Biochar Modification and Its Application in Plant Health Management

WANG Yao; ZHOU Xiao; ZHOU Hong-jiang; WANG Cong; LIANG Yi-jia; YANG Shao-qi; LI Shi-li; YANG Xiang

doi:10.13718/j.cnki.zwyx.2022.04.003

2022 Volume 1 Issue 4

Article Contents

Previous Article Next Article

WANG Yao, ZHOU Xiao, ZHOU Hong-jiang, et al. Biochar Modification and Its Application in Plant Health Management[J]. PLANT HEALTH AND MEDICINE, 2022, (4): 21-30. doi: 10.13718/j.cnki.zwyx.2022.04.003

Citation:

WANG Yao, ZHOU Xiao, ZHOU Hong-jiang, et al. Biochar Modification and Its Application in Plant Health Management[J]. PLANT HEALTH AND MEDICINE, 2022, (4): 21-30. doi: 10.13718/j.cnki.zwyx.2022.04.003

Biochar Modification and Its Application in Plant Health Management

1. School of Plant Protection, Southwest University, Chongqing 400715, China;
2. Zheng'an Branch of Zunyi Company of Guizhou Tobacco Company, Zunyi Guizhou 563400, China

More Information

Received Date: 01/07/2022
MSC: S156.2

Abstract

Biochar is a carbon-rich, highly stable and highly aromatic solid material produced by thermochemical decomposition of biomass under the conditions of high temperature and anaerobic condition. It has been widely used in the remediation of heavy metal contaminated soil and soil improvement for its specific surface area, porosity, alkaline and rich functional groups. In this paper, the modification methods of biochar were introduced. The control effects of biochar on agricultural pest and disease, the promotion of crop growth, and the reduction of greenhouse gas emission, as well as research on controlled-release pesticides and fertilizer were summarized. Besides, the existing problems in production and promotion of application of biochar in agriculture were analysis. Finally, new insights into the future application prospects and directions of biochar in the agricultural field were put forward.
- biochar,
- agricultural production,
- plant disease,
- application,
- progress

References

[1]	DE RAYMOND A B,GOULET F.Science,Technology and Food Security:an Introduction[J].Science,Technology and Society,2020,25(1):7-18. Google Scholar
[2]	JALAL F,ARIF M,AKHTAR K,et al.Biochar Integration with Legume Crops in Summer Gape Synergizes Nitrogen Use Efficiency and Enhance Maize Yield[J].Agronomy,2020,10(1):58. Google Scholar
[3]	AYAZ M,FEIZIEN É D,TILVIKIEN É V, et al. Biochar Role in the Sustainability of Agriculture and Environment[J].Sustainability,2021,13(3):1330. Google Scholar
[4]	PANWAR N L,PAWAR A.Influence of Activation Conditions on the Physicochemical Properties of Activated Biochar:a Review[J].Biomass Conversion and Biorefinery,2022,12(3):925-947. Google Scholar
[5]	邵光成,吴世清,房凯,等.生物炭添加提高渍水条件下番茄产量改善品质[J].农业工程学报,2019,35(19):160-167. Google Scholar
[6]	郑宇佳.改性核桃壳炭对水中Pb²⁺的去除及其对土壤中铅的钝化实验研究[D].南昌:华东交通大学,2021. Google Scholar
[7]	CHANG Z F,TIAN L P,ZHANG J,et al.Comparative Study on The Relative Significance of Low-/High-Condensation Aromatic Moieties in Biochar to Organic Contaminant Sorption[J].Ecotoxicology and Environmental Safety,2022,238:113598. Google Scholar
[8]	KANG M W,YIBELTAI M,KIM Y H,et al.Enhancement of Soil Physical Properties and Soil Water Retention with Biochar-Based Soil Amendments[J].Science of The Total Environment,2022,836:155746. Google Scholar
[9]	曾唯.施加生物炭和地膜覆盖对菜地CH₄和CO₂排放的影响[D].重庆:西南大学,2021. Google Scholar
[10]	YAHYA M A,AL-QODAH Z,NGAH C W Z.Agricultural Bio-Waste Materials as Potential Sustainable Precursors Used for Activated Carbon Production:a Review[J].Renewable and Sustainable Energy Reviews,2015,46:218-235. Google Scholar
[11]	CHEN L L,CHENG P J,YE L,et al.Biological Performance and Fouling Mitigation in The Biochar-amended Anaerobic Membrane Bioreactor (AnMBR) Treating Pharmaceutical Wastewater[J].Bioresource Technology,2020,302:122805. Google Scholar
[12]	严军华,王舒笑,袁浩然,等.新型花生壳生物炭基催化剂催化酯交换反应[J].太阳能学报,2020,41(4):257-263. Google Scholar
[13]	罗洋,梁运信,杨凯德,等.不同秸秆炭的制备及其对镉污染黄壤中镉的钝化效果[J].贵州农业科学,2020,48(2):29-33. Google Scholar
[14]	王旭日.负载Fe3C颗粒的多孔生物炭在锂硫电池中的应用[D].湘潭:湘潭大学,2021 Google Scholar
[15]	赵玉绮.木质素基生物炭材料的制备及其在超级电容器电极材料中的应用[D].常州:常州大学,2021. Google Scholar
[16]	解晓明,索习东,王璐瑶,等.玉米芯生物炭饼的太阳能水蒸发性能及其应用[J].农业工程学报,2022,38(10):286-295. Google Scholar
[17]	杜甜甜,李梅,高心雨,等.生物炭的改性方法及其在环境领域的研究进展[J].四川环境,2020,39(5):186-190. Google Scholar
[18]	RAJAPAKSHA A U,CHEN S S,TSANG D C W,et al.Engineered/Designer Biochar for Contaminant Removal/Immobilization from Soil and Water:Potential and Implication of Biochar Modification[J].Chemosphere,2016,148:276-291. Google Scholar
[19]	CHU G,ZHAO J,HUANG Y,et al.Phosphoric Acid Pretreatment Enhances The Specific Surface Areas of Biochars by Generation of Micropores[J].Environmental Pollution,2018,240:1-9. Google Scholar
[20]	刘蕊,李松,张辉,等.硝酸改性生物炭对水体中阴阳离子染料吸附特性[J].水处理技术,2019,45(3):28-34. Google Scholar
[21]	杨哲,胡文勇,沈良辰,等.硫酸改性生物炭对废水中Cr(Ⅵ)的吸附性能研究[J].化工新型材料,2021,49(S1):273-278,282. Google Scholar
[22]	HAMID S B A,CHOWDHURY Z Z,ZAIN S M.Base Catalytic Approach:a Promising Technique for the Activation of Biochar for Equilibrium Sorption Studies of Copper,Cu(II) Ions in Single Solute System[J].Materials (Basel,Switzerland),2014,7(4):2815-2832. Google Scholar
[23]	FAN S C,SUN Y,YANG T H,et al.Biochar Derived from Corn Stalk and Polyethylene Co-Pyrolysis:Characterization and Pb(Ii) Removal Potential[J].RSC Advances,2020,10(11):6362-6376. Google Scholar
[24]	DING Z H,HU X,WAN Y S,et al.Removal of Lead,Copper,Cadmium,Zinc,and Nickel from Aqueous Solutions by Alkali-modified Biochar:Batch and Column Tests[J].Journal of Industrial and Engineering Chemistry,2016,33:239-245. Google Scholar
[25]	TAN X F,LIU Y G,GU Y L,et al.Biochar-Based Nano-Composites for The Decontamination of Wastewater:A Review[J].Bioresource Technology,2016,212:318-333. Google Scholar
[26]	曹媛,李晓东,彭昌盛,等.浸渍热解法制备铁改性生物炭活化过硫酸盐去除2,4-二硝基甲苯[J].环境工程,2021,39(11):135-142,178. Google Scholar
[27]	XU H J,ZHANG X P,ZHANG Y D.Modification of Biochar by Fe₂O₃ for the Removal of Pyridine and Quinoline[J].Environmental Technology,2018,39(11):1470-1480. Google Scholar
[28]	YIN G C,TAO L,CHEN X L,et al.Quantitative Analysis on the Mechanism of Cd²⁺ Removal by MgCl^2-Modified Biochar in Aqueous Solutions[J].Journal of Hazardous Materials,2021,420:126487. Google Scholar
[29]	LIU Q Q,SHENG Y Q,LIU X Z.Efficacy of in Situ Active Capping Cd Highly Contaminated Sediments with Nano-Fe₂O₃ Modified Biochar[J].Environmental Pollution,2021,290:118134. Google Scholar
[30]	CAO Y,JIANG S Q,ZHANG Y N,et al.Investigation into Adsorption Characteristics and Mechanism of Atrazine on Nano-MgO Modified Fallen Leaf Biochar[J].Journal of Environmental Chemical Engineering,2021,9(4):105727. Google Scholar
[31]	WU L P,WEI C B,ZHANG S R,et al.MgO Modified Biochar Increases Phosphate Retention and Rice Yields in Saline-Alkaline Soil[J].Journal of Cleaner Production,2019,235:901-909. Google Scholar
[32]	黄安香,柏文恋,王忠伟,等.壳聚糖改性竹生物炭对土壤外源污染镉形态分布的影响[J].江苏农业科学,2022,50(15):195-202. Google Scholar
[33]	LIU Y X,GAO C X,WANG Y Y,et al.Vermiculite Modification Increases Carbon Retention and Stability of Rice Straw Biochar at Different Carbonization Temperatures[J].Journal of Cleaner Production,2020,254:120111. Google Scholar
[34]	王瑞,刘玉学,高诚祥,等.蛭石改性水稻秸秆生物炭在土壤中的短期降解[J].农业环境科学学报,2021,40(9):1954-1962. Google Scholar
[35]	刘春来,王爽,杨帆,等.生物碳对玉米茎腐病控害作用及植株生长的影响[J].黑龙江农业科学,2018(9):51-54. Google Scholar
[36]	刘春来,杨帆,王爽,等.生物碳对大豆根腐病防控效果及植株生长的影响[J].黑龙江农业科学,2020(8):49-52. Google Scholar
[37]	冯慧琳,付兵,任天宝,等.生物炭对青枯病烟株的根际土壤微生物群落结构调控机制分析[J].农业资源与环境学报,2022,39(1):173-181. Google Scholar
[38]	许笠.生物炭对褐飞虱生活史和稻田优势节肢动物群个体数量的影响[D].南京:南京农业大学,2015. Google Scholar
[39]	金雪.菊芋秸秆生物炭抑制番茄枯萎病发生的根际微生物学机理[D].哈尔滨:东北农业大学,2021. Google Scholar
[40]	张广雨.生物炭对烟草青枯病的防效及对土壤微生态的调控[D].北京:中国农业科学院,2020. Google Scholar
[41]	王耀晨.花椒籽炭基有机肥防治烟草黑胫病研究[D].北京:中国农业科学院,2020. Google Scholar
[42]	陈义轩.土壤菌群、秀丽线虫、番茄立枯病对生物炭输入的响应特征[D].沈阳:沈阳农业大学,2019. Google Scholar
[43]	谭磊.生物炭缓解自毒物质对甜瓜和木霉菌的毒害作用及其对土壤微生物种群的影响[D].沈阳:沈阳农业大学,2017. Google Scholar
[44]	谷益安.土壤细菌群落和根系分泌物影响番茄青枯病发生的生物学机制[D].南京:南京农业大学,2017. Google Scholar
[45]	饶霜.生物炭对番茄青枯病抗性、土壤微生物活性及有机酸含量的影响[D].广州:华南农业大学,2016. Google Scholar
[46]	马云艳,顾美英,徐万里,等.棉秆生物炭对大丽轮枝菌生长及毒素作用的影响[J].干旱地区农业研究,2015,33(5):217-224. Google Scholar
[47]	徐广平,滕秋梅,沈育伊,等.香蕉茎叶生物炭对香蕉枯萎病防控效果及土壤性状的影响[J].生态环境学报,2020,29(12):2373-2384. Google Scholar
[48]	刘悦,史文琦,曾凡松,等.生物炭对小麦赤霉病的防治效果及产量的影响[J].植物保护,2020,46(4):270-274,281. Google Scholar
[49]	KANG M W,YIBELTAL M,KIM Y H,et al.Enhancement of Soil Physical Properties and Soil Water Retention with Biochar-Based Soil Amendments[J].Science of the Total Environment,2022,836:155746. Google Scholar
[50]	MUHAMMAD N,GE L Y,KHAN M H,et al.Effects of Different Biochars on Physicochemical Properties and Immobilization of Potentially Toxic Elements in Soil — a Geostatistical Approach[J].Chemosphere,2021,277:130350. Google Scholar
[51]	ABRIZ S F,TORABIAN S,QIN R J,et al.Biochar Effects on Yield of Cereal and Legume Crops Using Meta-Analysis[J].Science of the Total Environment,2021,775:145869. Google Scholar
[52]	王晶,侯振安.不同原料生物碳对滴灌棉花产量及土壤磷素利用率的影响[J].西南农业学报,2018,31(11):2354-2360. Google Scholar
[53]	ZHENG J Y,ZHANG J X,GAO L,et al.Effect of Straw Biochar Amendment on Tobacco Growth,Soil Properties,and Rhizosphere Bacterial Communities[J].Scientific Reports,2021,11:20727. Google Scholar
[54]	李先才,夏贤仁,蔡宪杰,等.生物炭与复合肥混施对植烟土壤及烤烟生长的影响[J].贵州农业科学,2021,49(9):66-75. Google Scholar
[55]	廖娜.生物碳对滴灌棉田土壤微生物的影响[D].石河子:石河子大学,2016. Google Scholar
[56]	LI M,LIU M,LI Z P,et al.Soil N Transformation and Microbial Community Structure as Affected by Adding Biochar to a Paddy Soil of Subtropical China[J].Journal of Integrative Agriculture,2016,15(1):209-219. Google Scholar
[57]	LI M,WANG Y M,LIU M,et al.Three-year field Observation of Biochar-Mediated Changes in Soil Organic Carbon and Microbial Activity[J].Journal of Environmental Quality,2019,48(3):717-726. Google Scholar
[58]	XU W H,WHITMAN W B,GUNDALE M J,et al.Functional Response of the Soil Microbial Community to Biochar Applications[J].GCB Bioenergy,2021,13(1):269-281. Google Scholar
[59]	李青杰,方文生,张大琪,等.棉隆熏蒸联合生物炭和沸石对土壤微生态及土传病原菌的影响[J].植物保护,2022,48(4):150-157. Google Scholar
[60]	LABORDE D,MAMUN A,MARTIN W,et al.Agricultural Subsidies and Global Greenhouse Gas Emissions[J].Nature Communications,2021,12:2601. Google Scholar
[61]	MIELCAREK-BOCHEṄ SKA P, RZEŹ NIK W.Greenhouse Gas Emissions from Agriculture in EU Countries—State and Perspectives[J].Atmosphere,2021,12(11):1396. Google Scholar
[62]	王冠丽,孙铁军,刘廷玺,等.施用生物炭对干旱区玉米农田碳足迹的影响[J].农业环境科学学报,2019,38(11):2650-2658. Google Scholar
[63]	廖添怀,李欢,王艳玲.稻秆及稻秆生物炭添加对稻田红壤有机碳组分及CH₄和CO₂累积排放量的影响[J].农业环境科学学报,2022,41(7):1598-1609. Google Scholar
[64]	DONG D,YANG M,WANG C,et al.Responses of Methane Emissions and Rice Yield to Applications of Biochar and Straw in APaddy Field[J].Journal of Soils and Sediments,2013,13(8):1450-1460. Google Scholar
[65]	GUO F C,ZHANG J M,YANG X Y,et al.Impact of Biochar on Greenhouse Gas Emissions from Constructed Wetlands under Various Influent Chemical Oxygen Demand to Nitrogen Ratios[J].Bioresource Technology,2020,303:122908. Google Scholar
[66]	CHEN L,CHEN Q C,RAO P H,et al.Formulating and Optimizing a Novel Biochar-Based Fertilizer for Simultaneous Slow-Release of Nitrogen and Immobilization of Cadmium[J].Sustainability,2018,10(8):2740. Google Scholar
[67]	LUO W C,QIAN L,LIU W W,et al.A Potential Mg-Enriched Biochar Fertilizer:Excellent Slow-Release Performance and Release Mechanism of Nutrients[J].Science of The Total Environment,2021,768:144454. Google Scholar
[68]	XIANG Y B,LU X,YUE J T,et al.Stimuli-Responsive Hydrogel as Carrier for Controlling the Release and Leaching Behavior of Hydrophilic Pesticide[J].Science of the Total Environment,2020,722:137811. Google Scholar
[69]	MEI M,BAI B,ZHENG D,et al.Application of the Photothermal-Responsive Gelatin-Based Microspheres for Controlled Release of Imidacloprid by Helix-Coil Structural Transition Mechanism[J].Colloids and Surfaces A:Physicochemical and Engineering Aspects,2022,652:129792. Google Scholar
[70]	钟晓晓.油菜秸秆生物炭的制备及农药负载—缓释应用研究[D].武汉:华中农业大学,2017. Google Scholar
[71]	LIU B,CHEN C W,WANG R,et al.Near-Infrared Light-Responsively Controlled-Release Herbicide Using Biochar as a Photothermal Agent[J].ACS Sustainable Chemistry & Engineering,2019,7(17):14924-14932. Google Scholar
[72]	GAO Y J,CHEN C W,WANG D F,et al.TiO₂/Biochar with Light-Switchable Wettability as A Herbicide Safener and Foliar Fertilizer Adhesive[J].ACS Sustainable Chemistry & Engineering,2020,8 (2):1121-1128. Google Scholar
[73]	WANG Y F,PENG Z J,YANG Y Q,et al.Auricularia Auricula Biochar Supported γ-FeOOH Nanoarrays for Electrostatic Self-assembly and pH-Responsive Controlled Release of Herbicide and Fertilizer[J].Chemical Engineering Journal,2022,437:134984. Google Scholar
[74]	陈庆,孙丽枝.一种由温敏性凝胶控释的微生物肥增效剂及其制备方法:CN105481561A[P].[2016-04-13]. Google Scholar

Access History

通讯作者: 陈斌, bchen63@163.com

1.
沈阳化工大学材料科学与工程学院沈阳 110142

Export Citation

PDF

XML

Article Metrics

Article views(987) PDF downloads(275) Cited by(0)

Name
	Name cannot be empty!
E-mail
	Mailbox cannot be empty! Mailbox cannot be empty!
Telephone
	Mobile number cannot be empty! Please enter a valid mobile number!
Title

Content
Verification Code

Message Board

Biochar Modification and Its Application in Plant Health Management

Abstract

References

Access History

通讯作者: 陈斌, bchen63@163.com

Article Metrics

Access History

Other Articles By Authors