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Electrocatalysis of the Hydrogen Oxidation Reaction and Sodium Borohydride on Dispersed Catalysts Formed by AB5-type Metal Hydride Alloys

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Author(s):
Waldemir José Paschoalino Junior
Total Authors: 1
Document type: Doctoral Thesis
Press: São Carlos.
Institution: Universidade de São Paulo (USP). Instituto de Química de São Carlos (IQSC/BT)
Defense date:
Examining board members:
Edson Antonio Ticianelli; Assis Vicente Benedetti; Marcos Roberto de Vasconcelos Lanza
Advisor: Edson Antonio Ticianelli
Abstract

This work provides insights into the processes involved in the borohydride oxidation reaction (BOR) and hydrogen oxidation reaction in alkaline media on metal hydride alloys formed by LaNi4.7Sn0.2Cu0.1 and LaNi4.78Al0.22 with and without deposited Pt, Pd and Au, LaNi4,78Mn0,22 and LaNi4,7Sn0,2Co0,1. Measurements of BET, TEM, in situ XRD, DRIFTS, RRDE (gold ring) and OLEMS were made with the aim to characterize all the materials by different methodologies. The present investigation showed that the state of hydriding of LaNi4.7Sn0.2Cu0.1 and LaNi4.78Al0.22 is important in defining the kinetics and outcome of the BOR at these materials. The extent of hydride formation has been shown to depend on the rate of the BH4- hydrolysis, the hydrogen storage capacity of the alloy, and kinetics of H atom diffusion inside the alloy. The activity for the direct BOR is low in both bare metal hydride alloys, but the rate of the BH4- hydrolysis and the hydrogen storage capacity are higher, while the rate of H diffusion is slower in the bare LaNi4.78Al0.22. Results have shown that both the bare and all the noble metal modified alloys can be hydrided either electrochemically or by exposure to BH4- solutions, although for the LaNi4.78Al0.22-based materials the extent of this phenomenon is smaller. A continuous hydriding of all LaNi4.7Sn0.2Cu0.1-based and the bare LaNi4.78Al0.22 alloys are observed in the chronoamperometric BH4- oxidation measurements at low current densities. Addition of Pt on both alloys resulted in an increase of the BH4- hydrolysis, but the H2 formed is rapidly oxidized, confirming the initial predictions for this noble metal. In addition, the rates of the alloy hydriding/de-hydriding were not significantly affected by the presence of Pt, but this was not the case for Pd and Au, for which there was a drastic reduction of the rate of these processes. In the case of gold some increase of the BH4- hydrolysis is observed, although its presence does not change significantly the performances of the bare alloys. It was possible to confirm the formation of BH3OH- for all the samples by RRDE measurements, however for LaNi4.7Sn0.2Cu0.1 the formation of this product was lower compared to the other samples. Results showed that the first step of the electrode process is the hydriding of alloy by the hydrogen formed in the BH4- hydrolysis. The in situ XRD results have shown that the method of charging of the alloy, electrochemical or chemical, leads to different phase predominance and different site occupancies, but both methods lead to almost the same discharge capacity. In the electrolysis process, the α-β phase transition is predominant while in the chemical charging by the exposure to borohydride solution the α-β phase transition is more important. The results have also shown that the alloys with and without Pt lead essentially to the same phenomena, either with respect to the alloy structure and the electrochemical characteristics. All these phenomena point to the bare LaNi4.7Sn0.2Cu0.1 as a more adequate alloy system for applications in DBFC/MHB batteries. (AU)

FAPESP's process: 12/09109-2 - Electrocatalysis of the hydrogen oxidation reaction and sodium borohydride on dispersed catalysts formed by AB5-type metal hydride alloys
Grantee:Waldemir José Paschoalino Junior
Support Opportunities: Scholarships in Brazil - Doctorate (Direct)