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• [1] Zhao Y, Ou C, Chen J. (2008). A new analytical approach to model and evaluate the performance of a class of irreversible fuel cells, International Journal of Hydrogen Energy, 33, 4161 – 4170.
• [2] Zhang X, Guo J, Chen J. (2010) . The parametric optimum analysis of a proton exchange membrane (PEM) fuel cell and its load matching, Energy, 35, 5294-5299.
• [3] Zhang H, Lin G, Chen J. (2011). Performance analysis and multi-objective optimization of a new molten carbonate fuel cell system, International Journal of Hydrogen Energy, 36, 4015 – 4021.
• [4] Zhang H, Chen L, Zhang J, Chen J. (2014). Performance analysis of a direct carbon fuel cell with molten carbonate electrolyte, Energy, 68, 1-9.
• [5] Zhang H, Lin G, Chen J. (2012). Multi-objective optimization analysis and load matching of a phosphoric acid fuel cell system, International Journal of Hydrogen Energy, 37, 3438-3446.
• [6] Yang P, Zhang H, Hu Z. (2016). Parametric study of a hybrid system integrating a phosphoric acid fuel cell with an absorption refrigerator for cooling purposes, International Journal of Hydrogen Energy, 41, 3579 -3590.
• [7] Chen X , Wang Y, Zahao Y, Zhou Y. (2016). A study of double functions and load matching of a phosphoric acid fuel cell/heat-driven refrigerator hybrid system, Energy 101, 359-365.
• [8] Chen L, Zhang H,Gao S, Yan H. (2014)., Performance optimum analysis of an irreversible molten carbonate fuel cell - Stirling heat engine hybrid system, Energy 64, 923-930.
• [9] Chen L, Gao S, Zhang H. (2013). Performance Analysis and Multi-Objective Optimization of an Irreversible Solid Oxide Fuel Cell-Stirling Heat Engine Hybrid System, Int. J. Electrochem. Sci., 8, 10772 - 10787.
• [10]Açıkkalp E., Thermo-environmental performance analysis of irreversible solid oxide fuel cell – Stirling heat engine, International Journal of Ambient Energy, article in press DOI: 10.1080/01430750.2017.1345011.
• [11] Yang P, Zhang H. (2015). Parametric analysis of an irreversible proton exchange membrane fuel cell/absorption refrigerator hybrid system, Energy, 85, 458-467.
• [12] Zhao Y, Chen J. (2009). Modeling and optimization of a typical fuel cell–heat engine hybrid system and its parametric design criteria, Journal of Power Sources, 186, 96–103.
• [13] Zhang H, Lin G, Chen J. (2011). Performance Evaluation and Parametric Optimum Criteria of an Irreversible Molten Carbonate Fuel Cell-Heat Engine Hybrid System, Int. J. Electrochem. Sci,. 6, 4714 - 4729.
• [14] Zhang X, Chen J. (2010). Performance analysis and parametric optimum criteria of a class of irreversible fuel cell/heat engine hybrid systems, International Journal of Hydrogen Energy 35, 284 – 293.
• [15] Zhang X,Wang Y, Guo J, Shih T-M, Chen J. (2014). A unified model of high-temperature fuel-cell heat engine hybrid systems and analyses of its optimum performances, International Journal of Hydrogen Energy, 39, 1811 –1825.
• [16] Zhang X, Su S, Chen J, Zhao Y, Brandon N. (2011), A new analytical approach to evaluate and optimize the performance of an irreversible solid oxide fuel cell-gas turbine hybrid system, International Journal of Hydrogen Energy, 36, 15304 –15312.
• [17] Haseli H, Dincer I, Naterer GF. (2008). Thermodynamic analysis of a combined gas turbine power system with a solid oxide fuel cell through exergy, Thermochimica Acta, 480, 1–9.
• [18] Açıkkalp E. (2017). Ecologic and Sustainable Objective Thermodynamic Evaluation of Molten Carbonate Fuel Cell - Supercritical CO2 Brayton Cycle Hybrid System, International Journal of Hydrogen Energy, 42, 6272-6280.
• [19] Haseli H, Dincer I, Naterer GF. (2008). Thermodynamic modeling of a gas turbine cycle combined with a solid oxide fuel cell, International Journal of Hydrogen Energy, 33, 5811 –5822.
• [20] Açıkkalp E. (2017). Performance analysis of irreversible solid oxide fuel cell – Brayton heat engine with ecological based thermo-environmental criterion, Energy Conversion and Management, 148, 279-286.
• [21] Zhang X, Guo J, Chen J. (2012). Influence of multiple irreversible losses on the performance of a molten carbonate fuel cell-gas turbine hybrid system, International Journal of Hydrogen Energy 37, 8664 –8671.
• [22] Sánchez D, Chacartegui R, Jiménez-Espadafor F, Sánchez T. (2009). A new concept for high temperature fuel cell hybrid systems using supercritical carbon dioxide, J. Fuel Cell Sci. Technol., 6, 021306.
• [23] Sanchez D, Munoz de Escalona J.M, Chacartegui R, Munoz A., Sanchez T. (2011). A comparison between molten carbonate fuel cells based hybrid systems using air and supercritical carbon dioxide Brayton cycles with state of the art technology, Journal of Power Sources, 196, 4347–4354.
• [24] Zhang X, Liu H, Ni M, Chen J. (2015). Performance evaluation and parametric optimum design of a syngas molten carbonate fuel cell and gas turbine hybrid system, Renewable Energy, 80, 407-414.
• [25] Mehrpooya M ,Bahramian P, Pourfayaz F, Rosen M.A. Introducing and analysis of a hybrid molten carbonate fuel cell-supercritical carbon dioxide Brayton cycle system, Sustainable Energy Technologies and Assessments 18 (2016) 100–106.
• [26] Zhang H, Su S, Lin G, Chen J. (2012). Performance Analysis and Multi-Objective Optimization of a Molten Carbonate Fuel Cell Braysson Heat Engine Hybrid System, Int. J. Electrochem. Sci., 7, 3420 - 3435.
• [27] Açıkkalp E. (2017). Performance analysis of irreversible molten carbonate fuel cell – Braysson heat engine with ecological objective approach, Energy Conversion and Management, 13, 2432–2437
• [28] Huang C, Pan Y, Wang Y, Su G, Chen J. (2016). An efficient hybrid system using a thermionic generator to harvest waste heat from a reforming molten carbonate fuel cell, Energy Conversion and Management 121, 186–193.
• [29 ]Mahmoudi S.M.S., Ghavimi A.R. (2016). Thermoeconomic analysis and multi objective optimization of a molten carbonate fuel cell – Supercritical carbon dioxide – Organic Rankine cycle integrated power system using liquefied natural gas as heat sink, Applied Thermal Engineering, 107, 1219–1232.
• [30] Chen L, Gong J, Sun F, Wu C. (2002). Effect of heat transfer on the performance of thermoelectric generators, Int J ThermSci, 41(1), 95–99.
• [31] Meng F, Chen L, Sun F. (2010). Effects of heat reservoir temperatures on the performance of thermoelectric heat pump driven by thermoelectric generator, Int J Low-Carbon Technol,. 5(4),273–82.
• [32] Meng F, Chen L, Sun F, Wu C. (2009), Thermodynamic analysis and optimisation of a new-type thermoelectric heat pump driven by a thermoelectric generator, Int J Ambient Energy, 30(2), 95–101.
• [33]Chen L, Meng F, Sun F. Effect of heat transfer on the performance of thermoelectric generator-driven thermoelectric refrigerator system. Cryogenics 2012;52(1):58–65. [34] Kaushik S, Manikandan S, Hans R. (2015). Energy and exergy analysis of thermoelectric heat pump system, Int J Heat Mass Transfer, 86, 843–52.
• [35] Arora R, Kaushik SC, Arora R. (2015). Multi-objective and multi-parameter optimization of two-stage thermoelectric generator in electrically series and parallel configurations through NSGA-II, Energy, 30(91), 242–254.
• [36] Manikandan., Kaushik S.C. (2015). Thermodynamic studies and maximum power point tracking in thermoelectric generator–thermoelectric cooler combined system, Cryogenics, 6752–6762.
• [37] Meng F K, Chen L G, Sun F R. (2011). A numerical model and comparative investigation of a thermoelectric generator with multi-irreversibilities, Energy, 36(5), 3513-3522.
• [38] Chen L G, Meng F K, Sun F R. (2012). Maximum power and efficiency of an irreversible thermoelectric generator with a generalized heat transfer law, Scientia Iranica, Transaction B: Mechanical Engineering, 19 (5), 1337-1345
• [39] Chen L G, Meng F K, Sun F R. (2013). Internal and external simultaneous optimization of an irreversible multielement thermoelectric generator for maximum power output, International Journal of Low-Carbon Technologies, 8 (3), 188-196.
• [40] Meng F K, Chen L G, Sun F R, Yang B. (2014). Thermoelectric power generation driven by blast furnace slag flushing water, Energy, 66, 965-972.
• [41] Xiong B, Chen L G, Meng F K, Sun F R. (2014). Modeling and performance analysis of a two-stage thermoelectric energy harvesting system from blast furnace slag water waste heat, Energy, 77, 562-569.
• [42] Chen L G, Meng F K, Sun F R. (2016). Thermodynamic analyses and optimizations for thermoelectric devices: the state of the arts, Science China: Technological Sciences, 59(3), 442-455.
• [43] Meng F K, Chen L G, Sun F R. (2016). Effects of thermocouples physical dimension on the performance of TEG-TEH system, International Journal of Low-Carbon Technologies, 11(3), 375-382.
• [44] Meng F K, Chen L G, Feng Y L, Xiong B. (2017). Thermoelectric generator for industrial gas phase waste heat recovery, Energy, 135, 83-90.
• [45] Meng F K, Chen L G, Xie Z H, Ge Y L. (2017). Thermoelectric generator with air-cooling heat recovery device from wastewater, Thermal Science and Engineering Progress, 4, 106-112.
• [46] Chen X , Wang Y, Cai L, Zhou Y. (2015), Maximum power output and load matching of a phosphoric acid fuel cell-thermoelectric generator hybrid system, Journal of Power Sources 294, 430-436.
• [47] Zhao M , Zhang H, Hua Z, Zhang Z, Zhang J. (2015). Performance characteristics of a direct carbon fuel cell/thermoelectric generator hybrid system, Energy Conversion and Management 89, 683–689.
• [48] Chen X, Chen L, Guo J, Chen J. (2011). An available method exploiting the waste heat in a proton exchange membrane fuel cell system, International Journal of Hydrogen Energy 36, 6099 – 6104.
• [49] Feng H J, Chen L G, Xie Z H, Sun F R. (2015). Constructal optimization for a single tubular solid oxide fuel cell, Journal of Power Sources, 286, 406-413.
• [50] Abbas S. S., Ahmadi M.H., Ahmadi M.A. (2015). Optimization performance and thermodynamic analysis of an irreversible nano scale Brayton cycle operating with Maxwell–Boltzmann gas, Energy Conversion and Management 101, 592-605.
• [51] Ahmadi M H., Ahmad M.A., Pourfayaz F., Bidi M. (2016). Thermodynamic analysis and optimization for an irreversible heat pump working on reversed Brayton cycle. Energy Conversion and Management, 110, 260-267.
• [52] Ahmadi M.H, Ahmadi M.A,. (2016). Multi objective optimization of performance of three-heat-source irreversible refrigerators based algorithm NSGAII, Renewable and Sustainable Energy Reviews, 60, 784-794.
• [53] Ahmadi M.H., Sayyaadi H, Hosseinzadeh H. (2015). Optimization of Output Power and Thermal Efficiency of Solar‐Dish Stirling Engine Using Finite Time Thermodynamic Analysis, Heat Transfer—Asian Research 44, 347-376.
• [54] Dincer I , Rosen M.A, Exergy: Energy, Environment and Sustainable Development, Elsevier Science, 2 edition.
• [55] Aminyavari M., Haghighat A, Mamaghani A. S., Najafi B, Rinaldi F. (2016). Exergetic, economic, and environmental evaluations and multi-objective optimization of an internal-reforming SOFC-gas turbine cycle coupled with a Rankine cycle, Applied Thermal Engineering 108, 833–846.
• [56] Kwak H-Y, Lee H-S, Jung J-Y, Jeon J-S, Park D-R (2004) . Exergetic and thermoeconomic analysis of a 200-kW phosphoric acid fuel cell plant, Fuel 83, 2087–2094. [57] Staffell I, Green R. (2013). The cost of domestic fuel cell micro-CHP systems, International Journal of Hydrogen Energy, 38, 1088-1102.
• [58]https://energy.gov/sites/prod/files/2015/02/f19/QTR%20Ch8%20%20Thermoelectic%20Materials%20TA%20Feb-13-2015.pdf (access date, 07.04.2017).
• [59] Kazim A., (2005). Exergoeconomic analysis of a PEM fuel cell at various operating conditions, Energy Conversion and Management, 46, 1073–1081.