May 30, 2017 - Tectonic deformation damages the macromolecular structures of coal. No evidence can be found of tectonically deformed coal (TDC) structures ...
May 30, 2017 - Cipher Consulting, 6 Stardust Street, Kenmore, Brisbane, Queensland 4069, Australia. §. School of Earth, Environment and Biology, ...
Aly J. Castellanos S. , Jhoan Toro-Mendoza and Maximo Garcia-Sucre. The Journal of Physical .... Hee Jung Yang , Wan Goo Cho , Soo Nam Park. Journal of ...
May 5, 2018 - usage of giant single crystal of polymer is quite useful to reveal the details ... highly developed Ï-electron conjugate system is related strongly ...
4 days ago - Frontier Research Center for Applied Atomic Sciences, Ibaraki University .... However, the neutron diffraction data were collected using the ...
7 hours ago - The ÎÏ(x) derived for polydiacetylene was found similar to that of the low-molecular-weight model compound having the similar electronically ...
May 15, 2018 - orientation was made for about 2.4 h by shooting the. 183 600 ... dimensional detector, which is covered with Pb and B4C to guard the imaging ...
Sep 13, 2012 - School of Biological and Chemical Sciences, Queen Mary University of London, Mile End Road, London E1 4TN, U.K.. J. Phys. Chem. A , 2012 ...
Masaru Matsuo , Yumiko Takemoto (Nakano) , Rong Zhang , Jun Liu , Ru Chen , and ... Masaru Matsuo , Yuri Sugiura , Tsunehisa Kimura , and Tetsuya Ogita.
Subscriber access provided by Binghamton University | Libraries
Article
Characterization of the chemical structure of tectonically deformed coals Wu Li, Bo Jiang, Tim A Moore, Geoff G. X. Wang, Jie-gang Liu, and Yu Song Energy Fuels, Just Accepted Manuscript • Publication Date (Web): 30 May 2017 Downloaded from http://pubs.acs.org on June 3, 2017
Just Accepted “Just Accepted” manuscripts have been peer-reviewed and accepted for publication. They are posted online prior to technical editing, formatting for publication and author proofing. The American Chemical Society provides “Just Accepted” as a free service to the research community to expedite the dissemination of scientific material as soon as possible after acceptance. “Just Accepted” manuscripts appear in full in PDF format accompanied by an HTML abstract. “Just Accepted” manuscripts have been fully peer reviewed, but should not be considered the official version of record. They are accessible to all readers and citable by the Digital Object Identifier (DOI®). “Just Accepted” is an optional service offered to authors. Therefore, the “Just Accepted” Web site may not include all articles that will be published in the journal. After a manuscript is technically edited and formatted, it will be removed from the “Just Accepted” Web site and published as an ASAP article. Note that technical editing may introduce minor changes to the manuscript text and/or graphics which could affect content, and all legal disclaimers and ethical guidelines that apply to the journal pertain. ACS cannot be held responsible for errors or consequences arising from the use of information contained in these “Just Accepted” manuscripts.
Tectonic deformation can cause significant changes in the physical and chemical structures of coal.1 Tectonically deformed coal (TDC), defined as coal affected by
superimposed reformations caused by tectonic stress, is also called deformed coal and
is characterized by tectonically induced features, notably a granular or mylonitic texture.2 Primary coal is defined as coal with primary structure and no influence from
tectonic stress. Because of structural deformation, TDC is distinctly different from
primary coal in terms of macro-coal lithotypes, banded structure, fracture type, and
the degree of crumpling and fragmentation. On the whole, the primary structure and
bedding of coal that has been tectonically deformed is destroyed; the coal is most often sheared and displays a directional arrangement of grains.3 TDC has been
divided into 3 sequences: the brittle deformation sequence, the ductile deformation sequence, and the brittle-ductile transition deformation sequence.4 Locally, abnormal
thickening of a shear zone and extensive compressive structures where ductile fabrics frequently occur are closely related with the site of coal and gas outbursts.5 China will continue to be one of the largest coal producers and users in the world.6 TDC is
currently extracted from structurally complex areas in the eastern part of China, where
it formed as a result of superimposed tectonic stresses of different types having
different orientations. As a result, the formation of the coal and coalbed methane in eastern China is complicated.2 Previous studies have considered tectonic deformation
and the microstructure of the TDC to be important factors that cause coal gas outburst.5, 7-8 The results show that the outbursts are associated in many places with
anthracite and are found in association with such deformational and depositional
structures as folds, faults, rolls and slips; the outbursts are particularly common anywhere there are rapid fluctuations in the seam thickness.7
Tectonic deformation will damage the macrostructure and impact the macromolecular structures of coal.9 Tectonic deformation has also been linked, in rare
cases, to enhancement of rank, especially where shear stresses and thermal effects from frictional heating along thrust faults are found.10 It has been shown that “easy-slip” deformation is responsible for the enhanced deformation of coal seams.11
The nanoscale structure and the variations in the characteristics of closed pores in coal under tectonic deformation have also been investigated by many researchers.12-15
Tectonic deformation can also have an important influence on the macromolecular
small-angle neutron scattering (SANS), scanning electron microscopy (SEM),
transmission electron microscopy (TEM), XRD, Raman, FTIR, and NMR, as well as others.18 Based on SAXS, SANS, SEM, and TEM, much research has focused on the physical structure, particularly the pore structure, of TDCs.12 However, very few
attempts have been made to characterize the chemical structure of TDCs, especially
the deformation mechanism of the TDCs, using those methods.
It is generally accepted that the main microscopic deformation mechanisms seen
in ductile mylonite in rock involve lattice defects and recrystallization caused by
lattice slip. However, there is no evidence found within TDC structures that indicates
traces of lattice defects. In this study, a series of samples from one location that goes
from unaffected samples to highly deformed samples were collected. The ductile
deformation mechanisms of coal will be investigated in TDC samples using structural
characterization methods and by examining the evolution of the molecular structure.
The study will explore how coal is deformed and what kind of macromolecular
structure parameter-related information can be derived from ductile deformation.
2. Methods and Experiments
2.1 Geological Setting
The coals investigated in this study were collected from the Qinan Coal Mine,
which is located in the southern part of Huaibei coalfield and covers an area of 55 km2. The Permo-Carboniferous Huaibei Coalfield of the North China plate, which is
located in the northern part of Anhui province, China, is one of the major coalfields in China and contains 23 active underground coal mines.19 It is in the Xu–Su depression
in the central-southern Luxi–Xuhuai uplift. The Lower Shihezi Formation is a delta
plain deposit, which is regionally distributed and conformable with the underlying Shanxi Formation.20 A major coal-bearing stratum, approximately 250 m thick on
average, contains coal seams Nos. 4, 5, 6, 7, 8 and 9. The coal seams occur at
relatively shallow depths, due to the strong tectonic deformation that led to the
development of the TDCs. Of note, the movement of the NW-trending Xisipo normal
fault and the formation of the Sunan syncline has caused the texture of the coal to be severely disrupted.2
2.2 Samples
To avoid influences of other factors that may affect coal deformation, several
coal samples N20, N24-2, N25, N26-1, N27 and N32 were collected from the face of
the No. 6 coalbed in the Qinan Coal Mine in the Huaibei Coalfield of China,
following Chinese Standard Method GB/T 482-2008. The sampling position is
located in the No. 6125 coal face (Figure 1), where there is a thrust fault. Sample N25
were collected from the hanging wall of the fault, while samples N24-2, N26-1, and
N27 were collected from the footwall (Figure 2). The final maceral analysis data from
Raman spectrometer include a wavelength of 532 nm, a power of 5 mV, an integration time of 2 s, and a resolution of 9-18 cm-1. Each measurement was repeated 10 times.
3. RESULTS AND DISCUSSION
3.1 Raman spectra The coal samples all show two characteristic peaks that appear at ~1360 cm-1 (D peak) and ~1590 cm-1 (G peak) in the first-order Raman spectra. The G band is higher
than the D2 band, implying that graphite-like structures dominate over turbostratic structures.21 The D band position wave numbers of brittle deformed coal samples N20 and N27 are 1345 cm-1 and 1342 cm-1, which is smaller than those of ductile
deformed coal. This was considered to result from the resonance effect involved in Raman scattering from carbons.22 The G band of the coal is a result of aromatic ring quadrant breathing with contributions from graphitic structures.23 Many disordered
and amorphous carbons are also indicated by additional peaks appearing at ~1180 (D4), ~1500 (D3), and ~1620 cm-1 (D2), which are related to sp3 carbon, amorphous
carbon, and disordered carbon, respectively. The D3 band was further studied as a way to evaluate the amorphous carbon in the coal samples.24
coal (N24-2, N25, N26-1) is greater than that of the brittle deformation coal (N20,
N27) as a result of its high content of defects in the graphitic structures, as observed
in Figure 5. In this case, the D1 FWHM is in good agreement with the ductile
deformation, even though the differences relative to the G FWHM are not statistically
significant. One possible reason is that, during the process of ductile deformation,
mechanical energy transforms into strain energy, and the strain energy is released via
the rotation of C−C bonds, which produces defects. Then, the stress may finally
fragment the macromolecular structure by breaking the defect structure and old bonds and forming new bonds.25-26 Another possible reason is that the ID/IG ratio in coal
samples N25 and N27 (0.8861 and 0.8298, respectively; Table 2). An increase in ID/IG
indicates the growth of basic graphene structural units (BSUs). Ductile deformation leads to changes in carbon structure.22
Figure 5 Comparison of Raman parameters: (a) the height ratio of D1 to G (ID1/IG); (b)
the area ratio of D1 to G (AD1/AG); (c) D1 FWHM; and (d) G FWHM.
3.2 FTIR
Figure 6 shows the FTIR spectra of five coal samples which were determined to
have undergone deformation (samples N20, N24-2, N25, N26-1, N27) and one
primary structure coal (i.e. coal with no deformation; sample N32). These samples
displayed similar patterns as a result of the small organic functional groups in the coal
structure and because the coal samples were collected from one tectonic position. The broad band near 3400 cm-1 in all spectra, which indicates that the ductile deformation
coal has oxygen-containing functional groups and secondary bonding within its
structure, the result of O-H and N-H stretching. The peak at 3040 cm-1 is related to aromatic sp2-bonded C−H stretching. These coals contain aliphatic structures in the region of 3000−2800 cm−1,
indicating strong aliphatic C-H stretching. The coal samples exhibited bands at 2920 cm-1 and 2850 cm-1, which could be assigned to symmetric stretching vibrations and asymmetric stretching vibrations of -CH2- methylene groups, respectively.23 In addition, the intensity of the peak at 2920 cm-1 was greater than the intensity of the peak at 2850 cm-1, indicating the presence of long aliphatic chains in the ductile
deformation coal and the primary structure coal. As observed in the FTIR of ductile deformation coal, the absorption at 1700-1735 cm-1 is very weak, which may be due
to carbonyl (C=O) groups. Compared with the carbonyl group intensity of ductile
deformation coal, the primary structure coal represented by sample N32 exhibits a
higher absorption band intensity. The coal sample N32 has probably more
oxygen-containing functional groups in its structure because of its low degree of
coalification, while ductile deformation coals have less oxygen-containing functional
groups as a result of ductile deformation. The peak related to the stretching vibration
of the aromatic C=C band is of moderate intensity and occurs at approximately 1620 cm-1. The absorption of the asymmetric bending of -CH3 and symmetric bending of -CH2- is centered at 1444 cm-1 decrease with temperature. Bands were observed between 900 and 700 cm-1 regions in all the samples, which may be attributable to the
aromatic C-H out-of-plane bending vibrations.
Figure 6 FTIR spectra of coal samples.
Figure 7 XRD patterns of coal samples.
The coal samples that have experienced strong ductile deformation, N24-2, N25
and N26-1, which were all collected close to the fault, display less aromatic C=C
band stretching vibration. Noticeable differences were observed in the intensity of
(N32) and the brittle deformation coal samples (N20, N27) show greater aromatic
C=C band stretching than the ductile deformation coals. As evidenced by the higher
intensity of the C=C band in samples N32, N20, and N27, ductile deformation can
lead to the breaking of the C=C functional groups. The greater intensity of the C=O
band in sample N32 than in samples N20 and N27 indicates that brittle deformation
must cause the decrease in oxygen-containing functional groups. The spectral region at 3000−2800 cm−1, which represents aliphatic C−H stretching, was curve-fitted to derive A2920 cm−1 and A2950 cm−1 for calculation of the CH2/CH3 ratio. The spectral region at 1800−1000 cm−1, representing C=O and C =C bending, was then curve-fitted to derive A1800−1650 cm−1, A1650−1520 cm−1, A3000−2800 cm−1, and A1800−1520 cm−1 to calculate the A factor (3000-2800 cm-1/3000−2800 cm-1 + 1650−1520 cm-1) and C factor (1800−1650 cm-1/1800−1650 cm-1 + 1650−1520 cm-1), which represents the intensity of aliphatic relative to
aromatic peaks, as well as the Al/C=C, Al/OX, Aar/Aal, and C=O/C=C ratios. The
Information on interlayer spacing, stacking height and distance between
crystallite units can be investigated by XRD with a careful assignment of the peak positions, FWHM values, and intensities of the diffraction peaks.27-28 Figure 7 shows
the XRD curves with peak characteristics for the six coal samples. The peak (002) is
located at a 2θ equal to 25° reflection and is called the π-band, and the (10) band was near 40°.23 The intensities of the (002) peaks for the six coal samples are similar. The
spectra exhibit peaks at 20°, 35°, and 38°. In contrast, peaks at ~30° appeared in
samples N25, 26-1, and N27. This is possibly the result of deformation, as reflected in
the coal samples. In addition, sample N24-2 displays two new diffraction peaks at 47°
and 48°. The (002) band is correlated with the stacking of aromatic layers. Theoretically, the (002) band is symmetric and sharp.29
The interlayer spacing of aromatic ring layers (d002) and average stacking height
(Lc) values of the coals are presented in Table 4. For these coal samples, the d002
values varied from 3.42 to 3.55, indicating a low degree of ordered crystallite units
with respect to pure graphite (3.36-3.37). The Lc values of the tectonically deformed
coal samples and primary structure coal samples ranged from 20.35 to 26.52 and
90-130 ppm for protonated aromatic C−H, and 130-165 ppm for non-protonated aromatic C−C.30 There is no remarkable difference in the patterns of the NMR spectra
for the coal samples studied (Figure 8). The peaks at 154 ppm, 140 ppm, and 15 ppm
are shoulder peaks, and the 15 ppm peaks are not obvious in samples N24-2, N25,
N26-1, and N27. The aromaticity value of samples N20, N24-2, N25, N26-1, N27,
and N32 is approximately 0.67 (Table 5). The contents of alkylated aromatic carbons (faS) were higher than those of bridged aromatic carbon (faB) in the TDCs, indicating
that the contents of monocyclic aromatic structures were greater than those of polycyclic aromatic structures.31 The ratio of aromatic bridge carbon to aromatic
peripheral carbon (XBP) of naphthalene, which has two condensed aromatic rings, is
0.25. The XBP values of the TDCs were less than 0.24, indicating two rings.
bonds. Figure 9 shows that the Aar/Aal value of sample N20 is highest, and sample
N25 (located in the shear zone) has the maximum ID1/IG value. The former implies
that coal sample N20 contains more aromatic carbon structures, while the latter means
there are more defects in coal sample N25. Normally, the change in Lc in the TDCs
displaying ductile deformation is greater than the TDCs showing brittle deformation.17 Brittle deformation could alter the macromolecular structure of coal and can enhance coal metamorphism to a certain degree.32
Figure 9 Structure parameters of six samples.
Ductile deformed coals are thought to have formed through point defect
dislocations of single carbon atoms. Brittlely deformed coals are caused by line defects and stacking faults involving many carbon atoms.33 The defect types seen in
the molecules of carbon materials (e.g., graphene) include one-dimensional lines of defects and point defects.34 The difference between ductile and brittle deformation is
tectonic behavior, which is influenced by stress type, stress direction, temperature and
strain rate. It has been shown by the Raman results that the tectonic deformation is
probably a result of macromolecular defects. The defects have been strongly
influenced by factors such as stress, time, temperature and Td (the minimum energy
which has to be transferred to a carbon atom to cause it to leave its lattice position
without immediate recombination with the vacancy). Some bonds have been stretched,
while others may have been compressed.
As noted in Table 3, the content of C=O functional groups in TDCs is higher
than in the coal with primary structure. It has been reported that one mode of CO
generation is through the breaking of chemical bonds (one carbonyl) within the molecular structures of coal.26 Hence, it can be concluded that defects may be easily
formed by the breaking of C=O bonds in coal macromolecules, given that the
maximum energy of broken C=O bonds is less. Strain energy can promote
deformation and breakage of the coal’s molecular units.
Mechanism model of coal deformations. As illustrated in Figure 10, brittle coal
structure, which shows continuous bending deformation characteristics, may be
broken with development of some macropore and mesopores, However, the ductile
deformation of coal structure is a process of plastic deformation acting on successive
bedding. In summary, ductile deformation is related to the growth of defects as a
result of shear stress, while brittle deformation is related to a series of bonds broken
because of tensile stress. Thus, tectonic deformation plays an important role in the
ultrastructure of coal. Because tectonic deformation not only transforms the
macrostructure of coal and enhances the degree of coal deformation, but also slightly
improves the degree of coal metamorphism and significantly affects the macromolecular structures of coal.18 The secondary structural defect can make ductile
Dai, S.; Ren, D.; Chou, C. L.; Finkelman, R. B.; Seredin, V. V.; Zhou, Y.,
Geochemistry of trace elements in Chinese coals: A review of abundances, genetic types, impacts on human health, and industrial utilization. International Journal of Coal Geology 2012, 94 (3), 3-21. 7.
Cao, Y.; He, D.; Glick, D. C., Coal and gas outbursts in footwalls of reverse faults.
International Journal of Coal Geology 2001, 48 (1–2), 47-63. 8.
Cao, D.; Li, X.; Zhang, S., Influence of tectonic stress on coalification: Stress
degradation mechanism and stress polycondensation mechanism. Science in China Series D: Earth Sciences 2007, 50 (1), 43-54. 9.
of Chinese tectonically deformed coal studied by atomic force microscopy. Fuel 2015, 139, 94-101. 10.
Fowler, P.; Gayer, R. A., The association between tectonic deformation, inorganic
composition and coal rank in the bituminous coals from the South Wales coalfield, United Kingdom. International Journal of Coal Geology 1999, 42 (1), 1-31. 11.
Frodsham, K.; Gayer, R. A., The impact of tectonic deformation upon coal seams in
the South Wales coalfield, UK. International Journal of Coal Geology 1999, 38 (3–4), 297-332. 12.
Pan, J.; Niu, Q.; Wang, K.; Shi, X.; Li, M., The closed pores of tectonically
deformed coal studied by small-angle X-ray scattering and liquid nitrogen adsorption. Microporous and Mesoporous Materials 2016, 224, 245-252. 13.
Pan, J.; Zhao, Y.; Hou, Q.; Jin, Y., Nanoscale Pores in Coal Related to Coal Rank
and Deformation Structures. Transport in Porous Media 2015, 107 (2), 543-554. 14.
Li, W.; Liu, H.; Song, X., Multifractal analysis of Hg pore size distributions of
tectonically deformed coals. International Journal of Coal Geology 2015, 144-145, 138-152. 15.
Qu, Z.; Wang, G. G. X.; Jiang, B.; Rudolph, V.; Dou, X.; Li, M., Experimental Study
on the Porous Structure and Compressibility of Tectonized Coals. Energy & Fuels 2010, 24 (5), 2964-2973. 16.
study of the macromolecular structures of tectonically deformed coal using high-resolution transmission electron microscopy. Journal of Natural Gas Science and Engineering 2015, 27, 1852-1862.
Ju, Y.; Jiang, B.; Hou, Q.; Wang, G.; Ni, S., 13C NMR spectra of tectonic coals and
the effects of stress on structural components. Science in China Series D 2005, 48 (9), 1418-1437. 18.
Pan, J.; Lv, M.; Bai, H.; Hou, Q.; Li, M.; Wang, Z., Effects of Metamorphism and
Deformation on the Coal Macromolecular Structure by Laser Raman Spectroscopy. Energy & Fuels 2017, 31 (2), 1136-1146. 19.
Zheng, L.; Liu, G.; Qi, C.; Zhang, Y.; Wong, M., The use of sequential extraction to
determine the distribution and modes of occurrence of mercury in Permian Huaibei coal, Anhui Province, China. International Journal of Coal Geology 2008, 73 (2), 139-155. 20.
evolution of tectonically deformed coal of different deformation mechanisms. Science China Earth Sciences 2012, 55 (8), 1269-1279. 21.
Smȩdowski, Ł.; Krzesińska, M.; Kwaśny, W.; Kozanecki, M., Development of
Ordered Structures in the High-Temperature (HT) Cokes from Binary and Ternary Coal Blends Studied by Means of X-ray Diffraction and Raman Spectroscopy. Energy & Fuels 2011, 25 (7), 3142-3149. 22.
Dong, S.; Alvarez, P.; Paterson, N.; Dugwell, D. R.; Kandiyoti, R., Study on the
Effect of Heat Treatment and Gasification on the Carbon Structure of Coal Chars and Metallurgical Cokes using Fourier Transform Raman Spectroscopy. Energy & Fuels 2009, 23 (3), 1651-1661. 23.
Baysal, M.; Yürüm, A.; Yıldız, B.; Yürüm, Y., Structure of some western Anatolia
coals investigated by FTIR, Raman, 13C solid state NMR spectroscopy and X-ray diffraction. International Journal of Coal Geology 2016, 163, 166-176. 24.
Seong, H. J.; Boehman, A. L., Evaluation of Raman Parameters Using Visible
Raman Microscopy for Soot Oxidative Reactivity. Energy & Fuels 2013, 27 (3), 1613-1624. 25.
average polycyclic aromatic unit in Ledo coal. Journal of Applied Crystallography 2008, 41 (1), 27-30. 29.
Li, M.; Zeng, F.; Chang, H.; Xu, B.; Wang, W., Aggregate structure evolution of
low-rank coals during pyrolysis by in-situ X-ray diffraction. International Journal of Coal Geology 2013, 116-117, 262-269. 30.
Li, W.; Zhu, Y., Structural characteristics of coal vitrinite during pyrolysis. Energy &
Fuels 2014, 28 (6), 3645-3654. 31.
Wang, Q.; Ye, J.-b.; Yang, H.-y.; Liu, Q., Chemical Composition and Structural
Characteristics of Oil Shales and Their Kerogens Using Fourier Transform Infrared (FTIR) Spectroscopy and Solid-State13C Nuclear Magnetic Resonance (NMR). Energy & Fuels 2016, 30, 6271-6280. 32.
Cao, Y.; Mitchell, G. D.; Davis, A.; Wang, D., Deformation metamorphism of
bituminous and anthracite coals from China. International Journal of Coal Geology 2000, 43 (1–4), 227-242. 33.
Tatsumi, N.; Tamasaku, K.; Ito, T.; Sumiya, H., Behavior of crystal defects in
synthetic type-IIa single-crystalline diamond at high temperatures under normal pressure. Journal of Crystal Growth 2017, 458, 27-30. 34.
Banhart, F.; Kotakoski, J.; Krasheninnikov, A. V., Structural Defects in Graphene.
Figure 1 Structural geology and distribution of mining areas in the Qinan Coal Mine, Huaibei coalfield. Shaded area in the inset is the larger area shown to the right. Note the position of the No. 6125 coal face referred to in the text.
Figure 5 Comparison of Raman parameters: (a) the height ratio of D1 to G (ID1/IG); (b) the area ratio of D1 to G (AD1/AG); (c) D1 FWHM; and (d) G FWHM.
