Preparation of carbon-based monolith with macro-pore from chitosan and its adsorption performance for trace SO2

doi:10.3969/j.issn.0438-1157.2013.01.042

Abstract

Abstract: Chitosan-based monolithic carbon materials (CBMCMs) with three-dimensional macro-porous honeycomb structure have been prepared by coupling ice templating process with a low-temperature heat treatment one,of which the adsorption and regeneration performance for trace SO₂ in air were evaluated.It is found that formation of macro-porous structure can be tuned by varying the freezing time,and low temperature pyrolysis,such as 200℃,favors the retain of abundant surface nitrogen functional group in as-made CBMCMs.After ion-exchange treatment in ammonia solution,the adsorption capacity for trace SO₂ of the CBMCMs is greatly enhanced,as high as 57 mg·g^-1.The exhausted CBMCMs can be partially regenerated simply by air purge at room temperature.The unrecoverable part is due to the formation of ammonium salts from protonated amine group and sulfite and sulfate ions,as the product of irreversible adsorption.It is believed that after further optimization,the CBMCM materials reported here will be of potential in air cleaning for efficient removal of SO_x species,especially for cathode air desulfurization in proton exchange membrane fuel cells.

Key words: ice templating, chitosan, monolithic carbon materials with macro-pores, adsorption capability, SO₂

摘要： 以壳聚糖为碳源,综合采用冰模板技术和低温热解炭化技术,制备出具有蜂窝状孔结构特征的大孔炭质整体材料,研究了此类新材料对痕量二氧化硫的吸附性能及再生能力。结果表明,大孔炭质整体材料蜂窝状孔结构的形成及其规整程度与冰模板过程的冷冻时间等因素密切相关;200℃下低温热处理可得到具有丰富表面含氮官能团的大孔炭质整体材料;经氨水溶液中的离子交换功能化处理后,该大孔炭质整体材料对低浓度SO₂的吸附容量显著提高,可达到57 mg·g^-1;吸附饱和后,经空气简单吹扫处理,大孔炭质整体材料即可大部分再生,少数不可再生部分是由于质子化的氨基与亚硫酸根和硫酸根在吸附过程中形成了不可逆化学吸附产物季铵盐所致。壳聚糖基大孔炭质整体吸附剂材料有望在污染空气的脱硫净化,特别是在质子交换膜燃料电池的阴极空气脱硫净化方面发挥重要作用。

关键词: 冰模板法, 壳聚糖, 大孔炭质整体材料, 吸附性能, 二氧化硫

CLC Number:

TQ028.1⁺5

WAN Peng, ZHANG Hua, YU Chang, QIU Jieshan. Preparation of carbon-based monolith with macro-pore from chitosan and its adsorption performance for trace SO₂[J]. CIESC Journal, 2013, 64(1): 357-364.

万鹏, 张华, 于畅, 邱介山. 壳聚糖基大孔炭质整体材料的制备及其对痕量二氧化硫的吸附性能[J]. 化工学报, 2013, 64(1): 357-364.

References 26

[1]	Deville S.Freeze-casting of porous ceramics:a review of current achievements and issues[J].Advanced Engineering Materials,2008,10(3):155-169
[2]	Mahler W,Bechtold M F.Freeze-formed silica fibres[J].Nature,1980,285(1):27-28
[3]	Gutierrez M C,Ferrer M L,del Monte F.Ice-templated materials:sophisticated structures exhibiting enhanced functionalities obtained after unidirectional freezing and ice-segregation-induced self-assembly[J].Chemistry of Materials,2008,20(3):634-648
[4]	Mori H,Aotani K,Sano N,Tamon H.Synthesis of a hierarchically micro-macroporous structured zeolite monolith by ice-templating[J].Journal of Materials Chemistry,2011,21(15):5677-5681
[5]	Mukai S,Nishihara H,Yoshida T,Taniguchi K,Tamon H.Morphology of resorcinol-formaldehyde gels obtained through ice-templating[J].Carbon,2005,43(7):1563-1565
[6]	Nishihara H,Mukai S R,Yamashita D,Tamon H. Ordered macroporous silica by ice templating[J].Chemistry of Materials,2005,17(3):683-689
[7]	Portero A,Teijeiroosorio D,Alonso M,Remunanlopez C. Development of chitosan sponges for buccal administration of insulin[J].Carbohydrate Polymers,2007,68(4):617-625
[8]	Qian L,Ahmed A,Foster A,Rannard S P,Cooper A I,Zhang H.Systematic tuning of pore morphologies and pore volumes in macroporous materials by freezing[J].Journal of Materials Chemistry,2009,19(29):5212-5219
[9]	Launey M E,Munch E,Alsem D H,Saiz E,Tomsia A P,Ritchie R O.A novel biomimetic approach to the design of high-performance ceramic-metal composites[J].Journal of the Royal Society Interface,2010,7(46):741-753
[10]	Yi Baolian(衣宝廉).Fuel Cells:Principles,Techniques and Applications(燃料电池—原理·技术·应用)[M].Beijing:Chemical Industry Press,2003
[11]	Yin Geping(尹鸽平),Du Chunyu(杜春雨),Wang Zhenbo(王振波).The research progress of the durability of catalysts of proton exchange membrane fuel cell[J].Chinese Journal of Power Sources(电源技术),2008,32(4):210-214
[12]	Mohtadi R,Lee W K,Van Zee J W.Assessing durability of cathodes exposed to common air impurities[J].Journal of Power Sources,2004,138(1/2):216-225
[13]	Rinaudo M.Chitin and chitosan:properties and applications[J].Progress in Polymer Science,2006,31(7):603-632
[14]	Han Xiaojin(韩小进),Zhu Qingsong(朱庆松),Cheng Chunzu(程春祖),Wu Changcheng(武长城).Homogeneous synthesis and characterization of graft copolymer of chitosan/polycaprolactone[J].CIESC Journal(化工学报),2011,62(7):2055-2060
[15]	Suh J K F,Matthew H W T.Application of chitosan-based polysaccharide biomaterials in cartilage tissue engineering:a review[J].Biomaterials,2000,21(24):2589-2598
[16]	Ding Ping(丁萍),Huang Kelong(黄可龙),Li Guiyin(李桂银),Zeng Wenwen(曾雯雯),Jiao Feipeng(焦飞鹏).Adsorption behavior of Zn(Ⅱ)ion onto chitosan derivatives[J].Journal of Chemical Industry and Engineering (China)(化工学报)2006,57(11):2652-2656
[17]	Babel S,Kurniawan T A.Low-cost adsorbents for heavy metals uptake from contaminated water:a review[J].Journal of Hazardous Materials,2003,97(1/2/3):219-243
[18]	Ji Qianqian(季倩倩),Guo Peizhi(郭培志),Zhao Xiusong(赵修松).Preparation of chitosan-based porous carbons and their application as electrode materials for supercapacitors[J].Acta Physico-Chemica Sinica(物理化学学报),2010,26(5):1254-1258
[19]	Bengisu M,Yilmaz E.Oxidation and pyrolysis of chitosan as a route for carbon fiber derivation[J].Carbohydrate Polymers,2002,50(2):165-175
[20]	de Britto D,Campana-Filho S P.Kinetics of the thermal degradation of chitosan[J].Thermochimica Acta,2007,465(1/2):73-82
[21]	Lopez F A,Merce A L R,Alguacil F J,Lopez-Delgado A. A kinetic study on the thermal behaviour of chitosan[J].Journal of Thermal Analysis and Calorimetry,2008,91(2):633-639
[22]	de Britto D.A kinetic study on the thermal degradation of N,N,N-trimethylchitosan[J].Polymer Degradation and Stability,2004,84(2):353-361
[23]	Cooney M J,Lau C,Windmeisser M,Liaw B Y,Klotzbach T,Minteer S D.Design of chitosan gel pore structure:towards enzyme catalyzed flow-through electrodes[J].Journal of Materials Chemistry,2008,18(6):667-674
[24]	Zhao L,Li X,Zhao Q,Qu Z,Yuan D,Liu S,Hu X,Chen G.Synthesis,characterization and adsorptive performance of MgFe2O4 nanospheres for SO2 removal[J].Journal of Hazardous Materials,2010,184(1/2/3):704-709
[25]	Janciauskaite U,Rakutyte V,Miskinis J,Makuska R.Synthesis and properties of chitosan-N-dextran graft copolymers[J].Reactive and Functional Polymers,2008,68(3):787-796
[26]	Kundu S,Xia W,Busser W,Becker M,Schmidt D A,Havenith M,Muhler M.The formation of nitrogen-containing functional groups on carbon nanotube surfaces:a quantitative XPS and TPD study[J].Physical Chemistry Chemical Physics,2010,12(17):4351-4359

Preparation of carbon-based monolith with macro-pore from chitosan and its adsorption performance for trace SO₂

壳聚糖基大孔炭质整体材料的制备及其对痕量二氧化硫的吸附性能

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