[1] Li L., Lin J., Wu N., Xie S., Meng C., Zheng Y., Wang X., Zhao Y.: Review and outlook on the international renewable energy development. Energ. Built Environ. 3(2020), 2, 2666–1233.
[2] Papadis E., Tsatsaronis G.: Challenges in the decarbonization of the energy sector. Energy 205(2020), 118025.
[3] Hosseini S.E., Wahid M.A.: Renewable and sustainable energy reviews hydrogen production from renewable and sustainable energy resources: Promising green energy carrier for clean development. Renew. Sust. Energ. Rev. 57(2016), 850–866.
[4] Multon B., Gaël R., Ruellan M., Ahmed H.B.: Situation énergétique mondiale à l’aube du 3ème millénaire. Perspectives offertes par les ressources renouvelables. La Revue 3EI SEE (2004), 20–33.
[5] Notton G.: Solar radiation for energy applications. In: Encyclopedia of Sustainable Technologies (A.M. Abraham, Ed.). Elsevier, 2017, 339–356.
[6] Sanan T. Mohammad, Hussain H. Al-Kayiem, Mohammed A. Aurybi, Ayad K. Khlief: Measurement of global and direct normal solar energy radiation in Seri Iskandar and comparison with other cities of Malaysia. Case Stud.Therm. Eng. 18, (2020), 100591.
[7] Cavaco A., Canhoto P., Pereira M.C.: Corrigendum to “Procedures for solar radiation data gathering and processing and their application to DNI assessment in southern Portugal” [Renew. Energ. 163(2021) 2208–2219]. Renew. Energ. 168(2021), 1405.
[8] Yorukoglu M., Celik A.N.: A critical review on the estimation of daily global solar radiation from sunshine duration. Energ. Convers. Manage. 47(2006), 15–16, 2441–2450.
[9] Bakirci K.: Correlations for estimation of daily global solar radiation with hours of bright sunshine in Turkey. Energy 34(2009), 4, 485–501.
[10] Çengelet Y.A. Boles M.A.: Thermodynamics. An Engineering Approach (5th Edn.). McGraw-Hill, 2005.
[11] Dincer I., Rose M.A. (Eds.): Exergy, Energy, Environment, and Sustainable Development (3rd Edn.). Elsevier, 2021, 61–89.
[12] Ziebik A.: Thermodynamical motivation of the Polish energy policy. Arch. Thermodyn. 33(2012), 4, 3–21.
[13] Chu S.X., Liu L.H.: Analysis of terrestrial solar radiation exergy. Sol. Energy 83(2009), 8, 1390–1404.
[14] Candau Y.: On the exergy of radiation. Sol. Energy 75(2003), 3, 241–247.
[15] Gueymard Ch.A.: The sun’s total and spectral irradiance for solar energy applications and solar radiation models. Sol. Energy 76(2004), 4, 423–453.
[16] Kabelac S.: Exergy of solar radiation. Int. J. Energy Technol. Policy 3(2005), 1–2, 115–122.
[17] Joshi A.S., Dincer I., Reddy B.V: Development of new solar exergy maps. Int. J. Energ. Res. 33(2009), 8, 709–718.
[18] Alta D., Ertekin C., Evrendilek F.: Quantifying spatio-temporal dynamics of solar radiation exergy over Turkey. Renew. Energ. 35(2010), 12, 2821–2828.
[19] Jiménez-Muñoz J.C., Sobrino J.A., Mattar C.: Recent trends in solar exergy and net radiation at global scale. Ecol. Model. 228(2012), C, 59–65.
[20] Hepbasli A., Alsuhaibani Z.: Estimating and comparing the exergetic solar radiation values of various climate regions for solar energy utilization. Energ. Source. Part A 36(2014) 7, 764–773.
[21] Uçkan I.: Exergy analysis of solar radiation based on long term for Van city. J. Polytech. 20(2017), 3, 579–584.
[22] Petela R.: Energy of heat radiation. J. Heat Transfer 86(1964), 187–192.
[23] Spanner D.C.: Introduction to Thermodynamics. Academic Press, London, 1964.
[24] Jeter S.M.: Maximum conversion efficiency for the utilization of direct solar radiation. Sol. Energ. 26(1981), 231–236.
[25] Arslanoglu N.: Empirical modeling of solar radiation exergy for Turkey. Appl. Therm. Eng. 108(2016), 1033–1040.
[26] Jamil B., Bellos E.: Development of empirical models for estimation of global solar radiation exergy in India. J. Clean. Prod. 207(2019), 1–16.
[27] Khorasanizadeh H., Sepehrnia M.: Solar exergy evaluation and empirical model establishment; case study: Iran. Heliyon 6(2020), 12, 2405–8440, e05638.
[28] Lounissi D., Bouaziz N.: Exergetic analysis of an absorption/compression refrigeration unit based on R124/DMAC mixture for solar cooling. Int. J. Hydrog. Energ. 42(2017), 13, 8940–8947.
[29] Simpson A.P.: Decision making in energy: Advancing technical, environmental, and economic perspectives. PhD thesis, Stanford Univ. 2010, 28168075.
https://www.proquest.com/openview/6ee7749bfe128753d88ba805856d03b8/1?pqorigsite= gscholar&cbl=18750&diss=y (accessed 10 May 2010).
[30] Brand Correa L.I.: Exergy and useful work analysis as a tool for improved energy policy making: The case of the Colombian energy sector. MSc. thesis, Univ. of Edinburgh, 2014,
https://www.doi.org/10.13140/RG.2.1.4523.6089.
[31] Sciubba E.: Beyond thermoeconomics? The concept of extended exergy accounting and its application to the analysis and design of thermal systems. Exerg. Int. J. 1(2001), 2, 68–84.
[32] Abd Elbar A.R., Yousef M.S., Hassan H.: Energy, exergy, exergoeconomic and enviroeconomic (4E) evaluation of a new integration of solar still with photovoltaic panel. Clean. Prod. 233(2019), 665–680.
[33] Luminosu I., Fara L.: Determination of the optimal operation mode of a flat solar collector by exergetic analysis and numerical simulation. Energy 30(2005), 5, 731– 747.
[34] Sala Lizarraga J.M.P., Picallo-Perez A.: Exergy Analysis and Thermoeconomics of Buildings. Butterworth-Heinemann, 2020.
[35] Ghritlahre H.K., Sahu P.K.: A comprehensive review on energy and exergy analysis of solar air heaters. Arch. Thermodyn. 41(2020), 3, 183–222.
[36] Ghritlahre H.K.: An experimental study of solar air heater using arc shaped wire rib roughness based on energy and exergy analysis. Arch. Thermodyn. 42(2021), 3, 115–139.
[37] Sobhnamayan F., SarhaddF. i, Alavi M.A., Farahat S., Yazdanpanahi J.: Optimization of a solar photovoltaic thermal (PV/T) water collector based on exergy concept. Renew. Energ. 68(2014), 356–365.
[38] Hossain S., Chowdhur H., Chowdhury T., Ahamed J.U., Saidur R., Sait S.M., Rosen M.A.: Energy, exergy and sustainability analyses of Bangladesh’s power generation sector. Energ. Rep. 6(2020), 868–878.
[39] Chowdhury H., Chowdhury T., Chowdhury P., Islam M., Saidur R., Sait S.M.: Integrating sustainability analysis with sectoral exergy analysis: A case study of rural residential sector of Bangladesh, Energ. Buildings 202(2019), 109397.
[40] Cornelissen R.L.: Thermodynamics and sustainable development. PhD thesis, Univ. of Twente, 1997.
[41] Maruf M.H., Rabbani M., Ashique R.H., Islam M.T., Nipun M.K., Haq M.A.U., Al Mansur, Shihavuddin A.S.M.: Exergy based evaluation of power plants for sustainability and economic performance identification. Case Stud. Therm. Eng. 28(2021), 101393.
[42] Rosen M.A., Dincer I., Kanoglu M.: Role of exergy in increasing efficiency and sustainability and reducing environmental impact. Energy Policy 36(2008), 128–137.
[43] Zisopoulos F.K., Rossier-Miranda F.J., van der Goot A.J., Boom R.M.: The use of exergetic indicators in the food industry – A review. Crit. Rev. Food Sci. Nutrit. 57(2017), 197–211.
[44] Hepbasli A.: A key review on exergetic analysis and assessment of renewable energy resources for a sustainable future. Renew. Sust. Energ. Rev. 12(2008), 593–661.
[45] Sudhakar K., Tulika Srivastava: Energy and exergy analysis of 36 W solar photovoltaic module. Int. J. Amb. Energ. 35(2014), 1, 51–57.
[46] Press W.H.: Theoretical maximum for energy from direct and diffuse sunlight. Nature 264(1976), 734–735.
[47] Landsberg P.T., Tonge G.: Thermodynamics of the conversion of diluted radiation. J. Phys. A-Math. Gen. 12(1979), 4, 551–562.
[48] Parrott J.E.: Theoretical upper limit to the conversion efficiency of solar energy. Sol. Energy 21(1978), 3, 227–229.
[49] Parrott J.E.: A letter. Sol. Energy 22(1979), 6, 572–573.
[50] Kabelac S.: A new look at the maximum conversion efficiency of blackbody radiation. Sol. Energy 46(1991), 4, 231–236.
[51] Millan M.I., Hernandez F., Martin E.: Available solar exergy in an absorption cooling process. Sol. Energy 56(1996), 6, 505–511.
[52] Würfel P.: Thermodynamic limitations to solar energy conversion. Physica E 14(2002), 1–2, 18–26.
[53] Bejan A.: Advanced Engineering Thermodynamics. Wiley, New York, 2006.
[54] Petela R.: Exergy of undiluted thermal radiation. Sol. Energy 74(2003), 6, 469–488.
[55] ASHRAE. Handbook of Fundamentals. American Society of Heating, Refrigeration, and Air Conditioning Engineers, New York, 1979.
[56] Solar Position Calculator.
https://gml.noaa.gov/grad/solcalc/azel.html (accessed 10 May 2021).
[57] Khorasanizadeh H., Mohammadi K., Mostafaeipour A.: Establishing a diffuse solar radiation model for determining the optimum tilt angle of solar surfaces in Tabass, Iran. Energ. Convers. Manage. 78(2014), 805–814.
[58] Despotovic M., Nedic V., Despotovic D., Cvetanovic S.: Review and statistical analysis of different global solar radiation sunshine models. Renew. Sust. Energ. Rev.52(2015), 1869–1880.