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##  360 results 

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### Working Paper

Michael J. Aziz. “[AN INTERPRETATION OF CLASSICAL TRANSITION STATE THEORY FOR KINETICS IN MATERIALS SCIENCE](/publication/interpretation-classical-transition-state-theory-kinetics-materials-science)”. ChemRxiv



 

 

Michael J. Aziz. “[AN INTERPRETATION OF CLASSICAL TRANSITION STATE THEORY FOR KINETICS IN MATERIALS SCIENCE](/publication/interpretation-classical-transition-state-theory-kinetics-materials-science)”. ChemRxiv



 

 

 

- [ descriptionPublisher's Version](https://doi.org/10.26434/chemrxiv-2025-9p52m)
- [ picture\_as\_pdfmja355.pdf](/sites/g/files/omnuum6451/files/2025-09/mja355.pdf)
 
- [ descriptionPublisher's Version](https://doi.org/10.26434/chemrxiv-2025-9p52m)
- [ picture\_as\_pdfmja355.pdf](/sites/g/files/omnuum6451/files/2025-09/mja355.pdf)
 
 

 



### 2026

Haojin Li, Benli Jiang, Faith Hines, Wei-Jing Chen, Anubhav Wadehra, Walter Mendoza, Aviva Harman, Christina Wan, Derek Qin, Peco Myint, Jiaqi Tang, Joy C. Perkinson, Michael J. Aziz, and Karl F. Ludwig Jr. 2026. “[The Independence of Nanopattern Formation and Stress Evolution During Low-Energy Ar+ Bombardment of Si](/publication/independence-nanopattern-formation-and-stress-evolution-during-low-energy-ar)”. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions With Materials and Atoms



 

 

Haojin Li, Benli Jiang, Faith Hines, Wei-Jing Chen, Anubhav Wadehra, Walter Mendoza, Aviva Harman, Christina Wan, Derek Qin, Peco Myint, Jiaqi Tang, Joy C. Perkinson, Michael J. Aziz, and Karl F. Ludwig Jr. 2026. “[The Independence of Nanopattern Formation and Stress Evolution During Low-Energy Ar+ Bombardment of Si](/publication/independence-nanopattern-formation-and-stress-evolution-during-low-energy-ar)”. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions With Materials and Atoms



 

 

 

- [ descriptionPublisher's Version](https://doi.org/10.1016/j.nimb.2025.165958)
- [ picture\_as\_pdfmja357.pdf](/sites/g/files/omnuum6451/files/2025-12/mja357.pdf)
 
- [ descriptionPublisher's Version](https://doi.org/10.1016/j.nimb.2025.165958)
- [ picture\_as\_pdfmja357.pdf](/sites/g/files/omnuum6451/files/2025-12/mja357.pdf)
 
 

 



### 2025

Jordan D. Sosa and Michael J. Aziz. 2025. “[Evaluation of Highly Stable Redox‑active Materials for Aqueous Organic Redox Flow Batteries Using Static Cells](/publication/evaluation-highly-stable-redox-active-materials-aqueous-organic-redox-flow-batteries-0)”. MRS Energy &amp; Sustainability, 12



 

 

Jordan D. Sosa and Michael J. Aziz. 2025. “[Evaluation of Highly Stable Redox‑active Materials for Aqueous Organic Redox Flow Batteries Using Static Cells](/publication/evaluation-highly-stable-redox-active-materials-aqueous-organic-redox-flow-batteries-0)”. MRS Energy &amp; Sustainability, 12



 

 

 

- [ descriptionPublisher's Version](https://doi.org/10.1557/s43581-025-00140-7)
- [ picture\_as\_pdfMJA351.pdf](/sites/g/files/omnuum6451/files/2025-10/MJA351.pdf)
 
- [ descriptionPublisher's Version](https://doi.org/10.1557/s43581-025-00140-7)
- [ picture\_as\_pdfMJA351.pdf](/sites/g/files/omnuum6451/files/2025-10/MJA351.pdf)
 
 

Dylan M. Barber, Sofía Edgar, Michael S. Emanuel, Michael D. Nelwood, Bok Yeop Ahn, Benito Román-Manso, Thomas Cochard, Justin Platero, Kiana Amini, Chris H. Rycroft, Shmuel Rubinstein, Michael J. Aziz, and Jennifer A. Lewis. 2025. “[Print-and-Plate Architected Electrodes for Electrochemical Transformations Under Flow](/publication/print-and-plate-architected-electrodes-electrochemical-transformations-under-flow)”. Advanced Functional Materials



 

 

Dylan M. Barber, Sofía Edgar, Michael S. Emanuel, Michael D. Nelwood, Bok Yeop Ahn, Benito Román-Manso, Thomas Cochard, Justin Platero, Kiana Amini, Chris H. Rycroft, Shmuel Rubinstein, Michael J. Aziz, and Jennifer A. Lewis. 2025. “[Print-and-Plate Architected Electrodes for Electrochemical Transformations Under Flow](/publication/print-and-plate-architected-electrodes-electrochemical-transformations-under-flow)”. Advanced Functional Materials



 

 

 

- [ descriptionPublisher's Version](https://doi.org/10.1002/adfm.202419748)
- [ picture\_as\_pdfmja348.pdf](/sites/g/files/omnuum6451/files/2025-03/mja348.pdf)
 
- [ descriptionPublisher's Version](https://doi.org/10.1002/adfm.202419748)
- [ picture\_as\_pdfmja348.pdf](/sites/g/files/omnuum6451/files/2025-03/mja348.pdf)
 
 

Dawei Xi, Zheng Yang, Michael Emanuel, Panlin Zhao, and Michael Aziz. 2025. “[Electrochemical Acid–base Generators for Decoupled Carbon Management](/publication/electrochemical-acid-base-generators-decoupled-carbon-management-0)”. Energy &amp; Environmental Science



 

 

Dawei Xi, Zheng Yang, Michael Emanuel, Panlin Zhao, and Michael Aziz. 2025. “[Electrochemical Acid–base Generators for Decoupled Carbon Management](/publication/electrochemical-acid-base-generators-decoupled-carbon-management-0)”. Energy &amp; Environmental Science



 

 

 

- [ descriptionPublisher's Version](https://doi.org/10.1039/d4ee05109b)
- [ picture\_as\_pdfmja349.pdf](/sites/g/files/omnuum6451/files/2025-04/mja349.pdf)
 
- [ descriptionPublisher's Version](https://doi.org/10.1039/d4ee05109b)
- [ picture\_as\_pdfmja349.pdf](/sites/g/files/omnuum6451/files/2025-04/mja349.pdf)
 
 

Abdulrahman M. Alfaraidi, Nina Ni, Jordan Sosa, Sara Lia, Mayar Alhelaili, Nathan Faialaga, Nawal M. Alghoraibi, Husain H. Al Naji, Ammar H. Alahmed, Aqil Jamal, Michael J. Aziz, and Richard Liu. 2025. “[Ion Pairing Enhances Hydroquinone Stability Toward Oxygen in Aqueous Electrochemical Carbon Dioxide Capture](/publication/ion-pairing-enhances-hydroquinone-stability-toward-oxygen-aqueous-electrochemical)”. Nature Communications



 

 

Abdulrahman M. Alfaraidi, Nina Ni, Jordan Sosa, Sara Lia, Mayar Alhelaili, Nathan Faialaga, Nawal M. Alghoraibi, Husain H. Al Naji, Ammar H. Alahmed, Aqil Jamal, Michael J. Aziz, and Richard Liu. 2025. “[Ion Pairing Enhances Hydroquinone Stability Toward Oxygen in Aqueous Electrochemical Carbon Dioxide Capture](/publication/ion-pairing-enhances-hydroquinone-stability-toward-oxygen-aqueous-electrochemical)”. Nature Communications



 

 

 

- [ descriptionPublisher's Version](https://doi.org/10.1038/s41467-025-65258-1)
- [ picture\_as\_pdfmja354.pdf](/sites/g/files/omnuum6451/files/2025-12/mja354.pdf)
 
- [ descriptionPublisher's Version](https://doi.org/10.1038/s41467-025-65258-1)
- [ picture\_as\_pdfmja354.pdf](/sites/g/files/omnuum6451/files/2025-12/mja354.pdf)
 
 

Jordan D. Sosa, Arunraj Balaji-Wright, Jintao Wu, Luana Cristina Italiano Faria, Abdulrahman M. Alfaraidi, Kyumin Lee, Matthew E. Suss, Ali Mani, Filipe Camargo Dalmatti Alves Lima, Frank Nelson Crespilho, and Michael J. Aziz. 2025. “[Confinement of Organic Molecules in Microporous Electrodes for Enhanced Energy Storage](/publication/confinement-organic-molecules-microporous-electrodes-enhanced-energy-storage)”. ACS Applied Energy Materials



 

 

Jordan D. Sosa, Arunraj Balaji-Wright, Jintao Wu, Luana Cristina Italiano Faria, Abdulrahman M. Alfaraidi, Kyumin Lee, Matthew E. Suss, Ali Mani, Filipe Camargo Dalmatti Alves Lima, Frank Nelson Crespilho, and Michael J. Aziz. 2025. “[Confinement of Organic Molecules in Microporous Electrodes for Enhanced Energy Storage](/publication/confinement-organic-molecules-microporous-electrodes-enhanced-energy-storage)”. ACS Applied Energy Materials



 

 

 

- [ descriptionPublisher's Version](https://doi.org/10.1021/acsaem.5c01973)
- [ picture\_as\_pdfmja356.pdf](/sites/g/files/omnuum6451/files/2025-12/mja356.pdf)
 
- [ descriptionPublisher's Version](https://doi.org/10.1021/acsaem.5c01973)
- [ picture\_as\_pdfmja356.pdf](/sites/g/files/omnuum6451/files/2025-12/mja356.pdf)
 
 

Xinyu Jin, Shijian Jin, Lu Li, Roy G. Gordon, Pan Wang, Michael J. Aziz, and Yunlong Ji. 2025. “[Direct Air Capture of CO2 in an Electrochemical Hybrid Flow Cell With a Spatially Isolated Phenazine Electrode](/publication/direct-air-capture-co2-electrochemical-hybrid-flow-cell-spatially-isolated-phenazine-0)”. Nature Energy



 

 

Xinyu Jin, Shijian Jin, Lu Li, Roy G. Gordon, Pan Wang, Michael J. Aziz, and Yunlong Ji. 2025. “[Direct Air Capture of CO2 in an Electrochemical Hybrid Flow Cell With a Spatially Isolated Phenazine Electrode](/publication/direct-air-capture-co2-electrochemical-hybrid-flow-cell-spatially-isolated-phenazine-0)”. Nature Energy



 

 

 

- [ descriptionPublisher's Version](https://doi.org/10.1038/s41560-025-01836-3)
- [ picture\_as\_pdfmja350.pdf](/sites/g/files/omnuum6451/files/2025-12/mja350.pdf)
 
- [ descriptionPublisher's Version](https://doi.org/10.1038/s41560-025-01836-3)
- [ picture\_as\_pdfmja350.pdf](/sites/g/files/omnuum6451/files/2025-12/mja350.pdf)
 
 

Dawei Xi, Yuheng Wu, Yuli Li, Zifei Yan, Richard Liu, and Michael J. Aziz. 2025. “[Electrifying Industrial Hydrogen Peroxide Production via Soft Interfacial Molecular Mediation](/publication/electrifying-industrial-hydrogen-peroxide-production-soft-interfacial-molecular)”. Nature Chemistry



 

 

Dawei Xi, Yuheng Wu, Yuli Li, Zifei Yan, Richard Liu, and Michael J. Aziz. 2025. “[Electrifying Industrial Hydrogen Peroxide Production via Soft Interfacial Molecular Mediation](/publication/electrifying-industrial-hydrogen-peroxide-production-soft-interfacial-molecular)”. Nature Chemistry



 

 

 

- [ descriptionPublisher's Version](https://doi.org/10.1038/s41557-025-01940-7)
- [ picture\_as\_pdfmja353.pdf](/sites/g/files/omnuum6451/files/2025-12/mja353.pdf)
 
- [ descriptionPublisher's Version](https://doi.org/10.1038/s41557-025-01940-7)
- [ picture\_as\_pdfmja353.pdf](/sites/g/files/omnuum6451/files/2025-12/mja353.pdf)
 
 

Jordan D. Sosa and Michael J. Aziz. 2025. “[Evaluation of Highly Stable Redox-Active Materials for Aqueous Organic Redox Flow Batteries Using Static Cells](/publication/evaluation-highly-stable-redox-active-materials-aqueous-organic-redox-flow-batteries-1)”. MRS Energy &amp; Sustainability



 

 

Jordan D. Sosa and Michael J. Aziz. 2025. “[Evaluation of Highly Stable Redox-Active Materials for Aqueous Organic Redox Flow Batteries Using Static Cells](/publication/evaluation-highly-stable-redox-active-materials-aqueous-organic-redox-flow-batteries-1)”. MRS Energy &amp; Sustainability



 

 

 

- [ descriptionPublisher's Version](https://doi.org/10.1557/s43581-025-00140-7)
- [ picture\_as\_pdfmja351.pdf](/sites/g/files/omnuum6451/files/2025-12/mja351.pdf)
 
- [ descriptionPublisher's Version](https://doi.org/10.1557/s43581-025-00140-7)
- [ picture\_as\_pdfmja351.pdf](/sites/g/files/omnuum6451/files/2025-12/mja351.pdf)
 
 

Kyumin Lee, Kiana Amini, and Michael J. Aziz. 2025. “[Reduced Flow Battery Capacity Fade from Mixed Redox-Active Organics Beyond the Rule of Mixtures](/publication/reduced-flow-battery-capacity-fade-mixed-redox-active-organics-beyond-rule-mixtures)”. ACS Energy Letters



 

 

Kyumin Lee, Kiana Amini, and Michael J. Aziz. 2025. “[Reduced Flow Battery Capacity Fade from Mixed Redox-Active Organics Beyond the Rule of Mixtures](/publication/reduced-flow-battery-capacity-fade-mixed-redox-active-organics-beyond-rule-mixtures)”. ACS Energy Letters



 

 

 

- [ descriptionPublisher's Version](https://doi.org/10.1021/acsenergylett.5c01503)
- [ picture\_as\_pdfmja352.pdf](/sites/g/files/omnuum6451/files/2025-12/mja352.pdf)
 
- [ descriptionPublisher's Version](https://doi.org/10.1021/acsenergylett.5c01503)
- [ picture\_as\_pdfmja352.pdf](/sites/g/files/omnuum6451/files/2025-12/mja352.pdf)
 
 

 



### 2024

Yan Jing, Kiana Amini, Dawei Xi, Shijian Jin, Abdulrahman Alfaraidi, Emily Kerr, Roy Gordon, and Michael Aziz. 2024. “[Electrochemically Induced CO2 Capture Enabled by Aqueous Quinone Flow Chemistry](/publications/electrochemically-induced-co2-capture-enabled-aqueous-quinone-flow-chemistry)”. ACS Energy Letters, 9, Pp. 3526–3535



 

 

Yan Jing, Kiana Amini, Dawei Xi, Shijian Jin, Abdulrahman Alfaraidi, Emily Kerr, Roy Gordon, and Michael Aziz. 2024. “[Electrochemically Induced CO2 Capture Enabled by Aqueous Quinone Flow Chemistry](/publications/electrochemically-induced-co2-capture-enabled-aqueous-quinone-flow-chemistry)”. ACS Energy Letters, 9, Pp. 3526–3535



 

 

 

- [ descriptionPublisher's Version](https://pubs.acs.org/doi/10.1021/acsenergylett.4c01235)
- [ picture\_as\_pdfmja336.pdf](/sites/g/files/omnuum6451/files/mja336.pdf)
 
- [ descriptionPublisher's Version](https://pubs.acs.org/doi/10.1021/acsenergylett.4c01235)
- [ picture\_as\_pdfmja336.pdf](/sites/g/files/omnuum6451/files/mja336.pdf)
 
 

 



 

 

 

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