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Interaction between nitrogen fertilizer and biochar fertilization on crop yield and soil chemical quality in a temperate region

Published online by Cambridge University Press:  20 April 2021

Wenliang Wei*
Affiliation:
College of Resources and Environment, Qingdao Agricultural University, Qingdao266109, China Centre for Resources, Environment and Food Security, College of Resources and Environmental Sciences, China Agricultural University, Beijing100193, China
Shutang Liu
Affiliation:
College of Resources and Environment, Qingdao Agricultural University, Qingdao266109, China
Dejie Cui
Affiliation:
College of Resources and Environment, Qingdao Agricultural University, Qingdao266109, China
Xiaodong Ding
Affiliation:
College of Resources and Environment, Qingdao Agricultural University, Qingdao266109, China
*
Author for correspondence: Wenliang Wei, E-mail: [email protected]

Abstract

The North China Plain suffers excessive application of nitrogen (N) and soil degradation. Recently, biochar has been promoted as an agricultural soil amendment to ameliorate soil quality, increase crop yield and mitigate greenhouse gas emissions. However, most proofs on the positive effects of biochar addition have been based on small plots or short-term field studies located in tropical or subtropical regions with defective soils. A long-term field experiment was designed with five N levels and two biochar rates to observe the changes in crop (winter wheat and summer maize) growth and soil chemical quality. Notably, crop yield was strongly dependent upon N application, with both wheat and maize yields increasing with N application. Biochar addition increased crop yield but not significantly, although the increase in grain yield was 0.96 t/ha in a rotation. Correlation analysis revealed that the optimal root-layer soil mineral N (Nmin) for crop production was around N120, especially with biochar addition. The effect of fertilization on soil chemical quality was mainly reflected in the increase in soil organic carbon (SOC), and the highest value was obtained at N60 whether or not biochar was applied. Overall, biochar addition did not appear to promote wheat and maize growth or increase the yield on calcareous alluvial soils in temperate regions, but significantly enhanced SOC content, especially at N60, which may play an important role in sustainable agricultural production.

Type
Crops and Soils Research Paper
Copyright
Copyright © The Author(s), 2021. Published by Cambridge University Press

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References

Agegnehu, G, Bass, AM, Nelson, PN and Bird, MI (2016) Benefits of biochar, compost and biochar – compost for soil quality, maize yield and greenhouse gas emissions in a tropical agricultural soil. Science of the Total Environment 543, 295306.CrossRefGoogle Scholar
Asai, H, Samson, BK, Stephan, HM, Songyikhangsuthor, K, Homma, K, Kiyono, Y, Inoue, Y, Shiraiwa, T and Horie, T (2009) Biochar amendment techniques for upland rice production in Northern Laos: 1. Soil physical properties, leaf SPAD and grain yield. Field Crops Research 111, 8184.CrossRefGoogle Scholar
Atkinson, CJ, Fitzgerald, JD and Hipps, NA (2010) Potential mechanisms for achieving agricultural benefits from biochar application to temperate soils: a review. Plant and Soil 337, 118.CrossRefGoogle Scholar
Biederman, LA and Harpole, WS (2013) Biochar and its effects on plant productivity and nutrient cycling: a meta-analysis. GCB Bioenergy 5, 202214.CrossRefGoogle Scholar
Borges, BMMN, De Oliveira Bordonal, R, Silveira, ML and Coutinho, ELM (2019) Short-term impacts of high levels of nitrogen fertilization on soil carbon dynamics in a tropical pasture. Catena 174, 413416.CrossRefGoogle Scholar
Bowsher, AW, Evans, S, Tiemann, LK and Friesen, ML (2018) Effects of soil nitrogen availability on rhizodeposition in plants: a review. Plant and soil 423, 5985.CrossRefGoogle Scholar
Bruun, EW, Ambus, P, Egsgaard, H and Hauggaard-Nielsen, H (2012) Effects of slow and fast pyrolysis biochar on soil C and N turnover dynamics. Soil Biology and Biochemistry 46, 7379.CrossRefGoogle Scholar
Chen, HQ, Hou, RX, Gong, YS, Li, HW, Fan, MS and Kuzyakov, Y (2009) Effects of 11 years of conservation tillage on soil organic matter fractions in wheat monoculture in Loess Plateau of China. Soil and Tillage Research 106, 8594.CrossRefGoogle Scholar
Chen, SY, Zhang, XY, Shao, LW, Sun, HY, Niu, JF and Liu, XW (2020) Effects of straw and manure management on soil and crop performance in North China Plain. Catena 187, 104359.CrossRefGoogle Scholar
Cui, ZL, Yue, SC, Wang, GL, Meng, QF, Wu, L, Yang, ZP, Zhang, Q, Li, SQ, Zhang, FS and Chen, XP (2013) Closing the yield gap could reduce projected greenhouse gas emissions: a case study of maize production in China. Global Change Biology 19, 24672477.CrossRefGoogle ScholarPubMed
Cui, ZL, Zhang, HY, Chen, XP, Zhang, CC, Ma, WQ, Huang, CD, Zhang, WF, Mi, GH, Miao, YX, Li, XL, Gao, Q, Yang, JC, Wang, ZH, Ye, YL, Guo, SW, Lu, JW, Huang, JL, Lv, SH, Sun, YX, Liu, YY, Peng, XL, Ren, J, Li, SQ, Deng, XP, Shi, XJ, Zhang, Q, Yang, ZP, Tang, L, Wei, CZ, Jia, LL, Zhang, JW, He, MR, Tong, YN, Tang, QY, Zhong, XH, Liu, ZH, Cao, N, Kou, CL, Ying, H, Yin, YL, Jiao, XQ, Zhang, QS, Fan, MS, Jiang, RF, Zhang, FS and Dou, ZX (2018) Pursuing sustainable productivity with millions of smallholder farmers. Nature 555, 363366.CrossRefGoogle ScholarPubMed
Dendooven, L, Alcántara-Hernández, RJ, Valenzuela-Encinas, C, Luna-Guido, M, Perez-Guevara, F and Marsch, R (2010) Dynamics of carbon and nitrogen in an extreme alkaline saline soil: a review. Soil Biology and Biochemistry 42, 865877.CrossRefGoogle Scholar
Foster, EJ, Hansen, N, Wallenstein, M and Cotrufo, MF (2016) Biochar and manure amendments impact soil nutrients and microbial enzymatic activities in a semi-arid irrigated maize cropping system. Agriculture, Ecosystems and Environment 233, 404414.CrossRefGoogle Scholar
Glaser, B, Lehmann, J and Zech, W (2002) Ameliorating physical and chemical properties of highly weathered soils in the tropics with charcoal: a review. Biology and Fertility of Soils 35, 219230.CrossRefGoogle Scholar
Guo, JH, Liu, XJ, Zhang, Y, Shen, JL, Han, WX, Zhang, WF, Christie, P, Goulding, KWT, Vitousek, PM and Zhang, FS (2010) Significant acidification in major Chinese croplands. Science (New York, N.Y.) 327, 10081010.CrossRefGoogle ScholarPubMed
Haider, G, Steffens, D, Moser, G, Müller, C and Kammann, CI (2017) Biochar reduced nitrate leaching and improved soil moisture content without yield improvements in a four-year field study. Agriculture, Ecosystems and Environment 237, 8094.CrossRefGoogle Scholar
Hao, TX, Zhu, QC, Zeng, MF, Shen, JB, Shi, XJ, Liu, XJ, Zhang, FS and de Vires, W (2019) Quantification of the contribution of nitrogen fertilization and crop harvesting to soil acidification in a wheat-maize double cropping system. Plant and Soil 434, 167184.CrossRefGoogle Scholar
He, YH, Zhou, XH, Jiang, LL, Li, M, Du, ZG, Zhou, GY, Shao, JJ, Wang, XH, Xu, ZH, Bai, SH, Wallace, H and Xu, CY (2017) Effects of biochar application on soil greenhouse gas fluxes: a meta-analysis. GCB Bioenergy 9, 743755.CrossRefGoogle Scholar
Jeffery, S, Verheijen, FGA, Van der Velde, M and Bastos, AC (2011) A quantitative review of the effects of biochar application to soils on crop productivity using meta-analysis. Agriculture, Ecosystems and Environment 144, 175187.CrossRefGoogle Scholar
Jeffery, S, Abalos, D, Prodana, M, Bastos, AC, Groenigen, JWV, Hungate, BA and Verheijen, F (2017) Biochar boosts tropical but not temperate crop yield. Environmental Research Letters 12, 053001.CrossRefGoogle Scholar
Jin, ZW, Chen, C, Chen, XM, Hopkins, I, Zhang, XL, Han, ZQ, Jiang, F and Billy, G (2019) The crucial factors of soil fertility and rapeseed yield: a five year field trial with biochar addition in upland red soil, China. Science of the Total Environment 649, 14671480.CrossRefGoogle Scholar
Kanthle, AK, Lenka, NK and Tedia, A (2018) Land use and biochar effect on nitrate leaching in a Typic Haplustert of central India. Catena 167, 422428.CrossRefGoogle Scholar
Laird, DA, Fleming, P, Davis, DD, Horton, R, Wang, B and Karlen, DL (2010) Impact of biochar amendments on the quality of a typical Midwestern agricultural soil. Geoderma 158, 443449.CrossRefGoogle Scholar
Lehmann, J and Joseph, S (2015) Biochar for Environmental Management: Science and Technology and Implementation. New York: Routledge.CrossRefGoogle Scholar
Lehmann, J, Gaunt, J and Rondon, M (2006) Biochar sequestration in terrestrial ecosystems: a review. Mitigation and Adaptation Strategies for Global Change 11, 395419.CrossRefGoogle Scholar
Lu, DJ, Lu, FF, Yan, P, Cui, ZL and Chen, XP (2014) Elucidating population establishment associated with N management and cultivars for wheat production in China. Field Crops Research 163, 8189.CrossRefGoogle Scholar
Lu, DJ, Yue, SC, Lu, FF, Cui, ZL, Liu, ZH, Zou, CQ and Chen, XP (2016) Integrated crop-N system management to establish high wheat yield population. Field Crops Research 191, 6674.CrossRefGoogle Scholar
Meng, QF, Sun, QP, Chen, XP, Cui, ZL, Yue, SC, Zhang, FS and Römheld, V (2012) Alternative cropping systems for sustainable water and nitrogen use in the North China Plain. Agriculture, Ecosystems and Environment 146, 93102.CrossRefGoogle Scholar
Norse, D and Ju, XT (2015) Environmental costs of China's food security. Agriculture, Ecosystems and Environment 209, 514.CrossRefGoogle Scholar
Obia, A, Mulder, J, Martinsen, V, Cornelissen, G and Børresen, T (2016) In situ effects of biochar on aggregation, water retention and porosity in light-textured tropical soils. Soil and Tillage Research 155, 3544.CrossRefGoogle Scholar
Qi, DL, Hu, TT, Song, X and Zhang, ML (2019) Effect of nitrogen supply method on root growth and grain yield of maize under alternate partial root-zone irrigation. Scientific Reports 9, 110.CrossRefGoogle ScholarPubMed
Reis, S, Bekunda Mateete, A, Howard, C, Karanja, N, Winiwarter, W, Yan, XY, Bleeker, A and Sutton, MA (2016) Synthesis and review: tackling the nitrogen management challenge: from global to local scales. Environmental Research Letters 11, 120205.CrossRefGoogle Scholar
Shen, JB, Li, CJ, Mi, GH, Li, L, Yuan, LX, Jiang, RF and Zhang, FS (2013) Maximizing root/rhizosphere efficiency to improve crop productivity and nutrient use efficiency in intensive agriculture of China. Journal of Experimental Botany 64, 11811192.CrossRefGoogle ScholarPubMed
Shi, W, Ju, YY, Bian, RJ, Li, LQ, Joseph, S, Mitchell, DRG, Munroe, P, Taherymoosavi, S and Pan, GX (2020) Biochar bound urea boosts plant growth and reduces nitrogen leaching. Science of the Total Environment 701, 134424.CrossRefGoogle ScholarPubMed
Sreenivasulu, N and Schnurbusch, T (2012) A genetic playground for enhancing grain number in cereals. Trends in Plant Science 17, 91101.CrossRefGoogle ScholarPubMed
Sun, HJ, Lu, HY, Chu, L, Shao, HB and Shi, WM (2017) Biochar applied with appropriate rates can reduce N leaching, keep N retention and not increase NH3 volatilization in a coastal saline soil. Science of the Total Environment 575, 820825.CrossRefGoogle Scholar
Tammeorg, P, Simojoki, A, Mäkelä, P, Stoddard, FL, Alakukku, L and Helenius, J (2014) Biochar application to a fertile sandy clay loam in boreal conditions: effects on soil properties and yield formation of wheat, turnip rape and faba bean. Plant and Soil 374, 89107.CrossRefGoogle Scholar
Thomazini, A, Spokas, K, Hall, K, Ippolito, J, Lentz, R and Novak, J (2015) GHG impacts of biochar: predictability for the same biochar. Agriculture, Ecosystems and Environment 207, 183191.CrossRefGoogle Scholar
Tian, BJ, Zhu, JC, Nie, YS, Xu, CL, Meng, QF and Wang, P (2019) Mitigating heat and chilling stress by adjusting the sowing date of maize in the North China Plain. Journal of Agronomy and Crop Science 205, 7787.CrossRefGoogle Scholar
Van Zwieten, L, Kimber, S, Morris, S, Chan, KY, Downie, A, Rust, J, Joseph, S and Cowie, A (2010) Effects of biochar from slow pyrolysis of papermill waste on agronomic performance and soil fertility. Plant and Soil 327, 235246.CrossRefGoogle Scholar
Warnock, DD, Lehmann, J, Kuyper, TW and Rillig, MC (2007) Mycorrhizal responses to biochar in soil-concepts and mechanisms. Plant and Soil 300, 920.CrossRefGoogle Scholar
Wei, WL, Yang, HQ, Fan, MS, Chen, HQ, Guo, DY, Cao, J and Kuzyakov, Y (2020) Biochar effects on crop yields and nitrogen loss depending on fertilization. Science of the Total Environment 702, 134423.CrossRefGoogle ScholarPubMed
Xiao, ML, Zang, HD, Ge, TD, Chen, AL, Zhu, ZK, Zhou, P, Atere, CT, Wu, JS, Su, YR and Kuzyakov, Y (2019) Effect of nitrogen fertilizer on rice photosynthate allocation and carbon input in paddy soil. European Journal of Soil Science 70, 786795.Google Scholar
Xu, ZZ, Yu, ZW and Zhao, JY (2013) Theory and application for the promotion of wheat production in China: past, present and future. Journal of the Science of Food and Agriculture 93, 23392350.CrossRefGoogle ScholarPubMed
Yan, P, Yue, SC, Qiu, ML, Chen, XP, Cui, ZL and Chen, FJ (2014) Using maize hybrids and in-season nitrogen management to improve grain yield and grain nitrogen concentrations. Field Crops Research 166, 3845.CrossRefGoogle Scholar
Ye, YL, Wang, GL, Huang, YF, Zhu, YJ, Meng, QF, Chen, XP, Zhang, FS and Cui, ZL (2011) Understanding physiological processes associated with yield-trait relationships in modern wheat varieties. Field Crops Research 124, 316322.CrossRefGoogle Scholar
Yuan, JH, Xu, RK, Wang, N and Li, JY (2011) Amendment of acid soils with crop residues and biochars. Pedosphere 21, 302308.CrossRefGoogle Scholar
Zang, HD, Blagodatskaya, E, Wang, JY, Xu, XL and Kuzyakov, Y (2017) Nitrogen fertilization increases rhizodeposits incorporation into microbial biomass and reduces soil organic matter losses. Biology and Fertility of Soils 53, 419429.CrossRefGoogle Scholar
Zhang, DX, Yan, M, Niu, YR, Liu, XY, Van Zwieten, L, Chen, D, Bian, RJ, Cheng, K, Li, LQ, Joseph, S, Zheng, JW, Zhang, XH, Zheng, JF, Crowley, D, Filley, TR and Pan, GX (2016a) Is current biochar research addressing global soil constraints for sustainable agriculture? Agriculture, Ecosystems and Environment 226, 2532.CrossRefGoogle Scholar
Zhang, WF, Cao, GX, Li, XL, Zhang, HY, Wang, C, Liu, QQ, Chen, XP, Cui, ZL, Shen, JB, Jiang, RF, Mi, GH, Miao, YX, Zhang, FS and Dou, ZX (2016b) Closing yield gaps in China by empowering smallholder farmers. Nature 537, 671674.CrossRefGoogle Scholar
Zhu, QH, Peng, XH, Huang, TQ, Xie, ZB and Holden, NM (2014) Effect of biochar addition on maize growth and nitrogen use efficiency in acidic red soils. Pedosphere 24, 699708.CrossRefGoogle Scholar
Zhu, QC, De Vries, W, Liu, XJ, Hao, TX, Zeng, MF, Shen, JB and Zhang, FS (2018) Enhanced acidification in Chinese croplands as derived from element budgets in the period 1980–2010. Science of the Total Environment 618, 14971505.CrossRefGoogle ScholarPubMed
Zingore, S, Murwira, HK, Delve, RJ and Giller, KE (2007) Soil type, management history and current resource allocation: three dimensions regulating variability in crop productivity on African smallholder farms. Field Crops Research 101, 296305.CrossRefGoogle Scholar
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