| 1 |
Techno-economic and environmental analyses of a novel, sustainable process for production of liquid fuels using helium heat transfer
Hoseinzade L, Adams TA
Applied Energy, 236, 850, 2019 |
| 2 |
Performance and potential appraisal of various microalgae as direct combustion fuel
Choi HI, Lee JS, Choi JW, Shin YS, Sung YJ, Hong ME, Kwak HS, Kim CY, Sim SJ
Bioresource Technology, 273, 341, 2019 |
| 3 |
Combined heat and power generation with lime production for direct air capture
Hanak DP, Manovic V
Energy Conversion and Management, 160, 455, 2018 |
| 4 |
Bio-Energy with CCS (BECCS) performance evaluation: Efficiency enhancement and emissions reduction
Bui M, Fajardy M, Mac Dowell N
Applied Energy, 195, 289, 2017 |
| 5 |
Removal of non-CO2 greenhouse gases by large-scale atmospheric solar photocatalysis
de Richter R, Ming TZ, Davies P, Liu W, Caillol S
Progress in Energy and Combustion Science, 60, 68, 2017 |
| 6 |
BECCS potential in Brazil: Achieving negative emissions in ethanol and electricity production based on sugar cane bagasse and other residues
Moreira JR, Romeiro V, Fuss S, Kraxner F, Pacca SA
Applied Energy, 179, 55, 2016 |
| 7 |
Operational feasibility of biomass combustion with in situ CO2 capture by CaO during 360 h in a 300 kW(th) calcium looping facility
Diego ME, Alonso M
Fuel, 181, 325, 2016 |
| 8 |
Thermodynamics, economics and systems thinking: What role for air capture of CO2?
Pritchard C, Yang A, Holmes P, Wilkinson M
Process Safety and Environmental Protection, 94, 188, 2015 |
| 9 |
Negative carbon via Ocean Afforestation
N'Yeurt AD, Chynoweth DP, Capron ME, Stewart JR, Hasan MA
Process Safety and Environmental Protection, 90(6), 467, 2012 |
| 10 |
A comparative global assessment of potential negative emissions technologies
McLaren D
Process Safety and Environmental Protection, 90(6), 489, 2012 |
