Publications

[1]

A. Beltramo et al., "The Global Least-cost User-friendly CLEWs Open-Source Exploratory model," Environmental Modelling & Software, 2021.

[2]

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.

[3]

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.

[4]

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, 2021.

[5]

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.

[6]

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.

[7]

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.

[8]

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.

[9]

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.

[10]

E. Ramos et al., "The climate, land, energy, and water systems (CLEWs) framework : a retrospective of activities and advances to 2019," Environmental Research Letters, vol. 16, no. 3, 2021.

[11]

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.

[12]

C. Utama, S. Troitzsch and J. Thakur, "Demand-side flexibility and demand-side bidding for flexible loads in air-conditioned buildings," Applied Energy, vol. 285, 2021.

[13]

M. Henrysson and C. Nuur, "The Role of Institutions in Creating Circular Economy Pathways for Regional Development," Journal of Environment and Development, no. 2, pp. 127-148, 2021.

[14]

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.

[15]

E. Thwe, D. Khatiwada and A. Gasparatos, "Life cycle assessment of a cement plant in Naypyitaw, Myanmar," Cleaner Environmental Systems, vol. 2, 2021.

[16]

D. Khatiwada and P. Purohit, "Special Issue on Assessing the Modern Bioenergy Potential and Strategies for Sustainable Development: Transformations through Nexus, Policy, and Innovations," Sustainability, vol. 13, no. 1, pp. 374, 2021.

[17]

M. Henrysson and C. Hendrickson, "Scope for Circular Economy Model in Urban Agri-Food Value Chains," in Sustainable Consumption and Production, Volume II : Circular Economy and Beyond, Ranjula Bali Swain and Susanne Sweet Ed., 1st ed. Cham : Palgrave Macmillan, 2021, pp. 75-97.

[18]

A. Korkovelos et al., "Erratum : The role of open access data in geospatial electrification planning and the achievement of SDG7. An OnSSET-based case study for Malawi (Energies (2019) 12:7 (1395) DOI: 10.3390/en12071395)," Energies, vol. 13, no. 19, 2020.

[19]

G. Godinez-Zamora et al., "Decarbonising the transport and energy sectors : Technical feasibility and socioeconomic impacts in Costa Rica," Energy Strategy Reviews, vol. 32, 2020.

[20]

N. Moksnes et al., "Electrification pathways for Kenya-linking spatial electrification analysis and medium to long term energy planning (vol 12, 095008, 2017)," Environmental Research Letters, vol. 15, no. 12, 2020.

[21]

A. Rout et al., "A Monte Carlo based approach for exergo-economic modeling of solar water heater," Energy Sources, Part A: Recovery, Utilization, and Environmental Effects, pp. 1-19, 2020.

[22]

F. Golzar and S. Silveira, "Implications of improved heat recovery in builidngs - a case study of Stockholm," in Applied energy symposium MIT A+B, 2020.

[23]

S. Balderrama et al., "Model-base cost evaluation of microgrids systems for rural electrification and energy planning purposes," in Proceedings of the ISES Solar World Congress 2019 and IEA SHC International Conference on Solar Heating and Cooling for Buildings and Industry 2019, 2020, pp. 1638-1647.

[24]

C. Bataille et al., "Net-zero deep decarbonization pathways in Latin America : Challenges and opportunities," Energy Strategy Reviews, vol. 30, 2020.

[25]

V. Sridharan et al., "Land, energy and water resource management and its impact on GHG emissions, electricity supply and food production- Insights from a Ugandan case study," ENVIRONMENTAL RESEARCH COMMUNICATIONS, vol. 2, no. 8, 2020.

[26]

Y. Almulla et al., "A GIS-Based Approach to Inform Agriculture-Water-Energy Nexus Planning in the North Western Sahara Aquifer System (NWSAS)," Sustainability, vol. 12, no. 17, 2020.

[27]

C. Taliotis et al., "The Effect of Electric Vehicle Deployment on Renewable Electricity Generation in an Isolated Grid System : The Case Study of Cyprus," Frontiers in Energy Research, vol. 8, 2020.

[28]

T. Karpouzoglou et al., "Winners and losers during transition: the case of urban water and energy systems in Sweden," in 11th International Sustainability Transitions Conference, 2020.

[29]

F. Golzar, D. Nilsson and V. Martin, "Forecasting Wastewater Temperature Based on Artificial Neural Network (ANN) Technique and Monte Carlo Sensitivity Analysis," Sustainability, vol. 12, no. 16, 2020.

[30]

M. B. Siddique and J. Thakur, "Assessment of curtailed wind energy potential for off-grid applications through mobile battery storage," Energy, vol. 201, 2020.

[31]

J. G. Pena Balderrama et al., "Incorporating high-resolution demand and techno-economic optimization to evaluate micro-grids into the Open Source Spatial Electrification Tool (OnSSET)," Energy for Sustainable Development, vol. 56, pp. 98-118, 2020.

[32]

O. Saadeh et al., "Technoeconomic data adopted for the development of a long-term electricity supply model for the Hashmite Kingdome of Jordan," Data in Brief, vol. 30, 2020.

[33]

A. Palombelli et al., "Development of functionalities for improved storage modelling in OSeMOSYS," Energy, vol. 195, 2020.

[34]

P. Korkmaz et al., "A comparison of three transformation pathways towards a sustainable European society - An integrated analysis from an energy system perspective," Energy Strategy Reviews, vol. 28, 2020.

[35]

A. Korkovelos et al., "A Retrospective Analysis of Energy Access with a Focus on the Role of Mini-Grids," Sustainability, vol. 12, no. 5, 2020.

[36]

A. Korkovelos et al., "Supporting Electrification Policy in Fragile States : A Conflict-Adjusted Geospatial Least Cost Approach for Afghanistan," Sustainability, vol. 12, no. 3, 2020.

[37]

M. Henrysson, "Transforming the governance of energy systems: the politics of ideas in low-carbon infrastructure development in Mexico and Vietnam," Climate and Development, pp. 1-12, 2020.

[38]

V. Sridharan, "Impact of climate change on integrated resource systems- Insights from selected East African case studies," Doctoral thesis Stockholm : KTH Royal Institute of Technology, TRITA-ITM-AVL, 2020:17, 2020.

[39]

V. Menghwani et al., "Planning with justice : Using spatial modelling to incorporate justice in electricity pricing - The case of Tanzania," Applied Energy, vol. 264, 2020.

[40]

E. Fejzic, "Renewable energy outlook for the Drina River Basin countries," , 2020.

[41]

F. Harahap, "Exploring synergies between the palm oil industry and bioenergy production in Indonesia," Doctoral thesis Stockholm : KTH Royal Institute of Technology, TRITA-ITM-AVL, 2020:11, 2020.

[42]

F. Harahap et al., "Meeting the bioenergy targets from palm oil based biorefineries: An optimalconfiguration in Indonesia," Applied Energy, vol. 278, 2020.

[43]

D. Conti et al., "A techno-economic assessment for optimizing methanol production for maritime transport in Sweden," in ECOS 2019 - Proceedings of the 32nd International Conference on Efficiency, Cost, Optimization, Simulation and Environmental Impact of Energy Systems, 2019, pp. 4703-4712.

[44]

R. E. Segerström et al., "Cross-Scale Water and Land Impacts of Local Climate and Energy Policy—A Local Swedish Analysis of Selected SDG Interactions," Sustainability, vol. 11, no. 7, 2019.

[45]

N. Moksnes et al., "Determinants of energy futures—a scenario discovery method applied to cost and carbon emission futures for South American electricity infrastructure," Environmental Research Communications, vol. 02, no. 5001, 2019.

[46]

F. Gardumi, G. Avgerinopoulos and M. I. Howells, "Preface to the special issue on "Energy transition and decarbonisation pathways for the EU"," Energy Strategy Reviews, vol. 26, 2019.

[47]

V. Sridharan et al., "Vulnerability of Ugandas Electricity Sector to Climate Change : An Integrated Systems Analysis," in Handbook of Climate Change Resilience, Leal Filho, Walter Ed., Switzerland : Springer International Publishing, 2019, pp. 1-30.

[48]

M. A. D. Larsen et al., "Challenges of data availability : Analysing the water-energy nexus in electricity generation," Energy Strategy Reviews, vol. 26, 2019.

[49]

D. Khatiwada, P. Purohit and E. Ackom, "Mapping Bioenergy Supply and Demand in Selected Least Developed Countries (LDCs): Exploratory Assessment of Modern Bioenergy’s Contribution to SDG7," Sustainability, vol. 11, no. 24, 2019.

[50]

D. Timmons et al., "Cost minimization for fully renewable electricity systems : A Mauritius case study," Energy Policy, vol. 133, 2019.

Full list in the KTH publications portal