Draft:Paddy Soils

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Paddy Soils

Paddy soils are hydrologically managed soils under conditions of intentional flooding, primarily for rice cultivation, though other wetland-adapted crops may also be grown.[1] These soils are typically found in levelled fields surrounded by low earth walls (called bunds) to hold in water.[1] Due to repeated wetting, puddling, and cultivation, paddy soils develop distinct physical and morphological characteristics.

Paddy Soil Classification

In formal classification systems, such as the World Reference Base for Soil Resources, paddy soils are commonly designated as Anthrosols—soils created or modified by long-term human activity.[1][2] A defining feature of paddy soils is a compacted layer from puddling and plowing, known as the anthraquic horizon.[2] The anthraquic horizon is characterized by a reduced matrix—soil with grey or bluish colours caused by prolonged water saturation and lack of oxygen—and oxidized root channels, which appear reddish due to oxygen entering along plant roots during drainage periods.[2] Beneath this, a second layer—called the hydragric horizon—may develop.[2] This deeper layer often has mottling, which refers to patches of contrasting colours that form as the soil repeatedly shifts between wet and dry conditions, and may accumulate iron and manganese.[2]

Rice terraces in Sapa, Vietnam
Rice paddy in Pai, Thailand

Effects of Flooding on Soil Function

The saturated conditions of paddy soils significantly influence their chemical, biological, and physical properties, distinguishing them from soils in upland or non-flooded agricultural systems.[1] The prolonged submergence of paddy soils creates anaerobic conditions—environments with little to no oxygen—that significantly alter microbial activity, nutrient cycling, and soil structure.[1] This fundamentally changes the chemistry and nutrient dynamics of the soil. For example, nitrogen may be lost to the atmosphere as gaseous N₂ and nitrous oxide, N₂O, through a process called denitrification, pH may increase due to the accumulation of carbon dioxide (CO₂), and toxic compounds like hydrogen sulfide gas (H₂S) may form.[1][3] These changes may temporarily increase the availability of certain nutrients, but could also raise the risk of plant toxicity and impaired root function.[3] As a result, flooding creates conditions that can harm crop health if not carefully managed.

Greenhouse Gas Emissions

One major consequence of anaerobic conditions in paddy soils is the promotion of methanogenic microbes that produce methane (CH₄)—a potent greenhouse gas. Flooded rice fields are a significant source of agricultural methane emissions, accounting for nearly half of all crop-related greenhouse gas emissions.[1][4] To mitigate these emissions, many farmers have adopted alternate wetting and drying (AWD)—a water-saving method that periodically drains fields while maintaining crop yields.[5] AWD has been shown to cut methane emissions by over 60% in some cases,[6] although it can increase nitrous oxide emissions under frequent wet-dry cycles or with heavy nitrogen fertilizer use.[7][5] Consequently, the net greenhouse gas emissions associated with paddy soils depend on water management, soil conditions, and nutrient inputs, highlighting the need for carefully coordinated management strategies.[5]

Managing Soil Fertility

Maintaining soil fertility in paddy fields is essential for sustaining crop yields, especially in intensively managed systems.[8] Inorganic fertilizers play a critical role in maintaining soil fertility and achieving high crop yields in paddy systems, particularly where nutrient supplies are already low.[9] However, fertilizer use in many regions is not always aligned with site-specific nutrient deficits, leading to inefficiencies and environmental concerns such as nutrient leaching and greenhouse gas emissions​.[9] Site-specific nutrient management strategies have been developed to better align fertilizer applications with local soil and crop needs​.[9] While mineral fertilizers remain essential, integrating organic amendments can improve nutrient use efficiency​.[9] For example, in southern China, the co-incorporation of rice straw and milk vetch significantly improved soil organic carbon, microbial biomass, and enzyme activities, demonstrating that organic residue management can boost soil quality and crop performance in paddy soils.[8]

Methylmercury Toxicity

Under flooded conditions, soil microbes can convert inorganic mercury into methylmercury—a highly toxic and bioavailable form that can be absorbed by rice plants.[10] Studies from mercury mining areas in Guizhou Province, China, have shown that rice grown in contaminated paddy soils can contain elevated methylmercury concentrations, with rice consumption accounting for up to 94% of the population's total dietary methylmercury intake.[11] Although the World Health Organization (WHO) identifies fish as the primary global source of methylmercury, research highlights that rice can become a major exposure pathway in contaminated inland regions.[12][10][11] This raises concerns about the toxin's neurological effects, particularly for vulnerable groups such as pregnant women and children.[12][11] Although paddy soils create conditions favourable for methylmercury production, the underlying driver is mercury pollution rather than rice cultivation. Soil management strategies such as alternate wetting and drying (AWD), careful control of organic amendments, and regular testing of soil and grain mercury levels can help reduce the risk of methylmercury accumulation while maintaining soil health and crop productivity.[10]

References

  1. ^ a b c d e f g Witt, C.; Haefele, S. M. (2005-01-01), Hillel, Daniel (ed.), "PADDY SOILS", Encyclopedia of Soils in the Environment, Oxford: Elsevier, pp. 141–150, doi:10.1016/b0-12-348530-4/00286-1, ISBN 978-0-12-348530-4, retrieved 2025-04-09{{citation}}: CS1 maint: work parameter with ISBN (link)
  2. ^ a b c d e "Classification of Soils: World Reference Base (WRB) for Soil Resources", SpringerReference, Berlin/Heidelberg: Springer-Verlag, retrieved 2025-04-15
  3. ^ a b Tsutsumi, Michio (December 1980). "Intensification of arsenic toxicity to paddy rice by hydrogen sulfide and ferrous iron: I. Induction of bronzing and iron accumulation in rice by arsenic". Soil Science and Plant Nutrition. 26 (4): 561–569. doi:10.1080/00380768.1980.10431243. ISSN 0038-0768.
  4. ^ Kritee, Kritee; Nair, Drishya; Zavala-Araiza, Daniel; Proville, Jeremy; Rudek, Joseph; Adhya, Tapan K.; Loecke, Terrance; Esteves, Tashina; Balireddygari, Shalini; Dava, Obulapathi; Ram, Karthik; S. R., Abhilash; Madasamy, Murugan; Dokka, Ramakrishna V.; Anandaraj, Daniel (2018-09-25). "High nitrous oxide fluxes from rice indicate the need to manage water for both long- and short-term climate impacts". Proceedings of the National Academy of Sciences. 115 (39): 9720–9725. doi:10.1073/pnas.1809276115. PMC 6166800. PMID 30201704.
  5. ^ a b c Win, Ei Phyu; Win, Kyaw Kyaw; Bellingrath-Kimura, Sonoko D.; Oo, Aung Zaw (2021-06-30). "Influence of rice varieties, organic manure and water management on greenhouse gas emissions from paddy rice soils". PLOS ONE. 16 (6): e0253755. doi:10.1371/journal.pone.0253755. ISSN 1932-6203. PMC 8244889. PMID 34191848.{{cite journal}}: CS1 maint: article number as page number (link)
  6. ^ Runkle, Benjamin R. K.; Suvočarev, Kosana; Reba, Michele L.; Reavis, Colby W.; Smith, S. Faye; Chiu, Yin-Lin; Fong, Bryant (2019-01-15). "Methane Emission Reductions from the Alternate Wetting and Drying of Rice Fields Detected Using the Eddy Covariance Method". Environmental Science & Technology. 53 (2): 671–681. doi:10.1021/acs.est.8b05535. ISSN 0013-936X.
  7. ^ Kritee, Kritee; Nair, Drishya; Zavala-Araiza, Daniel; Proville, Jeremy; Rudek, Joseph; Adhya, Tapan K.; Loecke, Terrance; Esteves, Tashina; Balireddygari, Shalini; Dava, Obulapathi; Ram, Karthik; S. R., Abhilash; Madasamy, Murugan; Dokka, Ramakrishna V.; Anandaraj, Daniel (2018-09-25). "High nitrous oxide fluxes from rice indicate the need to manage water for both long- and short-term climate impacts". Proceedings of the National Academy of Sciences. 115 (39): 9720–9725. doi:10.1073/pnas.1809276115. PMC 6166800. PMID 30201704.
  8. ^ a b Wan, Li; Chen, Xiaofen; Yang, Shuang; Qin, Wenjing; Zhou, Guopeng; Xia, Longlong; Kang, Yuntao; Liu, Jia (2025-01-15). "Co‐incorporation of rice straw and milk vetch ( Astragalus sinicus L.) improves soil fertility and rice yield in two typical paddy soils". Soil Use and Management. 41 (1). doi:10.1111/sum.70018. ISSN 0266-0032.
  9. ^ a b c d Dobermann, A; Witt, C; Dawe, D; Abdulrachman, S; Gines, H. C; Nagarajan, R; Satawathananont, S; Son, T. T; Tan, P. S; Wang, G. H; Chien, N. V; Thoa, V. T. K; Phung, C. V; Stalin, P; Muthukrishnan, P (2002-02-15). "Site-specific nutrient management for intensive rice cropping systems in Asia". Field Crops Research. 74 (1): 37–66. doi:10.1016/S0378-4290(01)00197-6. ISSN 0378-4290.
  10. ^ a b c Cite error: The named reference :2 was invoked but never defined (see the help page).
  11. ^ a b c Feng, Xinbin; Li, Ping; Qiu, Guangle; Wang, Shaofeng; Li, Guanghui; Shang, Lihai; Meng, Bo; Jiang, Hongmei; Bai, Weiyang; Li, Zhonggen; Fu, Xuewu (2008-01-01). "Human Exposure To Methylmercury through Rice Intake in Mercury Mining Areas, Guizhou Province, China". Environmental Science & Technology. 42 (1): 326–332. doi:10.1021/es071948x. ISSN 0013-936X.
  12. ^ a b "Mercury". www.who.int. Retrieved 2025-04-25.

[1]

  1. ^ Tang, Zhenya; Fan, Fangling; Wang, Xinyue; Shi, Xiaojun; Deng, Shiping; Wang, Dingyong (2018-04-15). "Mercury in rice (Oryza sativa L.) and rice-paddy soils under long-term fertilizer and organic amendment". Ecotoxicology and Environmental Safety. 150: 116–122. doi:10.1016/j.ecoenv.2017.12.021. ISSN 0147-6513.

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