Publications
[1]
H. Dong et al.,
"Life Cycle Assessment of Thermal Energy Storage in Buildings,"
in Life Cycle Management from Global to Local, 2026.
[2]
F. Fuso Nerini,
"AI economics for the common good,"
Nature Machine Intelligence, vol. 8, no. 4, pp. 495-496, 2026.
[3]
A. Beltramo,
"Open Modelling for Robust and Transparent Climate and Energy Policymaking,"
Doctoral thesis Stockholm, Sweden : KTH Royal Institute of Technology, TRITA-ITM-AVL, 2026:11, 2026.
[4]
F. Lenhard et al.,
"‘Sustainable Choices’ - An intervention to promote climate change mitigation behaviours: Study protocol for a randomized controlled trial,"
PLOS ONE, vol. 21, no. 3, 2026.
[5]
A. Omondi et al.,
"Revitalizing biomass utilization for renewable energy and sustainable rural development in Japan,"
Discover Sustainability, vol. 7, no. 1, 2026.
[6]
F. Fuso Nerini et al.,
"A research agenda to support the achievement of clean cooking for all,"
Joule, vol. 10, no. 3, pp. 102382, 2026.
[7]
S. M. Soman et al.,
"Occupancy Detection for Residential Buildings using Machine Learning with Indoor Temperature as the Only Training Feature,"
in Proceedings 17th International Conference on Applied Energy (ICAE2025), 2026.
[8]
M. B. Ledari et al.,
"Optimizing resource management for water-smart, low-carbon futures : A CLEWs-IO model for job creation and climate resilience,"
Journal of Cleaner Production, vol. 544, 2026.
[9]
F. Harahap et al.,
"Assessing the climate impact of retail payment services,"
Ecological Economics, vol. 246, 2026.
[10]
A. Beltramo, M. Henrysson and W. Usher,
"Open science practices for better NDCs: Supporting transparent and accountable climate mitigation action,"
PLOS Climate, vol. 5, no. 2, 2026.
[11]
S. Z. A. Fakhry, F. Golzar and J. Ardelius,
"Forecasting and optimizing residential EV flexibility for the Swedish mFRR market using machine learning,"
International Journal of Electrical Power & Energy Systems, vol. 174, 2026.
[12]
I. Keppo et al.,
"Model linking for low-carbon transitions : Technical and conceptual challenges and best practices,"
Renewable & sustainable energy reviews, vol. 226, 2026.
[13]
P. Mohebi et al.,
"Optimal battery sizing using stochastic programming to consider building load variation and peak demand charge,"
Energy Conversion and Management, vol. 348, 2026.
[14]
L. Lundmark et al.,
"A validated forecasting model for optimizing dispatch schedules of PV - battery system in grid-connected apartment buildings,"
Applied Energy, vol. 404, 2026.
[15]
A. Furberg et al.,
"Guidelines for assessments of the global information and communication technology sector's direct energy use and climate impact : Key aspects and future scenarios,"
Renewable & sustainable energy reviews, vol. 226, 2026.
[16]
A. Aliyu et al.,
"Implication of Environmental Crises on the Socioeconomic Dimensions of the Sustainable Development Goals,"
in United Nations Environment Programme, Global Environment Outlook 7 : A Future We Choose: Why Investing in Earth Now Can Lead to a Trillion-Dollar Benefit for All., Nairobi : United Nations Environment Programme, 2025.
[17]
S. Mangalath Ramasan et al.,
"Grid aware electrification for decarbonising port logistics based on a case study from Sweden,"
Scientific Reports, vol. 15, no. 1, 2025.
[18]
S. M. Soman et al.,
"DIGITAL TWINS FOR SMART GRID CONNECTED BUILDINGS : A SYSTEMATIC LITERATURE REVIEW,"
in PROCEEDINGS OF ASME 2025 19TH INTERNATIONAL CONFERENCE ON ENERGY SUSTAINABILITY, ES2025, VOL 1, 2025.
[19]
M. G. Wolde et al.,
"Strategies for decarbonizing the cement industry in Ethiopia : Investigating the barriers and drivers,"
Energy Reports, vol. 14, pp. 2514-2534, 2025.
[20]
K. Alexander et al.,
"Analysing the development of the climate, land, energy, and water systems (CLEWs) modelling framework : a state-of-the-art review,"
ENVIRONMENTAL RESEARCH-CLIMATE, vol. 4, no. 3, 2025.
[21]
T. Xiao et al.,
"Environmental impact and net-zero pathways for sustainable artificial intelligence servers in the USA,"
Nature Sustainability, vol. 8, no. 12, pp. 1541-1553, 2025.
[22]
S. Kumar et al.,
"Exploring excess heat recovery in proton exchange membrane electrolysis for Green Hydrogen production : A Technical and economic analysis,"
Energy Conversion and Management, vol. 342, 2025.
[23]
J. Köstlbacher et al.,
"Application of an electrolysis system model for techno-economic optimization of hydrogen production in industry-based case studies,"
International journal of hydrogen energy, vol. 138, pp. 1144-1162, 2025.
[24]
S. M. Soman et al.,
"Digital Twins for Smart Grid Connected Buildings : A Systematic Literature Review,"
in Proceedings of the ASME 2025 19th International Conference on Energy Sustainability collocated with the ASME 2025 Heat Transfer Summer Conference, 2025.
[25]
H. Akay et al.,
"Training a Foundation Model in Engineering Design Understanding,"
in 35th CIRP Design, CIRP Design 2025, 2025, pp. 354-359.
[26]
F. Fuso Nerini et al.,
"Breaking the cycle of underinvestment in climate-resilient energy infrastructure,"
Nature Energy, vol. 10, no. 11, pp. 1291-1292, 2025.
[27]
M. Bergman et al.,
"Guidelines for inclusive and equitable energy and transport modeling,"
iScience, vol. 28, no. 9, 2025.
[28]
S. Kumar, D. Meha and J. Thakur,
"Evaluating the district cooling potential for India using a GIS-based top-down approach,"
Energy, vol. 335, 2025.
[29]
D. Meha et al.,
"Empowering sustainable energy technologies for electricity production in Kosovo using scenario approach analysis,"
Sustainable Energy Technologies and Assessments, vol. 82, 2025.
[30]
C. Rodés-Bachs et al.,
"Open Science Practices in Integrated Assessment Models,"
Open Research Europe, vol. 5, 2025.
[31]
R. Calvo García et al.,
"Techno-economic analysis of flexible sector coupling between electrical and thermal sectors,"
Energy Conversion and Management : X, vol. 27, 2025.
[32]
C. Gil Ribeiro, J. Thakur and M. Henrysson,
"Exploring the macro environment determinants behind the diffusion of electric Light Commercial Vehicles,"
Transportation, 2025.
[33]
Y. Khalifa et al.,
"The role of electric cooking in providing sustainable school meals in low-income and lower-middle-income countries,"
The Lancet Planetary Health, vol. 9, no. 11, 2025.
[34]
A. T. Mossie et al.,
"Techno-economic analysis of waste heat recovery power plants in cement industry – A case study in Ethiopia,"
Next Energy, vol. 8, 2025.
[35]
S. Kumar et al.,
"Strategic integration of urban excess heat sources in a district heating system : A Spatio-temporal optimisation methodology,"
Applied Energy, vol. 396, 2025.
[36]
B. Heidary, M. A. Kiani and F. Golzar,
"Toward Sustainable Development : Energy Transition Scenarios for Oil-Dependent Countries, with Iran as a Case Study,"
Energies, vol. 18, no. 10, 2025.
[37]
E. Ntostoglou,
"Upscaling biowaste valorization : A crucial component towards sustainable bioeconomies,"
Doctoral thesis Stockholm : KTH Royal Institute of Technology, TRITA-ITM-AVL, 2025:28, 2025.
[38]
M. Järvinen et al.,
"A Sustainable Path for Renewable Energy Technologies,"
in Green Energy and Technology, : Springer Nature, 2025, pp. 33-127.
[39]
R. Heredia-Fonseca,
"Exploring Low-Carbon Energy Transitions Through Energy System Modeling: Leveraging data, scenario and sensitivity analysis : Insights from case applications in Ecuador, Kenya, and the State of Goa (India),"
Doctoral thesis Stockholm, Sweden : KTH Royal Institute of Technology, TRITA-ITM-AVL, 2025:14, 2025.
[40]
R. Heredia Fonseca et al.,
"Sectoral interactions and primary drivers in integrated CLEWs modeling: insights from Kenya,"
Environmental Research Communications (ERC), vol. 7, no. 4, 2025.
[41]
X. Bin and J. Thakur,
"Circular economy metrics for batteries: Enhancing sustainability in energy storage systems,"
Sustainable Production and Consumption, vol. 55, pp. 470-485, 2025.
[42]
E. Fejzic and W. Usher,
"Stakeholder engagement for co-designing European climate and energy research priorities,"
Renewable & sustainable energy reviews, vol. 215, 2025.
[43]
R. Heredia Fonseca, F. Gardumi and W. Usher,
"Exploring interlinkages in land, energy, and water in cooking and agriculture sectors : A case study in Kenya,"
Energy Nexus, vol. 17, 2025.
[44]
B. van der Zwaan et al.,
"Electricity- and hydrogen-driven energy system sector-coupling in net-zero CO<inf>2</inf> emission pathways,"
Nature Communications, vol. 16, no. 1, 2025.
[45]
H. Akay et al.,
"Language Models for Functional Digital Twin of Circular Manufacturing,"
in Sustainable Manufacturing as a Driver for Growth - Proceedings of the 19th Global Conference on Sustainable Manufacturing, 2025, pp. 553-561.
[46]
N. Moksnes and W. Usher,
"The relative importance of uncertain parameters and structural formulation for electricity systems planning in Kenya and Benin,"
iScience, vol. 28, no. 2, 2025.
[47]
S. Alexandrou and D. Khatiwada,
"Strategies for decarbonizing the aviation sector : Evaluating economic competitiveness of green hydrogen value chains- A case study in France,"
Energy, vol. 314, 2025.
[48]
L. Smajila et al.,
"Comparative analysis of techno-economic and techno-environmental approach to optimal sizing and dispatch of hybrid solar–battery systems,"
Energy Conversion and Management : X, vol. 25, 2025.
[49]
P. Sundarrajan, J. Thakur and D. Meha,
"Harnessing hydrogen and thermal energy storage : Sweden's path to a 100 % renewable energy system by 2045,"
Renewable & sustainable energy reviews, vol. 210, 2025.
[50]
E. Ntostoglou et al.,
"Path-dependencies in the transition to sustainable biowaste valorization : Lessons from a socio-technical analysis of Sweden and Greece,"
Waste Management, vol. 192, pp. 47-57, 2025.