frackowiak – chapters

Book chapters and Edition

Edition

[1]         F. Béguin and E. Frackowiak, Supercapacitors: Materials, Systems, and Applications. 2013.

[2]         F. Béguin and E. Frąckowiak, Carbons for Electrochemical Energy Storage and Conversion Systems. 2009.

 

Book chapters

[1]         E. Frackowiak, P. Ratajczak, and F. Béguin, “Electrochemical Capacitors Based on Carbon Electrodes in Aqueous Electrolytes,” in Advances in Electrochemical Science and Engineering, vol. 16, 2016, pp. 285–312.

[2]         E. Frackowiak, G. Lota, and K. Fic, “Carbon nanotubes for energy storage application,” in Nanotechnology in Advanced Electrochemical Power Sources, 2014, pp. 249–280.

[3]         E. Frackowiak, “Electrode Materials with Pseudocapacitive Properties,” in Supercapacitors: Materials, Systems, and Applications, 2013, pp. 207–237.

[4]         F. Beguin, E. Raymundo-Pinero, and E. Frackowiak, “Electrical double layer capacitors and pseudocapacitors,” in Carbon Materials for Electrochemical Energy Storage Systems, F. Beguin and E. Frackowiak, Eds. CRC Press, 2010, pp. 329–375.

[5]         E. Frackowiak and F. Béguin, “Carbon-Based Nanomaterials for Electrochemical Energy Storage,” in Nanotechnology for the Energy Challenge, 2010, pp. 177–204.

[6]         F. Beguin, E. Raymundo-Pinero, and E. Frackowiak, “Electrical double layer capacitors and pseudocapacitors,” in Carbon Materials for Electrochemical Energy Storage Systems, F. Beguin and E. Frackowiak, Eds. CRC Press, 2009.

[7]         E. Frackowiak, “Carbon nanotubes for storage of energy: supercapacitors,” in Encyclopedia of Nanoscience and Nanotechnology, Dekker: Taylor & Francis, 2008, pp. 707–721.

[8]         F. Beguin and E. Frackowiak, “Nanotextured carbons for high performance supercapacitors and electrochemical hydrogen storage,” in Carbon Materials: Theory and Practice, A. P. Terzyk, P. A. Gauden, and P. Kowalczyk, Eds. Kerala, India: Research Signpost, 2008, pp. 283–304.

[9]         F. Beguin and E. Frackowiak, “Electrochemical Energy Storage,” in Adsorption by Carbons, Bottani E.J., Ed. Tascon J.M.D: Elsevier, 2008, pp. 593–625.

[10]      E. Frackowiak, “Nanotubes based composites for energy storage in supercapacitors,” in Trans Tech Publications, Disclosing Materials at the Nanoscale – Advances in Science and Technology, vol. 51, Switzerland, 2006, pp. 145–155.

[11]      F. Beguin et al., “Mechanism of reversible and irreversible insertion in nanostructured carbons used in lithium-ion batteries,” in New Carbon Based Materials for Electrochemical Energy Storage Systems, NATO Science Se-ries, Mathematics, Physics and Chemistry – vol. 229, Dordrecht, The Netherlands: Springer, 2006, pp. 231–243.

[12]      E. Frackowiak et al., “Novel carbonaceous materials for application in the electrochemical supercapacitors,” in New Carbon Based Materials for Electrochemical Energy Storage Systems: Batteries, Supercapacitors and Fuel Cells, vol. 229, 2006, pp. 5–20.

[13]      F. Beguin and E. Frackowiak, “Nanotextured carbons for electrochemical energy storage,” in Handbook of nanomaterials, Y. Gogotsi, Ed. CRC Press, 2006, pp. 713–737.

[14]      V. Khomenko et al., “Development of supercapacitors based on conducting polymers,” in New Carbon Based Materials for Electrochemical Energy Storage Systems: Batteries, Supercapacitors and Fuel Cells, vol. 229, 2006, pp. 41–50.

[15]      E. Frackowiak and F. Beguin, “Application of nanoporous carbons and nanotube composites for supercapacitors,” in Recent Advances in Supercapacitors, V. Gupta, Ed. Kerala, India: Transworld Research Network, 2006, pp. 79–114.

[16]      F. Beguin et al., “Carbon nanotubes as backbones for composite electrodes of supercapacitors,” in Electronic Properties of Synthetic Nanostructures, vol. 723, 2004, pp. 460–464.

[17]      E. Frackowiak et al., “Application of metal coated carbon nanotubes to direct methanol fuel cells and for the formation of nanowires,” in Electronic Properties of Synthetic Nanostructures, vol. 723, 2004, pp. 532–535.

[18]      E. Frackowiak, K. Jurewicz, S. Delpeux, F. Beguin, L. M. LizMarzan, and M. Giersig, “Electrochemical application of carbon nanotubes,” Low-Dimensional Syst. Theory, Prep. Some Appl., vol. 91, pp. 305–318, 2003.

[19]      E. Frackowiak et al., “Storage of energy in supercapacitors from nanotubes,” Electron. Prop. Nov. Mater. Nanostructures, vol. 544, pp. 533–536, 2000.

[20]      E. Frackowiak et al., “Capacitance properties of carbon nanotubes,” in Electronic Properties of Novel Materials – Science and Technology of Molecular Nanostructures, vol. 486, 1999, pp. 429–432.

[21]      F. Beguin et al., “Alkali-metal intercalation in carbon nanotubes,” in Electronic Properties of Novel Materials – Science and Technology of Molecular Nanostructures, vol. 486, 1999, pp. 273–277.

[22]      S. Gautier, E. Frackowiak, S. Bonnamy, F. Beguin, K. M. Kadish, and R. S. Ruoff, “Electrochemical insertion of lithium in catalytic multiwall carbon nanotubes,” in Recent Advances in the Chemistry and Physics of Fullerenes and Related Materials, Vol 6, vol. 98, 1998, pp. 1291–1301.

[23]      E. Frackowiak et al., “Carbon fluoride cathode for lithium cells,” in New Promising Electrochemical Systems For Rechargeable Batteries, vol. 6, 1996, pp. 85–100.

[24]      E. FRACKOWIAK, K. JUREWICZ, F. Lapicque, A. Storck, and A. A. Wragg, “IMPROVEMENT OF SECONDARY ZINC ELECTRODES,” Electrochem. Eng. Energy, pp. 41–46, 1994.

[25]      E. FRACKOWIAK, T. KEILY, and B. W. BAXTER, “MODIFICATION OF SECONDARY ZINC ELECTRODE,” in Power Sources 13, 1991, pp. 225–235.