[2] Pickles C A, Gao F, Kelebek S. Microwave drying of a low-rank sub-bituminous coal ［J］. Minerals Engineering, 2014, 62: 31-42.

[7] Silva A S V, Weinschutz R, Yamamoto C I, et al. Catalytic cracking of light gas oil using microwaves as energy source ［J］. Fuel, 2013, 106: 632-638.

[8] Madriz L, Carrero H, Dominguez J R, et al. Catalytic hydrotreatment in reverse microemulsions under microwave irradiation ［J］. Fuel, 2013, 112: 338-346.

[9] Shang H, Zhang H C, Du W, et al. Development of microwave assisted oxidative desulfurization of petroleum oils:A review ［J］. Journal of Industrial and Engineering Chemistry, 2013, 19: 1426-1432.

[10] Shang H, Du W, Liu Z C, et al. Development of microwave induced hydrodesulfurization of petroleum streams: A review ［J］. Journal of Industrial and Engineering Chemistry, 2013, 19: 1061-1068.

[11] Xia W C, Yang J G, Liang C. Effect of microwave pretreatment on oxidized coal flotation ［J］. Powder Technology, 2013, 233: 186-189.

[12] Ge L C, Zhang Y W, Wang Z H, et al. Effects of microwave irradiation treatment on physicochemical characteristics of Chinese low-rank coals ［J］. Energy Conversion and Management, 2013, 71: 84-91.

[13] Bardajee G R. Microwave-assisted solvent-free synthesis of fluorescent naphthalimide dyes ［J］. Dyes and Pigments, 2013, 99: 52-58.

[18] Ding J N, Kan B, Yuan N Y, et al. The effect of external electric fields on the electronic structure of (5,5)/(10,0) metal-semiconductor single wall carbon nanotube intramolecule junction ［J］. Physica E, 2010, 42: 1590-1596.

[19] Zhang S L, Zhang Y H, Huang S P, et al. Theoretical investigation of electronic structure and field emission properties of carbon nanotube-ZnO nanocontacts ［J］. Carbon, 2011, 49: 3835-3841.

[20] Surya V J, Iyakutti K, Mizuseki H, et al. First principles study on desorption of chemisorbed hydrogen atoms from single-walled carbon nanotubes under external electric field ［J］. International Journal of Hydrogen Energy, 2011, 36: 13645-13656.

[21] Zhang Z, Wang J Y, Ning M, et al. Field ionization effect on hydrogen adsorption over TiO2-coated activated carbon ［J］. International Journal of Hydrogen Energy, 2012, 37: 16018-16024.

[22] Liu W, Zhao Y H, Li Y, et al. A reversible switch for hydrogen adsorption and desorption: Electric fields ［J］. Physical Chemistry Chemical Physics, 2009, 11: 9233-9240.

[23] Shtogun Y V, Woods L M. Electronic structure modulations of radially deformed single wall carbon nanotubes under transverse external electric fields ［J］. Journal of Physical Chemistry C, 2009, 113: 4792-4796.

[24] Kan B, Ding J, Yuan N, et al. Transverse electric field-induced deformaton of armchair single-walled carbon nanotube ［J］. Nanoscale Research Letters, 2010, 5: 1144-1149.

[25] Ehinon D, Baraille I, Rérat M. Polariabilities of carbon nanotubes: Importance of the crystalline orbitals relaxation in presence of an electric field ［J］. International Journal of Quantum Chemistry, 2011, 111(4): 797-806.

[26] Liu W, Zhao Y H, Nguyen J, et al. Electric field induced reversible switch in hydrogen storage based on single-layer and bilayer graphemes ［J］. Carbon, 2009, 47(15): 3452-3460.

[27] Shi S, Hwang J Y, Li X, et al. Enhanced hydrogen sorption on carbonaceous sorbents under electric field ［J］. International Journal of Hydrogen Energy, 2010, 35(2): 629-631.

[28] Zhou J, Wang Q, Sun Q, et al. Electric field enhanced hydrogen storage on polarizable materials substrates ［C］. Proceedings of the National Academy of Sciences, 2010, 107(7): 2801-2806.

[29] Coelho R R, Hovell I, Rajagopal K. Elucidation of the functional sulphur chemical structure in asphaltenes using first principles and deconvolution of mid-infrared vibrational spectra ［J］. Fuel Processing Technology, 2012, 97: 85-92.