[1] Y. Cui, R. Gulfam, Y. Ishrat, S. Iqbal, and F. Yao, "Recent Progress of Phase Change Materials and Their Applications in Facility Agriculture and Related-Buildings—A Review," Buildings, vol. 14, no. 9, p. 2999, 2024.
[2] J. Zhu, X. Zhang, W. Hua, J. Ji, and X. Lv, "Current status and development of research on phase change materials in agricultural greenhouses: A review," Journal of Energy Storage, vol. 66, p. 107104, 2023.
[3] H. Mehling, "Use of phase change materials for food applications—State of the art in 2022," Applied Sciences, vol. 13, no. 5, p. 3354, 2023.
[4] D. Zou, X. Ma, X. Liu, P. Zheng, and Y. Hu, "Thermal performance enhancement of composite phase change materials (PCM) using graphene and carbon nanotubes as additives for the potential application in lithium-ion power battery," International Journal of Heat and Mass Transfer, vol. 120, pp. 33-41, 2018.
[5] H. Mehling and L. F. Cabeza, "Heat and cold storage with PCM," Heat and mass transfer, pp. 11-55, 2008.
[6] L. Zhang et al., "Fundamental studies and emerging applications of phase change materials for cold storage in China," Journal of Energy Storage, vol. 72, p. 108279, 2023.
[7] J. J. Espitia et al., "Solar Energy Applications in Protected Agriculture: A Technical and Bibliometric Review of Greenhouse Systems and Solar Technologies," Agronomy, vol. 14, no. 12, p. 2791, 2024.
[8] S. Nishad and I. Krupa, "Phase change materials for thermal energy storage applications in greenhouses: A review," Sustainable Energy Technologies and Assessments, vol. 52, p. 102241, 2022.
[9] A. M. Nair, C. Wilson, M. J. Huang, P. Griffiths, and N. Hewitt, "Phase change materials in building integrated space heating and domestic hot water applications: A review," Journal of Energy Storage, vol. 54, p. 105227, 2022.
[10] M. Marciukaitis, V. Katinas, and A. Kavaliauskas, "Wind power usage and prediction prospects in Lithuania," Renewable and Sustainable Energy Reviews, vol. 12, no. 1, pp. 265-277, 2008.
[11] S. Chen, Y. Zhu, Y. Chen, and W. Liu, "Usage strategy of phase change materials in plastic greenhouses, in hot summer and cold winter climate," Applied Energy, vol. 277, p. 115416, 2020.
[12] Y. Gu, X. Zheng, Z. Zhou, G. Chen, S. Chen, and Q. Li, "Amphiphilic ionic liquid hydrogel electrolytes with high ionic conductivity towards dendrite-free ultra-stable aqueous zinc ion batteries," Journal of Energy Storage, vol. 89, p. 111892, 2024.
[13] F. G. Montoya, A. García-Cruz, M. G. Montoya, and F. Manzano-Agugliaro, "Power quality techniques research worldwide: A review," Renewable and Sustainable Energy Reviews, vol. 54, pp. 846-856, 2016.
[14] N. Ghasem, K. Majid, and G. Amin, "The importance and application of phase change materials," presented at the 10th National Congress of Agricultural Machinery Engineering (Biosystems) and Mechanization of Iran, 1395. [Online]. Available: https://civilica.com/doc/563518/. (in Persian)
[15] S. M. Thaler, J. Zwatz, P. Nicolay, R. Hauser, and R. Lackner, "An Innovative Heating Solution for Sustainable Agriculture: A Feasibility Study on the Integration of Phase Change Materials as Passive Heating Elements," Applied Sciences, vol. 14, no. 16, p. 7419, 2024.
[16] M. Mu, S. Zhang, S. Yang, and Y. Wang, "Phase change materials applied in agricultural greenhouses," Journal of Energy Storage, vol. 49, p. 104100, 2022.
[17] P. Nasehi and A. Jamekhorshid, "Thermal Energy Storage Using Phase Change Materials (PCMs): A Literature Review," Journal of Renewable and New Energy, vol. 9, no. 2, pp. 34-45, 2022. (in Persian)
[18] khodkam, Himan, ghaebi, and Hadi, "Commercial production of antioxidants from fresh agricultural residues," Renewable and New Energy, 2025. (in Persian)
[19] W. Hu, V. N. Alekhin, Y. Huang, T. Meng, and Y. Du, "Design, thermal performance evaluation, and economic analysis of a new solar air dryer suitable for high latitude regions," Energy, p. 134766, 2025.
[20] B. Brahma, A. K. Shukla, and D. C. Baruah, "Energy, exergy, economic and environmental analysis of phase change material based solar dryer (PCMSD)," Journal of Energy Storage, vol. 88, p. 111490, 2024.
[21] D. CHAATOUF, M. SALHI, A. Bria, B. RAILLANI, S. AMRAQUI, and A. MEZRHAB, "Numerical and Experimental Evaluation of the Thermal and Dynamic Performance of a Phase Change Material in an Indirect Solar Dryer," International Journal of Refrigeration, 2025.
[22] M. A. Raheem Junaidi, "Influence of advanced composite phase change materials on thermal energy storage and thermal energy conversion," Journal of Thermal Analysis and Calorimetry, pp. 1-22, 2025.
[23] A. Bhardwaj, R. Chauhan, R. Kumar, M. Sethi, and A. Rana, "Experimental investigation of an indirect solar dryer integrated with phase change material for drying valeriana jatamansi (medicinal herb)," Case studies in thermal engineering, vol. 10, pp. 302-314, 2017.
[24] B. Bai, K. Zhao, and X. Li, "Application research of nano-storage materials in cold chain logistics of e-commerce fresh agricultural products," Results in Physics, vol. 13, p. 102049, 2019.
[25] A. K. Thakur, S. K. Hazra, A. M. Saleque, S. Bhattarai, J.-Y. Hwang, and M. S. Ahamed, "Toward Sustainable Water Solutions: A Review of Nanomaterials for Solar-Driven Water Harvesting," ACS ES&T Water, vol. 4, no. 11, pp. 4741-4757, 2024.
[26] Z. Sheykhani Nejad Fallah, M. Zangeneh, and N. Banaeian, "Evaluation of Kiwi Quality Indicators in the Drying Process by a Fixed Bed Dryer Equipped with Phase Change Materials," Agricultural Mechanization, vol. 9, no. 2, pp. 17-28, 2024. (in Persian)
[27] J. H. Tan, Y. Y. Liew, R. Bahar, H. K. Jun, and J. Low, "Enhancing solar still productivity in tropical climate with conductive particle-assisted phase change material," Solar Energy Materials and Solar Cells, vol. 279, p. 113227, 2025.
[28] R. Kumar et al., "Phase change materials integrated solar desalination system: An innovative approach for sustainable and clean water production and storage," Renewable and Sustainable Energy Reviews, vol. 165, p. 112611, 2022.
[29] C. Li, Y. Goswami, and E. Stefanakos, "Solar assisted sea water desalination: A review," Renewable and sustainable energy reviews, vol. 19, pp. 136-163, 2013.
[30] A. A. Omara, A. A. Abuelnuor, H. A. Mohammed, and M. Khiadani, "Phase change materials (PCMs) for improving solar still productivity: a review," Journal of Thermal Analysis and Calorimetry, vol. 139, pp. 1585-1617, 2020.
[31] S. Shalaby, E. El-Bialy, and A. El-Sebaii, "An experimental investigation of a v-corrugated absorber single-basin solar still using PCM," Desalination, vol. 398, pp. 247-255, 2016.
[32] S. Nasimi, M. Fakhroleslam, G. Zarei, and S. M. Sadrameli, "Passive energy-efficiency optimization in greenhouses using phase change materials; a comprehensive review," Journal of Energy Storage, vol. 90, p. 111762, 2024.
[33] Y. He, R. Feng, S. Wang, X.-W. Wu, and G. Hu, "Design of a Passive Temperature Management House Using Composite Phase Change Materials," Energy, p. 134962, 2025.
[34] B. Xiang and X. Zhang, "Advancements in the development of field precooling of fruits and vegetables with/without phase change materials," Journal of Energy Storage, vol. 73, p. 109007, 2023.
[35] M. Calati, G. Righetti, C. Zilio, K. Hooman, and S. Mancin, "CFD analyses for the development of an innovative latent thermal energy storage for food transportation," International Journal of Thermofluids, vol. 17, p. 100301, 2023.
[36] S. Tan and X. Zhang, "Preparation of organic ternary phase change materials for fruit and vegetable cold chain logistics," Journal of Energy Storage, vol. 108, p. 115067, 2025.
[37] W. J. Luo, P. Negi, Y.-C. Chang, C. Zuo, and B. Panigrahi, "Performance Evaluation of Mof-Coated Desiccant-Assisted Intermittent Heat Pump Drying for Energy-Efficient Dehydration of Apple Slices," Available at SSRN 5196293.
[38] G. Vasudevan, G. Muthuvairavan, S. K. Suraparaju, A. Yadav, M. Samykano, and S. K. Natarajan, "Exploring the role of phase change materials in low-temperature solar thermal applications: an extensive overview with challenges and opportunities," Environmental Science and Pollution Research, pp. 1-33, 2025.
[39] A. R. Al‐Hilphy et al., "A pilot‐scale rotary infrared dryer of shrimp (Metapenaeus affinis): Mathematical modeling and effect on physicochemical attributes," Journal of Food Process Engineering, vol. 45, no. 6, p. e13945, 2022.
[40] S. Singh, K. K. Gaikwad, and Y. S. Lee, "Phase change materials for advanced cooling packaging," Environmental Chemistry Letters, vol. 16, pp. 845-859, 2018.
[41] W. Aftab, X. Huang, W. Wu, Z. Liang, A. Mahmood, and R. Zou, "Nanoconfined phase change materials for thermal energy applications," Energy & Environmental Science, vol. 11, no. 6, pp. 1392-1424, 2018.
[42] A. Jain, M. Ghosh, M. Krajewski, S. Kurungot, and M. Michalska, "Biomass-derived activated carbon material from native European deciduous trees as an inexpensive and sustainable energy material for supercapacitor application," Journal of Energy Storage, vol. 34, p. 102178, 2021.
[43] S. Prasanth, S. Narayanan, N. Sivakumaran, and R. S. Rominus, "A hybrid technique to control superheater steam temperature in power plants using multi modeling and predictive sliding mode control," Sustainable Energy Technologies and Assessments, vol. 55, p. 102912, 2023.
[44] M. Sadi, A. mohammad Behzadi, A. S. Alsagri, K. H. Chakravarty, and A. Arabkoohsar, "An innovative green multi-generation system centering around concentrating PVTs and biomass heaters, design and multi-objective optimization," Journal of Cleaner Production, vol. 340, p. 130625, 2022.
[45] S. Agrawal et al., "Synthesis and water treatment applications of nanofibers by electrospinning," Processes, vol. 9, no. 10, p. 1779, 2021.
[46] Z. Raji, A. Karim, A. Karam, and S. Khalloufi, "Adsorption of heavy metals: mechanisms, kinetics, and applications of various adsorbents in wastewater remediation—a review," in Waste, 2023, vol. 1, no. 3: MDPI, pp. 775-805.
[47] B. COSKUN, U. N. Temel, and M. Bulut, "Investigation of thermal energy storage capacities of phase change material embedded different bio-based materials converted into biochar," Physica Scripta, 2025.
[48] P. Kahandage, M. H. Seyar, R. Noguchi, and T. Ahamed, "Purification of agricultural polluted water using solar distillation and hot water producing with continuous monitoring based on iot," in IoT and AI in Agriculture: Self-sufficiency in Food Production to Achieve Society 5.0 and SDG's Globally: Springer, 2023, pp. 75-96.
[49] R. Ahmed, M. Ahamed, S. M. F. Islam, and M. T. Alam, "IoT Based Water Purification and Monitoring System Using Solar Energy," Faculty of Engineering, American International University–Bangladesh, 2024.
