Publications
50 latest publications
[1]
M. J. Greencorn et al.,
"Mild-temperature gasification of biomass as a carbon-neutral CO2 utilisation process,"
Journal of CO2 Utilization, vol. 99, 2025.
[2]
[3]
P. H. Cabral de Souza et al.,
"Sustainable pathway towards red mud valorization through biomass thermochemical conversion and metals recovery,"
Bioresource Technology, vol. 434, 2025.
[4]
B. Á. Björnsson,
"Techno-economic analysis of biomass gasification and simultaneous metal recovery from redmud,"
, 2025.
[5]
[6]
K. Marnate,
"The lack of systems thinking and interdisciplinarity is killing the hydrogen economy,"
Frontiers in Energy Research, vol. 13, 2025.
[7]
K. Marnate and S. Grönkvist,
"Unlocking Sweden's hydrogen export potential : A Techno-Economic analysis of compressed hydrogen and chemical carriers,"
Sustainable Energy Technologies and Assessments, vol. 80, 2025.
[8]
A. Olsson, A. Lefvert and S. Grönkvist,
"An alternative pathway to negative emissions - revitalising the wood-based panel production in Sweden,"
Environmental Development, vol. 50, 2024.
[9]
A. Olsson, M. Fridahl and S. Grönkvist,
"Expectations on biochar as a climate solution in Sweden: Carbon dioxide removal with environmental co-benefits,"
Renewable and Sustainable Energy Transition, vol. 5, 2024.
[10]
[11]
K. Marnate and S. Grönkvist,
"Looking beyond compressed hydrogen storage for Sweden: Opportunities and barriers for chemical hydrides,"
International journal of hydrogen energy, vol. 77, pp. 677-694, 2024.
[12]
A. Lefvert and S. Grönkvist,
"Lost in the scenarios of negative emissions : The role of bioenergy with carbon capture and storage (BECCS),"
Energy Policy, vol. 184, 2024.
[13]
A. Lefvert,
"On the potential deployment of bioenergy with carbon capture and storage (BECCS) in Sweden,"
Doctoral thesis Stockholm, Sweden : KTH Royal Institute of Technology, TRITA-CBH-FOU, 2024:58, 2024.
[14]
[15]
M. Fridahl et al.,
"Potential and goal conflicts in reverse auction design for bioenergy with carbon capture and storage (BECCS),"
Environmental Sciences Europe, vol. 36, no. 1, 2024.
[16]
D. Katla-Milewska, S. M. Nazir and A. Skorek-Osikowska,
"Synthetic natural gas (SNG) production with higher carbon recovery from biomass: Techno-economic assessment,"
Energy Conversion and Management, vol. 300, 2024.
[17]
A. Olsson,
"Assessing Carbon Dioxide Removal methods amid uncertainty : soil carbon sequestration, biochar and harvested wood products as methods for climate change mitigation,"
Doctoral thesis Stockholm : KTH Royal Institute of Technology, TRITA-CBH-FOU, 2023:4, 2023.
[18]
K. Möllersten and L. Zetterberg,
"Bringing BECCS credits to voluntary carbon markets : A policy brief by Sustainable Finance Lab (Sweden),"
, TRITA-ABE-RPT, 2316, 2023.
[19]
[20]
F. Johnsson, L. Zetterberg and K. Möllersten,
"Mot nettonollutsläpp : hur kan koldioxidavskiljningbidra?,"
Stockholm, SNS Analys, 98, 2023.
[21]
M. Fridahl et al.,
"Novel carbon dioxide removals techniques must be integrated into the European Union’s climate policies,"
Communications Earth & Environment, vol. 4, no. 1, 2023.
[22]
N. Salvador Palacios,
"Process and techno-economic analysis of a compact CO2 capture technology,"
, 2023.
[23]
D. S. S. S. Sirigina, A. Goel and S. M. Nazir,
"Process concepts and analysis for co-removing methane and carbon dioxide from the atmosphere,"
Scientific Reports, vol. 13, no. 1, 2023.
[24]
A. Lefvert and S. Grönkvist,
"Smarter ways to capture carbon dioxide-exploring alternatives for small to medium-scale carbon capture in Kraft pulp mills,"
International Journal of Greenhouse Gas Control, vol. 127, 2023.
[25]
F. Johnsson, L. Zetterberg and K. Möllersten,
"Towards net-zero emissions – how can carbon dioxide capture and storage contribute?,"
Stockholm : SNS förlag, 2023.
[26]
Y. Shen et al.,
"Waste heat recovery optimization in ammonia-based gas turbine applications,"
Energy, vol. 280, 2023.
[27]
Z. Rong et al.,
"Experimental and theoretical investigation of an innovative composite nanofluid for solar energy photothermal conversion and storage,"
Journal of Energy Storage, vol. 52, pp. 104800, 2022.
[28]
A. Eltigani et al.,
"Exploring lessons from five years of biochar-producing cookstoves in the Kagera region, Tanzania,"
Energy for Sustainable Development, vol. 71, pp. 141-150, 2022.
[29]
A. Ugwu et al.,
"Gas switching technology : Economic attractiveness for chemical looping applications and scale up experience to 50 kW(th),"
International Journal of Greenhouse Gas Control, vol. 114, 2022.
[30]
N. Xu et al.,
"Global optimization energy management for multi-energy source vehicles based on "Information layer - Physical layer - Energy layer- Dynamic programming" (IPE-DP),"
Applied Energy, vol. 312, 2022.
[31]
K. Möllersten and M. Gustavsson,
"Implementing BECCS in Swedish district heating – An SDG assessment,"
in Proceedings 16th Greenhouse Gas Control Technologies Conference 2022 (GHGT-16), 2022.
[32]
J. Andersson and S. Grönkvist,
"Improving the economics of fossil-free steelmaking via co-production of methanol,"
Journal of Cleaner Production, vol. 350, pp. 131469, 2022.
[33]
[34]
[35]
[36]
D. S. S. S. Sirigina, A. Goel and S. M. Nazir,
"Multiple greenhouse gases mitigation (MGM) : Process concepts to co-remove non-CO2 (CH4) greenhouse gases and CO2 from air,"
in Multiple greenhouse gases mitigation (MGM): Process concepts to co-remove non-CO2 (CH4) greenhouse gases and CO2 from air, 2022.
[37]
D. S. S. S. Sirigina and S. M. Nazir,
"Non-Fossil Methane Emissions Mitigation From Agricultural Sector and Its Impact on Sustainable Development Goals,"
Frontiers in Chemical Engineering, vol. 4, 2022.
[38]
J. Andersson,
"Non-geological hydrogen storage for fossil-free steelmaking,"
Doctoral thesis : Kungliga Tekniska högskolan, TRITA-CBH-FOU, 2022:21, 2022.
[39]
Y. Ye et al.,
"Performance improvement of metal hydride hydrogen storage tanks by using phase change materials,"
Applied Energy, vol. 320, pp. 119290, 2022.
[40]
K. Zhang et al.,
"Quantifying the photovoltaic potential of highways in China,"
Applied Energy, vol. 324, pp. 119600, 2022.
[41]
[42]
Y. Tan,
"Thermo-physical properties of CO2 mixtures and their impacts on cryogenic carbon capture processes,"
Doctoral thesis Stockholm : KTH Royal Institute of Technology, TRITA-CBH-FOU, 2022:1, 2022.
[43]
G. Lo Zupone et al.,
"Understanding the development and interaction of wake induced by an open centre turbine and its array design implications,"
Applied Ocean Research, vol. 129, 2022.
[44]
A. F. Suarez-Corredor et al.,
"Understanding the NH3 adsorption mechanism on a vanadium-based SCR catalyst : A data-driven modeling approach,"
Chemical Engineering Science, vol. 262, 2022.
[45]
K. Zhang et al.,
"Using street view images to identify road noise barriers with ensemble classification model and geospatial analysis,"
Sustainable cities and society, vol. 78, 2022.
[46]
Z. Qian et al.,
"Vectorized dataset of roadside noise barriers in China using street view imagery,"
Earth System Science Data, vol. 14, no. 9, pp. 4057-4076, 2022.
[47]
A. Lefvert et al.,
"What are the potential paths for carbon capture and storage in Sweden? : A multi-level assessment of historical and current developments,"
Energy Research & Social Science, vol. 87, 2022.
[48]
R. Sadegh-Vaziri, H. Winberg-Wang and M. Bäbler,
"1D Finite Volume Scheme for Simulating Gas-Solid Reactions in Porous Spherical Particles with Application to Biomass Pyrolysis,"
Industrial & Engineering Chemistry Research, vol. 60, no. 29, pp. 10603-10614, 2021.
[49]
T. Zhong et al.,
"A city-scale estimation of rooftop solar photovoltaic potential based on deep learning,"
Applied Energy, vol. 298, 2021.
[50]
J. Andersson and S. Grönkvist,
"A comparison of two hydrogen storages in a fossil-free direct reduced iron process,"
International journal of hydrogen energy, vol. 46, no. 56, pp. 28657-28674, 2021.