[1] Ullah, R., Bai, P., Wu, P., Liu, B., Subhan, F., Yan, Z., "Cation–anion double hydrolysis derived mesoporous mixed oxides for reactive adsorption desulfurization", J. Microporous Mesoporous Mater, 238: pp. 36–45, (2017).
[2] Tang, W., Gu, J., Huang, H., Liu, D., Zhong, C., "Metal‐organic frameworks for highly efficient adsorption of dibenzothiophene from liquid fuels", J. AIChE, 62, 12, pp. 4491-4496, (2016).
[3] Ania, C. O., Bandosz, T. J., "Importance of structural and chemical heterogeneity of activated carbon surfaces for adsorption of dibenzothiophene", J. Langmuir, 21, 17, pp. 7752-7759, (2005).
[4] Zhu, W., Wu, P., Chao, Y., Li, H., Zou, F., Xun, S., Fengxia, Zh., Zhen, Zh., "A novel reaction-controlled foamtype polyoxometalate catalyst for deep oxidative desulfurization of fuels", J. Ind. Eng. Chem. Res., 52, 49, pp. 17399-17406, (2013).
[5] Mitchell, L., "Adsorption of light gases and gas mixtures on zeolites and nanoporous carbons", Vanderbilt University, (2014).
[6] Cosoli, P., Ferrone, M., Pricl, S., Fermeglia, M., "Hydrogen sulphide removal from biogas by zeolite adsorption: Part I. GCMC molecular simulations", Chemical Engineering Journal, 145(1), pp. 86-92, (2008).
[7] Chowanietz, V., Pasel, C., Luckas, M., Bathen, D., "Temperature Dependent Adsorption of Sulfur Components, Water, and Carbon Dioxide on a Silica−Alumina Gel Used in Natural Gas Processing", J. Chem. Eng. Data, (2019).
[8] Steuten, B., Pasel, C., Luckas, M., Bathen, D., "Trace Level Adsorption of Toxic Sulfur Compounds, Carbon Dioxide, and Water from Methane", J. Chem. Eng. Data, 58, pp. 2465−2473, (2013).
[9] Zhang, M., Wang, M., Yang, J., Li, H., Liu, J., Chen, X., Zhu, W., Li, H., "Polyoxometalate-based
silica-supported ionic liquids for heterogeneous oxidative desulfurization in fuels",
Petroleum Science, 15, pp. 882–889, (2018).
[10] Tavassoli, N., Ansaria, R., Mosayebzadeh, Z., "Synthesis and Application of Iron Oxide/Silica Gel Nanocomposite for Removal of Sulfur Dyes from Aqueous Solutions", Arch Hyg Sci, 6(2):
pp. 214-220, (2017).
[11] Cosoli, P., Ferrone, M., Pricl, S., Fermeglia, M., "Hydrogen sulfide removal from biogas by zeolite adsorption. Part II. MD simulations", Chemical Engineering Journal, 145(1), pp. 93-99, (2008).
[12] Yang, R. T., Takahashi, A., Yang, F. H., "New Sorbents for Desulfurization of Liquid Fuels by
π- Complexation", Ind. Eng. Chem. Res, (2001).
[13] Garcia, C. L., Lercher, J. A., "Adsorption of H2S on ZSM-5 zeolites", Phys. Chem, pp. 2230-2235, (1992).
[14] Barzaminia, R., Falamakib, C., Mahmoudia, R., "Adsorption of ethyl, iso-propyl, n-butyl and
iso-butyl mercaptans on AgX zeolite: Equilibrium and kinetic study", J. Fuel, pp. 46-53, (2014).
[15] Xiang, H., Zhang, H., Liu, P., Yan, Y., "Preperation of high puritybPropane from liquefied Petroleum Gas in a fixed Bed by Removal of Sulfur and Butanes", J. chemical engineering, pp. 224-232, (2016).
[16] Rezaei, S., Jarligo, M. O. D., Wu, L., Kuznicki, S. M., "Breakthrough performances of metal-exchanged nanotitanate ETS-2 adsorbents for room temperature desulfurization", J. Chemical Engineering Science, pp. 444-449, (2015).
[17] Micoli, L., Bagnasco, G., Turco, M., "H2S removal from biogas for fuelling MCFCs: New adsorbing materials", international journal of hydrogen energy, pp. 1783-1787, (2014).
[18] Mohammed, A. H. A., Nassrullah, Z. K., "Preparation and Formation of Zeolite 5A from Local Kaolin Clay for Drying and Desuphurization of Liquefied Petroleum Gas", J. Chemical and Petroleum Engineering, 14, pp. 1-13, (2013).
[19] Ratnasamy, C., Wagner, J. P., Spivey, S., Weston, E., "Removal of sulfur compounds from natural gas for fuel cell applications using a sequential bed system", J. Catalysis Today, pp. 233-238, (2012).
[20] Ryzhikov, A., Huleaa, V., Tichit, D., Leroi, C., Anglerot, D., Coq, B., "Methyl mercaptan and carbonyl sulfide traces removal through adsorption and catalysis on zeolites and layered double hydroxides", J. Applied Catalysis A: General.
pp. 218-224, (2011).
[21] Karge, H. G., Rask, J., "Hydrogen Sulfide Adsorption on Faujasite-Type Zeolites with Systematically Varied Si-AI Ratios", J. Colloid and Interface Science, (1977).
[22] Qazvini, O. T., Fatemi, S., "Modeling and Simulation Pressure - Temprature Swing Adsorption Process to Remove mercaptan from Humid Natural Gas, A Commercial Case Study", seperation and purification Technology, pp. 88-103, (2015).
[23] Zhang, X., Wang, R., Yang, X., "Effect of alkaline treatment on pore structure and acidity of HZSM-5 in the synthesis of ethyl mercaptan", Catalysis Communications pp. 32-36, (2015).
[24] Kim, K. M., Oh, H. T., Lim, S. J., Ho, K., Park, Y., Lee, C. H., "Adsorption Equilibria of Water Vapor on Zeolite 3A, Zeolite 13X, and Dealuminated Y Zeolite", Chem. Eng. Data, (2016).
[25] Ozekmekci, M., Salkic, G., Fellah, M. F., "Use of zeolites for the removal of H2S: A mini-review", Fuel Processing Technology, pp. 49-60, (2015).
[26] Yuan, W., Bandosz, T. J., "Removal of hydrogen sulfide from biogas on sludge-derived adsorbents", J. Fuel, pp. 2736-2746, (2007).
[27] Feaver, A., Cao, G., "Activated carbon cryogels for low pressure methane storage", J. Carbon, 44(3),
pp. 590-593, (2006).
[28] Suzuki, M., "Activated carbon fiber: fundamentals and applications", J. Carbon, 32(4), pp. 577-586, (1994).
[29] Jones, C. W., Koros, W. J., "Carbon molecular sieve gas separation membranes-I. Preparation and characterization based on polyimide precursors", J. Carbon, 32(8), pp. 1419-1425, (1997).
[30] Gilani, N., Towfighi, J., Rashidi, A., Mohammadi, T., Omidkhah, M., Sadeghian, S., "Investigation of H2S separation from H2S/CH4 mixtures using functionalized and non-functionalized vertically aligned carbon nanotube membranes", J. Applied Surface Science, (2012).
[31] Khaleghi Abbasabadi, M., Rashidi, A., Khodabakhshi, S., "Benzenesulfonic acid-grafted graphene as a new and green nanoadsorbent in hydrogen sulfide removal", J. Natural Gas Science and Engineering, 28 , pp. 87-94, (2016).
[32] Zhang, X., Tang, Y., Qu, S., Jianwen, D., Hao, Z., "H2S‑Selective Catalytic Oxidation: Catalysts and Processes", catalysis, (2015).
[33] Yan, R., Chin, T., Ng, Y. L., Duan, H., Liang, D. T., Tay, H., "Influence of surface properties on the mechanism of H2S removal by alkaline activated carbons", J. Environmental Science & Technology, pp. 316-323, (2004).
[34] Abatzoglou, N., Boivin, S., "A review of biogas purification processes", Biofuels, Bioproducts and Biorefining, pp. 42-71, (2009).
[35] Tajizadegan, H., "Novel ZnO–Al2O3 composite particles as sorbent for low temperature H2S removal", J. Chinese Chemical Letters, 24(2):
pp. 167-169, (2013).
[36] Blanco-Brieva, G., Campos-Martin, J., Al-Zahrani, S., Fierro, J., "Removal of refractory organic sulfur compounds in fossil fuels using MOF sorbents", J. Global Nest, 12(12), pp. 296-304, (2010).
[37] Barthelet, K., Marrot, J., Riou, D., Ferey, G., "A breathing hybrid organic–inorganic solid with very large pores and high magnetic characteristics", J. Angewandte Chemie, 114(2), pp. 291-294, (2002).
[38] Rowsell, J. L. C., Yaghi, O. M., "Metal organic framework: a new class of porous material",
J. Micropor. Mesopor. Mater, pp. 3-14, (2004).
[39] Li, Y., Wang, L. J., Fan, H. l., Shangguan, J., Wang, H., Mi, J., "Removal of sulfur compounds by a copper-based metal organic framework under ambient conditions", Energy & Fuels, 29(1), pp. 298-304, (2014).
[40] Li, H., Eddaoudi, M., OKeeffe, M., Yaghi, O. M., "Design and synthesis of an exceptionally stable and highly porous metal-organic framework", J. Nature, 402(6759), pp. 276-279, (1999).
[41] Ren, X., Miao, G., Xiao, Z., Ye, F., Li, Z., Wang, H., "Catalytic adsorptive desulfurization of model diesel fuel using TiO2/SBA-15 under mild conditions", J. Fuel, 174, pp. 118-125, (2016).
[42] Tang, M., Zhou, L., Du, M., Lyu, Z., Wen, X. D., Li, X., "A novel reactive adsorption desulfurization Ni/MnO adsorbent and its hydrodesulfurization ability compared with Ni/ZnO", J. Catalysis Communications, 61, pp. 37-40, (2015).
[43] Al-Zuhair, S., Khalil, A., Hassan, M., Abdulrazak, A., Basel, K., Fardoun, A., "Performance evaluation of LPG desulfurization by adsorption for hydrogen production", J. Energy Chemistry, 24(4), pp. 477-484, (2015).
[44] Pourreza, A., Askari, S., Rashidi, A., Seif, A., Kooti, M., "Highly efficient SO3Ag-functionalized
MIL-101(Cr) for adsorptive desulfurization of the gas stream: Experimental and DFT study", Chemical Engineering Journal, (2019).
[46] Liu, J., Wei, Y., Li, P., Zhao, Y., Zou, R., "Selective H2S/CO2 Separation by Metal−Organic Frameworks Based on Chemical-Physical Adsorption", J. Phys. Chem. C, 121, pp. 13249−13255, (2017).
[46] Wang, S., Fan, Y., Jia, X., "Sodium dodecyl sulfate-assisted synthesis of hierarchically porous ZIF-8 particles for removing mercaptan from gasoline", J. Chemical Engineering Journal 256, pp. 14–22, (2014).
[47] Fan, H. L., Shi, R. H., Zhang, Z. R., Zhen, T., Shangguan, J., Mi, J., "Cu-Based Metal−Organic Framework/Activated Carbon Composites for Sulfur Compounds Removal", J. applied surface science, 394: pp. 394-402, (2016).
[48] Chen, G., Tan, S., Koros, W. J., Jones, C. W., "Metal Organic Frameworks for Selective Adsorption of t‑Butyl Mercaptan from Natural Gas", J. American Chemical Society, 29(5): pp. 3312-3321, (2015).
[49] Peralta, D., Chaplais, G., Simon-Masseron, A., Barthelet, K., Pirngruber, G. D., "Metal−Organic Framework Materials for Desulfurization by Adsorption", J. Energy Fuels 26, pp. 4953−4960, (2012).
[50] Saeedirad, R., Taghvaei Ganjali, S., Bazmi, M., Rashidi, A., "Effective mesoporous silica-ZIF-8 nano-adsorbents for adsorptive desulfurization of gas stream", J. the Taiwan Institute of Chemical Engineers 82, pp. 10–22, (2018).
pp. 120866-120903, (2019).
[52] Hamon, L., Serre, C., Devic, T., Loiseau, T., Millange, F., Ferey, G., "Comparative study of hydrogen sulfide adsorption in the MIL-53 (Al, Cr, Fe), MIL-47 (V), MIL-100 (Cr), and MIL-101 (Cr) metal−organic frameworks at room temperature", J. Am. Chem. Soc. 131, pp. 8775–8777, (2009).
[53] Petit, C., Mendoza, B., Bandosz, T. J., "Hydrogen sulfide adsorption on MOFs and MOF/graphite oxide composites", J. Chem Phys Chem. 11, pp. 3678-3684, (2010).
[54] Khan, N. A., Jhung, S. H., "Remarkable adsorption capacity of CuCl2 loaded porous vanadium benzenedicarboxylate for benzothiophene", J. Angew Chem. 124, pp. 1224–1227, (2012).
[55] Lee, S., Lee, T., Kim, D., "Adsorption of hydrogen sulfide from gas streams using the amorphous composite of α-FeOOH and activated carbon powder", J. Ind Eng Chem Res, 56, pp. 3116–3122, (2017).
[56] Pourreza, A., Askari, S., Rashidi, A. M., Seif, A., Kooti, M., "Highly efficient SO3Ag-functionalized MIL-101(Cr) for adsorptive desulfurization of the gas stream: Experimental and DFT study", Chemical Engineering Journal. 363, pp. 73-83, (2019).
[57] Adib, F., Bagreev, A., Bandosz, T. J., "Adsorption/Oxidation of Hydrogen Sulfide on Nitrogen-Containing Activated Carbons", J. Langmuir, 16, pp. 1980-1986, (2000).
[58] Xiao, Y., Wang, S., Wu, D., Yuan, Q., "Experimental and simulation study of hydrogen sulfide adsorption on impregnated activated carbon under anaerobic conditions", J. Hazard. Mater. 153, pp. 1193−1200, (2008).