DEVELOPMENT OF MEMBRANE-ELECTRODE ASSEMBLIES PROTOTYPES BASED PLATINUM NANOCOMPOSITES FOR ENERGY SOURCES


Cite item

Full Text

Open Access Open Access
Restricted Access Access granted
Restricted Access Subscription Access

Abstract

Electrode materials with platinum nanoparticles on combined polymer-carbon matrix-carriers had been formed. Model tests of hydrogen-air fuel cells with varying loading and sizes of platinum nanoparticles had been carried out. It was found that the maximum value of specific power (64 mW/cm2) and current density (122-128 mA/cm2) are achieved when the catalyst load was 0.32 mg/cm2 and the nanoparticle size was 2-4 nm.

Full Text

Restricted Access

About the authors

Marina Vladimirovna Lebedeva

MIREA - Russian Technological University

Email: lebedevamv@mitht.ru
Candidate of Chemical Sciences; associate professor of Physical Chemistry. Ya.K. Syrkin Moscow, Russian Federation

Alexey Petrovich Antropov

MIREA - Russian Technological University

Email: alexeyantrop@yandex.ru
Candidate of Technical Sciences; associate professor, Department of Energy Technologies, Systems and Installations Moscow, Russian Federation

Alexander Victorovich Ragutkin

MIREA - Russian Technological University

Email: ragutkin@mirea.ru
Candidate of Technical Sciences; vice-rector for Innovative Development Moscow, Russian Federation

Nicolay Andreevich Yashtulov

MIREA - Russian Technological University

Email: yashtulovna@mail.ru
Doctor of Chemical Sciences; professor, Department of Energy Technologies, Systems and Installations Moscow, Russian Federation

References

  1. Dicks A., Rand D.A.J. Fuel cell systems explained. Wiley, London, 2018. 479 p.
  2. Ozoemena K.I., Chen S. Nanomaterials for fuel cell catalysis. Springer, 2016. 583 p.
  3. Goodarzi G.A., Hayes J.G. Electric powertrain: energy systems, power electronics & drives for hybrid, electric & fuel cell vehicles. Wiley, London, 2018. 557 p.
  4. Яштулов Н.А., Лебедева М.В. Водородная энергетика возобновляемых источников тока // Российский технологический журнал. 2017. № 5. С. 58-73. [Yashtulov N.A., Lebedeva M.V. Hydrogen energy of renewable current sources. Russian Technological Journal. 2017. No. 5. Р. 58-73.]
  5. Lebedeva M.V., Antropov A.P., Ragutkin A.V., Yashtulov N.A. The electrode materials based on carbon nanotubes and polymer matrix modified with platinum catalysts for chemical power sources. International Journal of Applied Engineering Research. 2018. No. 13. P. 16774-16777.
  6. Яштулов Н.А., Лебедева М.В., Рагуткин А.В., Зайцев Н.К. Электродные материалы на основе пористого кремния с наночастицами платины для химических источников тока // Журнал прикладной химии. 2018. № 91. С. 232-237. [Yashtulov N.A., Lebedeva M.V., Ragutkin A.V., Zaitsev N.K. Porous silicon-based electrode materials with platinum nanoparticles for chemical current sources. Journal of Applied Chemistry. 2018. No. 91. P. 232-237.]
  7. Yashtulov N.A., Lebedeva M.V., Patrikeev L.N., Zaitcev N.K. New polymer-graphene nanocomposite electrodes with platinum-palladium nanoparticles for chemical power sources. eXPRESS Polymer Letters. 2019. No. 13. P. 739-748.
  8. Abouzari-Lotf E., Zakeri M., Nasef M.M. et al. Highly durable polybenzimidazole composite membranes with phosphonated graphene oxide for high temperature polymer electrolyte membrane fuel cells. Journal of Power Sources. 2019. No. 412. P. 238-245.

Supplementary files

Supplementary Files
Action
1. JATS XML
Download


This website uses cookies

You consent to our cookies if you continue to use our website.

About Cookies