and Aquatic Pollution
  Industrial Pollution Prevention
  
• 出版者：Springer Berlin / Heidelberg
• ISSN：1614-7499

文摘

Changes in soil exchangeable cations relative to soil acidification are less studied particularly under long-term cash crop plantation. This study investigated soil acidification in an Ali-Periudic Argosols after 10-year (2002–2012) long-term continuous tobacco plantation. Soils were respectively sampled at 1933 and 2143 sites in 2002 and 2012 (also 647 tobacco plants), from seven tobacco plantation counties in the Chongqing Municipal City, southwest China. After 10-year continuous tobacco plantation, a substantial acidification was evidenced by an average decrease of 0.20 soil pH unit with a substantial increase of soil sites toward the acidic status, especially those pH ranging from 4.5 to 5.5, whereas 1.93 kmol H+ production ha−1 year−1 was mostly derived from nitrogen (N) fertilizer input and plant N uptake output. After 1 decade, an average decrease of 27.6 % total exchangeable base cations or of 0.20 pH unit occurred in all seven tobacco plantation counties. Meanwhile, for one unit pH decrease, 40.3 and 28.3 mmol base cations kg−1 soil were consumed in 2002 and 2012, respectively. Furthermore, the aboveground tobacco biomass harvest removed 339.23 kg base cations ha−1 year−1 from soil, which was 7.57 times higher than the anions removal, leading to a 12.52 kmol H+ production ha−1 year−1 as the main reason inducing soil acidification. Overall, our results showed that long-term tobacco plantation not only stimulated soil acidification but also decreased soil acid-buffering capacity, resulting in negative effects on sustainable soil uses. On the other hand, our results addressed the importance of a continuous monitoring of soil pH changes in tobacco plantation sites, which would enhance our understanding of soil fertility of health in this region.