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Investigation of the consequence of high-pressure CO2 pipeline failure through experimental and numerical studies Liu X, Godbole A, Lu C, Michal G, Linton V Applied Energy, 250, 32, 2019 |
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A sorbent-focused techno-economic analysis of direct air capture Azarabadi H, Lackner KS Applied Energy, 250, 959, 2019 |
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Size-tailored Ru nanoparticles deposited over gamma-Al2O3 for the CO2 methanation reaction Navarro-Jaen S, Navarro JC, Bobadilla LF, Centeno MA, Laguna OH, Odriozola JA Applied Surface Science, 483, 750, 2019 |
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Thermosynechococcus as a thermophilic photosynthetic microbial cell factory for CO2 utilisation Liang YM, Tang J, Luo YF, Kaczmarek MB, Li XK, Daroch M Bioresource Technology, 278, 255, 2019 |
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In-situ biogas upgrading by a stepwise addition of ash additives: Methanogen adaption and CO2 sequestration Yin CK, Shen YW, Yu YM, Yuan HP, Lou ZY, Zhu NW Bioresource Technology, 282, 1, 2019 |
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Direct capture and conversion of CO2 from air by growing a cyanobacterial consortium at pH up to 11.2 Ataeian M, Liu YH, Canon-Rubio KA, Nightingale M, Strous M, Vadlamani A Biotechnology and Bioengineering, 116(7), 1604, 2019 |
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Fabrication of porous carbons from mesitylene for highly efficient CO2 capture: A rational choice improving the carbon loop Qi SC, Liu Y, Peng AZ, Xue DM, Liu X, Liu XQ, Sun LB Chemical Engineering Journal, 361, 945, 2019 |
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Carbon nanotube silica composite hollow fibers impregnated with polyethylenimine for CO2 capture Keller L, Ohs B, Abduly L, Wessling M Chemical Engineering Journal, 359, 476, 2019 |
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Li-LSX-zeolite evaluation for post-combustion CO2 capture Kodasma R, Fermoso J, Sanna A Chemical Engineering Journal, 358, 1351, 2019 |
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Economic and environmental benefit analysis of a renewable energy supply system integrated with carbon capture and utilization framework Kim M, Kim K, Kim TH, Kim J Chemical Engineering Research & Design, 147, 200, 2019 |