Pine Research Instrumentation logo
HomeProductsLegacy ProductsLegacy Electrochemical Workstations

Computer-Controlled Bipotentiostat

Part Number
AFCBP1
Computer-Controlled Bipotentiostat
Computer-Controlled Bipotentiostat - Image 2
Computer-Controlled Bipotentiostat - Image 3
Product Discontinued - Replacement Available

This product has been discontinued and can no longer be purchased. The product remains on our website for reference and a listing of its specifications. We suggest purchasing the replacement product, WaveDriver 40 Electrochemical Workstation.

View Replacement Product

The AFCBP1 bipotentiostat is a general purpose electrochemical instrument with a built-in analog voltage Sweep Generator. It can function as a traditional potentiostat or galvanostat using three electrodes (working, reference, and counter electrodes), and it may also independently control an additional (second) working electrode. While this “bi”-potentiostat feature was originally designed for use in classic ring-disk electrode voltammetry, the instrument has also found use in many other dual working electrode techniques.

Login to View Prices

Customers must be logged into their account to view prices. Not all regions provide pricing online. If you do not see prices, you can obtain them from the designated sales channel in your region.

Categories
Legacy Products > Legacy Electrochemical Workstations
Tags
,
Computer-Controlled Bipotentiostat
Computer-Controlled Bipotentiostat - Image 2
Computer-Controlled Bipotentiostat - Image 3

The AFCBP1 bipotentiostat is a general purpose electrochemical instrument with a built-in analog voltage Sweep Generator. It can function as a traditional potentiostat or galvanostat using three electrodes (working, reference, and counter electrodes), and it may also independently control an additional (second) working electrode. While this “bi”-potentiostat feature was originally designed for use in classic ring-disk electrode voltammetry, the instrument has also found use in many other dual working electrode techniques.

References
  1. Thimiopoulos, A.; Vogiatzi, A.; Simandiras, E.D.; Mousdis, G.A.; Psaroudakis, N. Synthesis, characterization and DFT analysis of new phthalocyanine complexes containing sulfur rich substituents. Inorganica Chimica Acta 2019, 488, 170-181.
  2. Shao, J.; Johnson, A.; Hansen, C.A.; Kadish, K.M.; Han, B. Electroreductive dechlorination of γ-Hexachlorocyclohexane catalyzed by Rh2(dpf)4 in nonaqueous media, where dpf=N,N′-Diphenylformamidinate (1-) ion. Journal of Electroanalytical Chemistry 2019, 837, 208-218.
  3. Bystron, T.; Sramkova, E.; Dvorak, F.; Bouzek, K. Glassy carbon electrode activation – A way towards highly active, reproducible and stable electrode surface. Electrochimica Acta 2019, 299, 963-970.
  4. Li, T.; Deng, H.; Liu, J.; Jin, C.; Song, Y.; Wang, F. First-row transition metals and nitrogen co-doped carbon nanotubes: The exact origin of the enhanced activity for oxygen reduction reaction. Carbon 2019, 143, 859-868.
  5. Abrego-Martínez, J.C.; Wang, Y.; Moreno-Zuria, A.; Wei, Q.; Cuevas-Muñiz, F.M.; Arriaga, L.G.; Sun, S.; Mohamedi, M. Nanostructured Mn2O3/Pt/CNTs selective electrode for oxygen reduction reaction and methanol tolerance in mixed-reactant membraneless micro-DMFC. Electrochimica Acta 2019, 297, 230-239.
  6. Caron, E.; Brown, C.M.; Hean, D.; Wolf, M.O. Variable oxidation state sulfur-bridged bithiazole ligands tune the electronic properties of ruthenium(II) and copper(I) complexes. Dalton Trans. 2019, 48, 1263-1274.
  7. Henning, S.; Herranz, J.; Gasteiger, H.A. Bulk-Palladium and Palladium-on-Gold Electrocatalysts for the Oxidation of Hydrogen in Alkaline Electrolyte. J. Electrochem. Soc. 2015, 162, F178-F189.
  8. Yang, X.; Liu, Y.; Li, S.; Wei, X.; Wang, L.; Chen, Y. A direct borohydride fuel cell with a polymer fiber membrane and non-noble metal catalysts. Sci. Rep. 2012, 2, 567.
  9. Wu, H.; Wexler, D.; Wang, G. PtxNi alloy nanoparticles as cathode catalyst for PEM fuel cells with enhanced catalytic activity. Journal of Alloys and Compounds 2009, 488, 195-198.
  10. Schmidt, T.J.; Paulus, U.A.; Gasteiger, H.A.; Behm, R.J. The oxygen reduction reaction on a Pt/carbon fuel cell catalyst in the presence of chloride anions. J. Electroanal. Chem. , 508, 41–47.
  11. Schild, J. Catalyseurs supportés sur nanotubes de carbone pour la production d’énergies bas carbone. Ph.D. Dissertation, University of Paris - Saclay, .
Login
Register
Lost Password

Please enter your username (email address) and password below.

Confirm Logout

Are you sure you want to log out?

Yes, Logout Cancel

Request a Quote for this Cart

Below is the billing data we have on file. These details will be used on your quotation, so please update them here if you require any changes. Changing any details here updates them for your account.