Abstract
The ORR on surfaces of Ni-SiNT, Ni2-SiNT, Pt2-CNT, and Pt2-Si82 catalysts are investigated and compared with platinum metal catalysts. The structure–activity parameters for Ni-SiNT, Ni2-SiNT, Pt2-CNT, and Pt2-Si82 and their complexes with species are calculated and compared. The *OOH-nano-compounds can perform the pathway 1 which includes the reactions c, d, and e and pathway 2 which contains the reactions f, g, and h. When the amounts of U for ORR on Ni-SiNT, Ni2-SiNT, Pt2-CNT, and Pt2-Si82 are reached to 0.82, 0.85, 0.80, and 0.78 V, the reactions are downhill. Over-potential for ORR on Ni-SiNT, Ni2-SiNT, Pt2-CNT, and Pt2-Si82 are 0.41, 0.38, 0.43, and 0.45 V, respectively. The Ni2-SiNT can better catalyze the ORR than Ni-SiNT, Pt2-CNT, and Pt2-Si82 by lower over-potential.
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21 December 2022
This article has been retracted. Please see the Retraction Notice for more detail: https://doi.org/10.1007/s11581-022-04864-1
References
Timoshenko J (2021) Beatriz Roldan Cuenya. Chem Rev 121(2):882–961
Trindell JA, Duan Z (2020) Chem Rev 120(2):814–850
Xiao W, Lei W, Xin, Wang D (2018) ACS Catal 8(4):3237–3256
Marakatti VS (2017) ACS Appl Mater Interfaces 9(4):3602–3615
Chang F, Shan S (2016) J Am Chem Soc 138(37):12166–12175
Scofield ME, Zhou Y (2016) ACS Catal 6(6):3895–3908
Kaito T (2016) Hiroyuki Tanaka. J Phys Chem C 120(21):11519–11527
Shao M, Chang Q (2016) Chem Rev 116(6):3594–3657
Jinfang Wu, Shan S (2015) ACS Appl Mater Interfaces 7(46):25906–25913
Arán-Ais RM (2015) Nano Lett 15(11):7473–7480
Jinfang Wu, Shan S (2015) ACS Catal 5(9):5317–5327
Tan XueHai, Prabhudev S (2015) ACS Catal 5(3):1513–1524
Erini N (2014) Rameshwori ACS Catal 4(6):1859–1867
Shan S, Petkov V (2014) J Am Chem Soc 136(19):7140–7151
Antolini E (2014) ACS Catal 4(5):1426–1440
Shan S, Petkov V (2013) ACS Catal 3(12):3075–3085
Takahashi M (2020) Bull Chem Soc Jpn 93(1):37–42
Ahmad YH (2019) Assem T. Electrochem Commun 101:61–67
Petkov V, Maswadeh Y (2019) Nanoscale 11(12):5512–5525
G Darabdhara, PK Boruah (2019) Microchimica Acta 186 (1)
Belenov SV, Guterman VE (2018) Russ J Electrochem 54(12):1209–1221
Ding Z, Tang Z (2018) Inorganic Chem Front 5(10):2425–2431
Luo M, Sun Y (2017) Adv Energy Mater 7(11):1602073
Sheng Hu, Goenaga G (2016) Appl Catal B 182:286–296
Qaseem A, Chen F (2016) Catal Sci Technol 6(10):3317–3340
Zhu L, Zheng J (2016) RSC Adv 6(16):13110–13119
Petkov V, Prasai B (2016) Nanoscale 8(20):10749–10767
Kolla P, Smirnova A (2015) Electrochim Acta 182:20–30
Shan S, Jinfang Wu (2015) Catalysts 5(3):1465–1478
Cai F, Shan S, Yang L (2015) Sci China Chem 58(1):14–28
Zhang X, Tang Y, Zhang F, Lee C (2016) Adv Energy Mater 6(11):1502588
Wang M, Jiang C, Zhang S, Song X, Tang Y, Cheng H (2018) Nat Chem 10(6):667–672
Li J, Wang F, He Y (2020) Sustainability (Basel, Switzerland) 12(24):10537
Yan W, Cao M, Fan S, Liu X, Liu T, Li H, Su J (2021) Composites. Part B Eng 213:108732
Li H, Xu P, Liu D, He J, Zu H, Song J, Wang F (2021) Nanotechnology 32(37):375202
Li T, Yin W, Gao S, Sun Y, Xu P, Wu S, Wei G (2022) Nanomaterials 12(6):12060982
Liu H, Li X, Ma Z, Sun M, Li M, Zhang Z, Guo S (2021). Nano Lett. https://doi.org/10.1021/acs.nanolett.1c03381
Huo J, Wei H, Fu L, Zhao C, He C (2022). Chin Chem Lett. https://doi.org/10.1016/j.cclet.2022.02.066
Zhang M, Sun X, Wang C, Wang Y, Tan Z, Li J, Xi B (2022) Mater Chem Phys 278:125697
Qing, W. Xinmin, W. Shuo, P. (2022) China J Mol Struct 1255
You J, Liu C, Feng X, Lu B, Xia L, Zhuang X (2022) Carbohydrate polymershttps://doi.org/10.1016/j.carbpol.2022.119332
Jia J, Cao Y, Wu T, Tao Y, Pan Y, Huang F, Tang H (2021) ACS Catal 11(12):6944–6950
Ren S, Ye B, Li S, Pang L, Pan Y, Tang H (2021). Nano Res. https://doi.org/10.1007/s12274-021-3694-3
Wang Z, Lei Q, Wang Z, Yuan H, Cao L, Qin N, Liu J (2020) Chem Eng J 395:125180
Wang H, Cui J, Zhao Y, Li Z, Wang J (2021) Green Chem 23:405–411
Xie J, Hao W, Wang F (2022) Int J Hydrogen Energy 47(12):7975–7989
Lang X, Wang T, Wang Z, Li L, Yao C, Cai K (2022) Electrochimica acta 403:139723
Wang T, Lang X, Li L, Yao C, Liu J, Shi R, Cai K (2022) J Alloys Compd 902:162650
Andalib V, Sarkar J (2021) J Stat Theory Appl 20(2):180–192
Andalib V, Sarkar J (2022) Mathematics 10(6):852
Latif M, Zhang D, Gamez G (2021) Analytica Chimica Acta 1163:338507
Nourian P, Islam R, Khare R (2021) J Rheol 65(4):617–632
SundaravadiveluDevarajan D, Nourian P, McKenna GB, Khare R (2020) J Rheol 64(3):529–543
Ethier JG, Nourian P, Islam R, Khare R, Schieber JD (2021) J Rheol 65(6):1255–1267
Yosofvand M, Liyanage S, Kalupahana NS, Scoggin S, Moustaid-Moussa N, Moussa H (2020) Adipocyte 9(1):360–373
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Salahdin, O.D., Majdi, A., Opulencia, M.J.C. et al. RETRACTED ARTICLE: Oxygen reduction reaction on metal-doped nanotubes and nanocages for fuel cells. Ionics 28, 3409–3419 (2022). https://doi.org/10.1007/s11581-022-04564-w
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DOI: https://doi.org/10.1007/s11581-022-04564-w