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Long-chain Diesters of Fattyy Alcohols as Novel Phase Change Materials for Thermal Energy Storage

Year 2020, , 269 - 280, 22.03.2020
https://doi.org/10.17776/csj.669208

Abstract

References

  • [1] Mao Q., Chen H., Zhao Y., and Wu H. A novel heat transfer model of a phase change material using in solar power plant. Appl. Therm. Eng,. 129 (2018) 557–563.
  • [2] Tao Y. B. and He Y. L. A review of phase change material and performance enhancement method for latent heat storage system. Renew. Sustain. Energy Rev., 93 (2018) 245–259.
  • [3] Rezaie A. B. and Montazer M. One-step fabrication of fatty acids/nano copper/polyester shape-stable composite phase change material for thermal energy management and storage. Appl. Energy., 228 (2018) 1911–1920.
  • [4] Zhang P., Meng Z. N., Zhu H., Wang Y. L., and Peng S. P. Melting heat transfer characteristics of a composite phase change material fabricated by paraffin and metal foam. Appl. Energy., 185 (2017) 1971–1983.
  • [5] Lin Y., Jia Y., Alva G., and Fang G. Review on thermal conductivity enhancement, thermal properties and applications of phase change materials in thermal energy storage, Renew. Sustain. Energy Rev., 82 (2018) 2730–2742.
  • [6] Behzadi S. and Farid M. M. Long term thermal stability of organic PCMs. Appl. Energy, 122 (2014) 11–16.
  • [7] Zalba B., Marı́n J. M., Cabeza L. F., and Mehling H. Review on thermal energy storage with phase change: materials, heat transfer analysis and applications. Appl. Therm. Eng., 23 (2003) 251–283.
  • [8] Sharma A., Tyagi V. V., Chen C. R., and Buddhi D. Review on thermal energy storage with phase change materials and applications. Renew. Sustain. Energy Rev., 13 (2009) 318–345.
  • [9] Parameshwaran R., Kalaiselvam S., Harikrishnan S., and Elayaperumal A. Sustainable thermal energy storage technologies for buildings: A review. Renew. Sustain. Energy Rev., 16 (2012) 2394–2433.
  • [10] Sarı A., Bicer A., Karaipekli A., and Al-Sulaiman F.A. Preparation, characterization and thermal regulation performance of cement based-composite phase change material. Sol. Energy Mater. Sol. Cells., 174 (2018) 523–529.
  • [11] Yuan Y., Cao X., Xiang B., and Du Y. Effect of installation angle of fins on melting characteristics of annular unit for latent heat thermal energy storage. Sol. Energy., 136 (2016) 365–378.
  • [12] Zeinelabdein R., Omer S., and Gan G. Critical review of latent heat storage systems for free cooling in buildings. Renew. Sustain. Energy Rev., 82 (2018) 2843–2868.
  • [13] Liu M., Steven Tay N. H., Bell S., Belusko M., Jacob R., Will G., Saman W., and Bruno F. Review on concentrating solar power plants and new developments in high temperature thermal energy storage Technologies. Renew. Sustain. Energy Rev., 53 (2016) 1411–1432.
  • [14] Pardo P., Deydier A., Anxionnaz-Minvielle Z., Rougé S., Cabassud M., and Cognet P. A review on high temperature thermochemical heat energy storage. Renew. Sustain. Energy Rev., 32 (2014) 591–610.
  • [15] Fernandez A. I., Martínez M., Segarra M., Martorell I., Cabeza L. F. Selection of materials with potential in sensible thermal energy storage. Sol. Energy Mater. Sol. Cells., 94 (2010) 1723–1729.
  • [16] Kenisarin M. and Mahkamov K. Salt hydrates as latent heat storage materials:Thermophysical properties and costs. Sol. Energy Mater. Sol. Cells., 145 (2016) 255–286.
  • [17] Wang Q., Wang J., Chen Y., and Zhao C.Y. Experimental investigation of barium hydroxide octahydrate as latent heat storage materials. Sol. Energy., 177 (2019) 99–107.
  • [18] Baetens R., Jelle B.P., and Gustavsen A. Phase change materials for building applications: A state-of-the-art review. Energy Build., 42 (2010) 1361–1368.
  • [19] Zhou D., Zhao C.Y., and Tian Y. Review on thermal energy storage with phase change materials (PCMs) in building applications. Appl. Energy., 92 (2012) 593–605.
  • [20] Kahraman Döğüşcü D., Kızıl Ç., Biçer A., Sarı A., and Alkan C. Microencapsulated n-alkane eutectics in polystyrene for solar thermal applications. Sol. Energy., 160 (2018) 32-42.
  • [21] Alkan C., Sarı A., and Karaipekli A. Preparation, thermal properties and thermal reliability of microencapsulated n-eicosane as novel phase change material for thermal energy storage. Energy Convers. Manag., 52 (2011) 687–692.
  • [22] Alkan C. and Sari A. Fatty acid/poly(methyl methacrylate) (PMMA) blends as form-stable phase change materials for latent heat thermal energy storage. Sol. Energy., 82 (2008) 118–124.
  • [23] Zuo J., Li W., and Weng L. Thermal performance of caprylic acid/1-dodecanol eutectic mixture as phase change material (PCM). Energy Build., 43 (2011) 207–210.
  • [24] Cheng F., Wen R., Zhang X., Huang Z. Huang Y., Fang M., Liu Y., Wu X., and Min X., Synthesis and characterization of beeswax-tetradecanol-carbon fiber/expanded perlite form-stable composite phase change material for solar energy storage. Compos. Part A Appl. Sci. Manuf., 107 (2018) 180–188.
  • [25] Wang Y., Liu Z., Zhang T., and Zhang Z. Preparation and Characterization of Graphene Oxide-Grafted Hexadecanol Composite Phase-Change Material for Thermal Energy Storage. Energy Technol., 5 (2017) 2005–2014.
  • [26] Lv P., Ding M., Liu C., and Rao Z. Experimental investigation on thermal properties and thermal performance enhancement of octadecanol/expanded perlite form stable phase change materials for efficient thermal energy storage. Renew. Energy., 131 (2019) 911–922.
  • [27] Ma G., Sun J., Zhang Y., Jing Y., and Jia Y. Preparation and thermal properties of stearic acid-benzamide eutectic mixture/expanded graphite composites as phase change materials for thermal energy storage. Powder Technol., 342 (2019) 131–140.
  • [28] Hou P., Mao J., Chen F., Li Y., Dong X., Hou P., Mao J., Chen F., Li Y., and Dong X. Preparation and Thermal Performance Enhancement of Low Temperature Eutectic Composite Phase Change Materials Based on Na2SO4·10H2O. Materials, 11 (2018) 2230.
  • [29] Sarı A., Alkan C., Döğüşcü D.K., and Kızıl Ç. Micro/nano encapsulated n-tetracosane and n-octadecane eutectic mixture with polystyrene shell for low-temperature latent heat thermal energy storage applications. Sol. Energy., 115 (2015) 195–203.
  • [30] Döğüşcü D.K., Altıntaş A., Sarı A., and Alkan C. Polystyrene microcapsules with palmitic-capric acid eutectic mixture as building thermal energy storage materials. Energy Build., 150 (2017) 376-382.
  • [31] Stamatiou A., Obermeyer M., Fischer L.J., Schuetz P., and Worlitschek J. Investigation of unbranched, saturated, carboxylic esters as phase change materials. Renew. Energy., 108 (2017) 401–409.
  • [32] Pielichowski K. and Flejtuch K. Differential scanning calorimetry studies on poly(ethylene glycol) with different molecular weights for thermal energy storage materials. Polym. Adv. Technol., 13 (2002) 690–696.
  • [33] Baykut F., Aydın A. The synthesis and physical properties of the homologous series of fatty acids’ esters. Reveu La Fac. Des Sci. L’Universite D’Istanbul Ser. C., (1969) 119–148.
  • [34] Parameshwaran R., Jayavel R., and Kalaiselvam S. Study on thermal properties of organic ester phase-change material embedded with silver nanoparticles. J. Therm. Anal. Calorim., 114 (2013) 845–858.
  • [35] Wi S., Seo J., Jeong S. G., Chang S. J., Kang Y., and Kim S. Thermal properties of shape-stabilized phase change materials using fatty acid ester and exfoliated graphite nanoplatelets for saving energy in buildings. Sol. Energy Mater. Sol. Cells., 143 (2015) 168–173.
  • [36] Aydın A.A. Fatty acid ester-based commercial products as potential new phase change materials (PCMs) for thermal energy storage. Sol. Energy Mater. Sol. Cells., 108 (2013) 98–104.
  • [37] Feldman D., Banu D., Hawes D., and Ghanbari E. Obtaining an energy storing building material by direct incorporation of an organic phase change material in gypsum wallboard. Sol. Energy Mater. Sol. Cells., 22 (1991) 231–242.
  • [38] Feldman D., Banu D., and Hawes D. Low chain esters of stearic acid as phase change materials for thermal energy storage in buildings. Sol. Energy Mater. Sol. Cells., 36 (1995) 311–322.
  • [39] Sarı A., Biçer A., Karaipekli A., Alkan C., and Karadag A. Synthesis, thermal energy storage properties and thermal reliability of some fatty acid esters with glycerol as novel solid–liquid phase change materials. Sol. Energy Mater. Sol. Cells., 94 (2010) 1711–1715.
  • [40] Sarı A., Biçer A., and Karaipekli A. Synthesis, characterization, thermal properties of a series of stearic acid esters as novel solid–liquid phase change materials. Mater. Lett., 63 (2009) 1213–1216.
  • [41] Sarı A. and Biçer A. Thermal energy storage properties and thermal reliability of some fatty acid esters/building material composites as novel form-stable PCMs. Sol. Energy Mater. Sol. Cells., 101 (2012) 114–122.
  • [42] Sarı A. and Karaipekli A. Fatty acid esters-based composite phase change materials for thermal energy storage in buildings. Appl. Therm. Eng., 37 (2012) 208–216.
  • [43] Kahraman Döğüşcü D. Tetradecyl oxalate and octadecyl oxalate as novel phase change materials for thermal energy storage. Sol. Energy., 185 (2019) 341–349.
  • [44] Kahraman Döğüşcü D. Synthesis and characterization of ditetradecyl succinate and dioctadecyl succinate as novel phase change materials for thermal energy storage. Sol. Energy Mater. Sol. Cells., 200 (2019) 110006.
  • [45] Aydın A.A., and Okutan H. Polyurethane rigid foam composites incorporated with fatty acid ester-based phase change material. Energy Convers. Manag., 68 (2013) 74–81.
  • [46] Aydın A.A. In situ preparation and characterization of encapsulated high-chain fatty acid ester-based phase change material (PCM) in poly(urethane-urea) by using amino alcohol. Chem. Eng. J., 231 (2013) 477–483.
  • [47] Alkan C., Gunther E., Hiebler S., Ensari O.F., and Kahraman D. Polyurethanes as solid–solid phase change materials for thermal energy storage. Sol. Energy., 86(6) (2012) 1761-1769.
  • [48] Alkan C., Günther E., Hiebler S., and Himpel M. Complexing blends of polyacrylic acid-polyethylene glycol and poly(ethylene-co-acrylic acid)-polyethylene glycol as shape stabilized phase change materials. Energy Convers. Manag., 64 (2012) 364–370.
  • [49] Mehling H., Günther E. Hiebler S., Cabeza L.F., and Castellón C., A New Measurement and Evaluation Method For DSC of PCM Samples, In: Proceedings of Effstock -11th International Conference on Energy Storage. Stockholm, Sweden (2009).
  • [50] Nikolić R., Marinović-Cincović M. Gadžurić S., and Zsigrai I., New materials for solar thermal storage—solid/liquid transitions in fatty acid esters. Sol. Energy Mater. Sol. Cells., 79 (2003) 285–292.
  • [51] Aydın A.A. and Okutan H. High-chain fatty acid esters of myristyl alcohol with even carbon number: Novel organic phase change materials for thermal energy storage-1. Sol. Energy Mater. Sol. Cells., 95 (2011) 2752–2762.

Long-chain diesters of fattyy alcohols as novel phase change materials for thermal energy storage

Year 2020, , 269 - 280, 22.03.2020
https://doi.org/10.17776/csj.669208

Abstract

In this study, long chain diesters of fatty alcohols were synthesized for use in thermal energy storage applications. Long-chain diesters of adipic acid were proposed for the first time in this study to be used as phase change material (PCM). For this purpose, ditetradecyl adipate (DTA) and dioctadecyl adipate (DOA) were synthesized as novel solid-liquid PCMs by means of the direct esterification reaction of adipic acid with 1-tetradecanol and 1-octadecanol. The reaction was yielded at around 90% as an average at the end of 6 hours. The DTA and DOA were characterized chemically using FT-IR and 1HNMR techniques as the energy storage properties, total enthalpy, and specific heat (Cp) capacity values were determined by DSC analysis. Melting temperatures and enthalpies of DTA and DOA were measured as 44 and 60 C respectively; and 142.4 and 186.2 Jg-1 respectively. Total enthalpy calculation showed the latent heat storage capacity along with sensible heat capacity of fatty alcohols and long-chain diesters between 0 and 80 C. Cp values of fatty alcohols and long-chain diesters also calculated for solid and liquid phase separately. TGA analysis was performed to determine thermal stability of the esters. DTA and DOA compounds were found stable up to 248.3 and 342.5 C respectively. Thermal cycling test was applied to the materials and it was found that DTA and DOA are both found stable after 1000 times accelerated thermal cyclings. According to the results obtained, DTA and DOA with high energy storage capacity are promising to be used as new solid-liquid PCMs in thermal energy storage applications for medium temperature applications.

References

  • [1] Mao Q., Chen H., Zhao Y., and Wu H. A novel heat transfer model of a phase change material using in solar power plant. Appl. Therm. Eng,. 129 (2018) 557–563.
  • [2] Tao Y. B. and He Y. L. A review of phase change material and performance enhancement method for latent heat storage system. Renew. Sustain. Energy Rev., 93 (2018) 245–259.
  • [3] Rezaie A. B. and Montazer M. One-step fabrication of fatty acids/nano copper/polyester shape-stable composite phase change material for thermal energy management and storage. Appl. Energy., 228 (2018) 1911–1920.
  • [4] Zhang P., Meng Z. N., Zhu H., Wang Y. L., and Peng S. P. Melting heat transfer characteristics of a composite phase change material fabricated by paraffin and metal foam. Appl. Energy., 185 (2017) 1971–1983.
  • [5] Lin Y., Jia Y., Alva G., and Fang G. Review on thermal conductivity enhancement, thermal properties and applications of phase change materials in thermal energy storage, Renew. Sustain. Energy Rev., 82 (2018) 2730–2742.
  • [6] Behzadi S. and Farid M. M. Long term thermal stability of organic PCMs. Appl. Energy, 122 (2014) 11–16.
  • [7] Zalba B., Marı́n J. M., Cabeza L. F., and Mehling H. Review on thermal energy storage with phase change: materials, heat transfer analysis and applications. Appl. Therm. Eng., 23 (2003) 251–283.
  • [8] Sharma A., Tyagi V. V., Chen C. R., and Buddhi D. Review on thermal energy storage with phase change materials and applications. Renew. Sustain. Energy Rev., 13 (2009) 318–345.
  • [9] Parameshwaran R., Kalaiselvam S., Harikrishnan S., and Elayaperumal A. Sustainable thermal energy storage technologies for buildings: A review. Renew. Sustain. Energy Rev., 16 (2012) 2394–2433.
  • [10] Sarı A., Bicer A., Karaipekli A., and Al-Sulaiman F.A. Preparation, characterization and thermal regulation performance of cement based-composite phase change material. Sol. Energy Mater. Sol. Cells., 174 (2018) 523–529.
  • [11] Yuan Y., Cao X., Xiang B., and Du Y. Effect of installation angle of fins on melting characteristics of annular unit for latent heat thermal energy storage. Sol. Energy., 136 (2016) 365–378.
  • [12] Zeinelabdein R., Omer S., and Gan G. Critical review of latent heat storage systems for free cooling in buildings. Renew. Sustain. Energy Rev., 82 (2018) 2843–2868.
  • [13] Liu M., Steven Tay N. H., Bell S., Belusko M., Jacob R., Will G., Saman W., and Bruno F. Review on concentrating solar power plants and new developments in high temperature thermal energy storage Technologies. Renew. Sustain. Energy Rev., 53 (2016) 1411–1432.
  • [14] Pardo P., Deydier A., Anxionnaz-Minvielle Z., Rougé S., Cabassud M., and Cognet P. A review on high temperature thermochemical heat energy storage. Renew. Sustain. Energy Rev., 32 (2014) 591–610.
  • [15] Fernandez A. I., Martínez M., Segarra M., Martorell I., Cabeza L. F. Selection of materials with potential in sensible thermal energy storage. Sol. Energy Mater. Sol. Cells., 94 (2010) 1723–1729.
  • [16] Kenisarin M. and Mahkamov K. Salt hydrates as latent heat storage materials:Thermophysical properties and costs. Sol. Energy Mater. Sol. Cells., 145 (2016) 255–286.
  • [17] Wang Q., Wang J., Chen Y., and Zhao C.Y. Experimental investigation of barium hydroxide octahydrate as latent heat storage materials. Sol. Energy., 177 (2019) 99–107.
  • [18] Baetens R., Jelle B.P., and Gustavsen A. Phase change materials for building applications: A state-of-the-art review. Energy Build., 42 (2010) 1361–1368.
  • [19] Zhou D., Zhao C.Y., and Tian Y. Review on thermal energy storage with phase change materials (PCMs) in building applications. Appl. Energy., 92 (2012) 593–605.
  • [20] Kahraman Döğüşcü D., Kızıl Ç., Biçer A., Sarı A., and Alkan C. Microencapsulated n-alkane eutectics in polystyrene for solar thermal applications. Sol. Energy., 160 (2018) 32-42.
  • [21] Alkan C., Sarı A., and Karaipekli A. Preparation, thermal properties and thermal reliability of microencapsulated n-eicosane as novel phase change material for thermal energy storage. Energy Convers. Manag., 52 (2011) 687–692.
  • [22] Alkan C. and Sari A. Fatty acid/poly(methyl methacrylate) (PMMA) blends as form-stable phase change materials for latent heat thermal energy storage. Sol. Energy., 82 (2008) 118–124.
  • [23] Zuo J., Li W., and Weng L. Thermal performance of caprylic acid/1-dodecanol eutectic mixture as phase change material (PCM). Energy Build., 43 (2011) 207–210.
  • [24] Cheng F., Wen R., Zhang X., Huang Z. Huang Y., Fang M., Liu Y., Wu X., and Min X., Synthesis and characterization of beeswax-tetradecanol-carbon fiber/expanded perlite form-stable composite phase change material for solar energy storage. Compos. Part A Appl. Sci. Manuf., 107 (2018) 180–188.
  • [25] Wang Y., Liu Z., Zhang T., and Zhang Z. Preparation and Characterization of Graphene Oxide-Grafted Hexadecanol Composite Phase-Change Material for Thermal Energy Storage. Energy Technol., 5 (2017) 2005–2014.
  • [26] Lv P., Ding M., Liu C., and Rao Z. Experimental investigation on thermal properties and thermal performance enhancement of octadecanol/expanded perlite form stable phase change materials for efficient thermal energy storage. Renew. Energy., 131 (2019) 911–922.
  • [27] Ma G., Sun J., Zhang Y., Jing Y., and Jia Y. Preparation and thermal properties of stearic acid-benzamide eutectic mixture/expanded graphite composites as phase change materials for thermal energy storage. Powder Technol., 342 (2019) 131–140.
  • [28] Hou P., Mao J., Chen F., Li Y., Dong X., Hou P., Mao J., Chen F., Li Y., and Dong X. Preparation and Thermal Performance Enhancement of Low Temperature Eutectic Composite Phase Change Materials Based on Na2SO4·10H2O. Materials, 11 (2018) 2230.
  • [29] Sarı A., Alkan C., Döğüşcü D.K., and Kızıl Ç. Micro/nano encapsulated n-tetracosane and n-octadecane eutectic mixture with polystyrene shell for low-temperature latent heat thermal energy storage applications. Sol. Energy., 115 (2015) 195–203.
  • [30] Döğüşcü D.K., Altıntaş A., Sarı A., and Alkan C. Polystyrene microcapsules with palmitic-capric acid eutectic mixture as building thermal energy storage materials. Energy Build., 150 (2017) 376-382.
  • [31] Stamatiou A., Obermeyer M., Fischer L.J., Schuetz P., and Worlitschek J. Investigation of unbranched, saturated, carboxylic esters as phase change materials. Renew. Energy., 108 (2017) 401–409.
  • [32] Pielichowski K. and Flejtuch K. Differential scanning calorimetry studies on poly(ethylene glycol) with different molecular weights for thermal energy storage materials. Polym. Adv. Technol., 13 (2002) 690–696.
  • [33] Baykut F., Aydın A. The synthesis and physical properties of the homologous series of fatty acids’ esters. Reveu La Fac. Des Sci. L’Universite D’Istanbul Ser. C., (1969) 119–148.
  • [34] Parameshwaran R., Jayavel R., and Kalaiselvam S. Study on thermal properties of organic ester phase-change material embedded with silver nanoparticles. J. Therm. Anal. Calorim., 114 (2013) 845–858.
  • [35] Wi S., Seo J., Jeong S. G., Chang S. J., Kang Y., and Kim S. Thermal properties of shape-stabilized phase change materials using fatty acid ester and exfoliated graphite nanoplatelets for saving energy in buildings. Sol. Energy Mater. Sol. Cells., 143 (2015) 168–173.
  • [36] Aydın A.A. Fatty acid ester-based commercial products as potential new phase change materials (PCMs) for thermal energy storage. Sol. Energy Mater. Sol. Cells., 108 (2013) 98–104.
  • [37] Feldman D., Banu D., Hawes D., and Ghanbari E. Obtaining an energy storing building material by direct incorporation of an organic phase change material in gypsum wallboard. Sol. Energy Mater. Sol. Cells., 22 (1991) 231–242.
  • [38] Feldman D., Banu D., and Hawes D. Low chain esters of stearic acid as phase change materials for thermal energy storage in buildings. Sol. Energy Mater. Sol. Cells., 36 (1995) 311–322.
  • [39] Sarı A., Biçer A., Karaipekli A., Alkan C., and Karadag A. Synthesis, thermal energy storage properties and thermal reliability of some fatty acid esters with glycerol as novel solid–liquid phase change materials. Sol. Energy Mater. Sol. Cells., 94 (2010) 1711–1715.
  • [40] Sarı A., Biçer A., and Karaipekli A. Synthesis, characterization, thermal properties of a series of stearic acid esters as novel solid–liquid phase change materials. Mater. Lett., 63 (2009) 1213–1216.
  • [41] Sarı A. and Biçer A. Thermal energy storage properties and thermal reliability of some fatty acid esters/building material composites as novel form-stable PCMs. Sol. Energy Mater. Sol. Cells., 101 (2012) 114–122.
  • [42] Sarı A. and Karaipekli A. Fatty acid esters-based composite phase change materials for thermal energy storage in buildings. Appl. Therm. Eng., 37 (2012) 208–216.
  • [43] Kahraman Döğüşcü D. Tetradecyl oxalate and octadecyl oxalate as novel phase change materials for thermal energy storage. Sol. Energy., 185 (2019) 341–349.
  • [44] Kahraman Döğüşcü D. Synthesis and characterization of ditetradecyl succinate and dioctadecyl succinate as novel phase change materials for thermal energy storage. Sol. Energy Mater. Sol. Cells., 200 (2019) 110006.
  • [45] Aydın A.A., and Okutan H. Polyurethane rigid foam composites incorporated with fatty acid ester-based phase change material. Energy Convers. Manag., 68 (2013) 74–81.
  • [46] Aydın A.A. In situ preparation and characterization of encapsulated high-chain fatty acid ester-based phase change material (PCM) in poly(urethane-urea) by using amino alcohol. Chem. Eng. J., 231 (2013) 477–483.
  • [47] Alkan C., Gunther E., Hiebler S., Ensari O.F., and Kahraman D. Polyurethanes as solid–solid phase change materials for thermal energy storage. Sol. Energy., 86(6) (2012) 1761-1769.
  • [48] Alkan C., Günther E., Hiebler S., and Himpel M. Complexing blends of polyacrylic acid-polyethylene glycol and poly(ethylene-co-acrylic acid)-polyethylene glycol as shape stabilized phase change materials. Energy Convers. Manag., 64 (2012) 364–370.
  • [49] Mehling H., Günther E. Hiebler S., Cabeza L.F., and Castellón C., A New Measurement and Evaluation Method For DSC of PCM Samples, In: Proceedings of Effstock -11th International Conference on Energy Storage. Stockholm, Sweden (2009).
  • [50] Nikolić R., Marinović-Cincović M. Gadžurić S., and Zsigrai I., New materials for solar thermal storage—solid/liquid transitions in fatty acid esters. Sol. Energy Mater. Sol. Cells., 79 (2003) 285–292.
  • [51] Aydın A.A. and Okutan H. High-chain fatty acid esters of myristyl alcohol with even carbon number: Novel organic phase change materials for thermal energy storage-1. Sol. Energy Mater. Sol. Cells., 95 (2011) 2752–2762.
There are 51 citations in total.

Details

Primary Language English
Journal Section Natural Sciences
Authors

Derya Kahraman Döğüşcü 0000-0002-6181-5778

Publication Date March 22, 2020
Submission Date January 2, 2020
Acceptance Date January 31, 2020
Published in Issue Year 2020

Cite

APA Kahraman Döğüşcü, D. (2020). Long-chain diesters of fattyy alcohols as novel phase change materials for thermal energy storage. Cumhuriyet Science Journal, 41(1), 269-280. https://doi.org/10.17776/csj.669208