How AI guided the development of green hydrogen production: in the case of solid oxide electrolysis cell?

Adv search

How AI guided the development of green hydrogen production: in the case of solid oxide electrolysis cell?

Baoyin Yuan , Xiaohan Zhang , Chunmei Tang , Ning Wang , Siyu Ye

Journal of Materials Informatics ›› 2025, Vol. 5 ›› Issue (2) : 25

PDF

Journal of Materials Informatics ›› 2025, Vol. 5 ›› Issue (2) :25 DOI: 10.20517/jmi.2024.106

Perspective

How AI guided the development of green hydrogen production: in the case of solid oxide electrolysis cell?

Author information +

History +

PDF

Abstract

The development of efficient and stable hydrogen production technologies is crucial for global clean energy transition. Solid oxide electrolysis cells (SOECs) have emerged as a promising technology for green hydrogen production due to their high efficiency, low-cost catalysts, and excellent adaptability to renewable energy sources. However, significant challenges remain in materials design, interface engineering, and system integration. This perspective reviews recent advances in artificial intelligence (AI)-guided SOEC development, focusing on machine learning approaches for design of key materials. Furthermore, we highlight how AI technologies can address the key challenges in both single-cell performances and system-level integration with renewable energy sources. Looking forward, we outline strategic directions for advancing AI-driven SOEC development toward commercial implementation, which may offer valuable insights and experiences within the field of energy conversion and storage.

Keywords

Hydrogen energy / solid oxide electrolysis cell / anode material / machine learning

Cite this article

Download citation ▾

Baoyin Yuan, Xiaohan Zhang, Chunmei Tang, Ning Wang, Siyu Ye. How AI guided the development of green hydrogen production: in the case of solid oxide electrolysis cell?. Journal of Materials Informatics, 2025, 5(2): 25 DOI:10.20517/jmi.2024.106

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Bidwell D.Thinking through participation in renewable energy decisions.Nat Energy2016;1:16051

[2]	Yu N,Chen X.Rational design of Ruddlesden-Popper perovskite ferrites as air electrode for highly active and durable reversible protonic ceramic cells.Nanomicro Lett2024;16:177 PMCID:PMC11035539

[3]	Li J.Oxygen evolution reaction in energy conversion and storage: design strategies under and beyond the energy scaling relationship.Nanomicro Lett2022;14:112 PMCID:PMC9051012

[4]	Kim D,Ahn S.On the role of bimetal-doped BaCoO_3-_δ perovskites as highly active oxygen electrodes of protonic ceramic electrochemical cells.Adv Energy Mater2024;14:2304059

[5]	Jang I,Crawford JO.Electrocatalysis in solid oxide fuel cells and electrolyzers.Chem Rev2024;124:8233-306

[6]	Zhang W,Gu X,Deng Z.Water electrolysis toward elevated temperature: advances, challenges and frontiers.Chem Rev2023;123:7119-92

[7]	Ivanova ME,Müller M.Technological pathways to produce compressed and highly pure hydrogen from solar power.Angew Chem Int Ed Engl2023;62:e202218850

[8]	Tang C,Wang N.Green hydrogen production by intermediate-temperature protonic solid oxide electrolysis cells: advances, challenges, and perspectives.InfoMat2024;6:e12515

[9]	Liu Y,Liu W.Boosting interfacial charge transfer for alkaline hydrogen evolution via rational interior Se modification.Nano Energy2021;81:105641

[10]	Lei Y,Liu Y.Designing atomic active centers for hydrogen evolution electrocatalysts.Angew Chem Int Ed Engl2020;59:20794-812

[11]	Zhai S,Cui P.A combined ionic Lewis acid descriptor and machine-learning approach to prediction of efficient oxygen reduction electrodes for ceramic fuel cells.Nat Energy2022;7:866-75

[12]	Mo S,Huang Z.Recent advances on PEM fuel cells: from key materials to membrane electrode assembly.Electrochem Energy Rev2023;6:190

[13]	Zhao S,Wang W.Reverse atom capture on perovskite surface enabling robust and efficient cathode for protonic ceramic fuel cells.Adv Mater2024;36:e2405052

[14]	Liu Z,Sun H.Synergistic dual-phase air electrode enables high and durable performance of reversible proton ceramic electrochemical cells.Nat Commun2024;15:472 PMCID:PMC10784466

[15]	Li Z,Feng D.Prediction of perovskite oxygen vacancies for oxygen electrocatalysis at different temperatures.Nat Commun2024;15:9318 PMCID:PMC11522418

[16]	Murphy R,Zhang L.A new family of proton-conducting electrolytes for reversible solid oxide cells: BaHf_xCe_0.8-_xY_0.1Yb_0.1O_3-_δ.Adv Funct Mater2020;30:2002265

[17]	Matsumoto H,Okuyama Y.Proton-conducting oxide and applications to hydrogen energy devices.Pure Appl Chem2012;85:427-35

[18]	Jing J,Chen L,Lei Z.Structure, synthesis, properties and solid oxide electrolysis cells application of Ba(Ce, Zr)O₃ based proton conducting materials.Chem Eng J2022;429:132314

[19]	Li S.Composite oxygen electrode based on LSCF and BSCF for steam electrolysis in a proton-conducting solid oxide electrolyzer.J Electrochem Soc2013;160:F224-33

[20]	Yoo Y.Performance and stability of proton conducting solid oxide fuel cells based on yttrium-doped barium cerate-zirconate thin-film electrolyte.J Power Sources2013;229:48-57

[21]	Zhou D,Dong X,Wang Z.A facial and effective way to prepare high-performance hetero-structured composite cathode for intermediate temperature solid oxide fuel cells.Int J Hydrogen Energy2022;47:13112-20

[22]	Xiong D,Li Y,Liu C.Enhanced cathodic activity by tantalum inclusion at B-site of La_0.6Sr_0.4CO_0.4Fe_0.6O₃ based on structural property tailored via camphor-assisted solid-state reaction.J Adv Ceram2022;11:1330-42

[23]	Wang N,Du L.Advanced cathode materials for protonic ceramic fuel cells: recent progress and future perspectives.Adv Energy Mater2022;12:2201882

[24]	Zhang X,Yang Y.Novel high-entropy air electrodes enhancing electrochemical performances of reversible protonic ceramic cells. Adv. Funct. Mater. 2025, 2421083.

[25]	Fop S.Solid oxide proton conductors beyond perovskites.J Mater Chem A2021;9:18836-56

[26]	Li Y,Zhang S.Mutual conversion of CO-CO₂ on a perovskite fuel electrode with endogenous alloy nanoparticles for reversible solid oxide cells.ACS Appl Mater Interfaces2022;14:9138-50

[27]	Kojima H,Todoroki N,Matsui T.Influence of renewable energy power fluctuations on water electrolysis for green hydrogen production.Int J Hydrogen Energy2023;48:4572-93

[28]	Wang M,Zhu L.Exploring phase transitions in CdSe: a machine learning and swarm intelligence approach.J Mater Inf2024;4:29

[29]	Lu Z,Li Y,Zeng X.Machine learning driven design of high-performance Al alloys.J Mater Inf2024;4:19

[30]	Liu H,Qiao Z,Wang Y.Machine learning-assisted prediction, screen, and interpretation of porous carbon materials for high-performance supercapacitors.J Mater Inf2024;4:16

[31]	Szymanski NJ,Fei Y.An autonomous laboratory for the accelerated synthesis of novel materials.Nature2023;624:86-91 PMCID:PMC10700133

[32]	Moon J,Siek M.Active learning guides discovery of a champion four-metal perovskite oxide for oxygen evolution electrocatalysis.Nat Mater2024;23:108-15

[33]	Merchant A,Schoenholz SS,Cheon G.Scaling deep learning for materials discovery.Nature2023;624:80-5 PMCID:PMC10700131

[34]	Mao Y,Paul A.An AI-driven microstructure optimization framework for elastic properties of titanium beyond cubic crystal systems.npj Comput Mater2023;9:1067

[35]	Yang K,Wang Y.Machine-learning-assisted prediction of long-term performance degradation on solid oxide fuel cell cathodes induced by chromium poisoning.J Mater Chem A2022;10:23683-90

[36]	Wang N,Tang C.Machine-learning-accelerated development of efficient mixed protonic-electronic conducting oxides as the air electrodes for protonic ceramic cells.Adv Mater2022;34:e2203446

[37]	Yuan B,Tang C.Advances and challenges in high-performance cathodes for protonic solid oxide fuel cells and machine learning-guided perspectives.Nano Energy2024;122:109306

[38]	Hyodo J,Shiga M,Yamazaki Y.Accelerated discovery of proton-conducting perovskite oxide by capturing physicochemical fundamentals of hydration.ACS Energy Lett2021;6:2985-92

[39]	Luo Z,Zhou Y.Harnessing high-throughput computational methods to accelerate the discovery of optimal proton conductors for high-performance and durable protonic ceramic electrochemical Cells.Adv Mater2024;36:e2311159

[40]	Zhang W,Hu X.A synergistic three-phase, triple-conducting air electrode for reversible proton-conducting solid oxide cells.ACS Energy Lett2023;8:3999-4007 PMCID:PMC10580316

[41]	Wang N,Zheng F.Machine-learning assisted screening proton conducting Co/Fe based oxide for the air electrode of protonic solid oxide cell.Adv Funct Mater2024;34:2309855

[42]	Tang, C.; Yuan, B.; Zhang, X. Rationally designed air electrode boosting electrochemical performance of protonic ceramic cells. Adv. Energy. Mater. 2025, 2402654.

AI Summary AI Mindmap

PDF

56

Accesses

0

Citation

Detail

Sections

Recommended

/

〈

〉