Abstract
Purpose
Land use conversion from rice paddy to upland has been shown to decrease soil pH due to enhanced proton production from nitrification of ammonium-based N fertilizers and base cation loss. Parent material and altitude have a dominant impact on spatiotemporal distribution of soil base cations, but little information is available about their effects on soil acidification. This study examined changes in acidity indicators after the conversion, and their relationship with parent materials and altitude in a typical hilly region of southern China.
Materials and methods
To explore the effects, soils derived from limestone, quaternary red clay, and sandshale were sampled from 11 sites in Qiyang and Qidong counties, Hunan Province, China. In each sampling site, paddy field as control and upland maize under different conversion ages were selected in adjacent and pairs. The information on management and conversion ages were surveyed from local farmers, and altitude was recorded for each site. Soil pH, exchangeable acidity, base cations, cation exchange capacity, soil organic matter, nutrients, and their inner relationships were examined.
Results and discussion
The conversion significantly decreased soil pH, which was parent material dependent. Soils derived from limestone had much higher pH than that from quaternary red clay and sandshale. Soil pH negatively correlated with altitude ranging from 96.2 to 138.3 m in the study area. The conversion significantly increased exchangeable acidity of soils derived from quaternary red clay and sandshale by 1.53 and 1.13 cmol(+) kg−1, respectively, dominated by Al, but no change for soils derived from limestone. The boosted regression tree model driven by soil properties explained 96.5%, 91.8%, and 98.1% of the pH variation of soils derived from limestone, quaternary red clay, and sandshale, respectively. Soil exchangeable Ca was the most influential trigger on pH variability of limestone- and quaternary red clay-derived soils, while soil total N and available N loss played critical roles in accelerating acidification of sandshale-derived soils after land use conversion.
Conclusions
Our data indicated that Ca and N loss play critical roles in accelerating soil acidification from enhanced nitrification after land use conversion in the red soil hilly region, which could be influenced by parent materials and altitude. Practices such as liming, straw mulching, or catch crop should be taken to prevent Ca and N loss, and alleviate acidification as the conversion occurring, especially for soils at high altitude.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Alarima CI, Annan-Afful E, Obalum SE, Awotunde JM, Masunaga T, Igwe CA, Wakatsuki T (2020) Comparative assessment of temporal changes in soil degradation under four contrasting land-use options along a tropical toposequence. Land Degrad Dev 31:439–450
Alfaro FD, Manzano M, Marquet PA, Gaxiola A (2017) Microbial communities in soil chronosequences with distinct parent material: the effect of soil pH and litter quality. J Ecol 105:1709–1722. https://doi.org/10.1111/1365-2745.12766
Angst G, Messinger J, Greiner M, Häusler W, Hertel D, Kirfel K, Kögel-Knabner I, Leuschner C, Rethemeyer J, Mueller CW (2018) Soil organic carbon stocks in topsoil and subsoil controlled by parent material, carbon input in the rhizosphere, and microbial-derived compounds. Soil Biol Biochem 122:19–30. https://doi.org/10.1016/j.soilbio.2018.03.026
Bao SD (1999) Methods of soil phosphorus and potassium. In: Bao SD (ed) Analysis of soil agrochemistry, 3rd edn. China Agriculture Press, Beijing pp 70–114
Bertsch PM, Bloom PR (1996) Soil pH and soil acidity. In: Sparks DL (ed) Methods of soil analysis. Part 3. Chemical methods, SSSA Book Series 5. ASA and SSSA, Madison, WI pp 517–76
Cai J, Luo W, Liu H, Feng X, Zhang Y, Wang R, Xu Z, Zhang Y, Jiang Y (2017) Precipitation-mediated responses of soil acid buffering capacity to long-term nitrogen addition in a semi-arid grassland. Atmos Environ 170:312–318
Cai Z, Wang B, Xu M, Zhang H, He X, Zhang L, Gao S (2015) Intensified soil acidification from chemical N fertilization and prevention by manure in an 18-year field experiment in the red soil of southern China. J Soil Sediment 15:260–270
Cai Z, Wang B, Xu M, Zhang H, Zhang L, Gao S (2014) Nitrification and acidification from urea application in red soil (Ferralic Cambisol) after different long-term fertilization treatments. J Soil Sediment 14:1526–1536
Company J, Valiente N, Fortesa J, García-Comendador J, Lucas-Borja ME, Ortega R, Miralles I, Estrany J (2022) Secondary succession and parent material drive soil bacterial community composition in terraced abandoned olive groves from a Mediterranean hyper-humid mountainous area. Agr Ecosyst Environ 332:107932
Chen J, Li Z, Xiao H, Ning K, Tang C (2021a) Effects of land use and land cover on soil erosion control in southern China: Implications from a systematic quantitative review. J Environ Manage 282:111924
Chen RR, Zhong LH, Jing ZW, Guo ZY, Li ZP, Lin XG, Feng YZ (2017) Fertilization decreases compositional variation of paddy bacterial community across geographical gradient. Soil Biol Biochem 114:181–188
Chen X, Hu Y, Xia Y, Zheng S, Ma C, Rui Y, He H, Huang D, Zhang Z, Ge T, Wu J, Guggenberger G, Kuzyakov Y, Su Y (2021b) Contrasting pathways of carbon sequestration in paddy and upland soils. Global Change Biol 27:2478–2490
Choudhury BU, Ansari MA, Chakraborty M, Meetei TT (2021) Effect of land-use change along altitudinal gradients on soil micronutrients in the mountain ecosystem of Indian (Eastern) Himalaya. Sci Rep 11:14279
da Silva LF, Fruett T, Zinn YL, Inda AV, do Nascimento PC, (2019) Genesis, morphology and mineralogy of Planosols developed from different parent materials in southern Brazil. Geoderma 341:46–58
Dai X, Yuan Y, Wang H (2016) Changes of anaerobic to aerobic conditions but not of crop type induced bulk soil microbial community variation in the initial conversion of paddy soils to drained soils. CATENA 147:578–585
Dancer WS, Peterson LA, Chesters G (1973) Ammonification and nitrification of N as influenced by soil pH and previous N treatments. Soil Sci Soc Am J 37:67–69
Deng H, Yu YJ, Sun JE, Zhang JB, Cai ZC, Guo GX, Zhong WH (2015) Parent materials have stronger effects than land use types on microbial biomass, activity and diversity in red soil in subtropical China. Pedobiologia 58:73–79. https://doi.org/10.1016/j.pedobi.2015.02.001
Falkengren-Grerup U (1986) Soil acidification and vegetation changes in deciduous forest in southern Sweden. Oecologia 70(3):339–347
Gruba P, Mulder J (2015) Tree species affect cation exchange capacity (CEC) and cation binding properties of organic matter in acid forest soils. Sci Total Environ 511:655–662
Gu W, Driscoll CT, Shao S, Johnson CE (2017) Aluminum is more tightly bound in soil after wollastonite treatment to a forest watershed. Forest Ecol Manag 397:57–66
Guo J, Liu X, Zhang Y, Shen J, Han W, Zhang W, Christie P, Goulding KWT, Vitousek PM, Zhang F (2010) Significant acidification in major Chinese croplands. Science 327(5968):1008–1010. https://doi.org/10.1126/science.1182570
Han Y, Yi D, Ye Y, Guo X, Liu S (2022) Response of spatiotemporal variability in soil pH and associated influencing factors to land use change in a red soil hilly region in southern China. CATENA 212:106074
Hao T, Liu X, Zhu Q, Zeng M, Chen X, Yang L, Shen J, Shi X, Zhang F, de Vries W (2022) Quantifying drivers of soil acidification in three Chinese cropping systems. Soil till Res 215:105230
Helyar KR, Porter WM (1989) Soil acidification, its measurement and the process involved. In: Robson AD (ed) Soil acidity and plant growth.Academic, Sydney pp 61–102
Hepper EN, Buschiazzo DE, Hevia GG, Urioste A, Anton L (2006) Clay mineralogy, cation exchange capacity and specific surface area of loess soils with different volcanic ash contents. Geoderma 135:216–223
Iturri LA, Buschiazzo DE (2014) Cation exchange capacity and mineralogy of loess soils with different amounts of volcanic ashes. CATENA 121:81–87
Jiang RF (1999a) Cation-exchange capacity. In: Bao SD (ed) Analysis of soil agrochemistry, 3rd edn. China Agriculture Press, Beijing pp 152–177
Jiang RF (1999b) Methods of soil nitrogen and sulfur. In: Bao SD (ed) Analysis of soil agrochemistry, 3rd edn. China Agriculture Press, Beijing pp 39–69
Jiang J, Wang Y, Yu M, Cao N, Yan J (2018) Soil organic matter is important for acid buffering and reducing aluminum leaching from acidic forest soils. Chem Geol 501:86–94
Li Q, Li A, Yu X, Dai T, Peng Y, Yuan D, Zhao B, Tao Q, Wang C, Li B, Gao X, Li Y, Wu D, Xu Q (2020) Soil acidification of the soil profile across Chengdu Plain of China from the 1980s to 2010s. Sci Total Environ 698:134320
Li Q, Li S, Xiao Y, Zhao B, Wang C, Li B, Gao X, Li Y, Bai G, Wang Y, Yuan D (2019) Soil acidification and its influencing factors in the purple hilly area of southwest China from 1981 to 2012. CATENA 175:278–285
Liu H, Liu G, Li Y, Wu X, Liu D, Dai X, Xu M, Yang F (2016) Effects of land use conversion and fertilization on CH4 and N2O fluxes from typical hilly red soil. Environ Sci Pollut R 23:20269–20280
Liu J, Wang Z, Hu F, Xu C, Ma R, Zhao S (2020) Soil organic matter and silt contents determine soil particle surface electrochemical properties across a long-term natural restoration grassland. CATENA 190:104526
Nelson DW, Sommers LE (1996) Total carbon, organic carbon, and organic matter. In: Sparks DL (ed) Methods of soil analysis. Part 3. Chemical methods, SSSA Book Series 5. ASA and SSSA, Madison pp 961–1011
Nishimura S, Yonemura S, Sawamoto T, Shirato Y, Akiyama H, Sudo S, Yagi K (2008) Effect of land use change from paddy rice cultivation to upland crop cultivation on soil carbon budget of a cropland in Japan. Agr Ecosyst Environ 125:9–20
Olsen SR, Cole CV, Watanable FS, Dean LA (1954) Estimation of available phosphorus in soils by extraction with sodium bicarbonate. USDA Circular 939:1–19
Qian Z, Sun X, Gao J, Zhuang S (2021) Effects of bamboo (Phyllostachys praecox) cultivation on soil nitrogen fractions and mineralization. Forests 12:1109
Qin H, Quan Z, Yuan H, Liu X, Zhu Y, Chen C, Guo J, Wu J, Wei W (2014) Response of ammonium-oxidizing (amoA) and nitrate-reducing (narG) Gene abundances in groundwater to land use change. Water Air Soil Poll 225:1908. https://doi.org/10.1007/s11270-014-1908-y
Rengel Z (2003) Handbook of Soil Acidity. Marcel Dekker, New York
Rutkowska B, Szulc W, Hoch M, Spychaj-Fabisiak E (2015) Forms of Al in soil and soil solution in a long-term fertilizer application experiment. Soil Use Manage 31:114–120
Sachs S, Bernhard G (2011) Influence of humic acids on the actinide migration in the environment: suitable humic acid model substances and their application in studies with uranium: a review. J Radioanal Nucl Ch 290(1):17–29
Sagliker HA, Cenkseven S, Kizildag N, Kocak B, Ozdeniz E, Ozbey BG, Bölükbas A, Kurt L (2018) Is parent material an important factor in soil carbon and nitrogen mineralization? Eur J Soil Biol 89:45–50
Shen Y, Zhang Z, Xue Y (2021) Study on the new dynamics and driving factors of soil pH in the red soil, hilly region of South China. Environ Monit Assess 193:304
Sheng R, Meng D, Wu M, Di H, Qin H, Wei W (2013) Effect of agricultural land use change on community composition of bacteria and ammonia oxidizers. J Soil Sediment 13:1246–1256
Sheng R, Qin H, O’Donnell AG, Huang S, Wu J, Wei W (2015) Bacterial succession in paddy soils derived from different parent materials. J Soil Sediment 15:982–992
Sun Y, Guo G, Shi H, Liu M, Keith A, Li H, Jones KC (2020) Decadal shifts in soil pH and organic matter differ between land uses in contrasting regions in China. Sci Total Environ 740:139904
Szymańskia W, Maciejowski W, Ostafin K, Ziaja W, Sobucki M (2019) Impact of parent material, vegetation cover, and site wetness on variability of soil properties in proglacial areas of small glaciers along the northeastern coast of Sørkappland (SE Spitsbergen). CATENA 183:104209
Tan W, Zhang R, Cao H, Huang C, Yang QK, Wang M, Koopal LK (2014) Soil inorganic carbon stock under different soil types and land uses on the Loess Plateau region of China. CATENA 121:22–30
Takahashi T, Park CY, Nakajima H, Sekiya H, Toriyama K (1999) Ferric iron transformationTransformation in soils with rotation of irrigated rice-upland crops and effect on soil tillage properties. Soil Sci Plant Nutr 45:163–173
Tian D, Niu S (2015) A global analysis of soil acidification caused by nitrogen addition. Environ. Res Lett 10(2). https://doi.org/10.1088/1748-9326/10/2/024019
Tyler G, Olsson T (2001) Plant uptake of major and minor mineral elements as influenced by soil acidity and liming. Plant Soil 230:307–321
Ulrich B (1986) Natural and anthropogenic component of soil acidification. Z Pflanzenernähr Bodenk 149:702–717
Wang C, Li X, Min Q, Wang W, Sardans J, Zeng C, Tong C, Peñuelas J (2019) Responses of greenhouse-gas emissions to land-use change from rice to jasmine production in subtropical China. Atmos Environ 201:391–401
Wang H, Dong Y, Tong X, Liu X, Shao J, Shi R, Hong Z, Xu R, Jiang J (2020) The amelioration effects of canola straw biochar on Ultisol acidity varied with the soil in which the feedstock crop was cultivated. J Soils Sediments 20:1424–1434
Wang H, Guan D, Zhang R, Chen Y, Hu Y, Xiao L (2014) Soil aggregates and organic carbon affected by the land use change from rice paddy to vegetable field. Ecol Eng 70:206–211
Wang Y, Fan J, Cao L, Liang Y (2016) Infiltration and runoff generation under various cropping patterns in the red soil region of China. Land Degrad Dev 27:83–91
Wu X, Nguyen-Sy T, Sun Z, Wantanabe T, Tawaraya K, Hu R, Cheng W (2020) Soil organic matter dynamics as affected by land use change from rice paddy to wetland. Wetlands 40:2199–2207
Xie E, Zhao Y, Li H, Shi X, Lu F, Zhang X, Peng Y (2019) Spatio-temporal changes of cropland soil pH in a rapidly industrializing region in the Yangtze River Delta of China, 1980–2015. Agr Ecosyst Environ 272:95–104
Yan XY, Akimoto H, Ohara T (2003) Estimation of nitrous oxide, nitric oxide and ammonia emissions from croplands in East, Southeast and South Asia. Glob Chang Biol 9(7):1080–1096
Yang D, Zhang M (2014) Effects of land-use conversion from paddy field to orchard farm on soil microbial genetic diversity and community structure. Eur J Soil Biol 64:30–39
Yu Z, Zhang Y, Sheng H, Zhang L, Zhou Q, Yan X (2020) Composition of clay minerals and their pedogenetic and taxonomic implications for Stagnic Anthrosols derived from different parent materials in Hunan Province, China. J Soil Sediment 20:1558–1570
Zhou XY, Xu MG, Zhou SW, Gilles C (2015) Soil acidification characteristics in southern China`s croplands under long-term fertilization. J Plant Nutr Fert 21(6):1615–1621
Zhu Q, de Vries W, Liu X, Hao T, Zeng M, Shen J, Zhang F (2018) Enhanced acidification in Chinese croplands as derived from element budgets in the period 1980–2010. Sci Total Environ 618:1497–1505
Funding
This study was funded by the National Natural Science Foundation of China (41977104, U19A2046, 42271401).
Author information
Authors and Affiliations
Corresponding author
Ethics declarations
Conflict of interest
The authors declare no competing interests.
Additional information
Responsible editor: Caixian Tang
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary Information
Below is the link to the electronic supplementary material.
Rights and permissions
Springer Nature or its licensor (e.g. a society or other partner) holds exclusive rights to this article under a publishing agreement with the author(s) or other rightsholder(s); author self-archiving of the accepted manuscript version of this article is solely governed by the terms of such publishing agreement and applicable law.
About this article
Cite this article
Cai, Z., Yang, C., Du, X. et al. Parent material and altitude influence red soil acidification after converted rice paddy to upland in a hilly region of southern China. J Soils Sediments 23, 1628–1640 (2023). https://doi.org/10.1007/s11368-023-03426-w
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11368-023-03426-w