CO2 absorption properties of Ti- and Na-doped porous Li4SiO4 prepared by a sol–gel process
详细信息 查看全文
- 作者:Maoqiao Xiang ; Yingchun Zhang ; Ming Hong ; Shuyan Liu…
- 刊名:Journal of Materials Science
- 出版年:2015
- 出版时间:July 2015
- 年:2015
- 卷:50
- 期:13
- 页码:4698-4706
- 全文大小:2,564 KB
- 参考文献:1.Xu H, Cheng W, Jin X (2013) Effect of the particle size of quartz powder on the synthesis and CO2 absorption properties of Li4SiO4 at high temperature. Ind Eng Chem Res 52(5):1886-891View Article
2.Seggiani M, Puccini M, Vitolo S (2011) High-temperature and low concentration CO2 sorption on Li4SiO4 based sorbents: study of the used silica and doping method effects. Int J Greenh Gas Control 5(4):741-48View Article
3.Qi Z, Daying H, Yang L (2013) Analysis of CO2 sorption/desorption kinetic behaviors and reaction mechanisms on Li4SiO4. AIChE J 59(3):901-11View Article
4.Nair BN, Burwood RP, Goh VJ (2009) Lithium based ceramic materials and membranes for high temperature CO2 separation. Prog Mater Sci 54(5):511-41View Article
5.Mejía-Trejo VL, Fregoso-Israel E, Pfeiffer H (2008) Textural, structural, and CO2 chemisorption effects produced on the lithium orthosilicate by its doping with sodium (Li4?xNaxSiO4). Chem Mater 20(22):7171-176View Article
6.Radfarnia HR, liuta MCI (2011) Surfactant-template/ultrasound-assisted method for the preparation of porous nanoparticle lithium zirconate. Ind Eng Chem Res 50(15):9295-305View Article
7.Kato M, Yoshikawa S, Nakagawa KJ (2002) Carbon dioxide absorption by lithium orthosilicate in a wide range of temperature and carbon dioxide concentrations. J Mater Sci Lett 21(16):485-87View Article
8.Gauer C, Heschel W (2006) Doped lithium orthosilicate for absorption of carbon dioxide. J Mater Sci 41(8):2405-409. doi:10.-007/?s10853-006-7070-1 View Article
9.Ida JI, Xiong R, Lin YS (2004) Synthesis and CO2 sorption properties of pure and modified lithium zirconate. Sep Purif Technol 36(1):41View Article
10.Xiong R, Ida J, Lin YS (2003) Kinetics of carbon dioxide sorption on potassium-doped lithium zirconate. Chem Eng Sci 58(19):4377-385View Article
11.Essaki K, Kato M, Nakagawa K (2006) CO2 removal at high temperature using pace bed of lithium silicate pellets. J Ceram Soc Jpn 114(9):739-42View Article
12.Rodr?′guez-Mosqueda R, Pfeiffer H (2010) Thermokinetic analysis of the CO2 chemisorption on Li4SiO4 by using different gas flow rates and particle sizes. J Phys Chem A 114(13):4535-541View Article
13.Venegas MJ, Fregoso-Israel E, Escamilla R (2007) Kinetic and reaction mechanism of CO2 sorption on Li4SiO4: study of the particle size effect. Ind Eng Chem Res 46(8):2407-412View Article
14.Zhang S, Zhang Q, Wang H (2014) Absorption behaviors study on doped Li4SiO4 under a humidified atmosphere with low CO2 concentration. Int J Hydrogen Energy 39(31):17913-7920View Article
15.Pfeiffer H, Lima E, Bosch P (2006) Lithium-Sodium metazirconate solid solutions, Li2?em class="EmphasisTypeItalic">x Na x ZrO3 (0?≤?em class="EmphasisTypeItalic">x?≤?): a hierarchical architecture. Chem Mater 18(11):2642-647View Article
16.Pfeiffer H, Vazquez C, Lara VH, Bosch P (2007) Thermal behavior and CO2 absorption of Li2?em class="EmphasisTypeItalic">x Na x ZrO3 solid solutions. Chem Mater 19(4):922-26View Article
17.Veliz-Enriquez MY, Gonzalez G, Pfeiffer H (2007) Synthesis and CO2 capture evaluation of Li2?em class="EmphasisTypeItalic">x K x ZrO3 solid solutions and crystal structure of a new lithium–potassium zirconate phase. J Solid State Chem 180(9):2485-492View Article
18.Alcántar-Vázquez B, Diaz C, Romero-Ibarra IC (2013) Structural and CO2 chemisorption analyses on Na2(Zr1?em class="EmphasisTypeItalic">x Al x )O3 solid solutions. J Phys Chem C 117(32):16483-6491View Article
19.Ortiz-Landeros J, Romero-Ibarra IC, Gómez-Yá?ez C (2013) Li4+x (Si1?em class="EmphasisTypeItalic">x Al x )O4 Solid solution mechanosynthesis and kinetic analysis of the CO2 chemisorption process. J Phys Chem C. 117(12):6303-311View Article
20.Subha PV, Nair BN, Hareesh P (2014) Enhanced CO2 absorption kinetics in lithium silicate platelets synthesized by a sol–gel approach. J Mater Chem A 2(32):12792-2798View Article
21.Ortiz-Landeros J, Gómez-Yá?ez C, Palacios-Romero LM (2012) Structural and thermochemical chemisorption of CO2 on Li4+x (Si1?em class="EmphasisTypeItalic">x Al x )O4 and Li4-em class="EmphasisTypeItalic">x (Si1?em class="EmphasisTypeItalic">x V x )O4 solid solutions. J Phys Chem A 116(12):3163-171View Article
22.Knitter R, Kolb MHH, Kaufmann U (2013) Fabrication of modified lithium orthosilicate pebbles by addition of titania. J Nucl Mater 442(1):S433–S436View Article
23.Huheey JE (1981) Inorganic Chemistry, 2nd edn. Harper and Row, New York
24.Cotton FA, Wilkinson G (2001) Advanced inorganic chemistry, 9th edn. Limusa Noriega, Mexico
25.Duan Y, Pfeiffer H, Li B (2013) CO2 capture properties of lithium silicates with different ratios of Li2O/SiO2: an ab initio thermodynamic and experimental approach. Phys Chem Chem Phys 15(32):13538-3558View Article
26.Khomane RB, Sharma BK, Saha S (2006) Reverse microemulsion mediated sol–gel synthesis of lithium silicate nanoparticles under ambi - 作者单位:Maoqiao Xiang (1)
Yingchun Zhang (1)
Ming Hong (1)
Shuyan Liu (1)
Yun Zhang (1)
Hui Liu (1)
Cheng Gu (1)
1. School of Materials Science and Engineering, University of Science and Technology Beijing, 30 Xueyuan Road, Haidian District, Beijing, 100083, People’s Republic of China - 刊物类别:Chemistry and Materials Science
- 刊物主题:Chemistry
Materials Science
Characterization and Evaluation Materials
Polymer Sciences
Continuum Mechanics and Mechanics of Materials
Crystallography
Mechanics - 出版者:Springer Netherlands
- ISSN:1573-4803
文摘
To improve the carbon dioxide (CO2) absorption performance of lithium orthosilicate (Li4SiO4), tablet-like Li4Si1?em class="EmphasisTypeItalic">x Ti x O4 and Li3.9Na0.1Si0.96Ti0.04O4 sorbents with loose and porous texture were prepared by a sol–gel process. The relationship between the Ti doping and volume expansion was studied for the first time. The results indicated that the Ti presence into the Li4SiO4 structure inhibited the growth of grains and abated the volume expansion. The X-ray diffraction and scanning electron microscopy results showed that the loose and porous solid solutions with similar phase crystallite but different grain sizes could obtain by heat treatment of precursor at 700?°C. The optimum Ti content of Li4Si1?em class="EmphasisTypeItalic">x Ti x O4 seems to be 0.04 of Li4Si0.96Ti0.04O4. And the CO2 capture behaviors of Li3.9Na0.1Si0.96Ti0.04O4 were better than Li4Si0.96Ti0.04O4.