Time‐dependent climate impact of a bioenergy system–methodology development and application to Swedish conditions N Ericsson, C Porsö, S Ahlgren, Å Nordberg, C Sundberg, PA Hansson GCB Bioenergy, 2013 | 70 | 2013 |
Climate Impact of Willow Grown for Bioenergy in Sweden T Hammar, N Ericsson, C Sundberg, PA Hansson BioEnergy Research, 1-12, 2014 | 33 | 2014 |
Climate impact and energy efficiency from electricity generation through anaerobic digestion or direct combustion of short rotation coppice willow N Ericsson, Å Nordberg, C Sundberg, S Ahlgren, PA Hansson Applied Energy 132, 86-98, 2014 | 31 | 2014 |
Exploring the potential for biomethane production by willow pyrolysis using life cycle assessment methodology E Ahmadi Moghaddam, N Ericsson, PA Hansson, Å Nordberg Energy, Sustainability and Society 9, 1-18, 2019 | 26 | 2019 |
Climate impact of surface albedo change in Life Cycle Assessment: Implications of site and time dependence P Sieber, N Ericsson, PA Hansson Environmental Impact Assessment Review 77, 191-200, 2019 | 25 | 2019 |
Time‐dependent climate impact and energy efficiency of combined heat and power production from short‐rotation coppice willow using pyrolysis or direct combustion N Ericsson, C Sundberg, Å Nordberg, S Ahlgren, PA Hansson GCB Bioenergy 9 (5), 876-890, 2017 | 19 | 2017 |
Biogas plant management decision support–A temperature and time-dependent dynamic methane emission model for digestate storages N Ericsson, Å Nordberg, M Berglund Bioresource technology reports 11, 100454, 2020 | 14 | 2020 |
Albedo impacts of current agricultural land use: Crop-specific albedo from MODIS data and inclusion in LCA of crop production P Sieber, N Ericsson, T Hammar, PA Hansson Science of the Total Environment 835, 155455, 2022 | 12 | 2022 |
Including albedo in time‐dependent LCA of bioenergy P Sieber, N Ericsson, T Hammar, PA Hansson GCB Bioenergy, 2020 | 11 | 2020 |
Albedo on cropland: Field-scale effects of current agricultural practices in Northern Europe P Sieber, S Böhme, N Ericsson, PA Hansson Agricultural and Forest Meteorology 321, 108978, 2022 | 9 | 2022 |
Life cycle assessment of an all-organic battery: Hotspots and opportunities for improvement S Zhang, N Ericsson, PA Hansson, M Sjödin, Å Nordberg Journal of Cleaner Production 337, 130454, 2022 | 8 | 2022 |
Climate impact of willow grown for bioenergy in Sweden. Bioenergy Res 7: 1529–1540 T Hammar, N Ericsson, C Sundberg, PA Hansson | 6 | 2014 |
A Swedish comment on ‘review: the availability of life-cycle studies in Sweden’ The International Journal of Life Cycle Assessment, 2019 | 5 | 2019 |
Time-dependent climate impact of short rotation coppice willow-based systems for electricity and heat production N Ericsson Department of Energy and Technology, Swedish University of Agricultural Sciences, 2015 | 4 | 2015 |
Prospective life cycle assessment of a flexible all-organic battery S Zhang, N Ericsson, M Sjödin, HK Potter, PA Hansson, Å Nordberg Journal of Cleaner Production 373, 133804, 2022 | 2 | 2022 |
Klimatpåverkan av utfodring med halm som vinterfoder till dikor E Röös, K von Greyerz, M Jardstedt, A Hessle, KA Segerkvist, N Ericsson | | 2024 |
Time-dependent climate impact of bioenergy due to greenhouse gases and albedo. P Sieber, N Ericsson, T Hammar, PA Hansson Geophysical Research Abstracts 21, 2019 | | 2019 |
Pyrolysis and The Price of Carbon. The Value of Biochar N Ericsson, S Ahlgren European Biomass Conference and Exhibition Proceedings, 2017 | | 2017 |
Climate Impacts of Bioenergy Produced from Willow Grown in Sweden T Hammar, C Sundberg, N Ericsson, PA Hansson | | 2014 |
The Effect of Soil Organic Carbon and the Time Frame on the GWP in a Short Rotation Coppice LCA N Ericsson, C Porsö, Å Nordberg, PA Hansson 20th European Biomass Conference and Exhibition, 2235 - 2237, 2012 | | 2012 |