3D structure fungi-derived carbon stabilized stearic acid as a composite phase change material for thermal energy storage
Stearic acid (SA)/fungi-derived carbon (FDC) composite phase change materials (PCM) were fabricated by vacuum impregnation, where three types of FDC (FDC-C, FDC-H, and FDC-K) as carrier were synthesized by diverse synthetic procedures of carbonization. The FDC-K modified by synergistic hydrothermal...
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sg-ntu-dr.10356-1470102021-03-17T06:47:15Z 3D structure fungi-derived carbon stabilized stearic acid as a composite phase change material for thermal energy storage Li, Chuanchang Xie, Baoshan He, Zhangxing Chen, Jian Long, Yi School of Materials Science and Engineering Engineering::Materials Phase Change Materials Thermal Energy Storage Stearic acid (SA)/fungi-derived carbon (FDC) composite phase change materials (PCM) were fabricated by vacuum impregnation, where three types of FDC (FDC-C, FDC-H, and FDC-K) as carrier were synthesized by diverse synthetic procedures of carbonization. The FDC-K modified by synergistic hydrothermal and KOH-assisted calcination process had a 3D-cellular structure with considerably higher inner surface area (1799.48 m2 g−1) and cumulative pore volume (0.7476 cm3 g−1) than other matrixes, leading to that a loading capability value of SA (LC, %) in SA/FDC-K composite was up to 344.64%. X-ray diffraction and Fourier transform infrared spectroscopy shown that physical interaction instead of chemical reaction happened between FDC and SA. X-ray photoelectron spectroscopy indicated that KOH-assisted calcination treatment improved oxygenic functional groups on matrix surface so that facilitating SA loading. Raman spectra illustrated the IG/ID value of three amorphous carbons were ∼1.04. For SA/FDC-K composite, it had a melting and freezing enthalpy of 144.8 J g−1 and 142.6 J g−1, respectively, and phase transition point of 52.72 °C and 52.95 °C, respectively. The thermal conductivity (0.574 W m−1 K−1) was 115% higher than pure SA. It was also stable in terms of thermal and chemical after thermal cycles in heating and cooling. Thus, the SA/FDC-K exhibited high phase transition enthalpy and excellent thermal stability has potential application in thermal energy storage. This work was supported by the National Natural Science Foundation of China (51874047, 51504041); the Training Program for Excellent Young Innovators of Changsha (kq1802007); the Fund for University Young Core Instructors of Hunan Province; the Natural Science Foundation of Hunan Province (2016JJ3009); and the Hunan Province 2011 Collaborative Innovation Center of Clean Energy and Smart Grid. 2021-03-17T06:47:15Z 2021-03-17T06:47:15Z 2019 Journal Article Li, C., Xie, B., He, Z., Chen, J. & Long, Y. (2019). 3D structure fungi-derived carbon stabilized stearic acid as a composite phase change material for thermal energy storage. Renewable Energy, 140, 862-873. https://dx.doi.org/10.1016/j.renene.2019.03.121 0960-1481 0000-0001-5915-1119 https://hdl.handle.net/10356/147010 10.1016/j.renene.2019.03.121 2-s2.0-85063986436 140 862 873 en Renewable Energy © 2019 Elsevier Ltd. All rights reserved. |
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Engineering::Materials Phase Change Materials Thermal Energy Storage Li, Chuanchang Xie, Baoshan He, Zhangxing Chen, Jian Long, Yi 3D structure fungi-derived carbon stabilized stearic acid as a composite phase change material for thermal energy storage |
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Stearic acid (SA)/fungi-derived carbon (FDC) composite phase change materials (PCM) were fabricated by vacuum impregnation, where three types of FDC (FDC-C, FDC-H, and FDC-K) as carrier were synthesized by diverse synthetic procedures of carbonization. The FDC-K modified by synergistic hydrothermal and KOH-assisted calcination process had a 3D-cellular structure with considerably higher inner surface area (1799.48 m2 g−1) and cumulative pore volume (0.7476 cm3 g−1) than other matrixes, leading to that a loading capability value of SA (LC, %) in SA/FDC-K composite was up to 344.64%. X-ray diffraction and Fourier transform infrared spectroscopy shown that physical interaction instead of chemical reaction happened between FDC and SA. X-ray photoelectron spectroscopy indicated that KOH-assisted calcination treatment improved oxygenic functional groups on matrix surface so that facilitating SA loading. Raman spectra illustrated the IG/ID value of three amorphous carbons were ∼1.04. For SA/FDC-K composite, it had a melting and freezing enthalpy of 144.8 J g−1 and 142.6 J g−1, respectively, and phase transition point of 52.72 °C and 52.95 °C, respectively. The thermal conductivity (0.574 W m−1 K−1) was 115% higher than pure SA. It was also stable in terms of thermal and chemical after thermal cycles in heating and cooling. Thus, the SA/FDC-K exhibited high phase transition enthalpy and excellent thermal stability has potential application in thermal energy storage. |
| author2 |
School of Materials Science and Engineering |
| author_facet |
School of Materials Science and Engineering Li, Chuanchang Xie, Baoshan He, Zhangxing Chen, Jian Long, Yi |
| format |
Article |
| author |
Li, Chuanchang Xie, Baoshan He, Zhangxing Chen, Jian Long, Yi |
| author_sort |
Li, Chuanchang |
| title |
3D structure fungi-derived carbon stabilized stearic acid as a composite phase change material for thermal energy storage |
| title_short |
3D structure fungi-derived carbon stabilized stearic acid as a composite phase change material for thermal energy storage |
| title_full |
3D structure fungi-derived carbon stabilized stearic acid as a composite phase change material for thermal energy storage |
| title_fullStr |
3D structure fungi-derived carbon stabilized stearic acid as a composite phase change material for thermal energy storage |
| title_full_unstemmed |
3D structure fungi-derived carbon stabilized stearic acid as a composite phase change material for thermal energy storage |
| title_sort |
3d structure fungi-derived carbon stabilized stearic acid as a composite phase change material for thermal energy storage |
| publishDate |
2021 |
| url |
https://hdl.handle.net/10356/147010 |
| _version_ |
1695706237656629248 |