Introduction Enhancement of the oxygen reduction reaction (ORR) is important for the development of fuel cells. Pt oxides are blocking species of the ORR on Pt electrodes.1,2 Theoretical calculation predicts that the change of adsorbed water structure inhibits the formation of Pt oxides on n(111)−(111) series of Pt, resulting in the high ORR activity of this series.3 In the notation of high index planes n(hkl)−(mno), n, (hkl) and (mno) show the number of terrace atomic rows, structures of terrace and step, respectively.Hydrophobic species also changes water structure around electrode surfaces. Modification with alkyl amines (OA/PA) and melamine enhances the ORR activity of Pt nanoparticles.4,5 This paper summarized the structural effects on the enhancement of the ORR by hydrophobic species on single crystal electrodes of Pt6 and Pt x Pd y Co z . Experimental Linear sweep voltammograms were measured using rotating disk electrode (RDE) in 0.1 M HClO4 saturated with O2. Potential was scanned positively from 0.05 V(RHE) at scanning rate of 0.010 V s−1. The ORR activity was estimated using the specific activity at 0.90 V(RHE). Hydrophobic species examined were alkyl amines (OA/PA), tetraalkyl ammonium cation (THA+) and melamine. The structure formulae and the hard sphere models of single crystal electrodes are shown in Fig. 1. Results and Discussion <Pt single crystal electrodes> Alkyl amines (OA/PA) enhance the ORR activity on n(111)-(111) series of Pt with 7 ≤ n.7 This fact indicates that wide (111) terrace (7 ≤ n) is necessary for the ORR activation by OA/PA. The ORR activity on flat Pt(111) is most activated by OA/PA. However, OA/PA markedly deactivates the ORR on flat Pt(100). Wide flat hexagonal terrace plays a key role in the activation by OA/PA. Modification with OA/PA decreases the charges of Pt oxide formation of voltammograms of all the single crystal electrodes, even on the surfaces of which ORR activity decreases after the modification. Infrared reflection absorption spectroscopy (IRAS) shows that the formation of ice-like water with smaller cluster size enhances the ORR activity after OA/PA modification.8 The ORR activity of Pt(111) is enhanced with the increase of the alkyl chain length of tetraalkyl ammonium cation. The ORR activity of Pt(111) modified with THA+ is 8 times as high as that of bare Pt(111).9 IRAS band intensity of PtOH decreases markedly after THA+ modification. This fact indicates that the ORR activity of Pt(111) is extremely high without Pt oxides. THA+ slightly enhanced the activity of Pt(331) = 3(111)-(111) that has the highest ORR activity in single crystal Pt electrodes. Melamine enhances the ORR activity on all the n(111)-(111) series of Pt.10 The activity on Pt(111) is enhanced most markedly again after melamine modification. Melamine also increases the activity of Pt(331) twice, giving the highest activity in the Pt single crystal electrodes examined. IRAS spectra show that the enhancement of the activity was attributed to the decrease of the coverage of PtOH. <Pt x Pd y Co z single crystal electrodes> Pt x Pd y Co z single crystal electrodes have higher ORR activity than Pt and Pt3Co single crystal electrodes.11 THA+ enhances the ORR activity of Pt x Pd y Co z (111) electrodes. The ORR activity of PtPd0.1Co0.2(111) modified with THA+ is 3.7 and 19 times as high as that of bare PtPd0.1Co0.2(111) and Pt(111), respectively. However, THA+ deactivates the ORR on Pt x Pd y Co z (100) and Pt x Pd y Co z (110) electrodes. Melamine increases the ORR activity of all the Pt x Pd y Co z single crystal electrodes. The enhancement ratio of PtPd0.1Co0.2(111) (2.1) is the highest in Pt x Pd y Co z single crystal electrodes examined. Acknowledgements This study was supported by New Energy and Industrial Technology Development Organization (NEDO). References N. M. Marković, H. A. Gasteiger, B. N. Grgur, and P. N. Ross, J. Electroanal. Chem., 467, 157 (1999). T. Ueno, H. Tanaka, S. Sugawara, K. Shinohara, A. Ohma, N. Hoshi, and M. Nakamura, J. Electroanal. Chem., 800, 162 (2017). R. Jinnouchi, K. Kodama, and Y. Moromoto, J. Electroanal. Chem., 716, 31 (2014).K. Miyabayashi, H. Nishihara, and M. Miyake, Langmuir, 30, 2936 (2014). M. Asahi, S. Yamazaki, N. Taguchi, and T. Ioroi, J. Electrochem. Soc., 166, F498 (2019). N. Hoshi, and M. Nakamura, Chem. Lett., 50, 72 (2021). K. Saikawa, M. Nakamura, and N. Hoshi, Electrochem. Commun., 87, 5 (2018). N. Hoshi, K. Saikawa, and M. Nakamura, Electrochem. Cummun., 106, 106536 (2019). T. Kumeda, H. Tajiri, O. Sakata, N. Hoshi, and M. Nakamura, Nat. Commun., 9, 4378 (2018). N. Wada, M. Nakamura, and N. Hoshi, Electrocatalysis, 11, 275 (2020). M. Torihata, M. Nakamura, N. Todoroki, T. Wadayama, and N. Hoshi, Electrochem. Commun., 125, 107007 (2021). Figure 1
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