•  
  •  
 

Coal Geology & Exploration

Abstract

Graphene is an emerging carbon nanomaterial in the 21st century, has excellent properties and shows great application potential in many fields. Coal is the most abundant and the cheapest carbon source with unique structure and material composition. The application of coal in the development and the application of new carbonaceous materials such as graphene and their composites is a work worthy of further exploration. The development of coal-based graphene can both promote the clean utilization of coal and enhance the added value of coal resources. In this paper, the research developments in coal structure, the mechanism of coal graphitization, as well as the development of the research and preparation of coal-based graphene at home and abroad were reviewed in detail. In addition, according to the current research situation of coal-based graphene, the existing problems and future prospect of the research on coal-based graphene were put forward. At present, the research on the preparation of coal-based graphene and its derivatives is still in its infancy. The focus of the research is on the optimization of product preparation and performance. There are few studies on the influence of coal petrography characters on product quality. The difference of structure and composition of raw coal will ultimately affect the structure and performance of coal-based graphene, while the structural evolution of coal is significantly affected by geological factors. Therefore, in the future,the research on the influence of coal original structure and material composition on the product of coal-based graphene should be strengthened, so as to provide theoretical support for promoting the study on coal-based graphene and improving the clean and efficient utilization of coal resources.

Keywords

coal-based graphene, raw materials, preparation techniques, research progress, prospect

DOI

10.3969/j.issn.1001-1986.2020.06.001

Reference

[1] 杨再立. 地震勘探在查找深部煤矿中的应用研究[D]. 抚州:东华理工大学,2013. YANG Zaili. Seismic wave method in search for the research on the application of deep coal mine[D]. Fuzhou:East China Institute of Technology,2013.

[2] 赵立明,崔若飞. 全数字高密度三维地震勘探在煤田精细构造解释中的应用[J]. 地球物理学进展,2014,29(5):2332-2336. ZHAO Liming,CUI Ruofei. Application of digital high-density seismic exploration in fine structural interpretation in coalfield[J]. Progress in Geophysics,2014,29(5):2332-2336.

[3] 宁宏晓,唐东磊,皮红梅,等. 国内陆上"两宽一高"地震勘探技术及发展[J]. 石油物探,2019,58(5):645-653. NING Hongxiao,TANG Donglei,PI Hongmei,et al. The technology and development of "WBH" seismic exploration in land,China[J]. Geophysical Prospecting for Petroleum,2019,2019,58(5):645-653.

[4] 赵育台. 煤层陷落柱三维高密度地震探测与效果[J]. 工程地质学报,2012,20(增刊1):742-748. ZHAO Yutai. Coal seam collapse column 3D high density seismic exploration and effect[J]. Journal of Engineering Geology,2012,20(Sup.1):742-748.

[5] 韩文功,于静,刘学伟. 高密度三维地震技术[M]. 北京:地质出版社,2017. HAN Wengong,YU Jing,LIU Xuewei. High density 3D seismic technology[M]. Beijing:Geological Publishing House,2017.

[6] 赵镨,武喜尊. 高密度采集技术在西部煤炭资源勘探中的应用[J]. 中国煤炭地质,2008,20(6):11-15. ZHAO Pu,WU Xizun. High density acquisition technology and its application in Western China coal resource exploration[J]. Coal Geology of China,2008,20(6):11-15.

[7] ONGKIEHONG L. A changing philosophy in seismic data acquisition[J]. First Break,1988,6(9):281-284.

[8] PECHOLCS P I,HASTINGS-JAMES R,BAR-SOUKOV N,et al. Universal land acquisition 14 years later[C]//SEG Interlation Exposition and 72nd Annual Meeting,2002.

[9] LONG A S,RAMSDEN C R T,HOFFMANN J. In pursuit of the ideal 3D streamer symmetric sampling criteria[J]. ASEG Extended Abstracts 2003,2003(2):1-4.

[10] 程裕斌,陈加林. 高密度三维地震技术在潞安矿区高河煤矿的应用效果[J]. 中国煤炭地质,2010,22(8):50-53. CHENG Yubin,CHEN Jialin. Application effect of high-density 3D seismic exploration Technology in Gaohe Coal Mine,Lu'an Coal District[J]. Coal Geology of China,2010,22(8):50-53.

[11] 杨臣明. 全数字高密度煤矿采区三维地震技术研究与实践[J]. 中国煤炭地质,2014,26(3):46-52. YANG Chenming. All digital high density coalmine winning district 3D seismic prospecting technology research and practices[J]. Coal Geology of China,2014,26(3):46-52.

[12] 王琦. 全数字高密度三维地震勘探技术在淮北矿区的应用[J]. 煤田地质与勘探,2018,46(增刊1):41-45. WANG Qi. Application of all digital high density 3D seismic exploration technology in Huaibei mining area[J]. Coal Geology & Exploration,2018,46(Sup.1):41-45.

[13] 程增庆,高翔,张海燕,等. 高密度煤炭三维地震勘探观测系统:201520160285.5[P]. 2015-07-08. CHENG Zengqing,GAO Xiang,ZHANG Haiyan,et al. 3D seismic exploration and Observation System for high-density Coal:201520160285.5[P]. 2015-07-08.

[14] 牛跟彦. 全数字高密度三维地震勘探技术在煤矿采区的研究与应用[J]. 煤炭技术,2019,38(10):58-60. NIU Genyan. Application and research of all digital high density 3D seismic exploration technology in coalmine winning district[J]. Coal Technology,2019,38(10):58-60.

[15] 崔庆辉,尚新民,滕厚华,等. 高密度三维地震观测系统设计技术与应用[J]. 石油物探,2020,59(1):12-22. CUI Qinghui,SHANG Xinmin,TENG Houhua,et al. Design of a high density three dimensional seismic geometry and its application[J]. Geophysical Prospecting for Petroleum,2020,59(1):12-22.

[16] VERMEER G J O. 3D symmetric sampling in theory and practice[J]. Leading Edge,1998,17(11):1629-1647.

[17] 田忠斌. 高精度三维地震勘探关键技术研究及应用[J]. 中国煤炭地质,2010,22(3):44-49. TIAN Zhongbin. Research on high-precision 3D seismic prospecting key technologies and application[J]. Coal Geology of China,2010,22(3):44-49.

[18] 刘欣欣,吴国忱,梁锴. 单点高密度地震勘探技术研究综述[J]. 地球物理学进展,2009,24(4):1354-1366. LIU Xinxin,WU Guochen,LIANG Kai. The review of point-source/point receiver-high density seismic exploration technology[J]. Progress in GeoPhysics,2009,24(4):1354-1366.

[19] 马在田. 三维地震勘探方法[M]. 北京:石油工业出版社,1989. MA Zaitian. Method of 3D seismic exploration[M]. Beijing:Petroleum Industry Press,1989

[20] 冯春龙. 陷落柱地震观测系统研究[D]. 太原:太原理工大学,2014. FENG Chunlong. Study on seismic observation system of trapillar[D]. Taiyuan:Taiyuan University of Technology,2014.

[21] 郭雯. 东部老区三维地震观测系统评价设计方法研究[D]. 北京:中国地质大学(北京),2017. GUO Wen. Research on evaluation and design method of 3D seismic observation system in the eastern old area[D]. Beijing:China University of Geosciences (Beijing),2017.

[22] 张华,王梅生,李康虎,等. 确定排列片横纵比的方法:85%法则再分析[J]. 石油地球物理勘探,2019,54(5):947-953. ZHANG Hua,WANG Meisheng,LI Kanghu,et al. A method for determining the aspect ratio of patch:Reanalysis of 85% rule[J]. Oil Geophysical Prospecting,2019,54(5):947-953.

Share

COinS
 
 

To view the content in your browser, please download Adobe Reader or, alternately,
you may Download the file to your hard drive.

NOTE: The latest versions of Adobe Reader do not support viewing PDF files within Firefox on Mac OS and if you are using a modern (Intel) Mac, there is no official plugin for viewing PDF files within the browser window.