Advanced SearchSearch Tips
Comparative studies of porous carbon nanofibers by various activation methods
facebook(new window)  Pirnt(new window) E-mail(new window) Excel Download
  • Journal title : Carbon letters
  • Volume 14, Issue 3,  2013, pp.180-185
  • Publisher : Korean Carbon Society
  • DOI : 10.5714/CL.2013.14.3.180
 Title & Authors
Comparative studies of porous carbon nanofibers by various activation methods
Lee, Hye-Min; Kang, Hyo-Rang; An, Kay-Hyeok; Kim, Hong-Gun; Kim, Byung-Joo;
  PDF(new window)
In this study, activated carbons nanofibers (ACNFs) were prepared from polyacrylonitrile-based nanofibers by physical ( and ) and chemical (KOH) activation. The surface and structural characteristics of the porous carbon were observed by scanning electron microscopy and X-ray diffraction, respectively. Pore characteristics were investigated by /77K adsorption isotherms. The specific surface area of the physically ACNFs was increased up to and the ACNFs were found to be mainly composed of micropore structures. Chemical activation using KOH produced ACNFs with high specific surface area (up to ), and the micropores were mainly found in the ACNFs. The physically and chemically ACNFs showed both mainly type I from the International Union of Pure and Applied Chemistry classification.
various activation methods;activated carbons nanofibers;polyacrylonitrile;KOH;;;
 Cited by
Effects of pore structures on electrochemical behaviors of polyacrylonitrile-based activated carbon nanofibers by carbon dioxide activation,;;;;

Carbon letters, 2014. vol.15. 1, pp.71-76 crossref(new window)
Preparation of novolac-type phenol-based activated carbon with a hierarchical pore structure and its electric double-layer capacitor performance,;;;;

Carbon letters, 2014. vol.15. 3, pp.192-197 crossref(new window)
Separation of biomass using carbon molecular sieves treated with hydrogen peroxide,;;;

Journal of Industrial and Engineering Chemistry, 2015. vol.21. pp.278-282 crossref(new window)
Effects of pore structures on electrochemical behaviors of polyacrylonitrile (PAN)-based activated carbon nanofibers,;;;;;;

Journal of Industrial and Engineering Chemistry, 2015. vol.21. pp.736-740 crossref(new window)
Physico-chemical and electrochemical properties of pitch-based high crystallinity cokes used as electrode material for electric double layer capacitor,;;;;

Journal of Industrial and Engineering Chemistry, 2015. vol.23. pp.27-32 crossref(new window)
콜타르피치 기반 활성탄소섬유의 제조 및 특성에 관한 연구. II. 물리적 활성화법에 의한 활성탄소섬유의 구리(II), 니켈(II) 흡착 특성,최보경;윤광의;서민강;박수진;

한국섬유공학회지, 2015. vol.52. 2, pp.97-103 crossref(new window)
Preparation of novolac-type phenol-based activated carbon with a hierarchical pore structure and its electric double-layer capacitor performance, Carbon letters, 2014, 15, 3, 192  crossref(new windwow)
Influence of KMnO4 oxidation on the electrochemical performance of pitch-based activated carbons, Research on Chemical Intermediates, 2014, 40, 7, 2527  crossref(new windwow)
Preparation and Characterization of Coal Tar Pitch-based Activated Carbon Fibers. II. Cu(II) and Ni(II) Adsorption in Activated Carbon Fibers during Physical Activation, Textile Science and Engineering, 2015, 52, 2, 97  crossref(new windwow)
adsorption capacity of electrospun carbon fibers with thermal and chemical activation, Journal of Applied Polymer Science, 2017, 134, 47, 45534  crossref(new windwow)
Nguyen LN, Hai FI, Kang J, Price WE, Nghiem LD. Coupling granular activated carbon adsorption with membrane bioreactor treatment for trace organic contaminant removal: Breakthrough behaviour of persistent and hydrophilic compounds. J Environ Manage, 119, 173 (2013). crossref(new window)

Ahmad AA, Idris A, Hameed BH. Organic dye adsorption on activated carbon derived from solid waste. Desalin Water Treat, 51, 2554 (2013). crossref(new window)

Minakshi M, Meyrick D, Appadoo D. Maricite ($NaMn_1/_3Ni_1/_3Co_1/_3PO_4$)/ activated carbon: hybrid capacitor. Energy Fuels, 27, 3516 (2013). crossref(new window)

Lei C, Amini N, Markoulidis F, Wilson P, Tennison S, Lekakou C. Activated carbon from phenolic resin with controlled mesoporosity for an electric double-layer capacitor (EDLC). J Mater Chem A, 1, 6037 (2013). crossref(new window)

Kim DY, Park SJ, Jung YJ, Kim S. Electrochemical characterization of activated carbon-sulfur composite electrode in organic electrolyte solution. Carbon Lett, 14, 126 (2013). crossref(new window)

Harun MK, Yahya MZA, Abdullah S, Chan CH. Qualitative analysis of the effect of polymer solution and suspension properties on the electrospinning of nanocomposite fibers. Adv Mater Res, 686, 65 (2013). crossref(new window)

Patel N, Fernandes R, Gupta S, Edla R, Kothari DC, Miotello A. Co-B catalyst supported over mesoporous silica for hydrogen production by catalytic hydrolysis of Ammonia Borane: A study on influence of pore structure. Appl Catal B, 140-141, 125 (2013). crossref(new window)

Sun F, Gao J, Zhu Y, Chen G, Wu S, Qin Y. Adsorption of $SO_2$ by typical carbonaceous material: a comparative study of carbon nanotubes and activated carbons. Adsorption, in press (2013). crossref(new window)

Qin Y, Wang Y, Wang H, Gao J, Qu Z. Effect of morphology and pore structure of SBA-15 on toluene dynamic adsorption/desorption performance. Procedia Environ Sci, 18, 366 (2013). crossref(new window)

Bellino MG, Golbert S, De Marzi MC, Soler-Illia GJAA, Desimone MF. Controlled adhesion and proliferation of a human osteoblastic cell line by tuning the nanoporosity of titania and silica coatings. Biomater Sci, 1, 186 (2013). crossref(new window)

Fierro CM, Gorka J, Zazo JA, Rodriguez JJ, Ludwinowicz J, Jaroniec M. Colloidal templating synthesis and adsorption characteristics of microporous-mesoporous carbons from Kraft lignin. Carbon, in press (2013). crossref(new window)

Vovk EI, Turksoy A, Bukhtiyarov VI, Ozensoy E. Interactive Surface Chemistry of $CO_2$ and $NO_2$ on Metal Oxide Surfaces: Competition for Catalytic Adsorption Sites and Reactivity. J Phys Chem C, 117, 7713 (2013). crossref(new window)

Billemont P, Coasne B, De Weireld G. Adsorption of carbon dioxide, methane, and their mixtures in porous carbons: effect of surface chemistry, water content, and pore disorder. Langmuir, 29, 3328 (2013). crossref(new window)

Durimel A, Altenor S, Miranda-Quintana R, Couespel Du Mesnil P, Jauregui-Haza U, Gadiou R, Gaspard S. pH dependence of chlordecone adsorption on activated carbons and role of adsorbent physico-chemical properties. Chem Eng J, 229, 239 (2013). crossref(new window)

Song M, Jin B, Xiao R, Yang L, Wu Y, Zhong Z, Huang Y. The comparison of two activation techniques to prepare activated carbon from corn cob. Biomass Bioenergy, 48, 250 (2013). crossref(new window)

Bhati S, Mahur JS, Dixit S, Choubey ON. Surface and adsorption properties of activated carbon fabric prepared from cellulosic polymer: mixed activation method. Bull Korean Chem Soc, 34, 569 (2013). crossref(new window)

Oschatz M, Borchardt L, Senkovska I, Klein N, Leistner M, Kaskel S. Carbon dioxide activated carbide-derived carbon monoliths as high performance adsorbents. Carbon, 56, 139 (2013). crossref(new window)

Cheng Z, Sherman BJ, Lo CS. Carbon dioxide activation and dissociation on ceria (110): a density functional theory study. J Chem Phys, 138, 014702 (2013). crossref(new window)

Youssef AM, Hassan AF, Safan M. Modeling and characterization of steam-activated carbons developed from cotton stalks. Carbon Lett, 14, 14 (2013). crossref(new window)

Kong J, Yue Q, Huang L, Gao Y, Sun Y, Gao B, Li Q, Wang Y. Preparation, characterization and evaluation of adsorptive properties of leather waste based activated carbon via physical and chemical activation. Chem Eng J, 221, 62 (2013). crossref(new window)

Srenscek-Nazzal J, Kaminska W, Michalkiewicz B, Koren ZC. Production, characterization and methane storage potential of KOH-activated carbon from sugarcane molasses. Ind Crops Prod, 47, 153 (2013). crossref(new window)

Yang J, Qiu KQ. Preparation of activated carbons by $ZnCl_2$ activation from herb residues under vacuum. Carbon, 51, 437 (2013). crossref(new window)

Qie L, Chen WM, Wang ZH, Shao QG, Li X, Yuan LX, Hu XL, Zhang WX, Huang YH. Nitrogen-doped porous carbon nanofiber webs as anodes for lithium ion batteries with a superhigh capacity and rate capability. Adv Mater, 24, 2047 (2012). crossref(new window)

Brunauer S, Emmett PH, Teller E. Adsorption of gases in multimolecular layers. J Am Chem Soc, 60, 309 (1938). crossref(new window)

Barrett EP, Joyner LG, Halenda PP. The determination of pore volume and area distributions in porous substances. I. Computations from nitrogen isotherms. J Am Chem Soc, 73, 373 (1951). crossref(new window)