•  
  •  
 

Coal Geology & Exploration

Abstract

Objective Coals are highly sensitive to variations in temperature and pressure conditions. The structural evolution of coal macromolecules, driven by tectono-thermal processes, is the key to understanding coal rank transition and geological evolution. The structural alignment of polycyclic aromatic hydrocarbons (PAHs) in coals represents a critical indicator for characterizing coal rank transition and geological evolution. However, due to limited studies, there is a lack of systematic experimental demonstration and theoretical support for the structural alignment and microstructural characteristics of PAHs in coals, as well as their intrinsic relationships with the structural transition of coal macromolecules, during pyrolysis. Methods This study investigated bituminous coal samples from the Wuguantun Coal Mine in the Datong Coalfield, Shanxi Province. Using pyrolysis experiments at 400–1000 ℃, high-resolution transmission electron microscopy (HRTEM), laser Raman spectroscopy (LRS), and Fourier-transform infrared spectroscopy (FTIR), as well as comparison with actual geological evolution processes, this study revealed the mechanisms behind the thermal evolution of the structural alignment of PAHs, aiming to provide certain implications for the structural transition of coal macromolecules. Results The results indicated that the raw coals exhibited an increasing proportion of short PAHs and a decreasing proportion of long PAHs at approximately 400 ℃. In contrast, the raw coals showed a significantly elevated proportion of long PAHs at 400–1000 ℃. The PAH orientation decreased under low-temperature pyrolysis (≤ 400 ℃), increased slightly at 600–800 ℃, and increased markedly at 800–1000 ℃. These variations demonstrate pronounced stepwise characteristics. Curvature analysis reveals that with increasing pyrolysis temperature, coal samples generally showed a declining proportion of high-curvature aromatic fringes. This finding implies that thermal evolution would ultimately render the fringes progressively straighter. The PAH stacking ratio of raw coals changed slightly at approximately 400℃ and gradually increased at 400–1000 ℃. In contrast, under high-temperature pyrolysis at 800–1000 ℃, the PAH stacking tended to show a concentric layered distribution of graphene- and carbon onion-like structures.Conclusion The results of this study pose challenges to the conventional view that coal graphitization merely corresponds to the repair of structural defects. Instead, this study proposes that during the critical transition window from coalification to graphitization, the intense reorganization of the internal structures of PAHs induces significant secondary structural defects. These defects essentially represent the lattice distortions occurring as aromatic laminae evolve toward graphene- or carbon onion-like structures driven by thermal-kinetic processes. This insight also accounts for the microscopic strain heterogeneity ubiquitously observed in tectonically deformed coals. The presence of overall PAH orientation in pyrolyzed coals at 800–1000 ℃ marks the end of coalification and the onset of the graphitization stage (Rmax>6.22%).

Keywords

coal macromolecular structure, polycyclic aromatic hydrocarbon (PAH), thermal evolution, structural alignment, structural transition

DOI

10.12363/issn.1001-1986.25.08.0620

Reference

[1] 曹代勇,刘志飞,王安民,等. 构造物理化学条件对煤变质作用的控制[J]. 地学前缘,2022,29(1):439−448

CAO Daiyong,LIU Zhifei,WANG Anmin,et al. Control of coal metamorphism by tectonic physicochemical conditions[J]. Earth Science Frontiers,2022,29(1):439−448

[2] 曹代勇,宁树正,郭爱军,等. 中国煤田构造格局及其基本特征[J]. 矿业科学学报,2016,1(1):1−8

CAO Daiyong,NING Shuzheng,GUO Aijun,et al. Basic characteristics of coalfield tectonic framework in China[J]. Journal of Mining Science and Technology,2016,1(1):1−8

[3] 杨起,吴冲龙,汤达祯,等. 中国煤变质作用[M]. 北京:煤炭工业出版社,1996.

[4] FRANKLIN R E. A study of the fine structure of carbonaceous solids by measurements of true and apparent densities. Part I. Coals[J]. Transactions of the Faraday Society,1949,45:274−286.

[5] FRANKLIN R E. Crystallite growth in graphitizing and non–graphitizing carbons[J]. Proceedings of the Royal Society of London. A. Mathematical and Physical Sciences,1951,209(1097):196−218.

[6] GIVEN P H. An essay on the organic geochemistry of coal[M]//Coal science. Amsterdam:Elsevier,1984:63–252.

[7] HOWARD J B,ESSENHIGH R H. Pyrolysis of coal particles in pulverized fuel flames[J]. Industrial & Engineering Chemistry Process Design and Development,1967,6(1):74−84.

[8] SMITH P J,SMOOT L D. One–dimensional model for pulverized coal combustion and gasification[J]. Combustion Science and Technology,1980,23(1/2):17−31.

[9] TAKARADA T,TAMAI Y,TOMITA A. Reactivities of 34 coals under steam gasification[J]. Fuel,1985,64(10):1438−1442.

[10] BUSTIN R M,ROSS J V,MOFFAT I. Vitrinite anisotropy under differential stress and high confining pressure and temperature:Preliminary observations[J]. International Journal of Coal Geology,1986,6(4):343−351.

[11] ROSS J V,BUSTIN R M. The role of strain energy in creep graphitization of anthracite[J]. Nature,1990,343(6253):58−60.

[12] ROSS J V,BUSTIN R M. Vitrinite anisotropy resulting from simple shear experiments at high temperature and high confining pressure[J]. International Journal of Coal Geology,1997,33(2):153−168.

[13] MULLER G,NKUSI G,SCHOLER H F. Natural organohalogens in sediments[J]. Journal fur Praktische Chemie/Chemiker–Zeitung,1996,338(1):23−29.

[14] 秦勇. 中国高煤级煤的显微岩石学特征及结构演化[M]. 徐州:中国矿业大学出版社,1994.

[15] 胡社荣. 我国西北地区侏罗系含煤盆地低成熟油田的形成[J]. 新疆石油地质,1998,19(3):187−191

HU Sherong. Formation of immature oilfield in Jurassic coal–bearing basin in Northwestern China[J]. Xinjiang Petroleum Geology,1998,19(3):187−191

[16] THOMAS K M. The release of nitrogen oxides during char combustion[J]. Fuel,1997,76(6):457−473.

[17] 姜波,秦勇,金法礼. 煤变形的高温高压实验研究[J]. 煤炭学报,1997,22(1):80−84

JIANG Bo,QIN Yong,JIN Fali. Coal deformation test under high temperature and confining pressure[J]. Journal of China Coal Society,1997,22(1):80−84

[18] 姜波,秦勇,金法礼. 高温高压实验变形煤XRD结构演化[J]. 煤炭学报,1998,23(2):188−193

JIANG Bo,QIN Yong,JIN Fali. XRD analysis of the structural evolution of deformed coal samples tested under high temperature and high confined pressure[J]. Journal of China Coal Society,1998,23(2):188−193

[19] 曹代勇,李小明,张守仁. 构造应力对煤化作用的影响:应力降解机制与应力缩聚机制[J]. 中国科学D辑:地球科学,2006,36(1):59–68.

[20] 宋昱,朱炎铭,李伍. 东胜长焰煤热解含氧官能团结构演化的13C–NMR和FT–IR分析[J]. 燃料化学学报,2015,43(5):519−529

SONG Yu,ZHU Yanming,LI Wu. Structure evolution of oxygen functional groups in Dongsheng long flame coal by 13C–NMR and FT–IR[J]. Journal of Fuel Chemistry and Technology,2015,43(5):519−529

[21] 侯泉林,雒毅,韩雨贞,等. 煤的变形产气机理探讨[J]. 地质通报,2014,33(5):715−722

HOU Quanlin,LUO Yi,HAN Yuzhen,et al. Gas production mechanism in the process of coal tectonic deformation[J]. Geological Bulletin of China,2014,33(5):715−722

[22] 侯泉林,雒毅,宋超,等. 中煤级煤变形产气过程及其机理探讨[J]. 煤炭学报,2014,39(8):1675−1682

HOU Quanlin,LUO Yi,SONG Chao,et al. Gas generation during middle–rank coal deformation and the preliminary discussion of the mechanism[J]. Journal of China Coal Society,2014,39(8):1675−1682

[23] MATHEWS J P,FERNANDEZ–ALSO V,JONES A D,et al. Determining the molecular weight distribution of Pocahontas No. 3 low–volatile bituminous coal utilizing HRTEM and laser desorption ionization mass spectra data[J]. Fuel,2010,89(7):1461−1469.

[24] MATHEWS J P,SHARMA A. The structural alignment of coal and the analogous case of Argonne Upper Freeport coal[J]. Fuel,2012,95:19−24.

[25] GONZÁLEZ D,MONTES–MORÁN M A,YOUNG R J,et al. Effect of temperature on the graphitization process of a semianthracite[J]. Fuel Processing Technology,2002,79(3):245−250.

[26] RODRIGUES S,SUÁREZ–RUIZ I,MARQUES M,et al. Catalytic role of mineral matter in structural transformation of anthracites during high temperature treatment[J]. International Journal of Coal Geology,2012,93:49−55.

[27] 宋昱,姜波,王猛,等. 煤缩合芳环应力响应:对无烟煤石墨化的启示[J]. 煤炭学报,2022,47(12):4336−4351

SONG Yu,JIANG Bo,WANG Meng,et al. Stress response of coal condensed aromatic ring:Inspiration for graphitization of anthracite[J]. Journal of China Coal Society,2022,47(12):4336−4351

[28] LI Wu,SONG Yu,YANG Wenbin,et al. Structural transformations for a subbituminous coal,impact of temperature on gold–tube pyrolysis chars evaluated using HRTEM[J]. Fuel,2022,311:122581.

[29] DEURBERGUE A,OBERLIN A,OH J H,et al. Graphitization of Korean anthracites as studied by transmission electron microscopy and X–ray diffraction[J]. International Journal of Coal Geology,1987,8(4):375−393.

[30] LEVINE J R,DAVIS A. The relationship of coal optical fabrics to Alleghanian tectonic deformation in the central Appalachian fold–and–thrust belt,Pennsylvania[J]. Geological Society of America Bulletin,1989,101(10):1333−1347.

[31] SUCHY V,FREY M,WOLF M. Vitrinite reflectance and shear–induced graphitization in orogenic belts:A case study from the Kandersteg area,Helvetic Alps,Switzerland[J]. International Journal of Coal Geology,1997,34(1/2):1−20.

[32] WILKS K R,MASTALERZ M,ROSS J V,et al. The effect of experimental deformation on the graphitization of Pennsylvania anthracite[J]. International Journal of Coal Geology,1993,24(1/2/3/4):347−369.

[33] 曹代勇,王路,刘志飞,等. 我国煤系石墨研究及资源开发利用前景[J]. 煤田地质与勘探,2020,48(1):1−11

CAO Daiyong,WANG Lu,LIU Zhifei,et al. The research status and prospect of coal–based graphite in China[J]. Coal Geology & Exploration,2020,48(1):1−11

[34] 李阳,王路,曹代勇,等. 江西崇义矿煤成石墨的发现及其地质意义[J]. 煤田地质与勘探,2019,47(5):79−85

LI Yang,WANG Lu,CAO Daiyong,et al. The discovery and geological significance of coal–formed graphite in Chongyi coal mine in Jiangxi Province[J]. Coal Geology & Exploration,2019,47(5):79−85

[35] 王绍清,王小令,沙吉顿,等. 煤石墨化:结构和差异性演化[J]. 煤炭学报,2022,47(12):4300−4312

WANG Shaoqing,WANG Xiaoling,SHA Jidun,et al. Coal graphitization:Structures and their differential evolution[J]. Journal of China Coal Society,2022,47(12):4300−4312

[36] IBARRA J,MOLINER R,BONET A J. FT–i. r. investigation on char formation during the early stages of coal pyrolysis[J]. Fuel,1994,73(6):918−924.

[37] IBARRA J,MUÑOZ E,MOLINER R. FTIR study of the evolution of coal structure during the coalification process[J]. Organic Geochemistry,1996,24(6/7):725−735.

[38] SOLOMON P R,CARANGELO R M. FT–i. r. analysis of coal:2. Aliphatic and aromatic hydrogen concentration[J]. Fuel,1988,67(7):949−959.

[39] 苏现波,司青,宋金星. 煤的拉曼光谱特征[J]. 煤炭学报,2016,41(5):1197−1202

SU Xianbo,SI Qing,SONG Jinxing. Characteristics of coal Raman spectrum[J]. Journal of China Coal Society,2016,41(5):1197−1202

[40] ENETTE L. Structure and combustion reactivity of inertinite–rich and vitrinite rich South African coal chars:Quantification of the structural factors contributing to reactivity differences[D]. State College:The Pennsylvania State University,2013.

[41] SONG Yu,JIANG Bo,LI Ming,et al. Macromolecular transformations for tectonically–deformed high volatile bituminous via HRTEM and XRD analyses[J]. Fuel,2020,263:116756.

[42] SONG Yu,JIANG Bo,VANDEGINSTE V,et al. Deformation–related coalification:Significance for deformation within shallow crust[J]. International Journal of Coal Geology,2022,256:103999.

[43] OKOLO G N,NEOMAGUS H W J P,EVERSON R C,et al. Chemical–structural properties of South African bituminous coals:Insights from wide angle XRD–carbon fraction analysis,ATR–FTIR,solid state 13 C NMR,and HRTEM techniques[J]. Fuel,2015,158:779−792.

[44] VAN NIEKERK D,PUGMIRE R J,SOLUM M S,et al. Structural characterization of vitrinite–rich and inertinite–rich Permian–aged South African bituminous coals[J]. International Journal of Coal Geology,2008,76(4):290−300.

[45] SONG Yu,JIANG Bo,HAN Yuzhen. Macromolecular response to tectonic deformation in low–rank tectonically deformed coals (TDCs)[J]. Fuel,2018,219:279−287.

[46] SONG Yu,JIANG Bo,MATHEWS J P,et al. Structural transformations and hydrocarbon generation of low–rank coal (vitrinite) during slow heating pyrolysis[J]. Fuel Processing Technology,2017,167:535−544.

[47] SONG Yu,JIANG Bo,QU Meijun. Macromolecular evolution and structural defects in tectonically deformed coals[J]. Fuel,2019,236:1432−1445.

[48] SONG Yu,JIANG Bo,QU Meijun. Molecular dynamic simulation of self– and transport diffusion for CO2/CH4/N2 in low–rank coal vitrinite[J]. Energy & Fuels,2018,32(3):3085−3096.

[49] WANG Chang’an,HUDDLE T,LESTER E H,et al. Quantifying curvature in high–resolution transmission electron microscopy lattice fringe micrographs of coals[J]. Energy & Fuels,2016,30(4):2694−2704.

[50] WANG Chang’an,WATSON J K,LOUW E,et al. Construction strategy for atomistic models of coal chars capturing stacking diversity and pore size distribution[J]. Energy & Fuels,2015,29(8):4814−4826.

[51] 陈义林,秦勇,李久庆,等. 地球上最大天然碳洋葱的发现[J]. 中国科学:地球科学,2022,52(9):1785−1799

CHEN Yilin,QIN Yong,LI Jiuqing,et al. Discovery of the largest natural carbon onions on Earth[J]. Science China:Earth Sciences,2022,52(9):1785−1799

[52] CANÇADO L G,TAKAI K,ENOKI T,et al. Measuring the degree of stacking order in graphite by Raman spectroscopy[J]. Carbon,2008,46(2):272−275.

[53] SADEZKY A,MUCKENHUBER H,GROTHE H,et al. Raman microspectroscopy of soot and related carbonaceous materials:Spectral analysis and structural information[J]. Carbon,2005,43(8):1731−1742.

[54] TUINSTRA F,KOENIG J L. Raman spectrum of graphite[J]. The Journal of Chemical Physics,1970,53(3):1126−1130.

[55] FERRARI A C,ROBERTSON J. Interpretation of Raman spectra of disordered and amorphous carbon[J]. Physical Review B,2000,61(20):14095−14107.

[56] NEGRI F,CASTIGLIONI C,TOMMASINI M,et al. A computational study of the Raman spectra of large polycyclic aromatic hydrocarbons:Toward molecularly defined subunits of graphite[J]. The Journal of Physical Chemistry A,2002,106(14):3306−3317.

[57] 束振宇,徐祥,魏迎春,等. 不同类型接触变质煤大分子结构差异性研究[J]. 煤炭科学技术,2023,51(6):147−157

SHU Zhenyu,XU Xiang,WEI Yingchun,et al. Study on macromolecular structure of different types of contact metamorphic coals[J]. Coal Science and Technology,2023,51(6):147−157

[58] SOBKOWIAK M,PAINTER P. Determination of the aliphatic and aromatic CH contents of coals by FT–i. r. :Studies of coal extracts[J]. Fuel,1992,71(10):1105−1125.

[59] LI Wu,ZHU Yanming,WANG G,et al. Characterization of coalification jumps during high rank coal chemical structure evolution[J]. Fuel,2016,185:298−304.

[60] 王绍清,沙吉顿,张浩,等. 热接触变质煤制备石墨烯:化学结构演化[J]. 煤炭科学技术,2021,49(2):238−244

WANG Shaoqing,SHA Jidun,ZHANG Hao,et al. Graphene produced by thermally–altered coal:Chemical structure evolution[J]. Coal Science and Technology,2021,49(2):238−244

[61] 唐跃刚,陈鹏翔,李瑞青,等. 京西煤制备氧化石墨烯分子结构模型的构建与优化[J]. 煤炭科学技术,2021,49(6):126−134

TANG Yuegang,CHEN Pengxiang,LI Ruiqing,et al. Model construction and optimization of molecule structure of coal–based grapheme oxide from Jingxi coal[J]. Coal Science and Technology,2021,49(6):126−134

[62] HAN Yuzhen,WANG Jin,DONG Yijing,et al. The role of structure defects in the deformation of anthracite and their influence on the macromolecular structure[J]. Fuel,2017,206:1−9.

[63] HAN Yuzhen,XU Rongting,HOU Quanlin,et al. Deformation mechanisms and macromolecular structure response of anthracite under different stress[J]. Energy & Fuels,2016,30(2):975−983.

[64] 郭德勇,郭晓洁,李德全. 构造变形对烟煤级构造煤微孔–中孔的作用[J]. 煤炭学报,2019,44(10):3135−3144

GUO Deyong,GUO Xiaojie,LI Dequan. Effects of tectonic deformation on micropore–mesopore of bituminous deformed coal[J]. Journal of China Coal Society,2019,44(10):3135−3144

Download Chinese Version

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.