![(R)-N-[(S)-1-[2-(Diphenylphosphino)phenyl]ethyl]-2-methylpropane-2-sulfinamide structure](https://static.chemtradehub.com/structs/159/1595319-98-4-33e7.webp "(R)-N-[(S)-1-[2-(Diphenylphosphino)phenyl]ethyl]-2-methylpropane-2-sulfinamide structure")
A single-phase gadolinium-doped ceria cathode for highly efficient CO2 electrolysis
文献情報
出版日
2023-11-03
DOI
10.1039/D3TA03977C
インパクトファクター
12.732
著者
Ahmad Shaur, Michel Drazkowski, Shaochen Zhu, Bernard Boukamp
原文を見る
要旨
High-temperature solid-oxide CO2 electrolysers enable high-efficiency conversion of electrical energy to valuable fuels and chemicals and as such facilitate a sustainable-energy technology. Conventional cermet-based fuel electrodes used in such solid-oxide cells (SOCs) like nickel–yttria-stabilized zirconia (Ni–YSZ) suffer from morphological degradation and destructive carbon deposition. In recent years, there has been an increasing interest in employing single-phase ceria-based fuel electrodes, which are known to exhibit excellent carbon deposition resistance. Under sufficiently reducing conditions, doped ceria (substituted with trivalent cations such as samarium or gadolinium to generate mobile oxygen vacancies) becomes a mixed ionic–electronic conductor, showing appreciable electronic conductivity. Here, we show for the first time stable high performance in CO2 electrolysis using a ceria-based SOC. The single full cell incorporating a 10 mol% gadolinium-doped ceria (GCO) fuel electrode delivers a current density as high as 1.51 A cm−2 at 800 °C during pure CO2 electrolysis, which is the best electrode performance reported to date among all-ceramic cathode materials. We demonstrate that the electrode performance in CO2 electrolysis is linked with the electronic conductivity, and hence, with the electronic charge carrier concentration in GCO. The results of the present work pave the way for development of robust, nickel-free SOCs for direct CO2 electrolysis.
おすすめジャーナル
関連文献
Dynamics study of the atmospheric reaction involving vibrationally excited O3 with OH
Pingya Luo, Rong Zeng, Pedro J. S. B. Caridade, António J. C. Varandas
2010-08-02
Paper
DOI: 10.1039/B927542H
Nitrate radical addition–elimination reactions of atmospherically relevant sulfur-containing molecules
Joseph R. Lane, Solvejg Jørgensen, Henrik G. Kjaergaard
2010-08-27
Paper
DOI: 10.1039/C0CP00383B
Gas–surface energy exchange and thermal accommodation of CO2 and Ar in collisions with methyl, hydroxyl, and perfluorinated self-assembled monolayers
Jessica W. Lu, William A. Alexander, John R. Morris
2010-08-20
Paper
DOI: 10.1039/B921893A
In situ surface-enhanced Raman scattering and X-ray photoelectron spectroscopic investigation of coenzyme Q10 on silver electrode
Dan Li, Da-Wei Li, Yi-Tao Long
2010-12-08
Paper
DOI: 10.1039/C0CP01449D
Impact of surface mechanics on the reactivity of electrodes
R. N. Viswanath, L. A. Kibler, D. M. Kolb
2010-12-06
Communication
DOI: 10.1039/C0CP01742F
Microscopic model of carbonaceous nanoporous molecular sieves—anomalous transport in molecularly confined spaces
Piotr Kowalczyk, Piotr A. Gauden, Artur P. Terzyk, Sylwester Furmaniak
2010-08-05
Paper
DOI: 10.1039/B926206G
Molecular organization and effective energy transfer in iridium metallosurfactant–porphyrin assemblies embedded in Langmuir–Schaefer films
Cristina Roldán-Carmona, Antonio M. González-Delgado, Andrés Guerrero-Martínez, Luisa De Cola, Marta Pérez-Morales, María T. Martín-Romero, Luis Camacho
2010-12-14
Paper
DOI: 10.1039/C0CP01683G
Mesoscopic non-equilibrium thermodynamics of non-isothermal reaction-diffusion
I. Pagonabarraga, J. M. Ortiz de Zárate, J. V. Sengers
2010-08-27
Paper
DOI: 10.1039/C0CP00289E
The uptake of 2-methyl-3-buten-2-ol into aqueous mixed solutions of sulfuric acid and hydrogen peroxide‡
Ze Liu, Maofa Ge, Weigang Wang, Shi Yin, Shengrui Tong
2011-01-04
Paper
DOI: 10.1039/C0CP00905A
Charge carrier mobility in poly[methyl(phenyl)silylene] studied by time-resolved terahertz spectroscopy and molecular modelling
Hynek Němec, Irena Kratochvílová, Petr Kužel, Anna Kochalska, Juraj Nožár, Stanislav Nešpůrek
2010-12-15
Paper
DOI: 10.1039/C0CP00774A
こちらもおすすめ
化合物よくある質問
2,3-スチオエポキシマドルを取り扱う際の実験室安全事項は何ですか?
取り扱いにはPPE(プロテクティブ・パーソナル・エイド)が必要で、防ぐ手袋と保護眼鏡を着用してください。ドラフトチャンバーの使用を推奨します。漏洩した場合は、適...
4267-80-52,3-Thioepoxy Madol
53981-25-22-Amino-6-fluorophen...
化合物よくある質問
BOC-S-3-アミニ-4-(4-メチオキシベンチル)-ブタン酸の代替品はありますか?
この化合物の代替品としては、BOC保護基を有さないアミノ酸やその他の保護基化合物が考えられます。また、メチオキシ基を有しない他の芳香族アミノ酸も代替品として挙げ...
126800-59-7(3S)-4-(4-Methoxyphe...
化合物よくある質問
Methyl 2-(chloromethyl)-3-nitrobenzoate(1218910-61-2)の代替品はありますか?
Methyl 2-(chloromethyl)-3-nitrobenzoate(1218910-61-2)の代替品としては、化学組成を変えることで効果を達成する...
1218910-61-2Methyl 2-(chlorometh...
化合物よくある質問
(2R)-2-アミノ-N-ベンジル-3-ヒドロキシプロパナミドを含む廃棄物はどのように処理すべきですか?
(2R)-2-アミノ-N-ベンジル-3-ヒドロキシプロパナミドを含む廃棄物は、適切な廃棄物管理ガイドラインに基づき処理する必要があります。まず、廃棄物を適切に収...
175481-39-7(2R)-2-amino-N-benzy...
化合物よくある質問
6,7-二氢-咪唑並[1,2-a]ピリドイン-8(5h)-酮はどのように合成されますか?
6,7-二氢-咪唑並[1,2-a]ピリドイン-8(5h)-酮は、2-ブロモフェニルアセトインとリン酸ハロゲン化物を反応させることで合成できます。この反応は高温で...
457949-09-66,7-Dihydroimidazo[1...
化合物よくある質問
エチル(3R)-3-ピロリジニル酢酸水和塩とは何ですか?
エチル(3R)-3-ピロリジニル酢酸水和塩は、CAS番号1332459-32-1の化合物で、(R)-乙基2-(ピロリジン-3-基)酢酸塩水和塩と呼ばれます。この...
1332459-32-1Ethyl (3R)-3-pyrroli...
化合物よくある質問
(2S)-{[(2-メチルエチルオキシ]カルボニル}アミノ)[2-(トリアフルオロメチルフェニル]エチカシック酸の物理化学的性質は何ですか?
(2S)-{[(2-メチルエチルオキシ]カルボニル}アミノ)[2-(トリアフルオロメチルフェニル]エチカシック酸のCAS番号は1203454-45-8です。この...
1203454-45-8(2S)-({[(2-Methyl-2-...
化合物よくある質問
2-ブロモ-1-(2-メチル-2-プロパニル)-4-ニトロベンゼンはどのように保存すればよいですか?
2-ブロモ-1-(2-メチル-2-プロパニル)-4-ニトロベンゼンは、直射日光を避けて暗所で、室温(約15℃〜25℃)、乾燥した場所に保存する必要があります。ま...
6310-17-42-Bromo-1-(2-methyl-...
化合物よくある質問
1-[(4-硝基フェニル)スルホニル]-1H-1,2,4-三唑の市場動向や研究トレンドはどうですか?
市場動向としては、1-[(4-硝基フェニル)スルホニル]-1H-1,2,4-三唑は主に農業用除草剤や合成化学製品の原料として利用されています。研究トレンドとして...
57777-84-11-[(4-Nitrophenyl)su...
掲載誌
Journal of Materials Chemistry A
CiteScore:
19.5
自己引用率:
4.7%
年間論文数:
2211
Journal of Materials Chemistry A, B & C cover high quality studies across all fields of materials chemistry. The journals focus on those theoretical or experimental studies that report new understanding, applications, properties and synthesis of materials. The journals have a strong history of publishing quality reports of interest to interdisciplinary communities and providing an efficient and rigorous service through peer review and publication. The journals are led by an international team of Editors-in-Chief and Associate Editors who are all active researchers in their fields. Journal of Materials Chemistry A, B & C are separated by the intended application of the material studied. Broadly, applications in energy and sustainability are of interest to Journal of Materials Chemistry A, applications in biology and medicine are of interest to Journal of Materials Chemistry B, and applications in optical, magnetic and electronic devices are of interest to Journal of Materials Chemistry C. More than one Journal of Materials Chemistry journal may be suitable for certain fields and researchers are encouraged to submit their paper to the journal that they feel best fits for their particular article. Example topic areas within the scope of Journal of Materials Chemistry A are listed below. This list is neither exhaustive nor exclusive. Artificial photosynthesis Batteries Carbon dioxide conversion Catalysis Fuel cells Gas capture/separation/storage Green/sustainable materials Hydrogen generation Hydrogen storage Photocatalysis Photovoltaics Self-cleaning materials Self-healing materials Sensors Supercapacitors Thermoelectrics Water splitting Water treatment
おすすめ化合物
![5,10-Dihydroindeno[2,1-a]indene structure](https://static.chemtradehub.com/structs/654/6543-29-9-71ca.webp "5,10-Dihydroindeno[2,1-a]indene structure")
おすすめサプライヤー
免責事項
このページに表示される学術雑誌情報は、参考および研究目的のみを目的としています。当社は雑誌出版社とは提携しておらず、投稿の取り扱いも行っておりません。出版に関するお問い合わせは、各雑誌出版社に直接ご連絡ください。
表示されている情報に誤りがある場合は、support@chemtradehub.com までご連絡ください。迅速に確認し、対応いたします。