A New Approach for Exergoeconomics Evaluation by Considering ‎Uncertainty with Monte Carlo Method

[1] Worrell, E.,  Bernstein, L., Roy, J., Price, L., Harnisch, J., Industrial energy efficiency and climate change mitigation, Energy Efficiency, 2(2), 2009, 109-123.

[2] Spillias, S., Kareiva, P., Ruckelshaus M., McDonald-Madden, E., Renewable energy targets may undermine their sustainability, Nature Climate Change, 10, 2020, 974-976.

[3] Bejan, A., Tsatsaronis, G., Moran, M., Thermal design and optimization, John Wiley & Sons, 1996.

[4] Dincer, I., Rosen, M.A., Exergy: energy, environment and sustainable development, Newnes, 2012.

[5] Kamate, S.C., Gangavati, P.B., Exergy analysis of cogeneration power plants in sugar industries, Applied Thermal Engineering, 29(5), 2009, 1187-1194.

[6] Ameri, M., Ahmadi, P., Khanmohammadi, S., Exergy analysis of a 420 MW combined cycle power plant, International Journal of Energy Research, 32(2), 2008, 175-183.

[7] Gaggioli, R.A., Wepfer, W.J., Exergy economics: I. Cost accounting applications, Energy, 5(8-9), 1980, 823-837.

[8] Tribus, M., Evans, R., Thermo-economics of sea-water conversion, Industrial & Engineering Chemistry Process Design and Development, 4(2), 1963, 195-206.

[9] Tsatsaronis, G., Winhold, M., Exergoeconomic analysis and evaluation of energy-conversion plants—I. A new general methodology, Energy, 10(1), 1985, 69-80.

[10] Lozano, M.A., Valero, A., Theory of the exergetic cost, Energy, 18(9), 1993, 939-960.

[11] Kim, S.M., Oh, S.D., Kwon, Y.H., Kwak, H.Y., Exergoeconomic analysis of thermal systems, Energy, 23(5), 1998, 393-406.

[12] Tsatsaronis, G., Definitions and nomenclature in exergy analysis and exergoeconomics, Energy, 32(4), 2007, 249-253.

[13] Kwon, Y.H., Kwak, H.Y., Oh, S.D., Exergoeconomic analysis of gas turbine cogeneration systems, Exergy, An International Journal, 1(1), 2001, 31-40.

[14] Blumberg, T., Assar, M., Morosuk, T., and Tsatsaronis, G., Comparative exergoeconomic evaluation of the latest generation of combined-cycle power plants, Energy Conversion and Management, 153, 2017, 616-626.

[15] Wellmann, J., Meyer-Kahlen, B., Morosuk, T., Exergoeconomic evaluation of a CSP plant in combination with a desalination unit, Renewable Energy, 128, 2017, 586-602.

[16] Conejo, A.J., Carrión, M., Morales, J.M., Decision making under uncertainty in electricity markets, Springer, 2010.

[17] Soroudi, A., Amraee, T., Decision making under uncertainty in energy systems: State of the art, Renewable and Sustainable Energy Reviews, 28, 2013, 376-384.

[18] Posen, I.D., Jaramillo, P., Landis, A.E., Griffin, W.M., Greenhouse gas mitigation for US plastics production: energy first, feedstocks later, Environmental Research Letters, 12(3), 2017, 034024.

[19] da Silva Pereira, E.J., Pinho, J.T., Galhardo, M.A.B., Macêdo, W.N., Methodology of risk analysis by Monte Carlo Method applied to power generation with renewable energy, Renewable Energy, 69, 2014, 347–355.

[20] Momen, M., Shirinbakhsh, M., Baniassadi, A., Behbahani-nia, A., Application of Monte Carlo method in economic optimization of cogeneration systems–Case study of the CGAM system, Applied Thermal Engineering, 104, 2016, 34–41.

[21] Hofmann, M., Tsatsaronis, G., Comparative exergoeconomic assessment of coal-fired power plants – Binary Rankine cycle versus conventional steam cycle, Energy, 142, 2018, 168–179.

[22] Valero, A., Lozano, M.A., Serra, L., Tsatsaronis, G., Pisa, J., Frangopoulos, Ch., von Spakovsky, M.R., CGAM problem: Definition and conventional solution, Energy, 19(3), 1994, 279-286.