基于文献计量学的秸秆生物炭研究态势分析

doi:10.11924/j.issn.1000-6850.casb2024-0175

中国农学通报 ›› 2024, Vol. 40 ›› Issue (35): 138-147.doi: 10.11924/j.issn.1000-6850.casb2024-0175

基于文献计量学的秸秆生物炭研究态势分析

王晋飞¹^,²(), 朱勇勇¹, 高志红¹, 邝春议², 张翔², 陈晓远¹()

¹ 韶关学院生物与农业学院/粤北水土资源高效利用工程技术研究中心，广东韶关 512005
² 喀什大学生命与地理科学学院，新疆喀什 844006

收稿日期:2024-03-13 修回日期:2024-07-01 出版日期:2024-12-15 发布日期:2024-12-12
通讯作者:
陈晓远，男，1965年出生，内蒙古丰镇人，教授，博士研究生，主要从事土壤改良与修复方面的研究。通信地址：512005 广东省韶关市浈江区大学路288号，E-mail：chenxy2@163.com。
作者简介:
王晋飞，男，1989年出生，山西晋城人，硕士研究生，研究方向：生物资源与环境工程。通信地址：512005 广东省韶关市浈江区大学路288号，E-mail：wangjinfei89@163.com。
基金资助:
韶关市科技计划项目“水稻秸秆生物炭对重金属污染土壤的修复研究”(220606154533827); 广东省自然科学基金项目“局部根系水分胁迫下束鞘细胞调控水稻水分吸收的机制研究”(2023A515011736)

Research Trend Analysis of Straw Biochar Based on Bibliometric

WANG Jinfei¹^,²(), ZHU Yongyong¹, GAO Zhihong¹, KUANG Chunyi², ZHANG Xiang², CHEN Xiaoyuan¹()

¹ School of Biology and Agriculture, Shaoguan University/Engineering Technology Research Center for Efficient Utilization of Water and Soil Resources in Northern Guangdong, Shaoguan Guangdong 512005
² The College of Life and Geographic Sciences, Kashi University, Kashi, Xinjiang 844006

Received:2024-03-13 Revised:2024-07-01 Published:2024-12-15 Online:2024-12-12

摘要/Abstract

摘要：

秸秆生物炭在环境治理和资源循环利用中发挥着重要作用，为了解秸秆生物炭的发展历程，明确该领域的研究重点和前沿方向，通过利用文献计量学CiteSpace可视化软件，对Web of Science(WOS)核心合集数据库检索获得的数据进行文献计量和知识图谱分析。结果显示：秸秆生物炭的年发文量呈上升趋势，中国的发文量位居榜首，总量达3141篇；在全球研究机构中，中国科学院、农业农村部和土壤科学研究所是秸秆生物炭研究的代表性机构；该领域的研究成果主要发表在Science of the Total Environment和Bioresource Technology等高影响因子期刊，中国的王海龙是发文量最多的学者；研究热点及方向主要包括：秸秆生物炭的原料和制备条件、秸秆生物炭在固碳减排、改良土壤和污染修复上的应用以及机制。总体而言，秸秆生物炭是农业废弃物资源化利用的热点主题，今后秸秆生物炭的改性制备、对减缓气候变化和修复环境污染的机制与长期效应研究仍然是研究热点与趋势。

关键词: 环境治理, 资源循环, 秸秆, 生物炭, 文献计量

Abstract:

Straw biochar plays an important role in environmental governance and resource recycling. In order to grasp the development process of straw biochar and clarify the focus and preface direction of this research field, this article uses CiteSpace visualization software to conduct bibliometric and knowledge graph analysis on the data retrieved from the Web of Science (WOS) core collection database. The results show that the annual publication volume is on the rise, with China ranking first with a total of 3141 articles; among the global research institutions, Chinese Academy of Sciences, Ministry of Agriculture and Rural Affairs and Institute of Soil Science are representative institutions for straw biochar research; the research results in this field are mainly published in high impact factor journals such as Science of the Total Environment and Bioresource Technology, Wang Hailong from China is the scholar with the highest number of publications; the research hotspots and directions mainly include the raw materials and preparation conditions of straw biochar, the application and mechanisms of straw biochar in carbon sequestration and emission reduction, soil improvement, and pollution remediation. Overall, straw biochar is a hot topic in the resource utilization of agricultural waste. In the future, the modification and preparation of straw biochar, as well as the mechanism and long-term effects of mitigating climate change and repairing environmental pollution, will be the research hotspot and trend.

Key words: environmental governance, resource recycling, straw, biochar, bibliometrics

王晋飞, 朱勇勇, 高志红, 邝春议, 张翔, 陈晓远. 基于文献计量学的秸秆生物炭研究态势分析[J]. 中国农学通报, 2024, 40(35): 138-147.

WANG Jinfei, ZHU Yongyong, GAO Zhihong, KUANG Chunyi, ZHANG Xiang, CHEN Xiaoyuan. Research Trend Analysis of Straw Biochar Based on Bibliometric[J]. Chinese Agricultural Science Bulletin, 2024, 40(35): 138-147.

图/表 10

参考文献 45

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排序	国家/地区	发文量/篇	中心性
1	中国CHINA	3141	0.07
2	美国USA	376	0
3	印度INDIA	289	0
4	巴基斯坦PAKISTAN	247	0
5	澳大利亚AUSTRALIA	237	0.51
6	韩国SOUTH KOREA	162	0.04
7	加拿大CANADA	148	0.07
8	德国GERMANY	141	0.4
9	埃及EGYPT	122	0.17
10	波兰POLAND	119	0.04

排序	国家/地区	发文量/篇	中心性
1	中国CHINA	3141	0.07
2	美国USA	376	0
3	印度INDIA	289	0
4	巴基斯坦PAKISTAN	247	0
5	澳大利亚AUSTRALIA	237	0.51
6	韩国SOUTH KOREA	162	0.04
7	加拿大CANADA	148	0.07
8	德国GERMANY	141	0.4
9	埃及EGYPT	122	0.17
10	波兰POLAND	119	0.04

期刊	发文量/篇	总被引频次	篇均被引频次	期刊分区	近5年平均影响因子
Science of the Total Environment	331	3181	9.61	Q1	9.8
Bioresource Technology	232	3257	14.04	Q1	11.4
Environmental Science and Pollution Research	214	1979	9.25	Q2	5.8
Chemosphere	180	3193	17.74	Q1	8.8
Environmental Pollution	104	2068	19.88	Q1	8.9
Journal of Environmental Management	102	2070	20.29	Q1	8.7
Journal of Hazardous Materials	97	2519	25.97	Q1	13.6
Journal of Cleaner Production	90	1654	18.38	Q1	11.1
Journal of Soils and Sediments	81	1298	16.02	Q2	3.6
Agronomy-Basel	78	452	5.79	Q1	3.7

期刊	发文量/篇	总被引频次	篇均被引频次	期刊分区	近5年平均影响因子
Science of the Total Environment	331	3181	9.61	Q1	9.8
Bioresource Technology	232	3257	14.04	Q1	11.4
Environmental Science and Pollution Research	214	1979	9.25	Q2	5.8
Chemosphere	180	3193	17.74	Q1	8.8
Environmental Pollution	104	2068	19.88	Q1	8.9
Journal of Environmental Management	102	2070	20.29	Q1	8.7
Journal of Hazardous Materials	97	2519	25.97	Q1	13.6
Journal of Cleaner Production	90	1654	18.38	Q1	11.1
Journal of Soils and Sediments	81	1298	16.02	Q2	3.6
Agronomy-Basel	78	452	5.79	Q1	3.7

作者	频次/次	中心性	单位
Wang Hailong	50	0.22	佛山科学技术学院Foshan University
Ok Yong Sik	41	0.19	国立江原大学Kangwon National University
Zhang Zengqiang	39	0.05	西北农林科技大学Northwest Agriculture & Forestry University
Awasthi Mukesh Kumar	38	0.02	西北农林科技大学Northwest Agriculture & Forestry University
Pan Genxing	34	0	南京农业大学Nanjing Agricultural University
Rizwan Muhammad	28	0.13	费萨拉巴德政府学院大学Government College University Faisalabad
Joseph Stephen	28	0.02	悉尼新南威尔士大学University of New South Wales Sydney
Chang Scott X	26	0.17	阿尔伯塔大学University of Alberta
Li Hui	26	0.06	华中农业大学Huazhong Agricultural University
Meng Jun	26	0.03	沈阳农业大学Shenyang Agricultural University

基于文献计量学的秸秆生物炭研究态势分析

Research Trend Analysis of Straw Biochar Based on Bibliometric

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排序	频次/次	作者	年份	发表期刊	文章题目
1	861	Tomczyk Agnieszka	2020	Reviews in Environmental Science and Biotechnology	Biochar physicochemical properties: Pyrolysis temperature and feedstock kind effects
2	731	Xu Nan	2016	European Journal of Soil Biology	Effect of biochar additions to soil on nitrogen leaching, microbial biomass and bacterial community structure
3	573	Zhan Xiaokai	2013	Environmental Science and Pollution Research	Using biochar for remediation of soils contaminated with heavy metals and organic pollutants
4	543	Ronsse Frederik	2013	Global Change Biology Bioenergy	Production and characterization of slow pyrolysis biochar: influence of feedstock type and pyrolysis conditions
5	510	Fang Guodong	2014	Environmental Science & Technology	Key Role of Persistent Free Radicals in Hydrogen Peroxide Activation by Biochar: Implications to Organic Contaminant Degradation
6	484	Park Jong Hwan	2016	Chemosphere	Competitive adsorption of heavy metals onto sesame straw biochar in aqueous solutions
7	465	Jindo K.	2014	Biogeosciences	Physical and chemical characterization of biochars derived from different agricultural residues
8	447	Lu Kouping	2017	Journal of Environmental Management	Effect of bamboo and rice straw biochars on the mobility and redistribution of heavy metals (Cd, Cu, Pb and Zn) in contaminated soil
9	440	Wang Rongzhong	2014	Journal of Hazardous Materials	A three-year experiment confirms continuous immobilization of cadmium and lead in contaminated paddy field with biochar amendment
10	432	Zhao Bin	2018	Journal of Cleaner Production	Effect of pyrolysis temperature, heating rate, and residence time on rapeseed stem derived biochar

排序	关键词	中心性	频次/次	排序	关键词	中心性	频次/次
1	吸附Adsorption	0.53	723	21	有机质Organic matter	0	263
2	碳Carbon	0.37	646	22	生物有效性Bioavailability	0.26	262
3	去除Removal	0.4	642	23	污水污泥Sewage sludge	0.03	258
4	生物炭Biochar	0.05	627	24	影响Impact	0	257
5	重金属Heavy metals	1.09	591	25	修正Amendment	0.08	251
6	吸附Sorption	0.38	575	26	镉Cadmium	0.48	242
7	水稻秸秆Rice straw	0.03	554	27	微生物群落 Microbial community	0	233
8	秸秆Straw	0	534	28	浪费Waste	0	221
9	土壤Soil	0.41	504	29	温室气体排放 Greenhouse gas emissions	0.05	211
10	生物质Biomass	0.42	446	30	生长Growth	0	205
11	热解温度 Pyrolysis temperature	0.11	423	31	废水Waste water	0	202
12	水Water	0	414	32	肥料Manure	0.13	201
13	热解Pyrolysis	0.94	414	33	产量Yield	0.13	199
14	水溶液Aqueous solution	0.19	370	34	秸秆生物炭Straw biochar	0	192
15	活性炭Activated carbon	0.05	364	35	水溶液Aqueous solutions	0.03	186
16	机制Mechanisms	0.03	328	36	铅Lead	0.35	186
17	温度Temperature	0.03	312	37	性能Performance	0	186
18	黑炭Black carbon	0.29	311	38	降解Degradation	0.05	184
19	氮Nitrogen	0.29	288	39	修复Remediation	0	172
20	小麦秸秆Wheat straw	0.16	275	40	有效性Availability	0	161

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