OpenAlex is a bibliographic catalogue of scientific papers, authors and institutions accessible in open access mode, named after the Library of Alexandria. It's citation coverage is excellent and I hope you will find utility in this listing of citing articles!
If you click the article title, you'll navigate to the article, as listed in CrossRef. If you click the Open Access links, you'll navigate to the "best Open Access location". Clicking the citation count will open this listing for that article. Lastly at the bottom of the page, you'll find basic pagination options.
Requested Article:
Food–energy–water implications of negative emissions technologies in a +1.5 °C future
Jay Fuhrman, Haewon McJeon, Pralit Patel, et al.
Nature Climate Change (2020) Vol. 10, Iss. 10, pp. 920-927
Open Access | Times Cited: 172
Jay Fuhrman, Haewon McJeon, Pralit Patel, et al.
Nature Climate Change (2020) Vol. 10, Iss. 10, pp. 920-927
Open Access | Times Cited: 172
Showing 1-25 of 172 citing articles:
Strategies to achieve a carbon neutral society: a review
Lin Chen, Goodluck Msigwa, Mingyu Yang, et al.
Environmental Chemistry Letters (2022) Vol. 20, Iss. 4, pp. 2277-2310
Open Access | Times Cited: 796
Lin Chen, Goodluck Msigwa, Mingyu Yang, et al.
Environmental Chemistry Letters (2022) Vol. 20, Iss. 4, pp. 2277-2310
Open Access | Times Cited: 796
Policy and Management of Carbon Peaking and Carbon Neutrality: A Literature Review
Yi‐Ming Wei, Kaiyuan Chen, Jia-Ning Kang, et al.
Engineering (2022) Vol. 14, pp. 52-63
Open Access | Times Cited: 523
Yi‐Ming Wei, Kaiyuan Chen, Jia-Ning Kang, et al.
Engineering (2022) Vol. 14, pp. 52-63
Open Access | Times Cited: 523
Life-cycle assessment of an industrial direct air capture process based on temperature–vacuum swing adsorption
Sarah Deutz, André Bardow
Nature Energy (2021) Vol. 6, Iss. 2, pp. 203-213
Closed Access | Times Cited: 408
Sarah Deutz, André Bardow
Nature Energy (2021) Vol. 6, Iss. 2, pp. 203-213
Closed Access | Times Cited: 408
Direct air capture: process technology, techno-economic and socio-political challenges
María Erans, Eloy S. Sanz-Pérez, Dawid P. Hanak, et al.
Energy & Environmental Science (2022) Vol. 15, Iss. 4, pp. 1360-1405
Open Access | Times Cited: 378
María Erans, Eloy S. Sanz-Pérez, Dawid P. Hanak, et al.
Energy & Environmental Science (2022) Vol. 15, Iss. 4, pp. 1360-1405
Open Access | Times Cited: 378
1.5 °C degrowth scenarios suggest the need for new mitigation pathways
Lorenz Keyßer, Manfred Lenzen
Nature Communications (2021) Vol. 12, Iss. 1
Open Access | Times Cited: 242
Lorenz Keyßer, Manfred Lenzen
Nature Communications (2021) Vol. 12, Iss. 1
Open Access | Times Cited: 242
Recent advances in direct air capture by adsorption
Xuancan Zhu, Wenwen Xie, Junye Wu, et al.
Chemical Society Reviews (2022) Vol. 51, Iss. 15, pp. 6574-6651
Open Access | Times Cited: 216
Xuancan Zhu, Wenwen Xie, Junye Wu, et al.
Chemical Society Reviews (2022) Vol. 51, Iss. 15, pp. 6574-6651
Open Access | Times Cited: 216
Current status and pillars of direct air capture technologies
Mihrimah Ozkan, Saswat Priyadarshi Nayak, Anthony D. Ruiz, et al.
iScience (2022) Vol. 25, Iss. 4, pp. 103990-103990
Open Access | Times Cited: 193
Mihrimah Ozkan, Saswat Priyadarshi Nayak, Anthony D. Ruiz, et al.
iScience (2022) Vol. 25, Iss. 4, pp. 103990-103990
Open Access | Times Cited: 193
Emergency deployment of direct air capture as a response to the climate crisis
Ryan Hanna, Ahmed Abdulla, Yangyang Xu, et al.
Nature Communications (2021) Vol. 12, Iss. 1
Open Access | Times Cited: 180
Ryan Hanna, Ahmed Abdulla, Yangyang Xu, et al.
Nature Communications (2021) Vol. 12, Iss. 1
Open Access | Times Cited: 180
Life Cycle Assessment of Direct Air Carbon Capture and Storage with Low-Carbon Energy Sources
Tom Terlouw, Karin Treyer, Christian Bauer, et al.
Environmental Science & Technology (2021) Vol. 55, Iss. 16, pp. 11397-11411
Open Access | Times Cited: 177
Tom Terlouw, Karin Treyer, Christian Bauer, et al.
Environmental Science & Technology (2021) Vol. 55, Iss. 16, pp. 11397-11411
Open Access | Times Cited: 177
Assessment of carbon dioxide removal potentialviaBECCS in a carbon-neutral Europe
Lorenzo Rosa, Daniel L. Sanchez, Marco Mazzotti
Energy & Environmental Science (2021) Vol. 14, Iss. 5, pp. 3086-3097
Open Access | Times Cited: 156
Lorenzo Rosa, Daniel L. Sanchez, Marco Mazzotti
Energy & Environmental Science (2021) Vol. 14, Iss. 5, pp. 3086-3097
Open Access | Times Cited: 156
Understanding environmental trade-offs and resource demand of direct air capture technologies through comparative life-cycle assessment
Kavya Madhu, Stefan Pauliuk, Sumukha Dhathri, et al.
Nature Energy (2021) Vol. 6, Iss. 11, pp. 1035-1044
Closed Access | Times Cited: 151
Kavya Madhu, Stefan Pauliuk, Sumukha Dhathri, et al.
Nature Energy (2021) Vol. 6, Iss. 11, pp. 1035-1044
Closed Access | Times Cited: 151
Deep mitigation of CO2 and non-CO2 greenhouse gases toward 1.5 °C and 2 °C futures
Yang Ou, Christopher Roney, Jameel Alsalam, et al.
Nature Communications (2021) Vol. 12, Iss. 1
Open Access | Times Cited: 133
Yang Ou, Christopher Roney, Jameel Alsalam, et al.
Nature Communications (2021) Vol. 12, Iss. 1
Open Access | Times Cited: 133
Potential for hydrogen production from sustainable biomass with carbon capture and storage
Lorenzo Rosa, Marco Mazzotti
Renewable and Sustainable Energy Reviews (2022) Vol. 157, pp. 112123-112123
Open Access | Times Cited: 133
Lorenzo Rosa, Marco Mazzotti
Renewable and Sustainable Energy Reviews (2022) Vol. 157, pp. 112123-112123
Open Access | Times Cited: 133
Assessing the sequestration time scales of some ocean-based carbon dioxide reduction strategies
David A. Siegel, Tim DeVries, Scott C. Doney, et al.
Environmental Research Letters (2021) Vol. 16, Iss. 10, pp. 104003-104003
Open Access | Times Cited: 120
David A. Siegel, Tim DeVries, Scott C. Doney, et al.
Environmental Research Letters (2021) Vol. 16, Iss. 10, pp. 104003-104003
Open Access | Times Cited: 120
Impact of carbon dioxide removal technologies on deep decarbonization of the electric power sector
John Bistline, Geoffrey J. Blanford
Nature Communications (2021) Vol. 12, Iss. 1
Open Access | Times Cited: 120
John Bistline, Geoffrey J. Blanford
Nature Communications (2021) Vol. 12, Iss. 1
Open Access | Times Cited: 120
Diverse carbon dioxide removal approaches could reduce impacts on the energy–water–land system
Jay Fuhrman, Candelaria Bergero, Maridee Weber, et al.
Nature Climate Change (2023) Vol. 13, Iss. 4, pp. 341-350
Closed Access | Times Cited: 119
Jay Fuhrman, Candelaria Bergero, Maridee Weber, et al.
Nature Climate Change (2023) Vol. 13, Iss. 4, pp. 341-350
Closed Access | Times Cited: 119
Recent Advances and Future Perspectives in Carbon Capture, Transportation, Utilization, and Storage (CCTUS) Technologies: A Comprehensive Review
Kaiyin Zhao, Cunqi Jia, Zihao Li, et al.
Fuel (2023) Vol. 351, pp. 128913-128913
Closed Access | Times Cited: 110
Kaiyin Zhao, Cunqi Jia, Zihao Li, et al.
Fuel (2023) Vol. 351, pp. 128913-128913
Closed Access | Times Cited: 110
Incorporating health co-benefits into technology pathways to achieve China's 2060 carbon neutrality goal: a modelling study
Shihui Zhang, Kangxin An, Jin Li, et al.
The Lancet Planetary Health (2021) Vol. 5, Iss. 11, pp. e808-e817
Open Access | Times Cited: 108
Shihui Zhang, Kangxin An, Jin Li, et al.
The Lancet Planetary Health (2021) Vol. 5, Iss. 11, pp. e808-e817
Open Access | Times Cited: 108
Environmental trade-offs of direct air capture technologies in climate change mitigation toward 2100
Yang Qiu, Patrick Lamers, Vassilis Daioglou, et al.
Nature Communications (2022) Vol. 13, Iss. 1
Open Access | Times Cited: 84
Yang Qiu, Patrick Lamers, Vassilis Daioglou, et al.
Nature Communications (2022) Vol. 13, Iss. 1
Open Access | Times Cited: 84
Ratcheting of climate pledges needed to limit peak global warming
Gokul Iyer, Yang Ou, Jae Edmonds, et al.
Nature Climate Change (2022) Vol. 12, Iss. 12, pp. 1129-1135
Open Access | Times Cited: 83
Gokul Iyer, Yang Ou, Jae Edmonds, et al.
Nature Climate Change (2022) Vol. 12, Iss. 12, pp. 1129-1135
Open Access | Times Cited: 83
The cost of direct air capture and storage can be reduced via strategic deployment but is unlikely to fall below stated cost targets
John Young, Noah McQueen, Charithea Charalambous, et al.
One Earth (2023) Vol. 6, Iss. 7, pp. 899-917
Open Access | Times Cited: 79
John Young, Noah McQueen, Charithea Charalambous, et al.
One Earth (2023) Vol. 6, Iss. 7, pp. 899-917
Open Access | Times Cited: 79
Co-firing plants with retrofitted carbon capture and storage for power-sector emissions mitigation
Jing‐Li Fan, Jingying Fu, Xian Zhang, et al.
Nature Climate Change (2023) Vol. 13, Iss. 8, pp. 807-815
Closed Access | Times Cited: 64
Jing‐Li Fan, Jingying Fu, Xian Zhang, et al.
Nature Climate Change (2023) Vol. 13, Iss. 8, pp. 807-815
Closed Access | Times Cited: 64
Support Pore Structure and Composition Strongly Influence the Direct Air Capture of CO2 on Supported Amines
Guanhe Rim, Pranjali Priyadarshini, Mingyu Song, et al.
Journal of the American Chemical Society (2023) Vol. 145, Iss. 13, pp. 7190-7204
Open Access | Times Cited: 60
Guanhe Rim, Pranjali Priyadarshini, Mingyu Song, et al.
Journal of the American Chemical Society (2023) Vol. 145, Iss. 13, pp. 7190-7204
Open Access | Times Cited: 60
The synergistic role of carbon dioxide removal and emission reductions in achieving the Paris Agreement goal
Humphrey Adun, Jeffrey Dankwa Ampah, Olusola Bamisile, et al.
Sustainable Production and Consumption (2024) Vol. 45, pp. 386-407
Closed Access | Times Cited: 33
Humphrey Adun, Jeffrey Dankwa Ampah, Olusola Bamisile, et al.
Sustainable Production and Consumption (2024) Vol. 45, pp. 386-407
Closed Access | Times Cited: 33
The carbon dioxide removal gap
William F. Lamb, Thomas Gasser, Rosa María Román-Cuesta, et al.
Nature Climate Change (2024) Vol. 14, Iss. 6, pp. 644-651
Open Access | Times Cited: 29
William F. Lamb, Thomas Gasser, Rosa María Román-Cuesta, et al.
Nature Climate Change (2024) Vol. 14, Iss. 6, pp. 644-651
Open Access | Times Cited: 29
