Publications
[1]
F. Gardumi et al.,
"Carrying out a multi-model integrated assessment of European energy transition pathways : Challenges and benefits,"
Energy, vol. 258, pp. 124329-124329, 2022.
[2]
D. Khatiwada, R. A. Vasudevan and B. H. Santos,
"Decarbonization of natural gas systems in the EU-Costs, barriers, and constraints of hydrogen production with a case study in Portugal,"
Renewable & sustainable energy reviews, vol. 168, 2022.
[3]
E. Pereira Ramos et al.,
"Operationalizing the Nexus Approach : Insights From the SIM4NEXUS Project,"
Frontiers in Environmental Science, vol. 10, 2022.
[4]
R. Yudhistira, D. Khatiwada and F. Sanchez,
"A comparative life cycle assessment of lithium-ion and lead-acid batteries for grid energy storage,"
Journal of Cleaner Production, vol. 358, pp. 131999, 2022.
[5]
R. Heredia Fonseca and F. Gardumi,
"Assessing the impact of applying individual discount rates in power system expansion of Ecuador using OSeMOSYS,"
IJSEPM, 2022.
[6]
I. PAPPIS,
"Trade-offs and conflicting objectives of decision-making investments in low-carbon technology portfolios for sustainable development : National and continental insights offered by applying energy system models,"
Doctoral thesis Stockholm : KTH Royal Institute of Technology, TRITA-ITM-AVL, 2022:21, 2022.
[7]
I. Pappis,
"Strategic low-cost energy investment opportunities and challenges towards achieving universal electricity access (SDG7) in forty-eight African nations,"
Environmental Research: Infrastructure and Sustainability, 2022.
[8]
L. Allington et al.,
"Selected 'Starter kit' energy system modelling data for selected countries in Africa, East Asia, and South America (#CCG, 2021),"
Data in Brief, vol. 42, pp. 108021, 2022.
[9]
Y. Su et al.,
"Decarbonization strategies of Helsinki metropolitan area district heat companies,"
Renewable & sustainable energy reviews, vol. 160, 2022.
[10]
E. Pereira Ramos,
"Advancing Nexus Approaches: insights from practice in support of their operationalisation,"
Doctoral thesis Stockholm : KTH Royal Institute of Technology, TRITA-ITM-AVL, 2022:13, 2022.
[11]
E. Ramos et al.,
"Chapter 9: Capacity development and knowledge transfer on the climate, land, water and energy nexus,"
in Handbook on the Water-Energy-Food Nexus, Floor Brouwer Ed., 1st ed. : Edward Elgar Publishing, 2022, pp. 149-177.
[12]
I. Pappis et al.,
"The effects of climate change mitigation strategies on the energy system of Africa and its associated water footprint,"
Environmental Research Letters, vol. 17, no. 4, 2022.
[13]
R. E. Engström,
"Exploring cross-resource impacts of urban sustainability measures : an urban climate-land-energy-water nexus analysis,"
Doctoral thesis Stockholm : KTH Royal Institute of Technology, TRITA-ITM-AVL, 2022:6, 2022.
[14]
R. E. Engström et al.,
"Corrigendum : Multi-functionality of nature-based and other urban sustainability solutions: New York City study,"
Land Degradation and Development, vol. 33, no. 5, pp. 813-814, 2022.
[15]
T. K. Agrawal et al.,
"Enabling circularity of electric vehicle batteries-the need for appropriate traceability,"
in 2021 IEEE International Conference on Technology Management, Operations and Decisions, ICTMOD 2021, 2021.
[16]
E. Ramos et al.,
"The role of energy efficiency in the management of water resources of the syr darya river basin,"
International Journal of Environment and Sustainable Development (IJESD), vol. 20, no. 1, pp. 64-88, 2021.
[17]
A. T. Mossie et al.,
"A comparative study of the energy and environmental performance of cement industries in Ethiopia and Sweden,"
in International Conference on Electrical, Computer, Communications and Mechatronics Engineering, ICECCME 2021, 2021.
[18]
D. Khatiwada and F. Golzar,
"Exploring Uncertainty In The Technoeconomic And Emissions Assessment Of Waste-To-Energy Systems In Cities – The Case Of Curitiba,"
in International Conference on Applied Energy 2020. Nov 29 – Dec 02, 2020, Bangkok, Thailand, 2021.
[19]
F. Harahap,
"Bioenergy Sustainable development in Indonesia and its relation with SDGs goal,"
in IOP Conference Series : Earth and Environmental Science, 2021.
[20]
R. E. Engström et al.,
"Corrigendum to “Connecting the resource nexus to basic urban service provision – with a focus on water-energy interactions in New York City” [31 (May) (2017) 83–94] (Sustainable Cities and Society (2017) 31 (83–94), (S2210670716305947), (10.1016/j.scs.2017.02.007)),"
Sustainable cities and society, vol. 72, pp. 103002, 2021.
[21]
R. E. Engström et al.,
"Succeeding at home and abroad: accounting for the international spillovers of cities’ SDG actions,"
npj Urban Sustainability, vol. 1, no. 1, 2021.
[22]
F. Gardumi et al.,
"A scenario analysis of potential long-term impacts of COVID-19 on the Tunisian electricity sector,"
Energy Strategy Reviews, vol. 38, 2021.
[23]
B. Khavari et al.,
"The effects of population aggregation in geospatial electrification planning,"
Energy Strategy Reviews, vol. 38, pp. 100752, 2021.
[24]
A. Sahlberg et al.,
"A scenario discovery approach to least-cost electrification modelling in Burkina Faso,"
Energy Strategy Reviews, vol. 38, pp. 100714, 2021.
[25]
J. Mogren Olsson and F. Gardumi,
"Modelling least cost electricity system scenarios for Bangladesh using OSeMOSYS,"
Energy Strategy Reviews, vol. 38, pp. 100705, 2021.
[26]
F. Golzar, M. Astaneh and M. Ghorbanzadeh,
"A Multiphysics System-to-Cell Framework to Assess the Impact of Operating Conditions of Standalone PV Systems on Lithium-Ion Battery Lifetime,"
Electronics, vol. 10, no. 21, pp. 2582, 2021.
[27]
A. M. Elberry, J. Thakur and J. Veysey,
"Seasonal hydrogen storage for sustainable renewable energy integration in the electricity sector : A case study of Finland,"
Journal of Energy Storage, vol. 44, 2021.
[28]
E. Ntostoglou, D. Khatiwada and V. Martin,
"The Potential Contribution of Decentralized Anaerobic Digestion towards Urban Biowaste Recovery Systems : A Scoping Review,"
Sustainability, vol. 13, no. 23, pp. 13435-13435, 2021.
[29]
C. M. L. de Almeida et al.,
"Using the Sustainable Development Goals to Evaluate Possible Transport Policies for the City of Curitiba,"
Sustainability, vol. 13, no. 21, 2021.
[30]
J. Trinh et al.,
"What Are the Policy Impacts on Renewable Jet Fuel in Sweden?,"
Energies, vol. 14, no. 21, pp. 7194-7194, 2021.
[31]
F. Vanhuyse, N. R. Haddaway and M. Henrysson,
"Circular cities: an evidence map of research between 2010 and 2020,"
Discover Sustainability, vol. 2, no. 1, 2021.
[32]
I. Pappis et al.,
"Implications to the electricity system of Paraguay of different demand scenarios and export prices to Brazil,"
Energy Systems, Springer Verlag, 2021.
[33]
L. Sani et al.,
"Decarbonization pathways for the power sector in Sumatra, Indonesia,"
Renewable & sustainable energy reviews, vol. 150, 2021.
[34]
D. Khatiwada et al.,
"Circularity in the Management of Municipal Solid Waste - A Systematic Review,"
Vides un Klimata Tehnologijas / Scientific Proceedings of Riga Technical University : Environmental and Climate Technologies, vol. 25, no. 1, pp. 491-507, 2021.
[35]
F. Vanhuyse et al.,
"The lack of social impact considerations in transitioning towards urban circular economies : a scoping review,"
Sustainable cities and society, pp. 103394-103394, 2021.
[36]
A. Papageorgiou et al.,
"Mapping and assessing indicator-based frameworks for monitoring Circular Economy development at the city-level,"
Sustainable cities and society, vol. 75, 2021.
[37]
H. Henke, F. Gardumi and M. I. Howells,
"The Open Source electricity Model Base for Europe - An engagement framework for open and transparent European energy modelling,"
Energy, vol. 239, 2021.
[38]
P. Pradhan et al.,
"The COVID-19 Pandemic Not Only Poses Challenges, but Also Opens Opportunities for Sustainable Transformation,"
Earth's Future, vol. 9, no. 7, 2021.
[39]
T. Niet et al.,
"Developing a community of practice around an open source energy modelling tool,"
Energy Strategy Reviews, vol. 35, 2021.
[40]
F. Golzar and S. Silveira,
"Impact of wastewater heat recovery in buildings on the performance of centralized energy recovery – a case study of Stockholm,"
Applied Energy, vol. 297, 2021.
[41]
A. Beltramo et al.,
"The Global Least-cost User-friendly CLEWs Open-Source Exploratory model,"
Environmental Modelling & Software, vol. 143, 2021.
[42]
B. Khavari et al.,
"Population cluster data to assess the urban-rural split and electrification in Sub-Saharan Africa,"
Scientific Data, vol. 8, no. 1, 2021.
[43]
H. Abid et al.,
"Energy storage integration with solar PV for increased electricity access: A case study of Burkina Faso,"
Energy, vol. 230, no. 120656, pp. 120656, 2021.
[44]
R. C. Poudel et al.,
"Large-scale biogas upgrading plants : future prospective and technical challenges,"
in Emerging Technologies and Biological Systems for Biogas Upgrading, Netherlands : Elsevier, 2021, pp. 467-491.
[45]
S. P. Lohani et al.,
"Small-scale biogas technology and clean cooking fuel: Assessing the potential and links with SDGs in low-income countries – A case study of Nepal,"
Sustainable Energy Technologies and Assessments, vol. 46, no. 101301, 2021.
[46]
D. Meha et al.,
"A novel spatial based approach for estimation of space heating demand saving potential and CO2 emissions reduction in urban areas,"
Energy, vol. 225, 2021.
[47]
A. M. Elberry et al.,
"Large-scale compressed hydrogen storage as part of renewable electricity storage systems,"
International journal of hydrogen energy, vol. 46, no. 29, pp. 15671-15690, 2021.
[48]
C. Ramirez Gomez, Y. Almulla and F. F. Nerini,
"Reusing wastewater for agricultural irrigation : a water-energy-food Nexus assessment in the North Western Sahara Aquifer System,"
Environmental Research Letters, vol. 16, no. 4, 2021.
[49]
D. Meha et al.,
"A novel spatial?temporal space heating and hot water demand method for expansion analysis of district heating systems,"
Energy Conversion and Management, vol. 234, 2021.
[50]
I. Pappis et al.,
"Influence of Electrification Pathways in the Electricity Sector of Ethiopia-Policy Implications Linking Spatial Electrification Analysis and Medium to Long-Term Energy Planning,"
Energies, vol. 14, no. 4, 2021.