| An extended pinch analysis and design procedure utilizing pressure based exergy for subambient cooling A Aspelund, DO Berstad, T Gundersen Applied thermal engineering 27 (16), 2633-2649, 2007 | 254 | 2007 |
| An optimization-simulation model for a simple LNG process A Aspelund, T Gundersen, J Myklebust, MP Nowak, A Tomasgard Computers & Chemical Engineering 34 (10), 1606-1617, 2010 | 241 | 2010 |
| Using exergy analysis to reduce power consumption in air separation units for oxy-combustion processes C Fu, T Gundersen Energy 44 (1), 60-68, 2012 | 189 | 2012 |
| Improved optimization strategies for automated heat exchanger network synthesis through physical insights T Gundersen, IE Grossmann Computers & chemical engineering 14 (9), 925-944, 1990 | 155 | 1990 |
| Modeling and simulation of energy systems: A review ASR Subramanian, T Gundersen, TA Adams Processes 6 (12), 238, 2018 | 147 | 2018 |
| A comparison of exergy efficiency definitions with focus on low temperature processes D Marmolejo-Correa, T Gundersen Energy 44 (1), 477-489, 2012 | 138 | 2012 |
| Synthesis of heat exchanger networks at subambient conditions with compression and expansion of process streams A Wechsung, A Aspelund, T Gundersen, PI Barton AIChE Journal 57 (8), 2090-2108, 2011 | 126 | 2011 |
| A process integration primer T Gundersen IEA and SINTEF Energy Research, Department of Thermal Energy and Hydro Power …, 2002 | 112* | 2002 |
| Post-combustion carbon capture technologies: Energetic analysis and life cycle assessment X Zhang, B Singh, X He, T Gundersen, L Deng, S Zhang International Journal of Greenhouse Gas Control 27, 289-298, 2014 | 104 | 2014 |
| Optimal design and operation of an Organic Rankine Cycle (ORC) system driven by solar energy with sensible thermal energy storage H Yu, H Helland, X Yu, T Gundersen, G Sin Energy Conversion and Management 244, 114494, 2021 | 103 | 2021 |
| Post-combustion carbon capture with a gas separation membrane: parametric study, capture cost, and exergy analysis X Zhang, X He, T Gundersen Energy & Fuels 27 (8), 4137-4149, 2013 | 101 | 2013 |
| A liquefied energy chain for transport and utilization of natural gas for power production with CO2 capture and storage–Part 1 A Aspelund, T Gundersen Applied Energy 86 (6), 781-792, 2009 | 98 | 2009 |
| A study of working fluids for Organic Rankine Cycles (ORCs) operating across and below ambient temperature to utilize Liquefied Natural Gas (LNG) cold energy H Yu, D Kim, T Gundersen Energy 167, 730-739, 2019 | 97 | 2019 |
| Annotated bibliography—Use of optimization in LNG process design and operation B Austbø, SW Løvseth, T Gundersen Computers & Chemical Engineering 71, 391-414, 2014 | 82 | 2014 |
| Thermal efficiency of coal-fired power plants: From theoretical to practical assessments C Fu, R Anantharaman, K Jordal, T Gundersen Energy conversion and management 105, 530-544, 2015 | 80 | 2015 |
| Energy Level Composite Curves—a new graphical methodology for the integration of energy intensive processes R Anantharaman, OS Abbas, T Gundersen Applied Thermal Engineering 26 (13), 1378-1384, 2006 | 80 | 2006 |
| Recuperative vapor recompression heat pumps in cryogenic air separation processes C Fu, T Gundersen Energy 59, 708-718, 2013 | 77 | 2013 |
| An introduction to the concept of exergy and energy quality T Gundersen Department of Energy and Process Engineering Norwegian University of Science …, 2011 | 75 | 2011 |
| Optimal operation of heat exchanger networks B Glemmestad, S Skogestad, T Gundersen Computers & chemical engineering 23 (4-5), 509-522, 1999 | 73 | 1999 |
| Coal based power plants using oxy-combustion for CO2 capture: Pressurized coal combustion to reduce capture penalty R Soundararajan, T Gundersen Applied Thermal Engineering 61 (1), 115-122, 2013 | 71 | 2013 |
