Thermally enhanced nanocomposite phase change material slurry for solar-thermal energy storage
Thermally enhanced nanocomposite phase change material slurry for solar-thermal energy storage
This paper investigates the photothermal conversion performance of an innovative heat transfer fluid containing nano-encapsulated phase change material (PCM) with metallic shell materials in a solar thermal energy storage system. The influences of shell thickness, core size, shell material type, PCM mass and shell volume concentrations on the thermal performance of the heat storage medium are investigated and compared. The results show that the heat transfer rates of water-based Ag, Au, Cu and Al nanofluids are 6.89, 5.86, 7.05 and 6.99 W, respectively, while slurries formed by adding paraffin@Ag, Au, Cu and Al nano capsules to pure water enhance heat transfer by 6.18, 13.38, 10.8 and 11.33 %, respectively. The metallic nanoparticle-based shell materials further augment the temperature and energy storage gains by enhancing the solar radiation capture capability of the heat storage medium. Specifically, depending on the mass concentration of PCM, the storage capacity of paraffin@Cu slurry is augmented by up to 290 %. As the shell thickness of the Ag particles also decreases from 8 to 2 nm, it augments the slurry's storage ability for thermal energy by 7 %. The enhancement in the dimensions of the nano capsules, however, causes the surface area-to-volume ratio (SA:V) to reduce the photothermal conversion of the slurry by clustering. Therefore, the thermal energy storage behaviour of the Paraffin@Cu slurry is diminished by 5 % as the core size enhances from 10 to 40 nm. Further, the augmentation in the volume concentration of Al particles in the shell surprisingly reduces the thermal energy storage by 5 %. Finally, paraffin-based solid PCM is also experimentally tested for validation of the specific heat capacity model at various wind speeds and solar radiation.
Kazaz, Oguzhan
d7ffc7eb-cb32-4cf9-a130-03499b6f6bab
Karimi, Nader
620646d6-27c9-4e1e-948f-f23e4a1e773a
Kumar, Shanmugam
c3d461c7-96cb-437d-8f05-0e7334c8fcb6
Falcone, Gioia
827fedaf-6117-4d73-a1a0-430c98acbe1f
Paul, Manosh C.
fbb523c5-ff1d-4609-8327-0175d3c9e5b3
1 February 2024
Kazaz, Oguzhan
d7ffc7eb-cb32-4cf9-a130-03499b6f6bab
Karimi, Nader
620646d6-27c9-4e1e-948f-f23e4a1e773a
Kumar, Shanmugam
c3d461c7-96cb-437d-8f05-0e7334c8fcb6
Falcone, Gioia
827fedaf-6117-4d73-a1a0-430c98acbe1f
Paul, Manosh C.
fbb523c5-ff1d-4609-8327-0175d3c9e5b3
Kazaz, Oguzhan, Karimi, Nader, Kumar, Shanmugam, Falcone, Gioia and Paul, Manosh C.
(2024)
Thermally enhanced nanocomposite phase change material slurry for solar-thermal energy storage.
Journal of Energy Storage, 78, [110110].
(doi:10.1016/j.est.2023.110110).
Abstract
This paper investigates the photothermal conversion performance of an innovative heat transfer fluid containing nano-encapsulated phase change material (PCM) with metallic shell materials in a solar thermal energy storage system. The influences of shell thickness, core size, shell material type, PCM mass and shell volume concentrations on the thermal performance of the heat storage medium are investigated and compared. The results show that the heat transfer rates of water-based Ag, Au, Cu and Al nanofluids are 6.89, 5.86, 7.05 and 6.99 W, respectively, while slurries formed by adding paraffin@Ag, Au, Cu and Al nano capsules to pure water enhance heat transfer by 6.18, 13.38, 10.8 and 11.33 %, respectively. The metallic nanoparticle-based shell materials further augment the temperature and energy storage gains by enhancing the solar radiation capture capability of the heat storage medium. Specifically, depending on the mass concentration of PCM, the storage capacity of paraffin@Cu slurry is augmented by up to 290 %. As the shell thickness of the Ag particles also decreases from 8 to 2 nm, it augments the slurry's storage ability for thermal energy by 7 %. The enhancement in the dimensions of the nano capsules, however, causes the surface area-to-volume ratio (SA:V) to reduce the photothermal conversion of the slurry by clustering. Therefore, the thermal energy storage behaviour of the Paraffin@Cu slurry is diminished by 5 % as the core size enhances from 10 to 40 nm. Further, the augmentation in the volume concentration of Al particles in the shell surprisingly reduces the thermal energy storage by 5 %. Finally, paraffin-based solid PCM is also experimentally tested for validation of the specific heat capacity model at various wind speeds and solar radiation.
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Accepted/In Press date: 11 February 2023
e-pub ahead of print date: 8 January 2024
Published date: 1 February 2024
Identifiers
Local EPrints ID: 509354
URI: http://eprints.soton.ac.uk/id/eprint/509354
ISSN: 2352-152X
PURE UUID: 076b9f80-9b4b-40d8-be06-f37ff4660cb9
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Date deposited: 19 Feb 2026 17:41
Last modified: 20 Feb 2026 03:13
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Contributors
Author:
Oguzhan Kazaz
Author:
Nader Karimi
Author:
Shanmugam Kumar
Author:
Gioia Falcone
Author:
Manosh C. Paul
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