Interaction between biochar particle size and soil salinity levels on soil properties and tomato yield

Zhuqing Wu , Yaqiong Fan , Zhengquan Zhou , Xinmei Hao , Shaozhong Kang

Biochar ›› 2025, Vol. 7 ›› Issue (1) : 30

PDF
Biochar ›› 2025, Vol. 7 ›› Issue (1) : 30 DOI: 10.1007/s42773-024-00417-z
Original Research

Interaction between biochar particle size and soil salinity levels on soil properties and tomato yield

Author information +
History +
PDF

Abstract

The enhancement of saline soil yield potential by biochar was well-documented, but the changes brought by biochar particle size on soil properties and crop performance are not well understood. To investigate the changes in soil properties and tomato yield due to biochar particle size under varying salt stress, we conducted a pot experiment in China Northwest’s solar greenhouse. A total of nine treatments were applied, with three different salt amounts of [S0 (no salt), S1 (0.3% dry weight), and S2 (0.6% dry weight)], and three biochar treatments of B0, B1, and B2 (0, 0.5% of large particles and 0.5% of small particles). Adding biochar did not significantly affect the measured soil chemical properties, except for pH, total nitrogen (TN), and Ca2+. Specifically, the addition of biochar significantly increased soil pH and TN, while reduced soil Ca2⁺ content likely due to biochar selective adsorption of Ca2⁺. Biochar particle size had opposite effects on tomato yield under varying salt stress levels. Compared to S0, the yield under B1 was 19.1% and 36.5% higher, whereas under B2, the yield was 33.1% and 44.2% lower for S1 and S2, respectively. Under no salt stress, small-size biochar increased yield by 51.0% compared to B0, largely due to the improved soil water and nutrient status. These results are of great value for developing better strategies for adding biochar with appropriate properties into saline soils to achieve greater productivity gains.

Highlights

Biochar addition significantly reduced soil Ca2+ by 16.7–37.9%, while there was no significant difference in the other cations.

Large-size biochar alleviated salt stress and improved tomato yield by promoting salt leaching and enhancing soil nutrients.

Small particle size biochar exacerbated salinity stress and reduced tomato yield under higher salinity treatments.

Small particle size biochar boosted tomato yield in soils without salinity stress.

Graphical Abstract

Cite this article

Download citation ▾
Zhuqing Wu, Yaqiong Fan, Zhengquan Zhou, Xinmei Hao, Shaozhong Kang. Interaction between biochar particle size and soil salinity levels on soil properties and tomato yield. Biochar, 2025, 7(1): 30 DOI:10.1007/s42773-024-00417-z

登录浏览全文

4963

注册一个新账户 忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Agbna GHD, Dongli S, Zhipeng L, Elshaikh NA, Guangcheng S, Timm LC. Effects of deficit irrigation and biochar addition on the growth, yield, and quality of tomato. Sci Hortic-Amsterdam, 2017, 222 90-101.

[2]

Ahmad M, Rajapaksha AU, Lim JE, Zhang M, Bolan N, Mohan D, Vithanage M, Lee SS, Ok YS. Biochar as a sorbent for contaminant management in soil and water: a review. Chemosphere, 2014, 99 19-33.

[3]

Akhtar SS, Andersen MN, Liu F. Biochar mitigates salinity stress in potato. J Agron Crop Sci, 2015, 201 368-378.

[4]

Ali A, Ahmad W, Zeeshan M, Khan F, Billah MM. Biochar and biofertilizers residual effect on fertility status of soil two crop seasons after their application. Sarhad J Agric, 2019, 35(3): 727-733.

[5]

An X, Liu Q, Pan F, Yao Y, Luo X, Chen C, Liu T, Zou L, Wang W, Wang J, Liu X. Research advances in the impacts of biochar on the physicochemical properties and microbial communities of saline soils. Sustainability Basel, 2023, 15(19): 14439.

[6]

Beyzi E, Güneş A, Arslan M, Şatana A. Effects of foliar boron treatments on yield and yield components of fenugreek (Trigonella foenum graecum L.): detection by PCA analysis. Commun Soil Sci Plan, 2019, 50(16): 2023-2032.

[7]

Cha JS, Park SH, Jung S, Ryu C, Jeon J, Shin M, Park Y. Production and utilization of biochar: a review. J Ind Eng Chem, 2016, 40 1-15.

[8]

Chen H, Peng Y, Tang L, Min F, Nazhafati M, Li C, Ge J, Wang H, Li J. Synergetic enhancement of Pb2+ and Zn2+ adsorption onto size-selective sludge biochar portions in multiple ion solution systems. ACS Omega, 2022, 7(1): 496-503.

[9]

Chen JL, Kang SZ, Du TS, Qiu R, Guo P, Chen R. Quantitative response of greenhouse tomato yield and quality to water deficit at different growth stages. Agr Water Manage, 2013, 129 152-162.

[10]

Chen X, Li L, Li X, Kang J, Xiang X, Shi H, Ren X. Effect of biochar on soil-water characteristics of soils: a pore-scale study. Water-Sui, 2023, 15(10): 1909.

[11]

Chen Y, Wang L, Tong L, Hao X, Wu X, Ding R, Kang S, Li S. Effects of biochar addition and deficit irrigation with brackish water on yield-scaled N2O emissions under drip irrigation with mulching. Agr Water Manage, 2023, 277. 108129
[12]

de Jesus DS, Glaser B, Pellegrino Cerri C. Effect of biochar particle size on physical, hydrological and chemical properties of loamy and sandy tropical soils. Agronomy, 2019, 9(4): 165.

[13]

Dos Santos WM, Gonzaga MIS, Da Silva AJ, de Almeida AQ. Improved water and ions dynamics in a clayey soil amended with different types of agro-industrial waste biochar. Soil Tillage Res, 2022, 223. 105482
[14]

Du B, Shukla MK, Ding R, Yang X, Du T. Biofertilization with photosynthetic bacteria as a new strategy for mitigating photosynthetic acclimation to elevated CO2 on cherry tomato. Environ Exp Bot, 2022, 194. 104758
[15]

Duan M, Liu G, Zhou B, Chen X, Wang Q, Zhu H, Li Z. Effects of modified biochar on water and salt distribution and water-stable macro-aggregates in saline-alkaline soil. J Soil Sediment, 2021, 21(6): 2192-2202.

[16]

Edeh IG, Mašek O. The role of biochar particle size and hydrophobicity in improving soil hydraulic properties. Eur J Soil Sci, 2022, 73(1. c13138
[17]

Ge S, Wang S, Mai W, Zhang K, Tanveer M, Wang L, Tian C. Characteristics and acidic soil amelioration effects of biochar derived from a typical halophyte Salicornia europaea L. (common glasswort). Environ Sci Pollut R, 2023, 30(24): 66113-66124.

[18]

Głąb T, Palmowska J, Zaleski T, Gondek K. Effect of biochar application on soil hydrological properties and physical quality of sandy soil. Geoderma, 2016, 281 11-20.

[19]

Guo M, Wang XS, Guo HD, Bai SY, Khan A, Wang XM, Gao YM, Li JS. Tomato salt tolerance mechanisms and their potential applications for fighting salinity: a review. Front Plant Sci, 2022, 13. 949541
[20]

Guo H, Zhang Q, Chen Y, Lu H. Effects of biochar on plant growth and hydro-chemical properties of recycled concrete aggregate. Sci Total Environ, 2023, 882. 163557
[21]

Hailegnaw NS, Mercl F, Pračke K, Száková J, Tlustoš P. Mutual relationships of biochar and soil pH, CEC, and exchangeable base cations in a model laboratory experiment. J Soil Sediment, 2019, 19(5): 2405-2416.

[22]

He K, He G, Wang C, Zhang H, Xu Y, Wang S, Kong Y, Zhou G, Hu R. Biochar amendment ameliorates soil properties and promotes Miscanthus growth in a coastal saline-alkali soil. Appl Soil Ecol, 2020, 155. 103674
[23]

Hossain MZ, Bahar MM, Sarkar B, Donne SW, Ok YS, Palansooriya KN, Kirkham MB, Chowdhury S, Bolan N. Biochar and its importance on nutrient dynamics in soil and plant. Biochar, 2020, 2(4): 379-420.

[24]

Ibrahim A, Usman ARA, Al-Wabel MI, Nadeem M, Ok YS, Al-Omran A. Effects of conocarpus biochar on hydraulic properties of calcareous sandy soil: influence of particle size and application depth. Archiv Für Acker- und Pflanzenbau und Bodenkunde, 2017, 63(2): 185-197.

[25]

Kul R, Arjumend T, Ekinci M, Yildirim E, Turan M, Argin S. Biochar as an organic soil conditioner for mitigating salinity stress in tomato. Soil Sci Plant Nutr (Tokyo), 2021, 67(6): 693-706.

[26]

Li H, Hou X, Bertin N, Ding R, Du T. Quantitative responses of tomato yield, fruit quality and water use efficiency to soil salinity under different water regimes in Northwest China. Agr Water Manage, 2023, 277. 108134
[27]

Liao W, Thomas S. Biochar particle size and post-pyrolysis mechanical processing affect soil pH, water retention capacity, and plant performance. Soil Syst, 2019, 3(1): 14.

[28]

Liao JX, So PS, Bordoloi S, Li DN, Yuan HR, Chen Y, Xin LQ. Plant performance and soil–plant carbon relationship response to different biochar types. Biochar, 2024, 6(1): 75.

[29]

Liu Z, Dugan B, Masiello CA, Gonnermann HM. Biochar particle size, shape, and porosity act together to influence soil water properties. PLoS ONE, 2017, 12(6. e179079
[30]

Mahmoodabadi M, Yazdanpanah N, Sinobas LR, Pazira E, Neshat A. Reclamation of calcareous saline sodic soil with different amendments (I): redistribution of soluble cations within the soil profile. Agric Water Manage, 2013, 120 30-38.

[31]

Mikajlo I, Lerch TZ, Louvel B, Hynšt J, Záhora J, Pourrut B. Composted biochar versus compost with biochar: effects on soil properties and plant growth. Biochar, 2024, 6(1): 1-17.

[32]

Mitchell JP, Shennan C, Grattan SR, May DM. Tomato fruit yields and quality under water deficit and salinity. J Am Soc Hortic Sci, 1991, 116(2): 215-221.

[33]

Ng CWW, Guo H, Ni J, Zhang Q, Chen R, Zhang Y. Effects of plant-biochar interaction on the performance of a landfill cover system: field monitoring and numerical modelling. Can Geotech J, 2023, 60(11): 1663-1680.

[34]

Novak JM, Busscher WJ, Laird DL, Ahmedna M, Watts DW, Niandou MAS. Impact of biochar amendment on fertility of a southeastern coastal plain soil. Soil Sci, 2009, 174(2): 105-112.

[35]

Ors S, Ekinci M, Yildirim E, Sahin U, Turan M, Dursun A. Interactive effects of salinity and drought stress on photosynthetic characteristics and physiology of tomato (Lycopersicon esculentum L.) seedlings. S Afr J Bot, 2021, 137 335-339.

[36]

Sigua GC, Novak JM, Watts DW, Cantrell KB, Shumaker PD, Szögi AA, Johnson MG. Carbon mineralization in two ultisols amended with different sources and particle sizes of pyrolyzed biochar. Chemosphere, 2014, 103 313-321.

[37]

Tang E, Liao W, Thomas SC. Optimizing biochar particle size for plant growth and mitigation of soil salinization. Agronomy, 2023, 2(13): 1394.

[38]

Villagra-Mendoza K, Horn R. Effect of biochar addition on hydraulic functions of two textural soils. Geoderma, 2018, 326 88-95.

[39]

Wang S, Gao P, Zhang Q, Shi Y, Guo X, Lv Q, Wu W, Zhang X, Li M, Meng Q. Application of biochar and organic fertilizer to saline-alkali soil in the Yellow River Delta: Effects on soil water, salinity, nutrients, and maize yield. Soil Use Manage, 2022, 38(4): 1679-1692.

[40]

Wu Z, Fan Y, Qiu Y, Hao X, Li S, Kang S. Response of yield and quality of greenhouse tomatoes to water and salt stresses and biochar addition in Northwest China. Agr Water Manage, 2022, 270. 107736
[41]

Xie Y, Wang L, Li H, Westholm LJ, Carvalho L, Thorin E, Yu Z, Yu X, Skreiberg Ø. A critical review on production, modification and utilization of biochar. J Anal Appl Pyrol, 2022, 161. 105405
[42]

Yan N, Marschner P, Cao W, Zuo C, Qin W. Influence of salinity and water content on soil microorganisms. Int Soil Water Conserv Res, 2015, 3(4): 316-323.

[43]

Yang X, Igalavithana AD, Oh S, Nam H, Zhang M, Wang C, Kwon EE, Tsang DCW, Ok YS. Characterization of bioenergy biochar and its utilization for metal/metalloid immobilization in contaminated soil. Sci Total Environ, 2018, 640–641 704-713.

[44]

Yue Y, Guo WN, Lin QM, Li GT, Zhao XR. Improving salt leaching in a simulated saline soil column by three biochars derived from rice straw (Oryza sativa L.), sunflower straw (Helianthus annuus), and cow manure. J Soil Water Conserv, 2016, 71(6): 467-475.

[45]

Zeeshan M, Ahmad W, Hussain F, Ahamd W, Numan M, Shah M, Ahmad I. Phytostabalization of the heavy metals in the soil with biochar applications, the impact on chlorophyll, carotene, soil fertility and tomato crop yield. J Clean Prod, 2020, 255. 120318
[46]

Zhang L, Jing Y, Chen C, Xiang Y, Rezaei Rashti M, Li Y, Deng Q, Zhang R. Effects of biochar application on soil nitrogen transformation, microbial functional genes, enzyme activity, and plant nitrogen uptake: a meta-analysis of field studies. Gcb Bioenergy, 2021, 13(12): 1859-1873.

[47]

Zhang S, Cui J, Wu H, Zheng Q, Song D, Wang X, Zhang S. Organic carbon, total nitrogen, and microbial community distributions within aggregates of calcareous soil treated with biochar. Agric Ecosyst Environ, 2021, 314. 107408
[48]

Zhang S, Xue L, Liu J, Jia P, Feng Y, Xu Y, Li Z, Zhao X. One–third substitution of nitrogen with cow manure or biochar greatly reduced N2O emission and carbon footprint in saline–alkali soils. Field Crop Res, 2024, 316. 109517
[49]

Zhao X, Grossart H. Enhancing crop yield and microbial diversity in saline-affected paddy soil through biochar amendment under aquaculture wastewater irrigation. Eur J Soil Biol, 2024, 123. 103681
[50]

Zhao C, Zhang H, Song C, Zhu JK, Shabala S. Mechanisms of plant responses and adaptation to soil salinity. Innovation (Camb), 2020, 1(1. 100017
[51]

Zhao R, Wu J, Jiang C, Liu F. Effects of biochar particle size and concomitant nitrogen fertilization on soil microbial community structure during the maize seedling stage. Environ Sci Pollut R, 2020, 27(12): 13095-13104.

[52]

Zhou H, Guo J, Liu H, Wang J, Wang Y. Effects of biochar pyrolysis temperature and application rate on saline soil quality and maize yield. Agronomy, 2024, 14(7): 1529.

Funding

Key Technologies Research and Development Program(2022YFD1900503)

RIGHTS & PERMISSIONS

The Author(s)

AI Summary AI Mindmap
PDF

351

Accesses

0

Citation

Detail
Sections
Recommended

AI思维导图

/