The Open Electrochemistry Journal (Open Electrochem J )
The Open Electrochemistry Journal is an open access online journal, which publishes original full length, short research articles (letters) and reviews on all areas of fundamental and applied electrochemistry. The Open Electrochemistry Journal, a peer reviewed journal, aims to provide the most complete and reliable source of information on current developments in the field. The emphasis will be on publishing quality articles rapidly and freely available worldwide.
- Impact factor0.00
- 5-year impact0.00
- Cited half-life0.00
- Immediacy index0.00
- Article influence0.00
- WebsiteThe Open Electrochemistry Journal website
- Other titlesOEJ, Electrochemistry journal
- Material typeDocument, Internet resource
- Document typeInternet Resource, Computer File, Journal / Magazine / Newspaper
- Author can archive a pre-print version
- Author cannot archive a post-print version
- 12 months (unless federal, government, funding agencies or local policy mandates for the author's institute a different policy on self-archiving)
- On authors personal or authors institutions server
- Published source must be acknowledged
- Must link to journal home page
- Publisher's version/PDF cannot be used
- Articles in all journals can be made Open Access on payment of additional charge
- Classification yellow
Publications in this journal
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ABSTRACT: The electrochemical reduction of formic acid in acidic solution (2 mol L-1 HCl) on a Cu(88)Sn(6)Pb(6) cathode was studied. The main products of the reduction were methanol and ethanol having %Current Efficiencies (CEs) of 30.3 and 37.6% respectively at -0.8 V vs Ag/AgCl. Small amounts of methane and ethane were also detected. The rate of the reduction increased exponentially with the negative potential in the range -0.65 to -1.00 V and the maximum of the %CE was observed at -0.8 V. The rate of the reduction of HCOOH increased slightly with the concentration of HCOOH. In pure HCOOH as electrolyte a noticeable amount of CH3CHO (17.1%) was detected. A possible reduction mechanism was proposed in which the adsorbed CO is the key intermediate for the formation of all the products. Keywords: Copper, electrochemical reduction, ethanol, formic acid, lead, methanol, tin.The Open Electrochemistry Journal 01/2013; 5:8-12.
- The Open Electrochemistry Journal 01/2010; 2(1):11-14.
- The Open Electrochemistry Journal 01/2010; 2(1):22-42.
- The Open Electrochemistry Journal 01/2010; 2(1):15-21.
- The Open Electrochemistry Journal 01/2009; 1(1):1-7.
- The Open Electrochemistry Journal 01/2009; 1(1):37-41.
- The Open Electrochemistry Journal 01/2009; 1(1):42-47.
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ABSTRACT: Modified Pt and Ti substrates were prepared by electrodeposition of nanocrystallite Pt and Pt x –Sn y catalysts for electro-oxidation of ethanol, 1-propanol and 2-propanol. The chemical composition, the phase structure and the surface morphology of the Pt and Pt x –Sn y electrodeposits were studied by X-ray diffractometer (XRD), energy dispersive X-ray spectroscopy (EDX) and scanning electron microscope (SEM). Their electro-catalytic activities were studied in 0.5 M H 2 SO 4 by cyclic votlammetry and chronoamperometric techniques. It was found that, the nature of the substrate significantly affects the performance of the prepared catalyst towards electro-oxidation of different alcohols. Accordingly, the modified Pt substrates display enhanced catalytic activity and a higher stability towards alcohols electro-oxidation compared to the modified Ti substrates. Steady state Tafel plots experiments showed smoother and higher rate of alcohols oxidation on the modified Pt substrates than that on the modified Ti. High anodic Tafel slopes >200 for 1-propanol and 2-propanol electro-oxidation were obtained on Ti modified substrates indicating the complexity of the oxidation reaction on such electrodes.The Open Electrochemistry Journal 01/2009; 1(1):19-27.
Data provided are for informational purposes only. Although carefully collected, accuracy cannot be guaranteed. The impact factor represents a rough estimation of the journal's impact factor and does not reflect the actual current impact factor. Publisher conditions are provided by RoMEO. Differing provisions from the publisher's actual policy or licence agreement may be applicable.