posted on 2018-03-26, 00:00authored byJeongHoon Lim, Hyeyoung Shin, MinJoong Kim, Hoin Lee, Kug-Seung Lee, YongKeun Kwon, DongHoon Song, SeKwon Oh, Hyungjun Kim, EunAe Cho
Bimetallic
PtNi nanoparticles have been considered as a promising
electrocatalyst for oxygen reduction reaction (ORR) in polymer electrolyte
membrane fuel cells (PEMFCs) owing to their high catalytic activity.
However, under typical fuel cell operating conditions, Ni atoms easily
dissolve into the electrolyte, resulting in degradation of the catalyst
and the membrane-electrode assembly (MEA). Here, we report gallium-doped
PtNi octahedral nanoparticles on a carbon support (Ga–PtNi/C).
The Ga–PtNi/C shows high ORR activity, marking an 11.7-fold
improvement in the mass activity (1.24 A mgPt–1) and a 17.3-fold improvement in the specific activity (2.53 mA cm–2) compared to the commercial Pt/C (0.106 A mgPt–1 and 0.146 mA cm–2).
Density functional theory calculations demonstrate that addition of
Ga to octahedral PtNi can cause an increase in the oxygen intermediate
binding energy, leading to the enhanced catalytic activity toward
ORR. In a voltage-cycling test, the Ga–PtNi/C exhibits superior
stability to PtNi/C and the commercial Pt/C, maintaining the initial
Ni concentration and octahedral shape of the nanoparticles. Single
cell using the Ga–PtNi/C exhibits higher initial performance
and durability than those using the PtNi/C and the commercial Pt/C.
The majority of the Ga–PtNi nanoparticles well maintain the
octahedral shape without agglomeration after the single cell durability
test (30,000 cycles). This work demonstrates that the octahedral Ga–PtNi/C
can be utilized as a highly active and durable ORR catalyst in practical
fuel cell applications.