Pub Date : 2023-08-28DOI: 10.1149/ma2023-015480mtgabs
Indrek Kivi, Priit Moeller, Jaan Aruväli, Gunnar Nurk
La 0.25 Sr 0.25 Ca 0.45 TiO 3 - d (LSCT) is a perovskite (ABO 3 ) type mixed ionic-electronic conductive (MIEC) oxide and has been proposed as an electrode material for high temperature fuel cell [1]. This material owing high conductivity, robustness in hydrocarbon fuels and significant amount of attention has been paid to improve the electrochemical activity [1, 2]. Doping of B-site with some d-metal cation (Ni, Co, Mn, V, Mo) has been demonstrated to improve the catalytic activity. One of the advantages of the MIEC conducting scaffold based electrodes is that the catalyst phase on the electrode surface can be kept to a minimum, usually less than 5 wt%, which minimizes any risks of physical damage during redox cycling [2]. In this work, Ni/Co ratio and deficiency of A-site, of (La 0.25 Sr 0.25 Ca 0.45 ) x Ti 0.95 Ni 0.05-y Co y O 3 - d were varied. Electrical as well as electrochemical performance and chemical composition of LSCTNC surface was monitored. The electrochemical measurements of symmetric cells during 100 h tests show that small stochiometric changes in A-site significantly influence the activity and initial degradation rate of the electrode. The chemical and structural changes of the material surface have a key role on the electrochemical performance of the electrode [3]. The electrode materials were analysed using XRD, TOF SIMS and electrochemical methods. XRD and TOF SIMS results for studied electrode powders showed significant dependence of the lattice parameters and electrode surface composition on the perovskite elemental composition. The results from impedance spectroscopy (measured at temperatures from 973 to 1123 K in H 2 environment, at OCV) demonstrate a significant influence of the A-site deficiency and B-site composition on the electrochemical properties of studied electrodes. Robert Price, Mark Cassidy, Jan G. Grolig, Gino Longo, Ueli Weissen, Andreas Mai, John T. S. Irvine, Advanced Energy Materials, 11, 1 (2021). Paul A. Connor, Xiangling Yue, Cristian D. Savaniu, Robert Price, Georgios Triantafyllou, Mark Cassidy, Gwilherm Kerherve, David J. Payne, Robert C. Maher, Lesley F. Cohen, Rumen I. Tomov, Bartek A. Glowacki, Ramachandran Vasant Kumar, John T. S. Irvine, Advanced Energy Materials, 8, 1 (2018). Ove Korjus, Priit Möller, Kuno Kooser, Tanel Käämbre, Olga Volobujeva, Jaak Nerut, Sander Kotkas, Enn Lust, Gunnar Nurk, Journal of Power Sources, 494, 1 (2021).
La 0.25 Sr 0.25 Ca 0.45 TiO 3 - d (LSCT)是一种钙钛矿(ABO 3)型混合离子电子导电(MIEC)氧化物,已被提出作为高温燃料电池的电极材料[1]。这种材料具有高导电性,在碳氢燃料中的稳健性,并且在提高电化学活性方面受到了大量关注[1,2]。b位掺杂一些d金属阳离子(Ni, Co, Mn, V, Mo)已被证明可以提高催化活性。MIEC导电支架电极的优点之一是,电极表面的催化剂相可以保持在最低限度,通常小于5 wt%,从而最大限度地降低氧化还原循环过程中物理损伤的风险[2]。本文研究了(La 0.25 Sr 0.25 Ca 0.45) x Ti 0.95 Ni 0.05-y Co y O 3 - d的Ni/Co比值和a位缺乏量的变化。对LSCTNC表面的电学、电化学性能和化学成分进行了监测。对称电池100 h的电化学测量表明,a位的微小化学变化显著影响电极的活性和初始降解速率。材料表面的化学和结构变化对电极的电化学性能起着关键作用[3]。采用XRD、TOF SIMS和电化学方法对电极材料进行了分析。所研究电极粉末的XRD和TOF SIMS结果表明,钙钛矿元素组成对晶格参数和电极表面组成有显著的依赖性。阻抗谱(在温度从973到1123 K的h2环境下,在OCV下测量)的结果表明,a位缺乏和b位组成对所研究电极的电化学性能有显著影响。Robert Price, Mark Cassidy, Jan G. Grolig, Gino Longo, Ueli Weissen, Andreas Mai, John T. S. Irvine,先进能源材料,11(2021)。Paul A. Connor, Yue Xiangling, Cristian D. Savaniu, Robert Price, Georgios Triantafyllou, Mark Cassidy, Gwilherm Kerherve, David J. Payne, Robert C. Maher, Lesley F. Cohen, Rumen I. Tomov, Bartek A. Glowacki, Ramachandran Vasant Kumar, John T. S. Irvine,先进能源材料,8(2018)。Ove Korjus, Priit Möller, Kuno Kooser, Tanel Käämbre, Olga Volobujeva, Jaak Nerut, Sander Kotkas, Enn Lust, Gunnar Nurk,电源学报,494,1(2021)。
{"title":"Influence of A-site Deficiency and Ni/Co Ratio in B-site on Electrochemical Performance of (La<sub>0.25</sub>Sr<sub>0,25</sub>Ca<sub>0.45</sub>)<sub>y</sub>Ti<sub>0.95</sub>Ni<sub>0.05-x</sub>Co<sub>x</sub>O<sub>3-</sub> <sub>d </sub> Anode","authors":"Indrek Kivi, Priit Moeller, Jaan Aruväli, Gunnar Nurk","doi":"10.1149/ma2023-015480mtgabs","DOIUrl":"https://doi.org/10.1149/ma2023-015480mtgabs","url":null,"abstract":"La 0.25 Sr 0.25 Ca 0.45 TiO 3 - d (LSCT) is a perovskite (ABO 3 ) type mixed ionic-electronic conductive (MIEC) oxide and has been proposed as an electrode material for high temperature fuel cell [1]. This material owing high conductivity, robustness in hydrocarbon fuels and significant amount of attention has been paid to improve the electrochemical activity [1, 2]. Doping of B-site with some d-metal cation (Ni, Co, Mn, V, Mo) has been demonstrated to improve the catalytic activity. One of the advantages of the MIEC conducting scaffold based electrodes is that the catalyst phase on the electrode surface can be kept to a minimum, usually less than 5 wt%, which minimizes any risks of physical damage during redox cycling [2]. In this work, Ni/Co ratio and deficiency of A-site, of (La 0.25 Sr 0.25 Ca 0.45 ) x Ti 0.95 Ni 0.05-y Co y O 3 - d were varied. Electrical as well as electrochemical performance and chemical composition of LSCTNC surface was monitored. The electrochemical measurements of symmetric cells during 100 h tests show that small stochiometric changes in A-site significantly influence the activity and initial degradation rate of the electrode. The chemical and structural changes of the material surface have a key role on the electrochemical performance of the electrode [3]. The electrode materials were analysed using XRD, TOF SIMS and electrochemical methods. XRD and TOF SIMS results for studied electrode powders showed significant dependence of the lattice parameters and electrode surface composition on the perovskite elemental composition. The results from impedance spectroscopy (measured at temperatures from 973 to 1123 K in H 2 environment, at OCV) demonstrate a significant influence of the A-site deficiency and B-site composition on the electrochemical properties of studied electrodes. Robert Price, Mark Cassidy, Jan G. Grolig, Gino Longo, Ueli Weissen, Andreas Mai, John T. S. Irvine, Advanced Energy Materials, 11, 1 (2021). Paul A. Connor, Xiangling Yue, Cristian D. Savaniu, Robert Price, Georgios Triantafyllou, Mark Cassidy, Gwilherm Kerherve, David J. Payne, Robert C. Maher, Lesley F. Cohen, Rumen I. Tomov, Bartek A. Glowacki, Ramachandran Vasant Kumar, John T. S. Irvine, Advanced Energy Materials, 8, 1 (2018). Ove Korjus, Priit Möller, Kuno Kooser, Tanel Käämbre, Olga Volobujeva, Jaak Nerut, Sander Kotkas, Enn Lust, Gunnar Nurk, Journal of Power Sources, 494, 1 (2021).","PeriodicalId":11461,"journal":{"name":"ECS Meeting Abstracts","volume":null,"pages":null},"PeriodicalIF":0.0,"publicationDate":"2023-08-28","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"135089312","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
Pub Date : 2023-08-28DOI: 10.1149/ma2023-0154258mtgabs
Geraud Cubizolles, Simon Alamome, Félix Bosio, Brigitte Gonzalez, Christian Tantolin, Lucas Champelovier, Sebastien Fantin, Jerome Aicart
High Temperature Electrolysis based on Solid Oxide Cell technology is rapidly entering an industrialization phase, driven by promises of high efficiencies compared to the more market-ready solutions. To decrease the CAPEX and footprint related to module-based scale-up strategies, multiple stacks are typically assembled within the same thermal enclosure. As such, thermal phenomena become much more prominent in determining stack behavior compared to single stack test benches, and appropriate control strategies have to be developed. In this context, CEA LITEN has developed a new investigation tool (MURPHY) devoted to the operation of several Solid Oxide stacks within the same thermal enclosure. MURPHY enables stack operation in both the steam electrolysis (SOE) and the fuel cell (SOFC-H 2 ) modes. For the later, CH 4 , natural gas or NH 3 can be used as fuel, while additional gases are being considered. The one module system incorporates a compact Balance of Plant (BOP) located closely to the thermal enclosure. Its main functions are (i) to provide inlet process air by centrifugal blower towards higher efficiency, (ii) target high level of overall thermal integration and performances, (iii) actively preheat inlet gases independently of overall furnace temperature, (iv) recycle hot/cold fuel exhaust, and (v) control pressure levels distribution through multiple back-pressure valves. Overall, a high level of instrumentation was deployed to support modeling development and estimate accurate process efficiencies. MURPHY is currently compatible with four stacks of CEA standard base design [1]. Each comprising 25 cathode-supported cells each of 100 cm² active area, the corresponding maximum power range of the module is -16/4 kW DC [2], [3]. Nevertheless, the Hot Box has some capacity to adapt to different stack geometries and partner’s need. Finally, the MURPHY system is connected to the Multistack platform [4] for supply and venting of gases produced. This report details system architecture down to component level. It also puts forward preliminary experimental results related to stack operation in an environment controlled by thermal phenomena. Performance and efficiency curves obtained under parametric variations of operating conditions (Temperature, flowrates) are reported for both SOE and SOFC-H 2 modes. A special attention is given to heat performance of the overall system and its components. In this view, flow parameters (composition, temperature, pressure) at several locations over the reactant circuitries are provided. [1] G. Cubizolles, J. Mougin, S. Di Iorio, P. Hanoux, and S. Pylypko, “Stack Optimization and Testing for its Integration in a rSOC-Based Renewable Energy Storage System,” ECS Trans. , vol. 103, no. 1, pp. 351–361, Jul. 2021, doi: 10.1149/10301.0351ecst. [2] J. Aicart, S. Di Iorio, M. Petitjean, P. Giroud, G. Palcoux, and J. Mougin, “Transition Cycles during Operation of a Reversible Solid Oxide Electrolyzer/Fuel Cell (rSOC) System,
与市场就绪的解决方案相比,基于固体氧化物电池技术的高温电解技术正在迅速进入工业化阶段,其高效率的承诺推动了高温电解技术的发展。为了减少与基于模块的扩展策略相关的资本支出和占地面积,多个堆栈通常组装在同一个热罩内。因此,与单堆试验台相比,热现象在确定堆行为方面变得更加突出,因此必须开发适当的控制策略。在此背景下,CEA LITEN开发了一种新的研究工具(MURPHY),专门用于在同一热罩内运行多个固体氧化物堆。MURPHY可以在蒸汽电解(SOE)和燃料电池(sofc - h2)模式下进行堆操作。对于后者,可以使用甲烷、天然气或nh3作为燃料,同时正在考虑使用其他气体。单模块系统集成了一个紧凑的工厂平衡(BOP),靠近散热罩。它的主要功能是:(1)通过离心鼓风机提供更高效率的进口工艺空气,(2)实现高水平的整体热集成和性能,(3)独立于整体炉温主动预热进口气体,(4)回收热/冷燃料排气,(5)通过多个背压阀控制压力水平分布。总的来说,部署了高水平的工具来支持建模开发和估计准确的流程效率。MURPHY目前兼容四层CEA标准底座设计[1]。每个模块由25个阴极支撑电池组成,每个电池的有效面积为100 cm²,相应的模块最大功率范围为-16/ 4kw DC[2],[3]。然而,热盒有一定的能力,以适应不同的堆栈几何形状和合作伙伴的需要。最后,MURPHY系统连接到Multistack平台[4],用于供应和排放产出的气体。该报告详细介绍了系统架构直至组件级别。并提出了在热现象控制环境下叠垛操作的初步实验结果。报告了SOE模式和sofc - h2模式在参数工况(温度、流量)变化下的性能和效率曲线。特别注意的是整个系统及其组成部分的热性能。在这个视图中,提供了反应物电路上几个位置的流动参数(成分,温度,压力)。[1]王晓明,王晓明,王晓明,“基于rsoc的可再生能源储能系统优化研究”,能源工程学报,2011。,第103卷,第103期。1, pp. 351-361, july 2021, doi: 10.1149/10301.0351。[2]王晓明,王晓明,王晓明,“固体氧化物电解槽/燃料电池(rSOC)系统运行过程中的过渡循环”,《燃料电池》,vol. 19, no. 2。4, pp. 381-388, 2019年5月,doi: 10.1002/fu .201800183。[3]李建军,“高温电解过程中不同堆叠技术的性能与耐久性研究”,中国机械工程,2011;《国有企业论坛》,瑞士卢塞恩,2022年5月,第A0804卷,第138-149页。[4]张晓明,李晓明,“电解模式下固体氧化物模块的性能评价”,[j]。j . Hydrog。《能源》,第47卷,第7期。6, pp. 3568-3579, 2022年1月,doi: 10.1016/ j.j ijhydene.2021.11.056。图1
{"title":"Development of a Versatile and Reversible Multi-Stack Solid Oxide Cell System Towards Operation Strategies Optimization","authors":"Geraud Cubizolles, Simon Alamome, Félix Bosio, Brigitte Gonzalez, Christian Tantolin, Lucas Champelovier, Sebastien Fantin, Jerome Aicart","doi":"10.1149/ma2023-0154258mtgabs","DOIUrl":"https://doi.org/10.1149/ma2023-0154258mtgabs","url":null,"abstract":"High Temperature Electrolysis based on Solid Oxide Cell technology is rapidly entering an industrialization phase, driven by promises of high efficiencies compared to the more market-ready solutions. To decrease the CAPEX and footprint related to module-based scale-up strategies, multiple stacks are typically assembled within the same thermal enclosure. As such, thermal phenomena become much more prominent in determining stack behavior compared to single stack test benches, and appropriate control strategies have to be developed. In this context, CEA LITEN has developed a new investigation tool (MURPHY) devoted to the operation of several Solid Oxide stacks within the same thermal enclosure. MURPHY enables stack operation in both the steam electrolysis (SOE) and the fuel cell (SOFC-H 2 ) modes. For the later, CH 4 , natural gas or NH 3 can be used as fuel, while additional gases are being considered. The one module system incorporates a compact Balance of Plant (BOP) located closely to the thermal enclosure. Its main functions are (i) to provide inlet process air by centrifugal blower towards higher efficiency, (ii) target high level of overall thermal integration and performances, (iii) actively preheat inlet gases independently of overall furnace temperature, (iv) recycle hot/cold fuel exhaust, and (v) control pressure levels distribution through multiple back-pressure valves. Overall, a high level of instrumentation was deployed to support modeling development and estimate accurate process efficiencies. MURPHY is currently compatible with four stacks of CEA standard base design [1]. Each comprising 25 cathode-supported cells each of 100 cm² active area, the corresponding maximum power range of the module is -16/4 kW DC [2], [3]. Nevertheless, the Hot Box has some capacity to adapt to different stack geometries and partner’s need. Finally, the MURPHY system is connected to the Multistack platform [4] for supply and venting of gases produced. This report details system architecture down to component level. It also puts forward preliminary experimental results related to stack operation in an environment controlled by thermal phenomena. Performance and efficiency curves obtained under parametric variations of operating conditions (Temperature, flowrates) are reported for both SOE and SOFC-H 2 modes. A special attention is given to heat performance of the overall system and its components. In this view, flow parameters (composition, temperature, pressure) at several locations over the reactant circuitries are provided. [1] G. Cubizolles, J. Mougin, S. Di Iorio, P. Hanoux, and S. Pylypko, “Stack Optimization and Testing for its Integration in a rSOC-Based Renewable Energy Storage System,” ECS Trans. , vol. 103, no. 1, pp. 351–361, Jul. 2021, doi: 10.1149/10301.0351ecst. [2] J. Aicart, S. Di Iorio, M. Petitjean, P. Giroud, G. Palcoux, and J. Mougin, “Transition Cycles during Operation of a Reversible Solid Oxide Electrolyzer/Fuel Cell (rSOC) System,","PeriodicalId":11461,"journal":{"name":"ECS Meeting Abstracts","volume":null,"pages":null},"PeriodicalIF":0.0,"publicationDate":"2023-08-28","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"135089322","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
Pub Date : 2023-08-28DOI: 10.1149/ma2023-01402882mtgabs
Auston L. Clemens, Maira Raquel Ceron, Magi Mettry Yassa, Thomas Ferron, Adam Barnett, Joshua Aaron Hammons, Buddhinie Jayathilake, Valeria Molinero, John Joseph Karnes, James Spencer Oakdale
Anion exchange membranes (AEMs) promise significant capital cost saving associated with enabling use of Pt-group-free electrodes and components in alkaline fuel cells and electrolyzer devices. However, AEMs often lack the chemical and mechanical stability required for widespread commercial adoption. Crosslinking has proven to be an effective method to permit increased ion exchange capacity (IEC) while preventing exponential water uptake and retaining both conductivity and mechanical strength. In this work, we leverage molecular dynamics simulations to explore crosslinking methodologies in silico. We present a reproducible and quantitative UV-based nitrene chemistry that utilizes a mobile crosslinker that is straightforward to synthesize and implement. This crosslinking strategy significantly mitigates excess water uptake and improves alkaline stability without sacrificing IEC during the cure process. Additionally, we characterize electrochemically fielded AEMs by small angle X-ray scattering, mechanical strength testing, and other post-mortem analyses. The operational lifetime of crosslinked AEMs prepared in this work is 5 times greater than corresponding untreated AEMs. This work is performed under the auspices of the U.S. Department of Energy by Lawrence Livermore National Laboratory under Contract DE-AC52-07NA27344 within the LDRD program 21-ERD-013. LLNL-ABS-848147.
{"title":"UV-Controlled Nitrene Crosslinking in Poly(phenylene oxide) Anion Exchange Membranes","authors":"Auston L. Clemens, Maira Raquel Ceron, Magi Mettry Yassa, Thomas Ferron, Adam Barnett, Joshua Aaron Hammons, Buddhinie Jayathilake, Valeria Molinero, John Joseph Karnes, James Spencer Oakdale","doi":"10.1149/ma2023-01402882mtgabs","DOIUrl":"https://doi.org/10.1149/ma2023-01402882mtgabs","url":null,"abstract":"Anion exchange membranes (AEMs) promise significant capital cost saving associated with enabling use of Pt-group-free electrodes and components in alkaline fuel cells and electrolyzer devices. However, AEMs often lack the chemical and mechanical stability required for widespread commercial adoption. Crosslinking has proven to be an effective method to permit increased ion exchange capacity (IEC) while preventing exponential water uptake and retaining both conductivity and mechanical strength. In this work, we leverage molecular dynamics simulations to explore crosslinking methodologies in silico. We present a reproducible and quantitative UV-based nitrene chemistry that utilizes a mobile crosslinker that is straightforward to synthesize and implement. This crosslinking strategy significantly mitigates excess water uptake and improves alkaline stability without sacrificing IEC during the cure process. Additionally, we characterize electrochemically fielded AEMs by small angle X-ray scattering, mechanical strength testing, and other post-mortem analyses. The operational lifetime of crosslinked AEMs prepared in this work is 5 times greater than corresponding untreated AEMs. This work is performed under the auspices of the U.S. Department of Energy by Lawrence Livermore National Laboratory under Contract DE-AC52-07NA27344 within the LDRD program 21-ERD-013. LLNL-ABS-848147.","PeriodicalId":11461,"journal":{"name":"ECS Meeting Abstracts","volume":null,"pages":null},"PeriodicalIF":0.0,"publicationDate":"2023-08-28","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"135089344","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
Pub Date : 2023-08-28DOI: 10.1149/ma2023-0154169mtgabs
Franziska Elisabeth Winterhalder, Yousef Alizad Farzin, Olivier Guillon, Andre Weber, Norbert H. Menzler
Enhancing the lifetime of SOECs is a challenge to overcome regarding their commercialization. A major impact on the lifetime of a cell during electrolysis operation, particularly under thermoneutral potential and high current densities, is the degradation of the currently used electrode materials, mainly the Ni-based fuel electrode. Among other things, nickel migration, as well as agglomeration, is leading to a significant performance loss after a certain operating time. Hence, preventing degradation mechanisms of the fuel electrode during operation is a necessity to be tackled for using it commercially. Therefore the development of alternative materials which combine sufficient performance with the lowest possible degradation rate is needed. Perovskite-based materials have been investigated in the last years as all-ceramic possible substitutes. In this work, four perovskites (i.e., strontium-iron-niobate double perovskite (SFN), a strontium-iron-titanate material (STF), a lanthanum-strontium-titanate (LST) and a lanthanum-strontium-iron-manganese (LSFM)) were examined as alternative electrode materials. The aim is to substitute the active fuel electrode, at the moment commonly consisting of Ni cermets, with a perovskite-based electrode while at the same time using state-of-the-art materials for the remaining cell components. The first task here was to look at the chemical stability between the new electrode material and the electrolyte under the standard conditions used to manufacture fuel electrode-supported SOECs. Therefore, the compatibility between these perovskites with a yttria-stabilized-zirconia (8YSZ) electrolyte and how nickel inside the fuel electrode affected the chemical stability during sintering in air at 1400 °C for 5 h was investigated. At this point, SFN double perovskite shows the lowest interaction between the electrode and electrolyte after thermal treatment. A thorough evaluation of all preliminary tests (including compatibility, stability in reducing atmospheres and redox stability tests) indicates that SFN shows so far the best results of the four materials in terms of application as fuel electrode material, followed directly by STF. Thus SFN and STF were chosen to be evaluated in single cell tests. The tests of pure SFN and STF electrodes are carried out with electrolyte-supported single cells exhibiting an LSCF air electrode and symmetrical cells, respectively. CV-characteristics and impedance spectra are measured at varied operating conditions. Impedance spectra are evaluated by the distribution of relaxation times (DRT). These examinations are carried out to give an insight into the electrochemical properties of pure perovskite-based fuel electrodes in order to obtain a base for further optimization.
{"title":"Perovskite-Based Materials As Alternative Fuel Electrodes for Solid Oxide Electrolysis Cells (SOECs)","authors":"Franziska Elisabeth Winterhalder, Yousef Alizad Farzin, Olivier Guillon, Andre Weber, Norbert H. Menzler","doi":"10.1149/ma2023-0154169mtgabs","DOIUrl":"https://doi.org/10.1149/ma2023-0154169mtgabs","url":null,"abstract":"Enhancing the lifetime of SOECs is a challenge to overcome regarding their commercialization. A major impact on the lifetime of a cell during electrolysis operation, particularly under thermoneutral potential and high current densities, is the degradation of the currently used electrode materials, mainly the Ni-based fuel electrode. Among other things, nickel migration, as well as agglomeration, is leading to a significant performance loss after a certain operating time. Hence, preventing degradation mechanisms of the fuel electrode during operation is a necessity to be tackled for using it commercially. Therefore the development of alternative materials which combine sufficient performance with the lowest possible degradation rate is needed. Perovskite-based materials have been investigated in the last years as all-ceramic possible substitutes. In this work, four perovskites (i.e., strontium-iron-niobate double perovskite (SFN), a strontium-iron-titanate material (STF), a lanthanum-strontium-titanate (LST) and a lanthanum-strontium-iron-manganese (LSFM)) were examined as alternative electrode materials. The aim is to substitute the active fuel electrode, at the moment commonly consisting of Ni cermets, with a perovskite-based electrode while at the same time using state-of-the-art materials for the remaining cell components. The first task here was to look at the chemical stability between the new electrode material and the electrolyte under the standard conditions used to manufacture fuel electrode-supported SOECs. Therefore, the compatibility between these perovskites with a yttria-stabilized-zirconia (8YSZ) electrolyte and how nickel inside the fuel electrode affected the chemical stability during sintering in air at 1400 °C for 5 h was investigated. At this point, SFN double perovskite shows the lowest interaction between the electrode and electrolyte after thermal treatment. A thorough evaluation of all preliminary tests (including compatibility, stability in reducing atmospheres and redox stability tests) indicates that SFN shows so far the best results of the four materials in terms of application as fuel electrode material, followed directly by STF. Thus SFN and STF were chosen to be evaluated in single cell tests. The tests of pure SFN and STF electrodes are carried out with electrolyte-supported single cells exhibiting an LSCF air electrode and symmetrical cells, respectively. CV-characteristics and impedance spectra are measured at varied operating conditions. Impedance spectra are evaluated by the distribution of relaxation times (DRT). These examinations are carried out to give an insight into the electrochemical properties of pure perovskite-based fuel electrodes in order to obtain a base for further optimization.","PeriodicalId":11461,"journal":{"name":"ECS Meeting Abstracts","volume":null,"pages":null},"PeriodicalIF":0.0,"publicationDate":"2023-08-28","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"135089350","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
Pub Date : 2023-08-28DOI: 10.1149/ma2023-01452471mtgabs
Salatan Duangdangchote, Oleksandr Voznyy
Finding novel solid-state electrolyte materials with specific desired properties is one of the main challenges of first principles-based modelling due to its high computational cost. Recently, machine learning (ML) has been used exclusively in the materials discovery field due to its remarkable capabilities to process large amounts of data and extract useful information insights. The implementation of ML into atomic-scale materials modeling can accelerated materials sampling with first principles accuracy, this should provide a short workflow and highly reduce the computational cost. In this work, we facilitate the ML model that can effectively screen for targeted properties from the entire chemical database possibility, including those materials that have never been examined. Currently, we are developing a materials graph networks framework for representing periodic crystal systems with the capability to learn atomistic chemical insights, especially for the discovery of new solid-state electrolyte materials. In this talk, we will discuss the basic theory and our recent work towards the development of ML model that can extensively discover and explore materials. We will highlight the computational-guided evolution approaches and screening high-performance Li conductor materials. Finally, we will end on discussing the future of ML-assisted materials discovery to the future of all-solid-state lithium batteries.
{"title":"Materials Graph Networks Assisting the Discovery of New Solid-State Electrolyte Materials","authors":"Salatan Duangdangchote, Oleksandr Voznyy","doi":"10.1149/ma2023-01452471mtgabs","DOIUrl":"https://doi.org/10.1149/ma2023-01452471mtgabs","url":null,"abstract":"Finding novel solid-state electrolyte materials with specific desired properties is one of the main challenges of first principles-based modelling due to its high computational cost. Recently, machine learning (ML) has been used exclusively in the materials discovery field due to its remarkable capabilities to process large amounts of data and extract useful information insights. The implementation of ML into atomic-scale materials modeling can accelerated materials sampling with first principles accuracy, this should provide a short workflow and highly reduce the computational cost. In this work, we facilitate the ML model that can effectively screen for targeted properties from the entire chemical database possibility, including those materials that have never been examined. Currently, we are developing a materials graph networks framework for representing periodic crystal systems with the capability to learn atomistic chemical insights, especially for the discovery of new solid-state electrolyte materials. In this talk, we will discuss the basic theory and our recent work towards the development of ML model that can extensively discover and explore materials. We will highlight the computational-guided evolution approaches and screening high-performance Li conductor materials. Finally, we will end on discussing the future of ML-assisted materials discovery to the future of all-solid-state lithium batteries.","PeriodicalId":11461,"journal":{"name":"ECS Meeting Abstracts","volume":null,"pages":null},"PeriodicalIF":0.0,"publicationDate":"2023-08-28","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"135089356","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
Pub Date : 2023-08-28DOI: 10.1149/ma2023-01442420mtgabs
Shelley D. Minteer
Petroleum hydrocarbons are currently our major energy source and an important feedstock for the chemical industry. Beyond combustion, conversion of chemically inert hydrocarbons to more valuable chemicals is of considerable interest. However, two challenges hinder this conversion. One is the regioselective activation of inert carbon–hydrogen (C–H) bonds. The other is designing a pathway to realize this complicated conversion. This paper will discuss the use of alkane monoxygenases in bioelectrochemical systems for C-H activation, as well as enzyme cascades and hybrid catalytic cascades for the conversion of inert alkanes to complex organic molecules like imines with selectivity far beyond traditional homogeneous and heterogeneous catalysts.
{"title":"(Invited) Bioelectrochemical Strategies for C-H Activation","authors":"Shelley D. Minteer","doi":"10.1149/ma2023-01442420mtgabs","DOIUrl":"https://doi.org/10.1149/ma2023-01442420mtgabs","url":null,"abstract":"Petroleum hydrocarbons are currently our major energy source and an important feedstock for the chemical industry. Beyond combustion, conversion of chemically inert hydrocarbons to more valuable chemicals is of considerable interest. However, two challenges hinder this conversion. One is the regioselective activation of inert carbon–hydrogen (C–H) bonds. The other is designing a pathway to realize this complicated conversion. This paper will discuss the use of alkane monoxygenases in bioelectrochemical systems for C-H activation, as well as enzyme cascades and hybrid catalytic cascades for the conversion of inert alkanes to complex organic molecules like imines with selectivity far beyond traditional homogeneous and heterogeneous catalysts.","PeriodicalId":11461,"journal":{"name":"ECS Meeting Abstracts","volume":null,"pages":null},"PeriodicalIF":0.0,"publicationDate":"2023-08-28","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"135089364","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
Pub Date : 2023-08-28DOI: 10.1149/ma2023-01442408mtgabs
Bruno Fabre, Jesus Alejandro De Sousa, Raphael Pfattner, Concepcio Rovira, Marta Mas-Torrent, Nuria Crivillers
Among the large amount of families of molecules investigated in molecular junctions (MJs), stable free organic radicals have gained an increasing attention over the last years. 1 Thanks to their open-shell electronic configuration, these molecules are paramagnetic, redox and optically active, which make them appealing species for a variety of applications. 2 Chlorinated trityl radicals, and in particular the perchlorotriphenylmethyl radicals have shown to be highly stable as active molecular units in MJs. 3 Such functional molecules have been recently covalently bound to photoactive, hydrogen-terminated silicon surfaces and the so modified surfaces have been demonstrated to function as light-triggered capacitance switches with good stability. 4 Herein, the charge transport of these systems, employing the open- and closed-shell molecules ( Rad-PTM and α H-PTM , Figure 1a), is investigated as solid-state Metal/monolayer/Semiconductor (MmS) junctions using an eutectic Gallium-Indium liquid metal as the top electrode. A characteristic diode behavior is observed which is tuned by the electronic characteristics of the organic molecule. Our results clearly indicate that the presence of the SOMO-SUMO molecular orbitals impacts on the device performance. The junction incorporating the radical shows an almost two orders of magnitude higher rectification ratio ( R = 10 4.04 ) in comparison with the non-radical one ( R = 10 2.30 ) at ± 1 V bias. Interestingly, the high stability of the fabricated MmS permits to interrogate the system under irradiation, evidencing that at the wavelength where the photon energy is close to the band gap of the radical, there is a clear enhancement of the photoresponse. 5 (1) Ratera, I.; Vidal-Gancedo, J.; Maspoch, D.; Bromley, S. T.; Crivillers, N.; Mas-Torrent, M. J. Mater. Chem. C 2021 , 9 , 10610–10623. (2) Mas-Torrent, M.; Crivillers, N.; Mugnaini, V.; Ratera, I.; Rovira, C.; Veciana, J. J. Mater. Chem. 2009 , 19 , 1691–1695. (3) Bejarano, F.; Olavarria-Contreras, I. J.; Droghetti, A.; Rungger, I.; Rudnev, A.; Gutiérrez, D.; Mas-Torrent, M.; Veciana, J.; Van Der Zant, H. S. J.; Rovira, C.; et al. J. Am. Chem. Soc. 2018 , 140 , 1691–1696. (4) De Sousa, J. A.; Bejarano, F.; Gutiérrez, D.; Leroux, Y. R.; Nowik-Boltyk, E. M.; Junghoefer, T.; Giangrisostomi, E.; Ovsyannikov, R.; Casu, M. B.; Veciana, J.; et al. Chem. Sci. 2020 , 11 , 516–524. (5) De Sousa, J. A.; Pfattner, R.; Gutiérrez, D.; Bromley, S. T.; Veciana, J.; Rovira, C.; Mas-Torrent, M.; Fabre, B.; Crivillers, N. ACS Appl. Mater. Interf ., submitted. Figure 1
在分子连接(MJs)中研究的大量分子家族中,稳定的有机自由基近年来受到越来越多的关注。由于它们的开壳电子结构,这些分子具有顺磁性、氧化还原性和光学活性,这使得它们在各种应用中都很有吸引力。氯化三甲基自由基,特别是过氯三苯基甲基自由基,作为活性分子单元在MJs中表现出高度稳定。这些功能分子最近被共价结合到光活性的、端氢的硅表面上,这些修饰的表面已被证明具有良好稳定性的光触发电容开关功能。本文以共晶镓铟液态金属作为顶电极,研究了这些采用开壳和闭壳分子(Rad-PTM和α H-PTM,图1a)作为固态金属/单层/半导体(mm)结的系统的电荷输运。观察到由有机分子的电子特性调谐的特征二极管行为。我们的研究结果清楚地表明,SOMO-SUMO分子轨道的存在对器件性能有影响。在±1 V偏置下,与非自由基结(R = 10 2.30)相比,含有自由基结的整流比(R = 10 4.04)高出近两个数量级。有趣的是,制备的MmS的高稳定性允许在辐照下询问系统,证明在光子能量接近自由基带隙的波长处,光响应明显增强。5 (1) Ratera, I.;Vidal-Gancedo, j .;Maspoch d;布罗姆利,s.t.t;Crivillers:;M. J. Mater。化学。[C] 2017,9, 1010 - 1023。(2) M. Mas-Torrent;Crivillers:;Mugnaini诉;Ratera i;c·罗维拉;维西亚娜,j·j·马特。化学,2009,19,1691-1695。(3) Bejarano, F.;奥拉瓦里亚-孔特雷拉斯,i.j.;Droghetti, a;响,即;Rudnev, a;古铁雷斯,d;Mas-Torrent m;Veciana, j .;Van Der Zant, h.s.j.;c·罗维拉;et al。j。化学。生物工程学报,2018,35(4):1691-1696。(4) De Sousa, j.a.;Bejarano f;古铁雷斯,d;Leroux, Y. R.;Nowik-Boltyk, e.m.;Junghoefer t;Giangrisostomi大肠;Ovsyannikov r;卡苏,m.b.;Veciana, j .;et al。化学。科学通报,2020,11,516-524。(5) De Sousa, j.a.;Pfattner r;古铁雷斯,d;布罗姆利,s.t.t;Veciana, j .;c·罗维拉;Mas-Torrent m;法布尔b;Crivillers, n.c.苹果。板牙。Interf .,提交。图1
{"title":"Stable Organic Radical for Enhancing Metal-Monolayer-Semiconductor Junctions Performance","authors":"Bruno Fabre, Jesus Alejandro De Sousa, Raphael Pfattner, Concepcio Rovira, Marta Mas-Torrent, Nuria Crivillers","doi":"10.1149/ma2023-01442408mtgabs","DOIUrl":"https://doi.org/10.1149/ma2023-01442408mtgabs","url":null,"abstract":"Among the large amount of families of molecules investigated in molecular junctions (MJs), stable free organic radicals have gained an increasing attention over the last years. 1 Thanks to their open-shell electronic configuration, these molecules are paramagnetic, redox and optically active, which make them appealing species for a variety of applications. 2 Chlorinated trityl radicals, and in particular the perchlorotriphenylmethyl radicals have shown to be highly stable as active molecular units in MJs. 3 Such functional molecules have been recently covalently bound to photoactive, hydrogen-terminated silicon surfaces and the so modified surfaces have been demonstrated to function as light-triggered capacitance switches with good stability. 4 Herein, the charge transport of these systems, employing the open- and closed-shell molecules ( Rad-PTM and α H-PTM , Figure 1a), is investigated as solid-state Metal/monolayer/Semiconductor (MmS) junctions using an eutectic Gallium-Indium liquid metal as the top electrode. A characteristic diode behavior is observed which is tuned by the electronic characteristics of the organic molecule. Our results clearly indicate that the presence of the SOMO-SUMO molecular orbitals impacts on the device performance. The junction incorporating the radical shows an almost two orders of magnitude higher rectification ratio ( R = 10 4.04 ) in comparison with the non-radical one ( R = 10 2.30 ) at ± 1 V bias. Interestingly, the high stability of the fabricated MmS permits to interrogate the system under irradiation, evidencing that at the wavelength where the photon energy is close to the band gap of the radical, there is a clear enhancement of the photoresponse. 5 (1) Ratera, I.; Vidal-Gancedo, J.; Maspoch, D.; Bromley, S. T.; Crivillers, N.; Mas-Torrent, M. J. Mater. Chem. C 2021 , 9 , 10610–10623. (2) Mas-Torrent, M.; Crivillers, N.; Mugnaini, V.; Ratera, I.; Rovira, C.; Veciana, J. J. Mater. Chem. 2009 , 19 , 1691–1695. (3) Bejarano, F.; Olavarria-Contreras, I. J.; Droghetti, A.; Rungger, I.; Rudnev, A.; Gutiérrez, D.; Mas-Torrent, M.; Veciana, J.; Van Der Zant, H. S. J.; Rovira, C.; et al. J. Am. Chem. Soc. 2018 , 140 , 1691–1696. (4) De Sousa, J. A.; Bejarano, F.; Gutiérrez, D.; Leroux, Y. R.; Nowik-Boltyk, E. M.; Junghoefer, T.; Giangrisostomi, E.; Ovsyannikov, R.; Casu, M. B.; Veciana, J.; et al. Chem. Sci. 2020 , 11 , 516–524. (5) De Sousa, J. A.; Pfattner, R.; Gutiérrez, D.; Bromley, S. T.; Veciana, J.; Rovira, C.; Mas-Torrent, M.; Fabre, B.; Crivillers, N. ACS Appl. Mater. Interf ., submitted. Figure 1","PeriodicalId":11461,"journal":{"name":"ECS Meeting Abstracts","volume":null,"pages":null},"PeriodicalIF":0.0,"publicationDate":"2023-08-28","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"135089381","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
Pub Date : 2023-08-28DOI: 10.1149/ma2023-01452453mtgabs
Sharon Hammes-Schiffer
Proton-coupled electron transfer (PCET) plays a vital role in a wide range of electrochemical processes. This talk will describe theoretical and computational methods that have been developed to study electrochemical PCET and a variety of applications to molecular and heterogeneous electrocatalysis. My group has formulated a general PCET theory that includes the quantum mechanical effects of the electrons and transferring protons, as well as the motions of the donor-acceptor modes and solvent or protein environment. This PCET theory enables the calculation of rate constants and kinetic isotope effects for comparison to experiment. Our extension of this theory to electrochemical PCET incorporates the electronic structure of the electrode and the interfacial electric fields arising from the electrical double layer. Theoretical formulations for both homogeneous and heterogeneous electrochemical PCET provide analytical expressions for the rate constants and current densities as functions of applied potential. This theory has been applied to proton discharge on metal electrodes, as well as PCET at metal oxides and graphite-conjugated catalysts. These applications highlight the importance of using a theory that quantizes the transferring proton and includes the effects of hydrogen tunneling and excited electron-proton vibronic states. The insights from these theoretical studies are useful for the design of electrocatalytic systems to control the movement and coupling of electrons and protons for energy conversion processes. References Venkataraman, A. V. Soudackov, and S. Hammes-Schiffer, Theoretical formulation of nonadiabatic electrochemical proton-coupled electron transfer at metal-solution interfaces, J. Phys. Chem. C 112 , 12386-12397 (2008). K. Goldsmith, Y. C. Lam, A V. Soudackov, and S. Hammes-Schiffer, Proton discharge on a gold electrode from triethylammonium in acetonitrile: Theoretical modeling of potential-dependent kinetic isotope effects, J. Am. Chem. Soc. 141 , 1084-1090 (2019). C. Lam, A. V. Soudackov, and S. Hammes-Schiffer, Kinetics of proton discharge on metal electrodes: Effects of vibrational nonadiabaticity and solvent dynamics, J. Phys. Chem. Lett. 10 , 5312-5217 (2019). E. Warburton, P. Hutchison, M. N. Jackson, M. L. Pegis, Y. Surendranath, and S. Hammes-Schiffer, “Interfacial field-driven proton-coupled electron transfer at graphite-conjugated organic acids,” J. Am. Chem. Soc. 142 , 20855-20864 (2020). E. Warburton, A. V. Soudackov, and S. Hammes-Schiffer, Theoretical modeling of electrochemical proton-coupled electron transfer, Chem. Rev. 122 , 10599-10650 (2022).
质子耦合电子转移(PCET)在广泛的电化学过程中起着重要作用。本讲座将介绍用于研究电化学PCET的理论和计算方法,以及在分子和多相电催化中的各种应用。我的小组已经制定了一个通用的PCET理论,包括电子和转移质子的量子力学效应,以及供体-受体模式和溶剂或蛋白质环境的运动。这种PCET理论可以计算速率常数和动力学同位素效应,以便与实验进行比较。我们将这一理论扩展到电化学PCET,结合了电极的电子结构和双电层产生的界面电场。均相和非均相电化学PCET的理论公式提供了作为外加电位函数的速率常数和电流密度的解析表达式。该理论已应用于金属电极上的质子放电,以及金属氧化物和石墨共轭催化剂上的PCET。这些应用突出了使用一种理论的重要性,该理论将转移质子量子化,并包括氢隧穿和激发电子-质子振动态的影响。这些理论研究的见解有助于设计电催化系统来控制能量转换过程中电子和质子的运动和耦合。文卡塔曼,A. V. Soudackov, S. Hammes-Schiffer,金属-溶液界面非绝热电化学质子耦合电子转移的理论表述,物理学报。化学。[j] .科学通报,2008,(5):391 - 397。李建军,李建军,李建军,李建军,三乙基铵在金电极上的质子放电:电位依赖的动力学同位素效应的理论建模,J. m。化学。社会科学学报,41,1084-1090(2019)。林志强,李建军,金属电极上质子放电动力学:振动非绝热性和溶剂动力学的影响,物理学报。化学。Lett. 10, 5312-5217(2019)。E. Warburton, P. Hutchison, M. N. Jackson, M. L. Pegis, Y. Surendranath和S. Hammes-Schiffer,“石墨共轭有机酸的界面场驱动质子耦合电子转移”,J. Am。化学。社会科学学报,20855-20864(2020)。李志强,李志强,电化学中质子耦合电子转移的理论模拟,化学学报。中国生物医学工程学报,2012,32(2)。
{"title":"(Keynote) Electrochemical Proton-Coupled Electron Transfer Theory","authors":"Sharon Hammes-Schiffer","doi":"10.1149/ma2023-01452453mtgabs","DOIUrl":"https://doi.org/10.1149/ma2023-01452453mtgabs","url":null,"abstract":"Proton-coupled electron transfer (PCET) plays a vital role in a wide range of electrochemical processes. This talk will describe theoretical and computational methods that have been developed to study electrochemical PCET and a variety of applications to molecular and heterogeneous electrocatalysis. My group has formulated a general PCET theory that includes the quantum mechanical effects of the electrons and transferring protons, as well as the motions of the donor-acceptor modes and solvent or protein environment. This PCET theory enables the calculation of rate constants and kinetic isotope effects for comparison to experiment. Our extension of this theory to electrochemical PCET incorporates the electronic structure of the electrode and the interfacial electric fields arising from the electrical double layer. Theoretical formulations for both homogeneous and heterogeneous electrochemical PCET provide analytical expressions for the rate constants and current densities as functions of applied potential. This theory has been applied to proton discharge on metal electrodes, as well as PCET at metal oxides and graphite-conjugated catalysts. These applications highlight the importance of using a theory that quantizes the transferring proton and includes the effects of hydrogen tunneling and excited electron-proton vibronic states. The insights from these theoretical studies are useful for the design of electrocatalytic systems to control the movement and coupling of electrons and protons for energy conversion processes. References Venkataraman, A. V. Soudackov, and S. Hammes-Schiffer, Theoretical formulation of nonadiabatic electrochemical proton-coupled electron transfer at metal-solution interfaces, J. Phys. Chem. C 112 , 12386-12397 (2008). K. Goldsmith, Y. C. Lam, A V. Soudackov, and S. Hammes-Schiffer, Proton discharge on a gold electrode from triethylammonium in acetonitrile: Theoretical modeling of potential-dependent kinetic isotope effects, J. Am. Chem. Soc. 141 , 1084-1090 (2019). C. Lam, A. V. Soudackov, and S. Hammes-Schiffer, Kinetics of proton discharge on metal electrodes: Effects of vibrational nonadiabaticity and solvent dynamics, J. Phys. Chem. Lett. 10 , 5312-5217 (2019). E. Warburton, P. Hutchison, M. N. Jackson, M. L. Pegis, Y. Surendranath, and S. Hammes-Schiffer, “Interfacial field-driven proton-coupled electron transfer at graphite-conjugated organic acids,” J. Am. Chem. Soc. 142 , 20855-20864 (2020). E. Warburton, A. V. Soudackov, and S. Hammes-Schiffer, Theoretical modeling of electrochemical proton-coupled electron transfer, Chem. Rev. 122 , 10599-10650 (2022).","PeriodicalId":11461,"journal":{"name":"ECS Meeting Abstracts","volume":null,"pages":null},"PeriodicalIF":0.0,"publicationDate":"2023-08-28","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"135089382","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
Pub Date : 2023-08-28DOI: 10.1149/ma2023-01382294mtgabs
Mengxue Huang, Ruimin Ding, Lifang Chen, Jingchao Chen, Chaoqi Han, Wenwen Shi, Jie Yang, Shanshan Liu, Xi Yin
Metal- and nitrogen-doped carbon (M-N-C) catalysts have great potential in heterogeneous catalysis. They are used to catalyze various crucial electrochemical reactions, such as the oxygen reduction reaction (ORR), the hydrogen evolution reaction (HER), the oxygen evolution reaction (OER), and the CO 2 reduction reaction (CO 2 RR). 1-4 The nitrogen-coordinated metal sites (MN x ) have been considered the main active sites in these M-N-C catalysts. However, the synthesis of MN x moieties often undergoes a high-temperature heat-treatment step, resulting in low site density. On the other side, the coordination environment in the MN x sites is also affected by the metal species which induced the site formation. Therefore, it is challenging to single out the role of central metal in the structure-activity relationships for these MN x sites. In this presentation, we will discuss our recent progress in the development of a solution-phase coordination synthesis approach targeting M-N-C catalysts with high active-site density and well-defined coordination environments. 5, 6 A series of M-N-C catalysts are synthesized via this approach by coordinating electroactive target metal ions with the nitrogen-coordinated metal-vacancy (MVN x ) sites in N-C templated by sacrificial metals. With a combined experimental and computational approach, we explore the role of sacrificial metals, including s -, p -, 3 d -, 4 d -, and f -block metals, in forming various MVN x sites with unique coordination configurations. The structure-activity relationship between the coordination environment and the catalytic activity for ORR, HER, OER, and CO 2 RR is established by comparing the MN x site structures induced by various sacrificial metals. Furthermore, we will present the activity series of metal centers in M-N-C catalysts with the same and well-defined coordination environment for ORR, HER, OER, and CO 2 RR. These results will guide the future development of M-N-C catalysts. Acknowledgments Financial support from the State Key Laboratory of Coal Conversion, Institute of Coal Chemistry, Chinese Academy of Sciences is greatly appreciated. This study is financially supported by the Shanxi Province grant (Grant No. 20210302123011, 202203021212007, and 202103021224442), and Key Research and Development (R&D) Projects of Shanxi Province (202102070301018). References J. Cui, Q. Chen, X. Li and S. Zhang. Recent advances in non-precious metal electrocatalysts for oxygen reduction in acidic media and PEMFCs: an activity, stability and mechanism study. Green Chemistry , 23 , 6898 (2021). H. He, H. H. Wang, J. Liu, X. Liu, W. Li and Y. Wang. Research Progress and Application of Single-Atom Catalysts: A Review. Molecules , 26 , 6501 (2021). U. Martinez, S. Komini Babu, E. F. Holby, H. T. Chung, X. Yin and P. Zelenay. Progress in the Development of Fe-Based PGM-Free Electrocatalysts for the Oxygen Reduction Reaction. Advanced Materials , 31 , 1806545 (2019). Y. Wang, X. Cui, L. Peng,
金属和氮掺杂碳(M-N-C)催化剂在非均相催化方面具有很大的潜力。它们用于催化各种关键的电化学反应,如氧还原反应(ORR)、析氢反应(HER)、析氧反应(OER)和CO 2还原反应(CO 2 RR)。氮配位金属位(MN x)被认为是这些M-N-C催化剂的主要活性位。然而,MN x部分的合成通常要经过高温热处理步骤,导致位点密度低。另一方面,MN x位点的配位环境也受到诱导位点形成的金属种类的影响。因此,在这些MN x位点的结构-活性关系中,找出中心金属的作用是具有挑战性的。在本次演讲中,我们将讨论我们在针对具有高活性位点密度和良好定义的配位环境的M-N-C催化剂的溶液相配位合成方法的最新进展。5,6将电活性靶金属离子与牺牲金属模板化的N-C中氮配位金属空位(mvnx)配位,通过该方法合成了一系列M-N-C催化剂。通过实验和计算相结合的方法,我们探索了牺牲金属,包括s -, p -, 3d -, 4d -和f -块金属,在形成具有独特配位构型的各种mvnx位点中的作用。通过比较各种牺牲金属诱导的MN x位点结构,建立了配位环境与ORR、HER、OER和co2 RR催化活性之间的构效关系。此外,我们将在相同和明确的配位环境下,展示M-N-C催化剂中金属中心对ORR, HER, OER和CO 2 RR的活性系列。这些结果对今后M-N-C催化剂的开发具有指导意义。感谢中国科学院煤化学研究所煤转化国家重点实验室的资助。本研究由山西省基金(资助号:20210302123011、202203021212007和202103021224442)和山西省重点研发项目(202102070301018)资助。参考文献崔健,陈琪,李晓霞,张绍文。酸性介质中氧还原用非贵金属电催化剂及pemfc的研究进展:活性、稳定性及机理研究绿色化学,23,6898(2021)。何红红,王红红,刘建军,刘霞,李伟,王勇。单原子催化剂的研究进展及应用综述分子学报,26,6501(2021)。U. Martinez, S. Komini Babu, E. F. Holby, H. T. Chung, X. Yin, P. Zelenay。氧还原反应中无铁基pgm电催化剂的研究进展。高分子材料学报,2016,35(5):481 - 481。王勇,崔祥,彭丽丽,李丽丽,乔健,黄慧,石俊。典型电化学氧化还原反应的特殊配位金属-氮-碳催化剂。高分子材料学报,33,(1):481 - 481。黄明,丁仁,杨建军,石伟,石生,陈亮,刘树和殷祥。在镍和氮共掺杂碳模板上通过液相配位形成氮配位金属位(M = Fe, Co)电化学报,1999,16(4):444 - 444。黄明,陈丽丽,丁仁,石伟,秦琪,杨静,刘树生,殷晓明。碱金属诱导N-C模板液相合成Co-N-C催化剂的研究ChemRxiv, doi: 10.26434/ ChemRxiv -2022-xnh88(2022)。
{"title":"(Digital Presentation) Structure-Activity Relationship of M-N-C Electrocatalysts Synthesized Using a General Solution-Phase Coordination Approach","authors":"Mengxue Huang, Ruimin Ding, Lifang Chen, Jingchao Chen, Chaoqi Han, Wenwen Shi, Jie Yang, Shanshan Liu, Xi Yin","doi":"10.1149/ma2023-01382294mtgabs","DOIUrl":"https://doi.org/10.1149/ma2023-01382294mtgabs","url":null,"abstract":"Metal- and nitrogen-doped carbon (M-N-C) catalysts have great potential in heterogeneous catalysis. They are used to catalyze various crucial electrochemical reactions, such as the oxygen reduction reaction (ORR), the hydrogen evolution reaction (HER), the oxygen evolution reaction (OER), and the CO 2 reduction reaction (CO 2 RR). 1-4 The nitrogen-coordinated metal sites (MN x ) have been considered the main active sites in these M-N-C catalysts. However, the synthesis of MN x moieties often undergoes a high-temperature heat-treatment step, resulting in low site density. On the other side, the coordination environment in the MN x sites is also affected by the metal species which induced the site formation. Therefore, it is challenging to single out the role of central metal in the structure-activity relationships for these MN x sites. In this presentation, we will discuss our recent progress in the development of a solution-phase coordination synthesis approach targeting M-N-C catalysts with high active-site density and well-defined coordination environments. 5, 6 A series of M-N-C catalysts are synthesized via this approach by coordinating electroactive target metal ions with the nitrogen-coordinated metal-vacancy (MVN x ) sites in N-C templated by sacrificial metals. With a combined experimental and computational approach, we explore the role of sacrificial metals, including s -, p -, 3 d -, 4 d -, and f -block metals, in forming various MVN x sites with unique coordination configurations. The structure-activity relationship between the coordination environment and the catalytic activity for ORR, HER, OER, and CO 2 RR is established by comparing the MN x site structures induced by various sacrificial metals. Furthermore, we will present the activity series of metal centers in M-N-C catalysts with the same and well-defined coordination environment for ORR, HER, OER, and CO 2 RR. These results will guide the future development of M-N-C catalysts. Acknowledgments Financial support from the State Key Laboratory of Coal Conversion, Institute of Coal Chemistry, Chinese Academy of Sciences is greatly appreciated. This study is financially supported by the Shanxi Province grant (Grant No. 20210302123011, 202203021212007, and 202103021224442), and Key Research and Development (R&D) Projects of Shanxi Province (202102070301018). References J. Cui, Q. Chen, X. Li and S. Zhang. Recent advances in non-precious metal electrocatalysts for oxygen reduction in acidic media and PEMFCs: an activity, stability and mechanism study. Green Chemistry , 23 , 6898 (2021). H. He, H. H. Wang, J. Liu, X. Liu, W. Li and Y. Wang. Research Progress and Application of Single-Atom Catalysts: A Review. Molecules , 26 , 6501 (2021). U. Martinez, S. Komini Babu, E. F. Holby, H. T. Chung, X. Yin and P. Zelenay. Progress in the Development of Fe-Based PGM-Free Electrocatalysts for the Oxygen Reduction Reaction. Advanced Materials , 31 , 1806545 (2019). Y. Wang, X. Cui, L. Peng, ","PeriodicalId":11461,"journal":{"name":"ECS Meeting Abstracts","volume":null,"pages":null},"PeriodicalIF":0.0,"publicationDate":"2023-08-28","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"135089398","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
Pub Date : 2023-08-28DOI: 10.1149/ma2023-01382287mtgabs
Patrick Teppor, Rutha Jäger, Jaak Nerut, Miriam Koppel, Jaan Aruväli, Olga Volobujeva, Enn Lust
As society continues to adopt an increasingly eco-friendly stance, the efficient usage of natural resources needs to be maximised. For instance, energy obtained from biomass covers roughly a tenth of the global demand. This biomass can instead be used as a carbon source to produce value-added materials such as tnon-platinum group metal (NPGM) oxygen reduction catalysts, which are desperately sought after as global demand for fuel cells continues to rise [1,2]. For example, peat is an extremely abundant biomass material in Estonia covering roughly 20% of the country [3]. Herein, the viability of using peat-based catalysts as oxygen reduction catalysts in alkaline media was investigated. The peat sourced from a local peatland was processed and modified with inexpensive iron and nitrogen precursors through the common double-pyrolysis and acid washing synthesis procedure into peat-based NPGM catalysts. Additionally, zinc chloride was used as a pore forming agent. The influence of several principal synthesis parameters, e.g. precursor compound type and amount, on the physical and electrochemical properties of these materials was investigated using various characterization methods. The NPGM catalysts obtained from naturally abundant peat were highly microporous systems due to the inclusion of zinc chloride in the synthesis mixture. High onset (~0.93 V vs RHE) and half-wave potential (~0.83 V vs RHE) values were obtained for most of the materials in activity screening experiments conducted with a rotating disc electrode setup using 0.1 M KOH. However, using an excessive amount of the nitrogen precursor in the synthesis proved to be detrimental to the obtained activity. The high activity of the obtained peat-derived catalysts was further investigated in a rotating ring disc electrode setup where the influence of the studied synthesis parameters on the oxygen reduction reaction selectivity was more evident. Acknowledgments This work was supported by the EU through the European Regional Development Fund under projects TK141 “Advanced materials and high-technology devices for energy recuperation systems” (2014-2020.4.01.15-0011), NAMUR “Nanomaterials - research and applications” (3.2.0304.12-0397), NAMUR+ core facility funded by the Estonian Research Council (TT 13), PRG676 “Development of express analysis methods for micro-mesoporous materials for Estonian peat derived carbon supercapacitors” (01.01.2020–31.12.2024) and PUT1581 (1.01.2017–31.12.2020). References F. Jaouen, D. Jones, N. Coutard, V. Artero, P. Strasser, A. Kucernak, Johns. Matthey Technol Rev. 2018, 62, 231. E4tech, 2022, The Fuel Cell Industry Review 2021 . M. Orru, H. Orru, Est. J. Earth Sci. 2008, 57, 87.
随着社会继续采取越来越环保的立场,需要最大限度地有效利用自然资源。例如,从生物质能中获得的能源约占全球需求的十分之一。这种生物质可以作为碳源来生产增值材料,如非铂族金属(NPGM)氧还原催化剂,随着全球对燃料电池的需求持续上升,这种材料受到了迫切的追捧[1,2]。例如,泥炭是爱沙尼亚极其丰富的生物质材料,约占该国面积的20%[3]。本文研究了在碱性介质中使用泥炭基催化剂作为氧还原催化剂的可行性。从当地泥炭地获取泥炭,通过常见的双热解和酸洗合成工艺,用廉价的铁和氮前体对其进行处理和改性,制备出泥炭基NPGM催化剂。另外,氯化锌作为成孔剂。采用不同的表征方法研究了前驱体化合物类型和用量等主要合成参数对材料物理和电化学性能的影响。从天然丰富的泥炭中获得的NPGM催化剂由于在合成混合物中包含氯化锌而具有高度微孔体系。在0.1 M KOH的旋转圆盘电极装置上进行的活性筛选实验中,大多数材料获得了高起始电位(~0.93 V vs RHE)和半波电位(~0.83 V vs RHE)值。然而,在合成中使用过量的氮前体被证明对获得的活性是有害的。在旋转环盘式电极装置上进一步研究了所制备的泥炭系催化剂的高活性,其中合成参数对氧还原反应选择性的影响更为明显。本工作由欧盟通过欧洲区域发展基金项目TK141“能源回收系统的先进材料和高科技设备”(2014-2020.4.01.15-0011),NAMUR“纳米材料-研究和应用”(3.2.0304.12-0397),NAMUR+核心设施由爱沙尼亚研究理事会(TT 13)资助。PRG676“爱沙尼亚泥炭衍生碳超级电容器微介孔材料快速分析方法的发展”(01.01.2020-31.12.2024)和PUT1581(1.01.2017-31.12.2020)。参考文献F. Jaouen, D. Jones, N. Coutard, V. Artero, P. Strasser, A. Kucernak, Johns。自动化学报,2018,62,231。E4tech, 2022, The Fuel Cell Industry Review 2021。张建军,张建军,张建军,等。地球科学进展,2008,32(1):1 - 4。
{"title":"Valorization of Naturally Abundant Low-Value Peat into Highly Active Non-Platinum Group Metal Oxygen Reduction Catalysts","authors":"Patrick Teppor, Rutha Jäger, Jaak Nerut, Miriam Koppel, Jaan Aruväli, Olga Volobujeva, Enn Lust","doi":"10.1149/ma2023-01382287mtgabs","DOIUrl":"https://doi.org/10.1149/ma2023-01382287mtgabs","url":null,"abstract":"As society continues to adopt an increasingly eco-friendly stance, the efficient usage of natural resources needs to be maximised. For instance, energy obtained from biomass covers roughly a tenth of the global demand. This biomass can instead be used as a carbon source to produce value-added materials such as tnon-platinum group metal (NPGM) oxygen reduction catalysts, which are desperately sought after as global demand for fuel cells continues to rise [1,2]. For example, peat is an extremely abundant biomass material in Estonia covering roughly 20% of the country [3]. Herein, the viability of using peat-based catalysts as oxygen reduction catalysts in alkaline media was investigated. The peat sourced from a local peatland was processed and modified with inexpensive iron and nitrogen precursors through the common double-pyrolysis and acid washing synthesis procedure into peat-based NPGM catalysts. Additionally, zinc chloride was used as a pore forming agent. The influence of several principal synthesis parameters, e.g. precursor compound type and amount, on the physical and electrochemical properties of these materials was investigated using various characterization methods. The NPGM catalysts obtained from naturally abundant peat were highly microporous systems due to the inclusion of zinc chloride in the synthesis mixture. High onset (~0.93 V vs RHE) and half-wave potential (~0.83 V vs RHE) values were obtained for most of the materials in activity screening experiments conducted with a rotating disc electrode setup using 0.1 M KOH. However, using an excessive amount of the nitrogen precursor in the synthesis proved to be detrimental to the obtained activity. The high activity of the obtained peat-derived catalysts was further investigated in a rotating ring disc electrode setup where the influence of the studied synthesis parameters on the oxygen reduction reaction selectivity was more evident. Acknowledgments This work was supported by the EU through the European Regional Development Fund under projects TK141 “Advanced materials and high-technology devices for energy recuperation systems” (2014-2020.4.01.15-0011), NAMUR “Nanomaterials - research and applications” (3.2.0304.12-0397), NAMUR+ core facility funded by the Estonian Research Council (TT 13), PRG676 “Development of express analysis methods for micro-mesoporous materials for Estonian peat derived carbon supercapacitors” (01.01.2020–31.12.2024) and PUT1581 (1.01.2017–31.12.2020). References F. Jaouen, D. Jones, N. Coutard, V. Artero, P. Strasser, A. Kucernak, Johns. Matthey Technol Rev. 2018, 62, 231. E4tech, 2022, The Fuel Cell Industry Review 2021 . M. Orru, H. Orru, Est. J. Earth Sci. 2008, 57, 87.","PeriodicalId":11461,"journal":{"name":"ECS Meeting Abstracts","volume":null,"pages":null},"PeriodicalIF":0.0,"publicationDate":"2023-08-28","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"135089406","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
京公网安备 11010802042870号
京ICP备2023020795号-1
扫码关注我们
求助内容:
应助结果提醒方式: