| Electrochemically-mediated selective capture of heavy metal chromium and arsenic oxyanions from water X Su, A Kushima, C Halliday, J Zhou, J Li, TA Hatton Nature communications 9 (1), 4701, 2018 | 222 | 2018 |
| Sorbents for the Capture of CO2 and Other Acid Gases: A Review C Halliday, TA Hatton Industrial & Engineering Chemistry Research 60 (26), 9313-9346, 2021 | 65 | 2021 |
| Amine-Based Ionic Liquid for CO2 Capture and Electrochemical or Thermal Regeneration S Voskian, P Brown, C Halliday, K Rajczykowski, TA Hatton ACS sustainable chemistry & engineering 8 (22), 8356-8361, 2020 | 37 | 2020 |
| Molten ionic oxides for CO 2 capture at medium to high temperatures T Harada, C Halliday, A Jamal, TA Hatton Journal of Materials Chemistry A 7 (38), 21827-21834, 2019 | 28 | 2019 |
| Toward a Mechanistic Understanding and Optimization of Molten Alkali Metal Borates (AxB1–xO1.5–x) for High-Temperature CO2 Capture C Halliday, T Harada, TA Hatton Chemistry of Materials 32 (1), 348-359, 2019 | 27 | 2019 |
| The potential of molten metal oxide sorbents for carbon capture at high temperature: Conceptual design C Halliday, TA Hatton Applied Energy 280, 116016, 2020 | 19 | 2020 |
| Electrochemical selective recovery of heavy metal vanadium oxyanion from continuously flowing aqueous streams A Hemmatifar, N Ozbek, C Halliday, TA Hatton ChemSusChem 13 (15), 3865-3874, 2020 | 16 | 2020 |
| Net-negative emissions through molten sorbents and bioenergy with carbon capture and storage C Halliday, TA Hatton Industrial & Engineering Chemistry Research 59 (52), 22582-22596, 2020 | 15 | 2020 |
| Bench-Scale Demonstration of Molten Alkali Metal Borates for High-Temperature CO2 Capture C Halliday, T Harada, TA Hatton Industrial & Engineering Chemistry Research 59 (19), 8937-8945, 2020 | 15 | 2020 |
| Acid gas capture at high temperatures using molten alkali metal borates C Halliday, T Harada, TA Hatton Environmental Science & Technology 54 (10), 6319-6328, 2020 | 13 | 2020 |
| Understanding Material Compatibility in CO2 Capture Systems Using Molten Alkali Metal Borates C Halliday, N Ozbek, TA Hatton ACS Applied Materials & Interfaces 12 (46), 51468-51477, 2020 | 12 | 2020 |
| Electrochemical capture of Lewis acid gases S Voskian, TA Hatton, CG Halliday US Patent 11,219,858, 2022 | 7 | 2022 |
| Electrochemically-mediated selective capture of heavy metal chromium and arsenic oxyanions from water. Nat Commun 9: 4701 X Su, A Kushima, C Halliday, J Zhou, J Li, TA Hatton | 6 | 2018 |
| Electrochemically-mediated selective capture of heavy metal chromium and arsenic oxyanions from water, Nat Commun. 9 (2018) 4701 X Su, A Kushima, C Halliday, J Zhou, J Li, TA Hatton | 5 | |
| Treatment of acid gases using molten alkali metal borates and associated methods of separation TA Hatton, T Harada, CG Halliday US Patent 11,291,950, 2022 | 3 | 2022 |
| Carbon dioxide removal using sequestration materials that include salts in molten form, and related systems and methods TA Hatton, T Harada, A Jamal, CG Halliday US Patent 11,311,840, 2022 | 2 | 2022 |
| Treatment of acid gases using molten alkali metal borates, and associated methods of separation TA Hatton, T Harada, CG Halliday US Patent 11,602,716, 2023 | 1 | 2023 |
| Processes for regenerating sorbents, and associated systems TA Hatton, T Harada, CG Halliday US Patent 11,577,223, 2023 | 1 | 2023 |
| Target species recovery and related systems and methods TA Hatton, X Su, CG Halliday US Patent App. 17/272,007, 2022 | 1 | 2022 |
| Treatment of acid gases using molten alkali metal borates, and associated methods of separation TA Hatton, T Harada, CG Halliday US Patent App. 18/167,023, 2024 | | 2024 |
T. Alan HattonMassachusetts Institute of TechnologyVerified email at mit.edu
