纳米多级孔分子筛:简短的综述(英文)
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摘要
分子筛是一种三维微孔结构的硅铝酸盐晶体,具有灵活多变的骨架和组成、较高的物理和水热稳定性、无毒、高比表面积、离子可交换性以及很低的成本等特点,因而在油品精制、石油化学、农业、水和污水处理等众多领域中用作离子交换剂、催化剂和吸附剂.尽管分子筛的应用是基于其本身的微孔结构,但微孔也导致体积较大的反应物和产物分子的传质阻力高.通过制备纳米尺度和多级孔结构的分子筛等多种手段可克服常规分子筛所具有的传质限制.人们已经开发了多种方法制备了新型的分子筛材料,并考察了它们在各种催化反应和吸附反应中的性能.在反应体系中采用这种多级孔的纳米分子筛,有可能提高催化剂的使用寿命和催化性能,抑制积碳和失活.本综述概述了多级孔分子筛和纳米分子筛的高性能及其合成方法的最新进展,讨论了每个合成方法的优缺点,简述了纳米分子筛和二级孔结构分子筛的催化应用,并与常规分子筛进行了比较.
Zeolites are crystalline aluminosilicates with three-dimensional microporous structures. They have been used as ion-exchangers, catalysts, and adsorbents in various fields such as oil refining, petrochemistry,agriculture, and water and wastewater treatment. Their wide use is because of their many beneficial properties, such as framework and compositional flexibilities, physical and hydrothermal stabilities, non-toxicity, high surface areas, exchangeable cations, and good cost-benefit ratios. Although many zeolite applications depend on their microporous structures, this can cause diffusional constraints for bulky reactant and product molecules. There have been many efforts to overcome the intrinsic limitations of conventional zeolites by preparing nanosized and hierarchically structured zeolites. As a result of these efforts, several strategies have been established and the use of new zeolitic materials in various catalytic and adsorptive reactions has been investigated.Longer lifetimes, high catalytic performances, and postponed coking and catalyst deactivation can be achieved using hierarchical and nanosized zeolites. The aim of this review is to provide an overview of the enhanced properties of hierarchical and nanosized zeolites, and recent development methods for their synthesis. The advantages and disadvantages of each route are discussed, and the catalytic applications of nanozeolites and zeolites with secondary porosity, and a comparison with conventional zeolites, are briefly presented.
Zeolites are crystalline aluminosilicates with three-dimensional microporous structures. They have been used as ion-exchangers, catalysts, and adsorbents in various fields such as oil refining, petrochemistry,agriculture, and water and wastewater treatment. Their wide use is because of their many beneficial properties, such as framework and compositional flexibilities, physical and hydrothermal stabilities, non-toxicity, high surface areas, exchangeable cations, and good cost-benefit ratios. Although many zeolite applications depend on their microporous structures, this can cause diffusional constraints for bulky reactant and product molecules. There have been many efforts to overcome the intrinsic limitations of conventional zeolites by preparing nanosized and hierarchically structured zeolites. As a result of these efforts, several strategies have been established and the use of new zeolitic materials in various catalytic and adsorptive reactions has been investigated.Longer lifetimes, high catalytic performances, and postponed coking and catalyst deactivation can be achieved using hierarchical and nanosized zeolites. The aim of this review is to provide an overview of the enhanced properties of hierarchical and nanosized zeolites, and recent development methods for their synthesis. The advantages and disadvantages of each route are discussed, and the catalytic applications of nanozeolites and zeolites with secondary porosity, and a comparison with conventional zeolites, are briefly presented.
引文
[1]S.Kulprathipanja,Zeolites in Industrial Separation and Catalysis,Wiley‐VCH,Weinheim,2010.
[2]M.Anbia,A.Habibi Davijani,Chem.Eng.J.,2013,223,899–907.
[3]Z.P.Wang,J.H.Yu,R.R.Xu,Chem.Soc.Rev.,2012,41,1729–1741.
[4]M.Anbia,F.Mohammadi Nejati,M.Jahangiri,A.Eskandari,V.Garshasbi,J.Sci.I.R.Iran,2015,26(3),213–222.
[5]M.Anbia,Z.Parvin,Chem.Eng.Res.Des.,2011,89,641–647.
[6]F.Bandarchian,M.J.Anbia,Nat.Gas Sci.Eng.,2015,26,1380–1387.
[7]C.Martínez,J.Perez‐Pariente,Zeolites and Ordered Porous Solids:Fundamentals and Applications,Editorial Universitat Politècnica de València,Madrid,2011.
[8]R.M.Mohamed,H.M.Aly,M.F.El‐Shahat,I.A.Ibrahim,Microporous Mesoporous Mater.,2005,79,7–12.
[9]M.Moliner,F.Rey,A.Corma,Angew.Chem.Int.Ed.,2013,52,13880–13889.
[10]B.Liu,Y.H.Zheng,N.Hu,T.Gui,Y.Q.Li,F.Zhang,R.F.Zhou,X.S.Chen,H.Kita,Microporous Mesoporous Mater.,2014,196,270–276.
[11]H.Y.Zhang,B.Xie,X.J.Meng,U.Müller,B.Yilmaz,M.Feyen,S.Maurer,H.Gies,T.Tatsumi,X.H.Bao,W.P.Zhang,D.De Vos,F.S.Xiao,Microporous Mesoporous Mater.,2013,180,123–129.
[12]W.J.Roth,J.Cjka,Catal.Sci.Technol.,2011,1,43–53.
[13]A.W.Chester,E.G.Derouane,Zeolite Characterization and Catalysis,Springer,New York,2009.
[14]P.Misaelides,Microporous Mesoporous Mater.,2011,144,15–18.
[15]Y.I.Tarasevich,V.V.Goncharuk,V.E.Polyakov,D.A.Krysenko,Z.G.Ivanova,E.V.Aksenenko,M.Yu.Tryfonova,J.Ind.Eng.Chem.,2012,18,1438–1440.
[16]A.C.de Campos Bernardi,P.P.A.Oliviera,M.B.de Melo Monte,F.Souza‐Barros,Microporous Mesoporous Mater.,2013,167,16–21.
[17]M.W.Ackley,S.U.Rege,H.Saxena,Microporous Mesoporous Mater.,2003,61,25–42.
[18]D.Papaioannou,P.D.Katsoulos,N.Panousis,H.Karatzias,Microporous Mesoporous Mater.,2005,84,161–170.
[19]Y.Li,J.H.Yu,Chem.Rev.,2014,114,7268–7316.
[20]A.Seidel,M.Bickford,Kirk‐Othmer Encyclopedia of Chemical Technology,John Wiley&Sons,Inc.,Hoboken,2013.
[21]D.Serrano,J.Aguado,J.Escola,in:J.J.Spivey,Y.F.Han,K.M.Dooley eds,Catalysis,Vol.23,RSC Publishing,Cambridge,2011,53.
[22]M.Anbia,M.Lashgari,Chem.Eng.J.,2009,150,555–560.
[23]R.Chal,C.Gérardin,M.Bulut,S.van Donk,ChemCatChem,2011,3,67–81.
[24]L.Tosheva,V.P.Valtchev,Chem.Mater.,2005,17,2494–2513.
[25]M.Zaarour,B.Dong,I.Naydenova,R.Retoux,S.Mintova,Microporous Mesoporous Mater.,2014,189,11–21.
[26]V.Valtchev,L.Tosheva,Chem.Rev.,2013,113,6734–6760.
[27]K.K.Zhu,J.M.Sun,J.Liu,L.Q.Wang,H.Y.Wan,J.Z.Hu,Y.Wang,C.H.F.Peden,Z.M.Nie,ACS Catal.,2011,1,682–690.
[28]G.T.Vuong,V.T.Hoang,D.T.Nguyen,T.O.Do,Appl.Catal.A,2010,382,231–239..
[29]X.Y.Chen,K.Wendell,J.Zhu,J.L.Li,X.X.Yu,Z.J.Zhang,Bioresour.Technol.,2012,110,79–85.
[30]G.T.Vuong,T.O.Do,J.Am.Chem.Soc.,2007,129,3810–3811.
[31]W.Song,R.E.Justice,C.A.Jones,V.H.Grassian,S.C.Larsen,Langmuir,2004,20,4696–4702.
[32]S.Mintova,J.P.Gilson,V.Valtchev,Nanoscale,2013,5,6693–6703.
[33]L.Burel,A.Tuel,Microporous Mesoporous Mater.,2013,174,90–99.
[34]N.Esmaeili,H.Kazemian,D.Bastani,Iran.J.Chem.Chem.Eng.,2011,30,9–14.
[35]B.Xie,J.W.Song,L.M.Ren,Y.Y.Ji,J.X.Li,F.S.Xiao,Chem.Mater.,2008,20,4533–4535.
[36]G.Reding,T.Maurer,B.Kraushaar‐Czarnetzki,Microporous Mesoporous Mater.,2003,57,83–92.
[37]D.Serrano,J.Aguado,J.Rodriguez,A.Peral,Stud.Surf.Sci.Catal.,2007,170,282–288.
[38]Y.S.Li,W.S.Yang,J.Membrane Sci.,2008,316,3–17.
[39]Z.W.Chen,S.Li,Y.Yan,Chem.Mater.,2005,17,2262–2266.
[40]M.Mehdipourghazi,A.Moheb,H.Kazemian,Microporous Mesoporous Mater.,2010,136,18–24.
[41]Y.Y.Hu,C.Liu,Y.H.Zhang,N.Ren,Y.Tang,Microporous Mesoporous Mater.,2009,119,306–314.
[42]Y.M.Liu,W.Huang,Y.S.Zhao,T.Dou,React.Kinet.Catal.Lett.,2009,96,157–163.
[43]M.Nasrollahzadeh,A.Ehsani,A.Rostami‐Vartouni,Ultrason.Sonochem.,2014,21,275–282.
[44]H.Zhao,G.A.Baker,J.Chem.Technol.Biotechnol.,2013,88,3–12.
[45]X.J.Wang,C.L.Yan,Inorg.Mater.,2010,46,517–521.
[46]R.Cai,Y.Liu,S.Gu,Y.Yan,J.Am.Chem.Soc.,2010,132,12776–12777.
[47]C.X.Zhao,L.He,S.Z.Qiao,A.P.Middelberg,Chem.Eng.Sci.,2011,66,1463–1479.
[48]Y.C.Pan,M.H.Ju,J.F.Yao,L.X.Zhang,N.P.Xu,Chem.Commun.,2009,7233–7235.
[49]T.Wakihara,A.Ihara,S.Inagaki,J.Tatami,K.Sato,K.Komeya,T.Meguro,Y.Kubota,A.Nakahira,Cryst.Growth.Des.,2011,11,5153–5158.
[50]T.Wakihara,R.Ichikawa,J.Tatami,A.Endo,K.Yoshida,Y.Sasaki,K.Komeya,T.Meguro,Cryst.Growth Des.,2011,11,955–958.
[51]A.Charkhi,H.Kazemian,M.Kazemeini,Powder Technol.,2010,203,389–396.
[52]A.Nezamzadeh‐Ejhieh,S.Khorsandi,J.Ind.Eng.Chem.,2014,20,937–946.
[53]G.T.Vuong,T.O.Do,Microporous Mesoporous Mater.,2009,120,310–316.
[54]J.Kecht,S.Mintova,T.Bein,Langmuir,2008,24,4310–4315.
[55]J.Kecht,S.Mintova,T.Bein,Microporous Mesoporous Mater.,2008,116,258–266.
[56]S.Mintova,V.Valtchev,T.Onfroy,C.Marichal,H.Kn鰖inger,T.Bein,Microporous Mesoporous Mater.,2006,90,237–245.
[57]A.Sakthivel,A.Iida,K.Komura,Y.Sugi,K.V.R.Chary,Microporous Mesoporous Mater.,2009,119,322–330.
[58]M.Jafari,T.Mohammadi,M.Kazemimoghadam,Ceram.Int.,2014,40,12075–12080.
[59]M.Maldonado,M.D.Oleksiak,S.Chinta,J.D.Rimer,J.Am.Chem.Soc.,2013,135,2641–2652.
[60]L.Zhang,S.L.Liu,S.J.Xie,L.Y.Xu,Microporous Mesoporous Mater.,2012,147,117–126.
[61]S.Gopalakrishnan,T.Yamaguchi,S.i.Nakao,J.Membrane Sci.,2006,274,102–107.
[62]E.P.Ng,J.M.Goupil,A.Vicente,C.Fernandez,R.Retoux,V.Valtchev,S.Mintova,Chem.Mater.,2012,24,4758–4765.
[63]N.Ren,J.Bronic B.Subotic Y.M.Song,X.C.Lü,Y.Tang,Microporous Mesoporous Mater.,2012,147,229–241.
[64]G.Majano,A.Darwiche,S.Mintova,V.Valtchev,Ind.Eng.Chem.Res.,2009,48,7084–7091.
[65]C.Madsen,C.Madsen,C.J.H.Jacobsen,Chem.Commun.,1999,673–674.
[66]I.Schmidt,C.Madsen,C.J.H.Jacobsen,Inorg.Chem.,2000,39,2279–2283.
[67]C.J.H.Jacobsen,C.Madsen,T.V.W.Janssens,H.J.Jakobsen,J.Skibsted,Microporous Mesoporous Mater.,2000,39,393–401.
[68]K.Tang,Y.G.Wang,L.J.Song,L.H.Duan,X.T.Zhang,Z.L.Sun,Mater.Lett.,2006,60,2158–2160.
[69]Y.C.Pan,J.F.Yao,L.X.Zhang,J.X.Ju,H.T.Wang,N.P.Xu,Chem.Eng.Technol.,2009,32,732–737.
[70]M.Rasouli,N.Yaghobi,M.Hafezi,M.Rasouli,J.Ind.Eng.Chem.,2012,18,1970–1976.
[71]S.K.H.Nejad‐Darzi,A.Samadi‐Maybodi,M.Ghobakhluo,J.Porous Mater.,2013,20,909–916.
[72]L.Seifi,A.Torabian,H.Kazemian,G.N.Bidhendi,A.A.Azimi,A.Charkhi,Water Air Soil Poll.,2011,217,611–625.
[73]F.Adam,J.T.Wong,E.P.Ng,Chem.Eng.J.,2013,214,63–67.
[74]X.M.Ji,W.Yao,Y.Y.Hu,N.Ren,J.Zhou,Y.P.Huang,Y.Tang,Sensor Mater.,2011,23,303–313.
[75]T.Tago,H.Konno,Y.Nakasaka,T.Masuda,Catal.Surv.Asia,2012,16,148–163.
[76]Y.M.Ni,A.M.Sun,X.L.Wu,G.L.Hai,J.L.Hu,T.Li,G.X.Li,Microporous Mesoporous Mater.,2011,143,435–442.
[77]S.G.Bao,G.Z.Liu,X.W.Zhang,L.Wang,Z.T.Mi,Ind.Eng.Chem.Res.,2010,49,3972–3975.
[78]C.Covarrubias,F.Gracia,H.Palza,Appl.Catal.A,2010,384,186–191.
[79]H.B.Zhang,Y.C.Ma,K.S.Song,Y.H.Zhang,Y.Tang,J.Catal.,2013,302,115–125.
[80]B.Louis,A.Vicente,C.Fernandez,V.Valtchev,J.Phys.Chem.C,2011,115,18603–18610.
[81]H.Konno,T.Tago,Y.Nakasaka,R.Ohnaka,J.i Nishimura,T.Masuda,Microporous Mesoporous Mater.,2013,175,25–33.
[82]A.A.Rownaghi,F.Rezaei,J.Hedlund,Catal.Commun.,2011,14,37–41.
[83]Y.Huang,J.Ho,Z.Wang,P.Nakashima,A.J.Hill,H.Wang,Microporous Mesoporous Mater.,2009,117,490–496.
[84]Y.Zhang,N.Ren,Y.Tang,in:V.Valtchev,S.Mintova,M.Tsapatsis ed.,Ordered Porous Solids:Recent Advances and Prospects,Elsevier,Amsterdam,2008,441.
[85]X.Y.Li,M.H.Sun,J.C.Rooke,L.H.Chen,B.L.Su,Chin.J.Catal.,2013,34,22–47.
[86]M.S.Holm,E.Taarning,K.Egeblad,C.H.Christensen,Catal.Today,2011,168,3–16.
[87]D.P.Serrano,J.M.Escola,P.Pizarro,Chem.Soc.Rev.,2013,42,4004–4035.
[88]J.Perez‐Ramirez,C.H.Christensen,K.Egeblad,C.H.Christensen,J.C.Groen,Chem.Soc.Rev.,2008,37,2530–2542.
[89]Q.T.Sheng,K.C.Ling,Z.R.Li,L.F.Zhao,Fuel Process.Technol.,2013,110,73–78.
[90]R.Otomo,T.Yokoi,J.N.Kondo,T.Tatsumi,Appl.Catal.A,2014,470,318–326.
[91]K.Moller,T.Bein,Chem.Soc.Rev.,2013,42,3689–3707.
[92]M.D.González,Y.Cesteros,P.Salagre,Microporous Mesoporous Mater.,2011,144,162–170.
[93]R.Giudici,H.W.Kouwenhoven,R.Prins,Appl.Catal.A,2000,203,101–110.
[94]J.M.Müller,G.C.Mesquita,S.M.Franco,L.D.Borges,J.L.de Macedo,J.A.Dias,S.C.L.Dias,Microporous Mesoporous Mater.,2015,204,50–57.
[95]M.Müller,G.Harvey,R.Prins,Microporous Mesoporous Mater.,2000,34,135–147.
[96]J.Datka,J.Klinowski,B.Sulikowski,Catal.Lett.,1994,25,403–404.
[97]D.Verboekend,J.Pérez‐Ramírez,Catal.Sci.Technol.,2011,1,879–890.
[98]A.Bonilla,D.Baudouin,J.Pérez‐Ramírez,J.Catal.,2009,265,170–180.
[99]J.C.Groen,S.Abelló,L.A.Villaescusa,J.Pérez‐Ramírez,Microporous Mesoporous Mater.,2008,114,93–102.
[100]J.C.Groen,J.C.Jansen,J.A.Moulijn,J.Pérez‐Ramírez,J.Phys.Chem.B,2004,108,13062–13065.
[101]S.Abello,A.Bonilla,J.Perez‐Ramirez,Appl.Catal.A,2009,364,191–198.
[102]K.H.Li,J.Valla,J.Garcia‐Martinez,ChemCatChem,2014,6,46–66.
[103]D.P.Serrano,R.Sanz,P.Pizarro,I.Moreno,S.Shami,Microporous Mesoporous Mater.,2014,189,71–82.
[104]J.García‐Martínez,M.Johnson,J.Valla,K.H.Li,J.Y.Ying,Catal.Sci.Technol.,2012,2,987–994.
[105]I.I.Ivanova,I.A.Kasyanov,A.A.Maerle,V.I.Zaikovskii,Microporous Mesoporous Mater.,2014,189,163–172.
[106]J.P.Na,G.Z.Liu,T.Y.Zhou,G.C.Ding,S.L.Hu,L.Wang,Catal.Lett.,2013,143,267–275.
[107]I.I.Ivanova,E.E.Knyazeva,Chem.Soc.Rev.,2013,42,3671–3688.
[108]N.D.Lysenko,V.G.Il’in,P.S.Yaremov,Theor.Exp.Chem.,2011,47,257–263.
[109]M.B.Yue,L.B.Sun,T.T.Zhuang,X.Dong,Y.Chun,J.H.Zhu,J.Mater.Chem.,2008,18,2044–2050.
[110]Y W.Zhang,T Okubo,M.Ogura,Chem.Commun.,2005,2719–2720.
[111]Y.X.Jia,W.Han,G.X.Xiong,W.S.Yang,Mater.Lett.,2008,62,2400–2403.
[112]Y.J.Wang,Y.Tang,A.G.Dong,X.D.Wang,N.Ren,Z.Gao,J.Mater.Chem.,2002,12,1812–1818.
[113]Y.P.Guo,H.J.Wang,Y.J.Guo,L.H.Guo,L.F.Chu,C.X.Guo,Chem.Eng.J.,2011,166,391–400.
[114]G.Majano,S.Mintova,O.Ovsitser,B.Mihailova,T.Bein,Microporous Mesoporous Mater.,2005,80,227–235.
[115]D.P.Serrano,J.Aguado,G.Morales,J.M.Rodriguez,A.Peral,M.Thommes,J.P.Epping,B.F.Chmelka,Chem.Mater.,2009,21,641–654.
[116]K.Mo.ller,B.Yilmaz,U.Mu.ller,T.Bein,Chem.Mater.,2011,23,4301–4310.
[117]Y.M.Fang,H.Q.Hu,G.H.Chen,Chem.Mater.,2008,20,1670–1672.
[118]C.J.H.Jacobsen,C.Madsen,J.Houzvicka,I.Schmidt,A.Carlsson,J.Am.Chem.Soc.,2000,122,7116–7117.
[119]S.Frisch,L.M.Roken,J.Caro,M.Wark,Microporous Mesoporous Mater.,2009,120,47–52.
[120]Y.C.Tong,T.B.Zhao,F.Y.Li,Y.Wang,Chem.Mater.,2006,18,4218–4220.
[121]K.K.Zhu,K.Egeblad,C.H.Christensen,Eur.J.Inorg.Chem.,2007,3955–3960.
[122]I.Schmidt,A.Boisen,E.Gustavsson,K.St録l,S.Pehrson,S.Dahl,A.Carlsson,C.J.H.Jacobsen,Chem.Mater.,2001,13,4416–4418.
[123]H.B.Zhu,Z.C.Liu,Y.D.Wang,D.J.Kong,X.H.Yuan,Z.K.Xie,Chem.Mater.,2007,20,1134–1139.
[124]L.F.Wang,C.Y.Yin,Z.C.Shan,S.Liu,Y.C.Du,F.S.Xiao,Colloids Surf.A,2009,340,126–130.
[125]F.J.Liu,T.Willhammar,L.Wang,L.F.Zhu,Q.Sun,X.J.Meng,W.Carrillo‐Cabrera,X.D.Zou,F.S.Xiao,J.Am.Chem.Soc.,2012,134,4557–4560.
[126]F.S.Xiao,L.F.Wang,C.Y.Yin,K.F.Lin,Y.Di,J.X.Li,R.R.Xu,D.S.Su,R.Schlol,T.Yokoi,T.Tatsumi,Angew.Chem.Int.Ed.,2006,45,3090‐3093.
[127]R.Srivastava,M.Choi,R.Ryoo,Chem.Commun.,2006,4489–4491.
[128]L.F.Wang,Z.Zhang,C.Y.Yin,Z.C.Shan,F.S.Xiao,Microporous Mesoporous Mater.,2010,131,58–67.
[129]H.X.Tao,H.Yang,X.H.Liu,J.W.Ren,Y.Q.Wang,G.Z.Lu,Chem.Eng.J.,2013,225,686–694.
[130]H.X.Tao,C.L.Li,J.W.Ren,Y.Q.Wang,G.Z.Lu,J.Solid State Chem.,2011,84,1820–1827.
[131]J.Zhu,Y.H.Zhu,L.K.Zhu,M.Rigutto,A.van der Made,C.G.Yang,S.X.Pan,L.Wang,L.F.Zhu,Y.Y.Jin,Q.Sun,Q.M.Wu,X.J.Meng,D.L.Zhang,Y.Han,J.X.Li,Y.Y.Chu,A.M.Zheng,S.L.Qiu,X.M.Zheng,F.S.Xiao,J.Am.Chem.Soc.,2014,136,2503–2510.
[132]Q.Lü,G.Li,H.Y.Sun,Fuel,2014,130,70–75.
[133]C.Yin,D.Tian,M.Xu,Y.J.Wei,X.Bao,Y.H.Chen,F.W.Wang,J.Colloid Interface Sci.,2013,397,108–113.
[134]C.Y.Yin,L.L.Feng,R.Ni,L.Y.Hu,X.Zhao,D.Tian,Powder Technol.,2014,253,10–13.
[135]J.S.Jin,C.Y.Peng,J.J.Wang,H.T.Liu,X.H.Gao,H.H.Liu,C.Y.Xu,Ind.Eng.Chem.Res.,2014,53,3406–3411.
[136]A.A.Rownaghi,F.Rezaei,M.Stante,J.Hedlund,Appl.Catal.B,2012,119,56–61.
[137]A.A.Rownaghi,J.Hedlund,Ind.Eng.Chem.Res.,2011,50,11872–11878.
[138]Y.E.Yan,X.Guo,Y.H.Zhang,Y.Tang,Catal.Sci.Technol.,2015,5,772–785.
[139]D.Verboekend,J.Pérez‐Ramírez,ChemSusChem,2014,7,753–764.
[140]P.R.Makgwane,S.S.Ray,J.Nanosci.Nanotechnol.,2014,14,1338–1363.
[141]R.R.Willis,A.I.Benin,Stud.Surf.Sci.Catal.,2007,170,242–249.
[142]D.Verboekend,S.Mitchell,J.Pérez‐Ramírez,Chimia,2013,67,327–332.
[143]J.C.Groen,J.A.Moulijn,J.Pérez‐Ramírez,Ind.Eng.Chem.Res.,2007,46,4193–4201.
[144]J.Pérez‐Ramírez,S.Mitchell,D.Verboekend,M.Milina,N.L.Michels,F.Krumeich,N.Marti,M.Erdmann,ChemCatChem,2011,3,1731–1734.
[2]M.Anbia,A.Habibi Davijani,Chem.Eng.J.,2013,223,899–907.
[3]Z.P.Wang,J.H.Yu,R.R.Xu,Chem.Soc.Rev.,2012,41,1729–1741.
[4]M.Anbia,F.Mohammadi Nejati,M.Jahangiri,A.Eskandari,V.Garshasbi,J.Sci.I.R.Iran,2015,26(3),213–222.
[5]M.Anbia,Z.Parvin,Chem.Eng.Res.Des.,2011,89,641–647.
[6]F.Bandarchian,M.J.Anbia,Nat.Gas Sci.Eng.,2015,26,1380–1387.
[7]C.Martínez,J.Perez‐Pariente,Zeolites and Ordered Porous Solids:Fundamentals and Applications,Editorial Universitat Politècnica de València,Madrid,2011.
[8]R.M.Mohamed,H.M.Aly,M.F.El‐Shahat,I.A.Ibrahim,Microporous Mesoporous Mater.,2005,79,7–12.
[9]M.Moliner,F.Rey,A.Corma,Angew.Chem.Int.Ed.,2013,52,13880–13889.
[10]B.Liu,Y.H.Zheng,N.Hu,T.Gui,Y.Q.Li,F.Zhang,R.F.Zhou,X.S.Chen,H.Kita,Microporous Mesoporous Mater.,2014,196,270–276.
[11]H.Y.Zhang,B.Xie,X.J.Meng,U.Müller,B.Yilmaz,M.Feyen,S.Maurer,H.Gies,T.Tatsumi,X.H.Bao,W.P.Zhang,D.De Vos,F.S.Xiao,Microporous Mesoporous Mater.,2013,180,123–129.
[12]W.J.Roth,J.Cjka,Catal.Sci.Technol.,2011,1,43–53.
[13]A.W.Chester,E.G.Derouane,Zeolite Characterization and Catalysis,Springer,New York,2009.
[14]P.Misaelides,Microporous Mesoporous Mater.,2011,144,15–18.
[15]Y.I.Tarasevich,V.V.Goncharuk,V.E.Polyakov,D.A.Krysenko,Z.G.Ivanova,E.V.Aksenenko,M.Yu.Tryfonova,J.Ind.Eng.Chem.,2012,18,1438–1440.
[16]A.C.de Campos Bernardi,P.P.A.Oliviera,M.B.de Melo Monte,F.Souza‐Barros,Microporous Mesoporous Mater.,2013,167,16–21.
[17]M.W.Ackley,S.U.Rege,H.Saxena,Microporous Mesoporous Mater.,2003,61,25–42.
[18]D.Papaioannou,P.D.Katsoulos,N.Panousis,H.Karatzias,Microporous Mesoporous Mater.,2005,84,161–170.
[19]Y.Li,J.H.Yu,Chem.Rev.,2014,114,7268–7316.
[20]A.Seidel,M.Bickford,Kirk‐Othmer Encyclopedia of Chemical Technology,John Wiley&Sons,Inc.,Hoboken,2013.
[21]D.Serrano,J.Aguado,J.Escola,in:J.J.Spivey,Y.F.Han,K.M.Dooley eds,Catalysis,Vol.23,RSC Publishing,Cambridge,2011,53.
[22]M.Anbia,M.Lashgari,Chem.Eng.J.,2009,150,555–560.
[23]R.Chal,C.Gérardin,M.Bulut,S.van Donk,ChemCatChem,2011,3,67–81.
[24]L.Tosheva,V.P.Valtchev,Chem.Mater.,2005,17,2494–2513.
[25]M.Zaarour,B.Dong,I.Naydenova,R.Retoux,S.Mintova,Microporous Mesoporous Mater.,2014,189,11–21.
[26]V.Valtchev,L.Tosheva,Chem.Rev.,2013,113,6734–6760.
[27]K.K.Zhu,J.M.Sun,J.Liu,L.Q.Wang,H.Y.Wan,J.Z.Hu,Y.Wang,C.H.F.Peden,Z.M.Nie,ACS Catal.,2011,1,682–690.
[28]G.T.Vuong,V.T.Hoang,D.T.Nguyen,T.O.Do,Appl.Catal.A,2010,382,231–239..
[29]X.Y.Chen,K.Wendell,J.Zhu,J.L.Li,X.X.Yu,Z.J.Zhang,Bioresour.Technol.,2012,110,79–85.
[30]G.T.Vuong,T.O.Do,J.Am.Chem.Soc.,2007,129,3810–3811.
[31]W.Song,R.E.Justice,C.A.Jones,V.H.Grassian,S.C.Larsen,Langmuir,2004,20,4696–4702.
[32]S.Mintova,J.P.Gilson,V.Valtchev,Nanoscale,2013,5,6693–6703.
[33]L.Burel,A.Tuel,Microporous Mesoporous Mater.,2013,174,90–99.
[34]N.Esmaeili,H.Kazemian,D.Bastani,Iran.J.Chem.Chem.Eng.,2011,30,9–14.
[35]B.Xie,J.W.Song,L.M.Ren,Y.Y.Ji,J.X.Li,F.S.Xiao,Chem.Mater.,2008,20,4533–4535.
[36]G.Reding,T.Maurer,B.Kraushaar‐Czarnetzki,Microporous Mesoporous Mater.,2003,57,83–92.
[37]D.Serrano,J.Aguado,J.Rodriguez,A.Peral,Stud.Surf.Sci.Catal.,2007,170,282–288.
[38]Y.S.Li,W.S.Yang,J.Membrane Sci.,2008,316,3–17.
[39]Z.W.Chen,S.Li,Y.Yan,Chem.Mater.,2005,17,2262–2266.
[40]M.Mehdipourghazi,A.Moheb,H.Kazemian,Microporous Mesoporous Mater.,2010,136,18–24.
[41]Y.Y.Hu,C.Liu,Y.H.Zhang,N.Ren,Y.Tang,Microporous Mesoporous Mater.,2009,119,306–314.
[42]Y.M.Liu,W.Huang,Y.S.Zhao,T.Dou,React.Kinet.Catal.Lett.,2009,96,157–163.
[43]M.Nasrollahzadeh,A.Ehsani,A.Rostami‐Vartouni,Ultrason.Sonochem.,2014,21,275–282.
[44]H.Zhao,G.A.Baker,J.Chem.Technol.Biotechnol.,2013,88,3–12.
[45]X.J.Wang,C.L.Yan,Inorg.Mater.,2010,46,517–521.
[46]R.Cai,Y.Liu,S.Gu,Y.Yan,J.Am.Chem.Soc.,2010,132,12776–12777.
[47]C.X.Zhao,L.He,S.Z.Qiao,A.P.Middelberg,Chem.Eng.Sci.,2011,66,1463–1479.
[48]Y.C.Pan,M.H.Ju,J.F.Yao,L.X.Zhang,N.P.Xu,Chem.Commun.,2009,7233–7235.
[49]T.Wakihara,A.Ihara,S.Inagaki,J.Tatami,K.Sato,K.Komeya,T.Meguro,Y.Kubota,A.Nakahira,Cryst.Growth.Des.,2011,11,5153–5158.
[50]T.Wakihara,R.Ichikawa,J.Tatami,A.Endo,K.Yoshida,Y.Sasaki,K.Komeya,T.Meguro,Cryst.Growth Des.,2011,11,955–958.
[51]A.Charkhi,H.Kazemian,M.Kazemeini,Powder Technol.,2010,203,389–396.
[52]A.Nezamzadeh‐Ejhieh,S.Khorsandi,J.Ind.Eng.Chem.,2014,20,937–946.
[53]G.T.Vuong,T.O.Do,Microporous Mesoporous Mater.,2009,120,310–316.
[54]J.Kecht,S.Mintova,T.Bein,Langmuir,2008,24,4310–4315.
[55]J.Kecht,S.Mintova,T.Bein,Microporous Mesoporous Mater.,2008,116,258–266.
[56]S.Mintova,V.Valtchev,T.Onfroy,C.Marichal,H.Kn鰖inger,T.Bein,Microporous Mesoporous Mater.,2006,90,237–245.
[57]A.Sakthivel,A.Iida,K.Komura,Y.Sugi,K.V.R.Chary,Microporous Mesoporous Mater.,2009,119,322–330.
[58]M.Jafari,T.Mohammadi,M.Kazemimoghadam,Ceram.Int.,2014,40,12075–12080.
[59]M.Maldonado,M.D.Oleksiak,S.Chinta,J.D.Rimer,J.Am.Chem.Soc.,2013,135,2641–2652.
[60]L.Zhang,S.L.Liu,S.J.Xie,L.Y.Xu,Microporous Mesoporous Mater.,2012,147,117–126.
[61]S.Gopalakrishnan,T.Yamaguchi,S.i.Nakao,J.Membrane Sci.,2006,274,102–107.
[62]E.P.Ng,J.M.Goupil,A.Vicente,C.Fernandez,R.Retoux,V.Valtchev,S.Mintova,Chem.Mater.,2012,24,4758–4765.
[63]N.Ren,J.Bronic B.Subotic Y.M.Song,X.C.Lü,Y.Tang,Microporous Mesoporous Mater.,2012,147,229–241.
[64]G.Majano,A.Darwiche,S.Mintova,V.Valtchev,Ind.Eng.Chem.Res.,2009,48,7084–7091.
[65]C.Madsen,C.Madsen,C.J.H.Jacobsen,Chem.Commun.,1999,673–674.
[66]I.Schmidt,C.Madsen,C.J.H.Jacobsen,Inorg.Chem.,2000,39,2279–2283.
[67]C.J.H.Jacobsen,C.Madsen,T.V.W.Janssens,H.J.Jakobsen,J.Skibsted,Microporous Mesoporous Mater.,2000,39,393–401.
[68]K.Tang,Y.G.Wang,L.J.Song,L.H.Duan,X.T.Zhang,Z.L.Sun,Mater.Lett.,2006,60,2158–2160.
[69]Y.C.Pan,J.F.Yao,L.X.Zhang,J.X.Ju,H.T.Wang,N.P.Xu,Chem.Eng.Technol.,2009,32,732–737.
[70]M.Rasouli,N.Yaghobi,M.Hafezi,M.Rasouli,J.Ind.Eng.Chem.,2012,18,1970–1976.
[71]S.K.H.Nejad‐Darzi,A.Samadi‐Maybodi,M.Ghobakhluo,J.Porous Mater.,2013,20,909–916.
[72]L.Seifi,A.Torabian,H.Kazemian,G.N.Bidhendi,A.A.Azimi,A.Charkhi,Water Air Soil Poll.,2011,217,611–625.
[73]F.Adam,J.T.Wong,E.P.Ng,Chem.Eng.J.,2013,214,63–67.
[74]X.M.Ji,W.Yao,Y.Y.Hu,N.Ren,J.Zhou,Y.P.Huang,Y.Tang,Sensor Mater.,2011,23,303–313.
[75]T.Tago,H.Konno,Y.Nakasaka,T.Masuda,Catal.Surv.Asia,2012,16,148–163.
[76]Y.M.Ni,A.M.Sun,X.L.Wu,G.L.Hai,J.L.Hu,T.Li,G.X.Li,Microporous Mesoporous Mater.,2011,143,435–442.
[77]S.G.Bao,G.Z.Liu,X.W.Zhang,L.Wang,Z.T.Mi,Ind.Eng.Chem.Res.,2010,49,3972–3975.
[78]C.Covarrubias,F.Gracia,H.Palza,Appl.Catal.A,2010,384,186–191.
[79]H.B.Zhang,Y.C.Ma,K.S.Song,Y.H.Zhang,Y.Tang,J.Catal.,2013,302,115–125.
[80]B.Louis,A.Vicente,C.Fernandez,V.Valtchev,J.Phys.Chem.C,2011,115,18603–18610.
[81]H.Konno,T.Tago,Y.Nakasaka,R.Ohnaka,J.i Nishimura,T.Masuda,Microporous Mesoporous Mater.,2013,175,25–33.
[82]A.A.Rownaghi,F.Rezaei,J.Hedlund,Catal.Commun.,2011,14,37–41.
[83]Y.Huang,J.Ho,Z.Wang,P.Nakashima,A.J.Hill,H.Wang,Microporous Mesoporous Mater.,2009,117,490–496.
[84]Y.Zhang,N.Ren,Y.Tang,in:V.Valtchev,S.Mintova,M.Tsapatsis ed.,Ordered Porous Solids:Recent Advances and Prospects,Elsevier,Amsterdam,2008,441.
[85]X.Y.Li,M.H.Sun,J.C.Rooke,L.H.Chen,B.L.Su,Chin.J.Catal.,2013,34,22–47.
[86]M.S.Holm,E.Taarning,K.Egeblad,C.H.Christensen,Catal.Today,2011,168,3–16.
[87]D.P.Serrano,J.M.Escola,P.Pizarro,Chem.Soc.Rev.,2013,42,4004–4035.
[88]J.Perez‐Ramirez,C.H.Christensen,K.Egeblad,C.H.Christensen,J.C.Groen,Chem.Soc.Rev.,2008,37,2530–2542.
[89]Q.T.Sheng,K.C.Ling,Z.R.Li,L.F.Zhao,Fuel Process.Technol.,2013,110,73–78.
[90]R.Otomo,T.Yokoi,J.N.Kondo,T.Tatsumi,Appl.Catal.A,2014,470,318–326.
[91]K.Moller,T.Bein,Chem.Soc.Rev.,2013,42,3689–3707.
[92]M.D.González,Y.Cesteros,P.Salagre,Microporous Mesoporous Mater.,2011,144,162–170.
[93]R.Giudici,H.W.Kouwenhoven,R.Prins,Appl.Catal.A,2000,203,101–110.
[94]J.M.Müller,G.C.Mesquita,S.M.Franco,L.D.Borges,J.L.de Macedo,J.A.Dias,S.C.L.Dias,Microporous Mesoporous Mater.,2015,204,50–57.
[95]M.Müller,G.Harvey,R.Prins,Microporous Mesoporous Mater.,2000,34,135–147.
[96]J.Datka,J.Klinowski,B.Sulikowski,Catal.Lett.,1994,25,403–404.
[97]D.Verboekend,J.Pérez‐Ramírez,Catal.Sci.Technol.,2011,1,879–890.
[98]A.Bonilla,D.Baudouin,J.Pérez‐Ramírez,J.Catal.,2009,265,170–180.
[99]J.C.Groen,S.Abelló,L.A.Villaescusa,J.Pérez‐Ramírez,Microporous Mesoporous Mater.,2008,114,93–102.
[100]J.C.Groen,J.C.Jansen,J.A.Moulijn,J.Pérez‐Ramírez,J.Phys.Chem.B,2004,108,13062–13065.
[101]S.Abello,A.Bonilla,J.Perez‐Ramirez,Appl.Catal.A,2009,364,191–198.
[102]K.H.Li,J.Valla,J.Garcia‐Martinez,ChemCatChem,2014,6,46–66.
[103]D.P.Serrano,R.Sanz,P.Pizarro,I.Moreno,S.Shami,Microporous Mesoporous Mater.,2014,189,71–82.
[104]J.García‐Martínez,M.Johnson,J.Valla,K.H.Li,J.Y.Ying,Catal.Sci.Technol.,2012,2,987–994.
[105]I.I.Ivanova,I.A.Kasyanov,A.A.Maerle,V.I.Zaikovskii,Microporous Mesoporous Mater.,2014,189,163–172.
[106]J.P.Na,G.Z.Liu,T.Y.Zhou,G.C.Ding,S.L.Hu,L.Wang,Catal.Lett.,2013,143,267–275.
[107]I.I.Ivanova,E.E.Knyazeva,Chem.Soc.Rev.,2013,42,3671–3688.
[108]N.D.Lysenko,V.G.Il’in,P.S.Yaremov,Theor.Exp.Chem.,2011,47,257–263.
[109]M.B.Yue,L.B.Sun,T.T.Zhuang,X.Dong,Y.Chun,J.H.Zhu,J.Mater.Chem.,2008,18,2044–2050.
[110]Y W.Zhang,T Okubo,M.Ogura,Chem.Commun.,2005,2719–2720.
[111]Y.X.Jia,W.Han,G.X.Xiong,W.S.Yang,Mater.Lett.,2008,62,2400–2403.
[112]Y.J.Wang,Y.Tang,A.G.Dong,X.D.Wang,N.Ren,Z.Gao,J.Mater.Chem.,2002,12,1812–1818.
[113]Y.P.Guo,H.J.Wang,Y.J.Guo,L.H.Guo,L.F.Chu,C.X.Guo,Chem.Eng.J.,2011,166,391–400.
[114]G.Majano,S.Mintova,O.Ovsitser,B.Mihailova,T.Bein,Microporous Mesoporous Mater.,2005,80,227–235.
[115]D.P.Serrano,J.Aguado,G.Morales,J.M.Rodriguez,A.Peral,M.Thommes,J.P.Epping,B.F.Chmelka,Chem.Mater.,2009,21,641–654.
[116]K.Mo.ller,B.Yilmaz,U.Mu.ller,T.Bein,Chem.Mater.,2011,23,4301–4310.
[117]Y.M.Fang,H.Q.Hu,G.H.Chen,Chem.Mater.,2008,20,1670–1672.
[118]C.J.H.Jacobsen,C.Madsen,J.Houzvicka,I.Schmidt,A.Carlsson,J.Am.Chem.Soc.,2000,122,7116–7117.
[119]S.Frisch,L.M.Roken,J.Caro,M.Wark,Microporous Mesoporous Mater.,2009,120,47–52.
[120]Y.C.Tong,T.B.Zhao,F.Y.Li,Y.Wang,Chem.Mater.,2006,18,4218–4220.
[121]K.K.Zhu,K.Egeblad,C.H.Christensen,Eur.J.Inorg.Chem.,2007,3955–3960.
[122]I.Schmidt,A.Boisen,E.Gustavsson,K.St録l,S.Pehrson,S.Dahl,A.Carlsson,C.J.H.Jacobsen,Chem.Mater.,2001,13,4416–4418.
[123]H.B.Zhu,Z.C.Liu,Y.D.Wang,D.J.Kong,X.H.Yuan,Z.K.Xie,Chem.Mater.,2007,20,1134–1139.
[124]L.F.Wang,C.Y.Yin,Z.C.Shan,S.Liu,Y.C.Du,F.S.Xiao,Colloids Surf.A,2009,340,126–130.
[125]F.J.Liu,T.Willhammar,L.Wang,L.F.Zhu,Q.Sun,X.J.Meng,W.Carrillo‐Cabrera,X.D.Zou,F.S.Xiao,J.Am.Chem.Soc.,2012,134,4557–4560.
[126]F.S.Xiao,L.F.Wang,C.Y.Yin,K.F.Lin,Y.Di,J.X.Li,R.R.Xu,D.S.Su,R.Schlol,T.Yokoi,T.Tatsumi,Angew.Chem.Int.Ed.,2006,45,3090‐3093.
[127]R.Srivastava,M.Choi,R.Ryoo,Chem.Commun.,2006,4489–4491.
[128]L.F.Wang,Z.Zhang,C.Y.Yin,Z.C.Shan,F.S.Xiao,Microporous Mesoporous Mater.,2010,131,58–67.
[129]H.X.Tao,H.Yang,X.H.Liu,J.W.Ren,Y.Q.Wang,G.Z.Lu,Chem.Eng.J.,2013,225,686–694.
[130]H.X.Tao,C.L.Li,J.W.Ren,Y.Q.Wang,G.Z.Lu,J.Solid State Chem.,2011,84,1820–1827.
[131]J.Zhu,Y.H.Zhu,L.K.Zhu,M.Rigutto,A.van der Made,C.G.Yang,S.X.Pan,L.Wang,L.F.Zhu,Y.Y.Jin,Q.Sun,Q.M.Wu,X.J.Meng,D.L.Zhang,Y.Han,J.X.Li,Y.Y.Chu,A.M.Zheng,S.L.Qiu,X.M.Zheng,F.S.Xiao,J.Am.Chem.Soc.,2014,136,2503–2510.
[132]Q.Lü,G.Li,H.Y.Sun,Fuel,2014,130,70–75.
[133]C.Yin,D.Tian,M.Xu,Y.J.Wei,X.Bao,Y.H.Chen,F.W.Wang,J.Colloid Interface Sci.,2013,397,108–113.
[134]C.Y.Yin,L.L.Feng,R.Ni,L.Y.Hu,X.Zhao,D.Tian,Powder Technol.,2014,253,10–13.
[135]J.S.Jin,C.Y.Peng,J.J.Wang,H.T.Liu,X.H.Gao,H.H.Liu,C.Y.Xu,Ind.Eng.Chem.Res.,2014,53,3406–3411.
[136]A.A.Rownaghi,F.Rezaei,M.Stante,J.Hedlund,Appl.Catal.B,2012,119,56–61.
[137]A.A.Rownaghi,J.Hedlund,Ind.Eng.Chem.Res.,2011,50,11872–11878.
[138]Y.E.Yan,X.Guo,Y.H.Zhang,Y.Tang,Catal.Sci.Technol.,2015,5,772–785.
[139]D.Verboekend,J.Pérez‐Ramírez,ChemSusChem,2014,7,753–764.
[140]P.R.Makgwane,S.S.Ray,J.Nanosci.Nanotechnol.,2014,14,1338–1363.
[141]R.R.Willis,A.I.Benin,Stud.Surf.Sci.Catal.,2007,170,242–249.
[142]D.Verboekend,S.Mitchell,J.Pérez‐Ramírez,Chimia,2013,67,327–332.
[143]J.C.Groen,J.A.Moulijn,J.Pérez‐Ramírez,Ind.Eng.Chem.Res.,2007,46,4193–4201.
[144]J.Pérez‐Ramírez,S.Mitchell,D.Verboekend,M.Milina,N.L.Michels,F.Krumeich,N.Marti,M.Erdmann,ChemCatChem,2011,3,1731–1734.