| 1 |
A quantitative analysis of Japan's optimal power generation mix in 2050 and the role of CO2-free hydrogen
Matsuo Y, Endo S, Nagatomi Y, Shibata Y, Komiyama R, Fujii Y
Energy, 165, 1200, 2018 |
| 2 |
A systems approach to quantifying the value of power generation and energy storage technologies in future electricity networks
Heuberger CF, Staffell I, Shah N, Mac Dowell N
Computers & Chemical Engineering, 107, 247, 2017 |
| 3 |
Demand flexibility versus physical network expansions in distribution grids
Spiliotis K, Gutierrez AIR, Belmans R
Applied Energy, 182, 613, 2016 |
| 4 |
Rethinking how to support intermittent renewables
Narbel PA
Energy, 77, 414, 2014 |
| 5 |
Exploration of the integration of renewable resources into California's electric system using the Holistic Grid Resource Integration and Deployment (HiGRID) tool
Eichman JD, Mueller F, Tarroja B, Schell LS, Samuelsen S
Energy, 50, 353, 2013 |
| 6 |
Super Grid or Smart Grid: Competing strategies for large-scale integration of intermittent renewables?
Blarke MB, Jenkins BM
Energy Policy, 58, 381, 2013 |
| 7 |
Wind energy really is the last to be stored and solar energy cannot be stored economically
Swift-Hook D
Renewable Energy, 50, 971, 2013 |
| 8 |
Towards an intermittency-friendly energy system: Comparing electric boilers and heat pumps in distributed cogeneration
Blarke MB
Applied Energy, 91(1), 349, 2012 |
| 9 |
Metrics for evaluating the impacts of intermittent renewable generation on utility load-balancing
Tarroja B, Mueller F, Eichman JD, Samuelsen S
Energy, 42(1), 546, 2012 |
| 10 |
Intermittency-friendly and high-efficiency cogeneration: Operational optimisation of cogeneration with compression heat pump, flue gas heat recovery, and intermediate cold storage
Blarke MB, Dotzauer E
Energy, 36(12), 6867, 2011 |
