Abstract
The study of soil organic carbon and total nitrogen in relation to texture, landforms, and soil pH in riverine rice growing wetlands is very important for both agrarian economy and land use related issues in Majuli island of Upper Brahmaputra valley, Assam. Thus, thirteen soil series classified under the subgroups of Inceptisols and Entisols under different alluvial landforms in Majuli river island were selected to investigate the distribution of organic carbon (OC) and Total nitrogen (Total N) in pedological point of view. Our results showed an enrichment in OC and Total N on superficial Ap horizons (silt loam to silty clay loam) to the detriment of the deep sandy C horizons. Nevertheless, the irregular distribution of OC and total N contents with depth in stratified soils of the Island showed differential rates of leaching and its subsequent accumulations due to depositional episodes during seasonal floods in the region. These soils are slightly acid to neutral with mean densities of 30.49 Mg/ha of OC in Majuli series (P5) to 196.78 Mg/ha in Dakshinpat series (P7) with significant variations between the horizons (F = 5.904). The data further shows that silty clay texture have mean SOC of 25.24 ± 10.48 Mg/ha but low with value of 6.26 ± 2.81 Mg/ha for sand texture whereas total N stocks were high for sand (mean 4.71 ± 3.45 Mg/ha). The stratification of Total N and its stocks are highly variable having positive relation with cation exchange capacity (R2 = 0.57**) and Clay (R2 = 0.35*). The mean C/N ratio of soils was 8.3 ± 10.33 but highly variable (Cv of 124%). The regional study shows that geographically explicit information on soil carbon and total N pools must be combined with seasonal flooding history and depositional episodes for better rice management factors in the island.
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References
Adhikari K, Phillip R, Owens, Libohova Z et al (2019) Assessing soil organic carbon stock of Wisconsin, USA and its fate underfuture land use and climate change. Sci Total Environ 667:833–845
Ahmed T, Chetia SK, Chowdhury R, Ali S (2011) Status paper on Rice in Assam. RKMP:1–49
Anshori A, Pramono A, Mujiyo (2020) The stratification of organic carbon and nitrogen in top soils as affected by the Management of Organic and Conventional Rice Cultivation. Caraka Tani J Sustain Agric 35:126–134
Baldock JA, Skjemstad JO (2000) Role of the soil matrix and minerals in protecting natural organic materials against biological attack. Org Geochem 31:697–710
Barah BC, Pandey S (2005) Rainfed Rice production Systems in Eastern India: an on-farm diagnosis and policy alternatives—National Symposium—a report. Ind J Agric Econ 60:110–136
Barrios E (2007) Soil biota, ecosystem services and land productivity. Ecol. Econ. Biodiversity synthesis. In: World resources institute. D.C, Washington
Barthakur M (2004) Weather and climate. The Brahmaputra basin water resources. In: Singh VP et al (eds) The Brahmaputra Basin water resource, vol 47. Kluwer Academic Publishers, Dordrecht, pp 17–23
Batjes NH, Dijkshoonn JA (1999) Carbon and nitrogen stocks in the soils of the Amazon region. Geoderma 89:273–286
Bhaskar BP (2019) Evaluating potentials of riverine floodplain soils for management of Rice(Oryza sativa L) in Majuli river island, Assam. Ind Int J Ecol Environ Sci 45:145–156
Bhaskar BP, Sarkar D (2013) Capability and quality assessment of rice growing hydric soils in Majuli river island, Assam, India. J Agric Environ Int Development 107:13–32
Bhaskar BP, Baruah U, Vadivelu S, Butte PS (2005) Characterization in the bile environs of Brahmaputra valley in Jorhat district, Assam for land use interpretation. J Indian Soc Soil Sci 53:3–10
Bhaskar BP, Baruah U, Vadivelu S, Sarkar D (2008) Characterization of depositional soils in dynamic fluvial landforms of Majuli island for land use related issues. Agropedology 18:33–43
Bhaskar BP, Baruah U, Vadivelu S et al (2009) Pedogenesis in some subaqueous soils of Brahmaputra Valley, Assam, India. J Indian Soc Soil Sci 57:237–244
Bhaskar BP, Baruah U, etal VS (2010) Remote sensing and GIS in the management of wetland resources of Majuli Island, Assam, India. Trop Ecol 51:31–40
Blake GR, Harte KH (1986) Bulk density, in methods of SoiAnalysis part 1. Physical and mineralogical methods-AgronomyMonograph. In: Klute A (ed) , 2nd edn. American Society of Agronomy-Soil Science Society of America, Madison, WI, pp 363–375
Bremner JM, Mulvaney CS (1982) “Nitrogen—total—1,” in methods of soil analysis. Part 2. Chemical and microbiological properties. American Society of Agronomy, Soil Science Society of America, Madison, WI, pp 595–624
Brinkman R (1970) Ferrolysis. A hydromorphic soil forming process. Geoderma 3:199–206
Chakravarthy SK, Sinha H, Mathur BS (1984) Morphological and Physico-chemical characteristics of some alluvial soils of Assam. J Ind Soc Soil Sci 32:128–136
Chayes F (1971) Ratio correlation: a manual for students of petrology and geochemistry, vol 99. University of Chicago Press
Costanza R, d’Arge R, de Groot R et al (1997) The value of the world’s ecosystem services and natural capital. Nature 387:253–260
Dahal H, Bajracharya RM (2013) Prospects of soil organic carbon sequestration: implications for Nepal’s mountain agriculture. J Forest Livelihood 9:45–56
FAO (2005) Fertilizer use by crop in India. First version, published by FAO. Rome
Gee G, Bauder JW (1986) Particle size analysis in methods of soil analysis, Part-1. In: Klute A (ed) Agronomy 9. American Society of Agronomy, Madison, WI, pp 383–411
Government of India (GOI) (2016) Ministry of agriculture agricultural statistics at a glance 2016: 83–84. http://eands.dacnet.nic.in/PDF/Glance-2016.pdf
de Groot R, Brander L, van der Ploeg S et al (2012) Global estimates of the value of ecosystems and their services in monetary units. Ecosyst Serv 1:50–61
Hassink J (1994) Effects of soil texture and grassland management on soil organic C and N and rates of C and N mineralization. Soil Biol Biochem 26:1221–1231. https://doi.org/10.1016/0038-0717(94)90147
Herrera R, Jordan CF, Klinge H, Medina E (1978) Amazon ecosystems: their structure and functioning with particular emphasis on nutrients. Interciencia 3:223–232
Hong S, Gan P, Chen A (2019) Environmental controls on soil pH in planted forest and its response to nitrogen deposition. Environ Res 172:159–165. https://doi.org/10.1016/j.envres.2019.02.020
Jackson ML (1973) Soil chemical analysis. Prentice Hall of India, New Delhi
Jackson ML (1979) Soil chemical analysis. Advanced course. 2nd edn. Published by the author, Madison, WI
Karmakar KM (1985) Genesis and classification of soils in the northern Brahmaputra valley of Assam. PhD. Thesis. IARI. New Delhi
Kawaguchi K, Kyuma K (1969) Lowland rice soils in Thailand centre for southeast Asian studies, Kyoto University, Kyoto
Krishna VV, Byju NG, Tamizheniyan S (2003) Integrated pest management in Indian agriculture: a developing economic perspective. In: Radcliff EB, Hutchson WD (eds) IPM World Text book, St Paul, MN. https://ipmworld.umn.edu/krishna-indian-ag
Kyuma K, Kawaguchi K (1977) Paddy soils in tropical Asia, their maerial, nature and fertility.University Press of Hawaii. Honolulu 1977:258
Liu L, Greaver TL (2010) A global perspective on belowground carbon dynamics under nitrogen enrichment. Ecol Lett 13:819–828
Lloyd J, Bloomfield K, Domingues TF, Farquhar GD (2013) Photosynthetically relevant foliar traits correlating better on a mass vs. an area basis of ecophysiological relevance or just a case of mathematical imperatives and statistical quicksand? New Phytol 199:311–321
Ma S, Swinton SM, Lupi F (2012) Farmer’s willingness to participate in payment for-environmental-services programmes. J Agric Econ 63:604–626
MEA (Millennium Ecosystem Assessment) (2005) Ecosystems and human wellbeing:biodiversity synthesis. World Resources Institute, Washington, DC
Mi N, Wang SQ, Liu JY, Yu G, Zhang W, Jobbagy E (2008) Soil inorganic carbon storage in China. Global Change Biology 14(10):2380–2387
Mitsuchi M (1974) Pedogenic characteristics of paddy soils and their significance in soil classification. Bull Nat Inst Agric Sci B 1974:29–115. (in Japanese)
Mokma DI, Sprecher SW (1994) Water table depths and colour patterns in Spodosols of two hydrosequences in northern Michigan, USA. Catena 22:275–286
Nayak AK, Md Shahid AD, Nayak AD (2019) Assessment of the C/N ratio as an indicator of the decomposability of organic matter in forest soils. Ecol Indic 49:104–109
Olk DC, Cassman KG, Randall EW (1996) Changes in chemical properties of organic matter with intensified rice cropping in tropical lowland soil. Eur J Soil Sci 47:293–303
Ponnamperuma FN (1972) The chemistry of submerged soils. Adv Agron 24:29–90
Quesada CA, Paz C, Oblitas Mendoza E, Phillips OL, Saiz G, Lloyd J (2020) Variations in soil chemical and physical properties explain basin-wide Amazon forest soil carbon concentrations. Soil 6:53–88. https://doi.org/10.5194/soil-6-53-2020
Raju DSR, Reddy VR, Reddy PP, Reddy MS (2005) Water use efficiency: a study ofsystem of rice intensification (SRI) adoption in Andhra Pradesh. Ind J Agric Econ 60:458–472
Rousk J, Baath E, Brookes PC, Lauber CL, Lozupone C, Caporaso JG, Knight R, Fierer N (2010) Soil bacterial and fungal communities across pH gradients in arable soils. The ISME J 4:1340–1351
Sahrawat KL, Bhattacharyya T, Wani SP (2005) Long-term lowland rice and arable cropping effects on carbon and nitrogen status of some semi-arid tropical soils. Curr Sci 89:2159–2162
Sarma JN, Phukan MK (2004) Origin and some geomorphological changes in Majuli island of the Brahmaputra river in Assam, India. Geomorphology 60:1–19
Schoeneberger PJ, Wysocki DA, Benham EC, Soil Survey Staff (2012) Field book for describing and sampling soils. Version 3.0., Natural Resources Conservation Service, National Soil Survey Center, Lincoln, NE
Singaravel R, Balasundaram CS, Johnson K (1996) Physico-chemical characteristics and nutrient status of coastal saline soils of Tamil Nadu. J Ind Soc Coastal Agric Res 14:59–61
Smeck NE, Ritchie A, Wilding LP, Drees LR (1981) Clay accumulation in sola of poorly drained soils of Western Ohio. Soil Sci Soc Am J 45:95–102
Stallman HR (2011) Ecosystem services in agriculture: determining suitability for provision by collective management. Ecol Econ 71:131–139
Vijayakumar M, Lakshmi GV, Madhuvani P (2013) Appraisal of soil fertility status in salt-affected soils of Ongole division, Prakasam district, Andhra Pradesh. J Indian Soc Soil Sci 61:333–340
Walkley AJ, Black IA (1934) An examination of theDegtjareff method for determining soil organic matter, and a proposed modification of the chromic acidtitration method. Soil Sci 37:29–38
Wossink A, Swinton SM (2007) Jointness in production and farmers’ willingness to supply non-marketed ecosystem services. Ecol Econ 64:297–304
Yang YH, Fang JY, Guo DL, Ji C (2010) Vertical patterns of soil carbon, nitrogen and carbon: nitrogen stoichiometry in Tibetan grasslands. Biogeosci Discuss 7:1–24
Zhang X (1985, 1974) Ion adsorption, physical chemistry of paddy soils. Science Press, Springer Verlag, Beijing/Berlin
Zhao X, Xue JF, Zhang XQ (2015) Stratification and storage of soil organic carbon and nitrogen as affected by tillage practices in the North China plain. PLoS One 10(6):e0128873. https://doi.org/10.1371/journal.pone.0128873
Zhou W, Han G, Liu M, Li X (2019) Effects of soil pH and texture on soil carbon and nitrogen in soil profiles under different land uses in Mun River basin. Northeast Thailand Peer J 7:e7880. https://doi.org/10.7717/peerj.7880
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Bhaskar, B.P., Ramamurthy, V., Maske, S. (2021). Pedological Assessment of Soil Organic Carbon and Total Nitrogen Contents in Wetland Rice Ecosystems of Majuli River Island, Assam, India. In: Cruz, C., Vishwakarma, K., Choudhary, D.K., Varma, A. (eds) Soil Nitrogen Ecology. Soil Biology, vol 62. Springer, Cham. https://doi.org/10.1007/978-3-030-71206-8_4
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