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Highly Active and Durable Transition Metal Oxide-Based Oxygen Electrode Catalysts for Unitized Reversible Fuel Cells

Choi, Sung Ryul ; Choi, Sungyong ; Kim, Dongyeong ; [et al.]

The Electrochemical Society ; 2020

In: ECS Meeting Abstracts Vol. MA2020-01, No. 37 ( 2020-05-01), p. 1572-1572

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In: ECS Meeting Abstracts, The Electrochemical Society, Vol. MA2020-01, No. 37 ( 2020-05-01), p. 1572-1572

Abstract: Facing with the increasing environmental concerns for global warming and environmental pollutions, it is essential to develop renewable and sustainable energy sources to substitute traditional fossil fuel-based technologies. As a major candidate technology, unitized reversible fuel cells (URFCs) are recognized as a promising electrochemical energy conversion device due to their high energy efficiency and negligible carbon emissions [1]. However, the low electrocatalytic activity related to the large overpotential loss for oxygen reduction reaction (ORR) and oxygen evolution reaction (OER) is the key technical issue for the development of URFCs [2] . Until now, precious metal-based catalysts (e.g., Pt/C, Ir/C, and IrO 2 ) have been used for OER and ORR in URFCs due to high electrocatalytic activity [3]. Nevertheless, making commercialization of URFCs has hampered by the scarcity and limited durability of these materials [4, 5] . In order to solve these technical barriers, non-precious transition metal oxide based materials have considered as promising alternatives for bifunctional OER and ORR electrocatalysts because of their low cost, earth-abundance, and long-term stability [6] . However, transition metal-based oxygen catalysts have several issues such as low electrical conductivity, small surface area, and low electroactivity. Herein, as main strategies to improve bifunctional electrocatalytic activity for OER and ORR, other transition metals are doped to increase intrinsic property of oxide materials with hybridizing with highly conductive carbonaceous materials as supporting material. The synthesized catalysts are analyzed by various physicochemical and electrochemical analysis tools [7. 8]. References 1. Landon, E. Demeter, N. Inoglu, C. Keturakis, I. Wachs, R. Vasic, A. Frenkel, and J. Kitchin, ACS. Catal. 8 , 1793 (2012). 2. Fominykh, P. Chernev, I. Zaharieva, J. Sicklinger, G. Stefanic, M. Doblinger, A. Muller, A. Pokharel, S. Bocklein, C. Scheu, T. Bein, and D. F. Rohifing, ACS. Nano . 5 , 5180 (2015). 3. Ren, Z. Ma, and P. G. Bruce , Chem. Soc. Rev . 41 , 4909 (2012). 4. Han, N. Chen, J. Zhang and L. Qu, Mater. Horiz . 4 , 832 (2017) 5. W. Louie, and A.T. Bell, J. Am. Chem. Soc . 33 , 12329 (2013). 6. -F. Li, and A. Selloni, ACS Catal . 4 , 1148 (2014). 7. -I. Kim, Y.J. Sa, S.-H. Cho, I. So, K. Kwon, S.H. Joo, and J.-Y. Park, J. Electrochem. Soc. 163 , F3020 (2016). 8. -S. So, N.-I. Kim, S.-H. Cho, Y.-R. Kim, J. Yoo, Y. Seo, Y.-S. Seo, B. Park, K. Kwon, and J.-Y. Park, J. Electrochem. Soc. 163 , F3041 (2016). Keywords: Oxygen evolution reaction; Oxygen reduction reaction; Bifunctional electrocatalyst; Unitized reversible fuel cell; Transition metal oxide.

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ISSN: 2151-2043

URL: Article

DOI: 10.1149/MA2020-01371572mtgabs

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Publisher: The Electrochemical Society

Publication Date: 2020

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Oxygen Evolution and Reduction Activity of Perovskite-Based Oxide Catalysts

Park, Jun-Young ; Kim, Nam-In ; Choi, Sung Ryul ; [et al.]

The Electrochemical Society ; 2016

In: ECS Meeting Abstracts Vol. MA2016-02, No. 53 ( 2016-09-01), p. 3959-3959

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In: ECS Meeting Abstracts, The Electrochemical Society, Vol. MA2016-02, No. 53 ( 2016-09-01), p. 3959-3959

Abstract: Unitized regenerative fuel cells (URFCs), which include fuel cells and water electrolyzers, have received many interests because the hydrogen fuel and electricity can be produced by only an electrochemical device. However, the oxygen electrode in the URFCs exhibit slow kinetics for both oxygen evolution reactions (OERs) and oxygen reduction reactions (ORRs). As a results, efficiency of the hydrogen production using URFCs is limited due to the high polarization resistance of the electrode for water splitting. Likewise, the productions of electricity are also restricted by the tardiness of ORRs because of the 4-electrons multi-step electrochemical reactions, then decreasing the overall reaction rate of the fuel cells. Up to now, the noble metal-based catalysts, such as carbon-supported platinum, iridium, ruthenium and their alloys, have still used as bifunctional OER and ORR catalysts to overcome the slow reaction kinetics. However, the utilization of precious metal-based catalysts is inappropriate for making the commercialization of the electrochemical cells. In order to replace these expensive catalysts, researches of perovskite-based oxide catalysts for URFCs have performed significantly. In particular, double-perovskite structured materials show the great potential as the bifunctional electrocatalyst with various dopants such as lanthanides (A-site) and transition metals (B-site). In this study, the double perovskite-based catalyst are selected and several transition metals (Mn, Fe, Ni and Cu) are doped to enhance their electrocatalytic activity and durability. The catalysts are synthesized by the combustion method and calcined at 900 o C for 4h in the electric furnace at a heating rate of 5 o C min -1 . The physicochemical properties of the final samples are characterized by various tools such as X-ray diffraction, X-ray photoelectron spectroscopy, scanning electron microscope and transmission electron microscope. For the electrochemical analysis, a rotating disk electrode (RDE) system is used with a 0.1 M KOH solution, an Hg/HgO and a Pt wire for electrolyte, reference electrode and counter electrode, respectively. The electrochemical activities are measured by linear sweep voltammetry (LSV) at a scan rate of 5 mV s -1 for OER (1.2~1.7 V) and ORR (0.05~1.2 V). The long-term stability of the catalysts for OER are also analyzed by potential cycling between 1.25 and 1.65 V at a scan rate of 200 mV s -1 for 1,500 cycles. A. Grimaud, K.J. May, C.E. Carlton, Y.-L. Lee, M. Risch, W.T. Hong, J. Zhou and Y. Shao-Horn, Nat. Comm. , 4 , 2439 (2013). Y. Liang, Y. Li, H. Wang, J. Zhou, J. Wang, T. Regier, H. Dai, Nature Materials , 10 , 780 (2011). J. Kim, X. Yin, K.-C. Tsao, S. Fang and H. Yang, J. Am. Chem. Soc. , 136, 14646 (2014). J.-I. Jung, H.Y. Jeong, M.G. Kim, G. Nam, J. Park and J. Cho , Adv. Mater. , 27 , 266 (2015). J. Suntivich, K.J. May, H.A. Gasteiger, J.B. Goodenough, Y. Shao-Horn, Science , 334 , 1383 (2011). J. Suntivich, H. A. Gasteiger, N. Yabuuchi, Y. Shao-Horn, Nature Chemistry , 3 , 546 (2011). T. Reier, M. Oezaslan, P.Strasser, ACS Catal. , 2 , 1765 (2012). I. C. Man, H. Y. Su, F. C. Vallejo, H. A. Hansen, J. I. Martínez, N. G. Inoglu, J. Kitchin, T. F. Jaramillo, J. K. Nørskov, J. Rossmeisl, ChemCatChem , 3 , 1159 (2011) * Corresponding authors: jyoung@sejong.ac.kr (J.-Y. Park)

Type of Medium: Online Resource

ISSN: 2151-2043

URL: Article

DOI: 10.1149/MA2016-02/53/3959

Language: Unknown

Publisher: The Electrochemical Society

Publication Date: 2016

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Mitigation of Performance Degradation of Cathodes for Polymer Electrolyte Membrane Fuel Cells

Park, Jun-Young ; Choi, Sungyong ; Choi, Sung Ryul

The Electrochemical Society ; 2022

In: ECS Meeting Abstracts Vol. MA2022-02, No. 64 ( 2022-10-09), p. 2371-2371

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In: ECS Meeting Abstracts, The Electrochemical Society, Vol. MA2022-02, No. 64 ( 2022-10-09), p. 2371-2371

Abstract: Polymer electrolyte membrane fuel cells (PEMFCs) are green energy conversion devices that convert chemical energy to electrical energy. Compared to other types of fuel cells, PEMFCs have various advantages including the low operating temperature, high power density, and short start-up times [1, 2]. However, the limited durability and high cost of platinum catalysts are the primary obstacles to the large scale commercialization of PEMFCs. Hence, a variety of scientific approaches have tried to improve the durability of Pt electrocatalysts as a main component of PEMFC membrane electrode assemblies (MEAs) [3] . Studies reported that the performance degradation of the catalyst layer in MEAs can be divided into the reversible and irreversible degradation processes. The first case is the permanent degradations caused by the platinum dissolution or corrosion of carbon support. It is well known results in PMEFC MEAs that carbon corrosion mainly occurs at operating conditions of higher than 1.0 V, whereas platinum agglomeration/dissolution happen at 0.6‒1.0 V. That is, the deterioration of platinum in the cathode is unavoidable under general PEMFC operating conditions of 0.6‒1.0 V [4, 5]. Numerous studies, such as tuning of platinum alloy composition and use of highly durable Pt-alloy catalysts have been conducted to suppress irreversible performance degradation [6-8] . In the reversible degradation phenomena, oxygen or hydroxyl groups are bonded to platinum in the cathode, which interferes with oxygen reduction reactions and reduces performance. However, even reversible degradation can result in permanent performance decay if not removed for a long time. Hence, researches on the strategies to mitigate reversible degradation are necessary to extend the lifetime of PEMFC MEAs. In particular, Pt-O film generated during operation is reversible and can be easily recovered by the periodical reduction of cathode potential [9, 10]. In this research, we develop the mitigation method to prevent performance degradation of MEAs during constant current operation. In addition, we quantitatively analyze the mitigation mechanism of MEAs via various physicochemical and electrochemical analysis tools. References [1] L. J. M. J. Blomen, M. N. Mugerwa, "Fuel Cell Systems", Plenum Press, New York, 1993. [2] K. Kordesch, G. Simader, "Fuel Cells and Their Applications", VCH, Weinheim, Germany, 1996. [3] R. L. Borup, A. Kusoglu, K. C. Neyerlin, R. Mukundan, R. K. Ahluwalia, D. A. Cullen , Current Opinion in Electrochemistry 21 (2020) 192-200. [4] E. Guilminot, A. Corcella, F. Charlot, F. Maillard, M. Chatenet, Journal of the Electrochemical Society 154 (2006) B96. [5] P. Schneider, C. Sadeler, A.-C. Scherzer, N. Zamel, D. Gerteisen, Journal of the Electrochemical Society 166 (2019) F322-F333. [6] N. Linse, G. G. Scherer, A. Wokaun, L. Gubler, Journal of Power Sources 219 (2012) 240-248. [7] A. Ganesan, M. Narayanasamy, Materials for Renewable and Sustainable Energy 18 (2019) 1-14. [8] M. Khorshidian, M. Sedighi, Iranian Journal of Hydrogen & Fuel Cell 6 (2019) 91-115. [9] X. Zhang, L. Guo, H. Liu, Journal of Power Sources 296 (2015) 327-334. [10] M. Zago, A. Baricci, A. Bisello, T. Jahnke, H. Yu, R. Maric, P. Zelenay, A. Casalegno, Journal of Power Sources 455 (2020) 227990. Keywords: Polymer electrolyte membrane fuel cell, Pt-O layer, Water management, Oxide stripping *Corresponding author: jyoung@sejong.ac.kr (J. Y. Park)

Type of Medium: Online Resource

ISSN: 2151-2043

URL: Article

DOI: 10.1149/MA2022-02642371mtgabs

Language: Unknown

Publisher: The Electrochemical Society

Publication Date: 2022

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Enhancement of Bifunctional Catalytic Activity and Stability of Perovskite Oxide-Based Catalysts

Kim, Nam-In ; Choi, Sung Ryul ; Lee, Sung Won ; [et al.]

The Electrochemical Society ; 2017

In: ECS Meeting Abstracts Vol. MA2017-01, No. 43 ( 2017-04-15), p. 1997-1997

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In: ECS Meeting Abstracts, The Electrochemical Society, Vol. MA2017-01, No. 43 ( 2017-04-15), p. 1997-1997

Abstract: The electrochemical energy devices such as unitized regenerative fuel cells (URFCs) have many advantages in terms of producing hydrogen gas and electricity easily. However, the oxygen electrode of the URFC systems show slow kinetics for oxygen evolution reactions (OERs) and oxygen reduction reactions (ORRs) [1, 2]. As a results, efficiency related with the hydrogen and electricity production are limited in URFCs because of the high polarization resistance (charge- and mass-transfer) at the oxygen electrode. Furthermore, the OERs and ORRs are also restricted by the 4-electrons multi-step electrochemical reactions, then decreasing the overall reaction rate of this system [3] . Up to date, the carbon-supported noble materials, such as Pt/C, Ir/C, PtRu/C, and their alloys with transition metals, have still used to overcome the slow reaction kinetics [4]. However, the utilization of noble metal-based catalysts is not suitable for commercialization of the URFCs. In order to reduce these precious catalysts, many researchers have studied for other type of catalysts such as oxide, carbide, nitride, and carbonaceous materials [1, 5, 6] . In this study, therefore, the perovskite oxide-based catalysts are investigated to improve their electrocatalytic performance and long-term stability for both OERs and ORRs. Several lanthanides (Nd, Sm, and Gd) are doped into A-site of the catalysts to obtain the double perovskite structure [7]. The physicochemical properties of the final products are analyzed by various tools such as X-ray diffraction, scanning electron microscope and transmission electron microscope. For the electrochemical investigations, a rotating disk electrode (RDE) system is used with a 0.1 M KOH solution, a Pt wire and an Hg/HgO for electrolyte, counter electrode and reference electrode, respectively [8, 9] . The computational calculations based on density functional theory (DFT) are also investigated to confirm the relations between oxygen O p- band center and Fermi energy level of the catalysts [6, 10]. Y. Liang, Y. Li, H. Wang, J. Zhou, J. Wang, T. Regier, H. Dai, Nature Materials , 10 , 780 (2011). J.-I. Jung, H.Y. Jeong, M.G. Kim, G. Nam, J. Park and J. Cho , Adv. Mater. , 27 , 266 (2015). J. Suntivich, H. A. Gasteiger, N. Yabuuchi, Y. Shao-Horn, Nature Chemistry , 3 , 546 (2011). T. Reier, M. Oezaslan, P.Strasser, ACS Catal. , 2 , 1765 (2012). K. Kwon, Y.J. Sa, J.Y. Cheon, and S.H. Joo, Langmuir , 28 , 991 (2012) A. Grimaud, K.J. May, C.E. Carlton, Y.-L. Lee, M. Risch, W.T. Hong, J. Zhou and Y. Shao-Horn, Nat. Comm. , 4 , 2439 (2013). T.-H. Lee, K.-Y. Park, N.-I. Kim, S.-J. Song, K.-H. Hong, D. Ahn, A.K. Azad, J. Hwang, S. Bhattacharjee, S.-C. Lee, H.-T. Lim, and J.-Y. Park, J. Power Sources , 331 , 495 (2016). N.-I. Kim, Y.J. Sa, S.-H. Cho, I. So, K. Kwon, S.H. Joo, and J.-Y. Park, J. Electrochem. Soc. , 163 , F3020 (2016). I.-S. So, N.-I. Kim, S.-H. Cho, Y.-R. Kim, J. Yoo, Y. Seo, Y.-S. Seo, B. Park, K. Kwon, and J.-Y. Park, J. Electrochem. Soc. , 163 , F3041 (2016). J. Kim, X. Yin, K.-C. Tsao, S. Fang and H. Yang, J. Am. Chem. Soc. , 136, 14646 (2014). Keywords: Unitized regenerative fuel cells; Bi-functional activity; Perovskite; Electrocatalyst; Density functional theory. * Corresponding authors: jyoung@sejong.ac.kr (J.-Y. Park)

Type of Medium: Online Resource

ISSN: 2151-2043

URL: Article

DOI: 10.1149/MA2017-01/43/1997

Language: Unknown

Publisher: The Electrochemical Society

Publication Date: 2017

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Transition Metal Doped-Chalcogenide Based Electrocatalysts for Oxygen Evolution Reaction

An, Wonyoung ; Choi, Sung Ryul ; Park, Jun-Young

The Electrochemical Society ; 2022

In: ECS Meeting Abstracts Vol. MA2022-02, No. 64 ( 2022-10-09), p. 2370-2370

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In: ECS Meeting Abstracts, The Electrochemical Society, Vol. MA2022-02, No. 64 ( 2022-10-09), p. 2370-2370

Abstract: Hydrogen, which possesses high gravimetric energy density, has recently received great attentions to respond to the seriousness of global climate change [1, 2]. In particular, the alkaline water electrolysis cells (AECs) that can produce hydrogen through electrochemical reactions without greenhouse gas emissions are substantially promising as renewable next-generation energy storage and conversion devices. In AECs, oxygen evolution reactions (OERs) occur at the anode, while hydrogen evolution reactions take place at the cathode [3, 4] . However, the sluggish kinetics of the multi-electron transfer process is a paramount challenge for efficient OER activity. Furthermore, precious metal catalysts such as iridium and ruthenium are still mainly used as an OER catalyst, and their low economic efficiency and durability are acting as major problems in the commercialization stage. Therefore, the reduction of reaction overpotential is crucial to boost catalytic efficiency for OER in AECs. In this study, the OER catalyst study is performed on sulfide-based chalcogenide materials. It has been reported that the sulfide-based chalcogenide materials have shown the excellent catalytic activity because the covalent characteristics between transition metal and chalcogenide is stronger than that of oxide-based catalysts [5]. In particular, among various sulfide-based chalcogenide materials, nickel sulfide-based catalysts have actively studied because they can simply synthesize using a hydrothermal method. Additionally, nickel sulfides have a structurally Ni-Ni metal bond that makes it easy to transfer charge species for OERs. Herein, various transition metals are doped into the nickel sulfide to improve the catalytic activity and electrical conductivity via generation of extra defects in the crystal structure. The crystal structure and catalytic activity of chalcogenide catalysts are analyzed through various physicochemical and electrochemical analysis methods. References [1] Hainan Sun, Xiaomin Xu, Zhiwei Hu, Liu Hao Tjeng, Jie Zhao, Qin Zhang, Hong-Ji Lin, Chien-Te Chen, Ting-Shan Chan, Wei Zhou, Zongping Shao, Journal of Materials Chemistry A 7 (2019) 9924. [2] Thomas E. Mallouk, Nature Chemistry 5 (2013) 362–363. [3] Muhammad Saqib, In-Gyu Choi, Hohan Bae, Kwangho Park, Ji-sup Shin, You-Dong Kim, John-In Lee, Minkyeong Jo, Yeong-Cehol Kim, Kug-Seung Lee, Sun-Ku Song, Eric D. Wachsman and Jun-Young Park, Energy & Environmental Science 14 (2021) 2472–2484. [4] Sung Ryul Choi, John-In Lee, Hyunyoung Park, Sung Won Lee, Dong Yeong Kim, Won Young An, Jung Hyun Kim, Jongsoon Kim, Hyun-seok Cho, Jun-Young Park, Chemical Engineering Journal 409 (2021) 128226. [5] Hatem M. A. Amin, UIf-Peter Apfel, European Journal of Inorganic Chemistry 2020 (2020) 2679–2690. Keywords: Oxygen evolution reaction, Alkaline electrolysis cell, Water splitting, Transition metal, Post-transition metal, Chalcogenide. * Corresponding author: jyoung@sejong.ac.kr (J. Y. Park)

Type of Medium: Online Resource

ISSN: 2151-2043

URL: Article

DOI: 10.1149/MA2022-02642370mtgabs

Language: Unknown

Publisher: The Electrochemical Society

Publication Date: 2022

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Bifunctional Non-Noble Transition Metal Oxide-Based Materials for Unitized Reversible Fuel Cells

Choi, Sung Ryul ; Afzal, Rana Arslan ; Park, Jun-Young

The Electrochemical Society ; 2018

In: ECS Meeting Abstracts Vol. MA2018-01, No. 44 ( 2018-04-13), p. 2535-2535

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In: ECS Meeting Abstracts, The Electrochemical Society, Vol. MA2018-01, No. 44 ( 2018-04-13), p. 2535-2535

Abstract: Because of the emerging global warming and environmental pollutions, hydrogen as a renewable and sustainable energy source has expected to solve those global issues [1]. In particular, hydrogen-fueled fuel cells are one of the most promising electrochemical energy conversion devices due to their high efficiency and negligible pollution emissions. Furthermore, URFCs that produce both hydrogen fuel and electricity in one single device have received great attentions these days. However, URFCs have several technical barriers for making commercialization, such as sluggish catalytic kinetics of oxygen reduction (ORR) and oxygen evolution reactions (OER) [2] . Up to now, noble metal (e.g Pt/C and IrO 2 )-based electrocatalysts have still used to get high performances of OER and ORR, even though these metals have critical drawbacks such as expensive price and low durability [3]. In order to overcome these problems, many transition metal oxide-based materials have studied as bifunctional electrocatalysts [4, 5] . In this work, in order to improve electrocatalytic activity of transition metal oxide-based catalysts, high surface area carbon-based supporting materials such as graphene or carbon nanofiber are considered [6]. The graphene-carbon nanofiber-suppported transition oxide catalysts are synthesized by the hydrothermal method and analyzed by various physicochemical and electrochemcial tools [7] . References Landon, E. Demeter, N. İnoğlu, C. Keturakis, I. E. Wachs, R. Vasić, A. I. Frenkel, and J. R. Kitchin, ACS. Catal., 8 , 1793 (2012). K. Fominykh, P. Chernev, I. Zaharieva, J. Sicklinger, G. Stefanic, M. Döblinger, A. Müller, A. Pokharel, S. Böcklein, C. Scheu, T. Bein, and D. Fattakhova-Rohlfing, ACS. Nano ., 5 , 5180 (2015). M.W. Louie, and A.T. Bell, J. Am. Chem. Soc ., 33 , 12329 (2013). A. C. Pebley, E. Decolvenaere, T. M. Pollock, and M. J. Gordon, Nanoscale ., 9 , 15070 (2017). Y.-F. Li, and A. Selloni, ACS Catal ., 4 , 1148 (2014). I.-S. So, N.-I. Kim, S.-H. Cho, Y.-R. Kim, J. Yoo, Y. Seo, Y.-S. Seo, B. Park, K. Kwon, and J.-Y. Park, J. Electrochem. Soc. , 163 , F3041 (2016). N.-I. Kim, Y.J. Sa, S.-H. Cho, I. So, K. Kwon, S.H. Joo, and J.-Y. Park, J. Electrochem. Soc. , 163 , F3020 (2016).

Type of Medium: Online Resource

ISSN: 2151-2043

URL: Article

DOI: 10.1149/MA2018-01/44/2535

Language: Unknown

Publisher: The Electrochemical Society

Publication Date: 2018

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Bifunctional Transition Metal Oxide-Based Oxygen Electrode Catalysts for Unitized Reversible Fuel Cells

Choi, Sung Ryul ; Lee, Sungwon ; Park, Jun-Young

The Electrochemical Society ; 2019

In: ECS Meeting Abstracts Vol. MA2019-01, No. 29 ( 2019-05-01), p. 1454-1454

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In: ECS Meeting Abstracts, The Electrochemical Society, Vol. MA2019-01, No. 29 ( 2019-05-01), p. 1454-1454

Abstract: While the global warming and environmental pollutions have been emerged as international issues, hydrogen, which is renewable and sustainable energy source has received extensive attentions. Especially, unitized reversible fuel cells (URFCs) are considered as a prospective electrochemical energy conversion device due to their high energy efficiency and non-polluting system [1]. However, sluggish electrochemical kinetics and overpotential loss for oxygen reduction reaction (ORR) and oxygen evolution reaction (OER) in both electrodes are still the biggest technical obstacles for entering into the real markets [2] . Until now, platinum-based noble metals such as platinum, iridium, and their alloys have been used for OER and ORR catalysts because of their high electrocatalytic activity [3]. However, the main weaknesses of these materials are low durability, low bifunctionality, and high price [4, 5] . In order to overcome these barriers, non-precious transition metal oxide-based material have regarded as promising alternative for bifunctional electrocatalysts due to their low price and high durability [6]. In this study, to increase intrinsic property and electrical conductivity of catalysts for OER and ORR, doping of other transition metals with various high surface area carbonaceous materials as a supporting material is adopted. The synthesized catalysts are analyzed by various physicochemical and electrochemical tools [7. 8] . References Y. Liang, Y. Li, H. Wang, J. Zhou, J. Wang, T. Regier, H.Dai, Nat . Mater. 10 , 780-786 (2011). K. Fominykh, P. Chernev, I. Zaharieva, J. Sicklinger, G. Stefanic, M. Doblinger, A. Muller, A. Pokharel, S. Bocklein, C. Scheu, T. Bein, and D. F. Rohifing, ACS. Nano ., 5 , 5180 (2015). S. Anantharaj, P. E. Karthik and S. Kundu, J. Mater. Chem. A. , 3 , 24463 (2015). Q. Han, N. Chen, J. Zhang and L. Qu, Mater. Horiz ., 4 , 832 (2017). A. C. Pebley, E. Decolvenaere, T. M. Pollock, and M. J. Gordon, Nanoscale ., 9 , 15070 (2017). Y.-F. Li, and A. Selloni, ACS Catal ., 4 , 1148 (2014). N.-I. Kim, Y.J. Sa, S.-H. Cho, I. So, K. Kwon, S.H. Joo, and J.-Y. Park, J. Electrochem. Soc. , 163 , F3020 (2016). I.-S. So, N.-I. Kim, S.-H. Cho, Y.-R. Kim, J. Yoo, Y. Seo, Y.-S. Seo, B. Park, K. Kwon, and J.-Y. Park, J. Electrochem. Soc. , 163 , F3041 (2016). Keywords: Oxygen evolution reaction; Oxygen reduction reaction; Bifunctional electrocatalysts; Unitized reversible fuel cell; Transition metal oxide.

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ISSN: 2151-2043

URL: Article

DOI: 10.1149/MA2019-01/29/1454

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Publisher: The Electrochemical Society

Publication Date: 2019

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