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W4313254976 endingPage "120549" @default.
W4313254976 startingPage "120549" @default.
W4313254976 abstract "2D MXene nanohybrid is a next-generation energy-storage material. Here, we demonstrate a novel thermochemical heat storage material using magnesium sulfate heptahydrate/titanium carbide and MXene (MgSO4/Ti3C2Tx) with improved hydration/dehydration enthalpy, superior thermal conductivity, good cyclic ability, maximum water sorption performance, and larger thermal energy conversion. The TG-DSC fitted with a Wetsys flow humidity generator shows outstanding thermal performance and larger hydration for MgSO4/Ti3C2Tx (1963 J/g) and dehydration (1861 J/g) enthalpies with 5 % fluctuation as compared to pure MgSO4 (38 %). The cyclicability results showed that MgSO4/MXene has good stability of TCMs across several charging/discharging cycles (up to 20 cycles), confirming that the MXene matrix avoids hydrated salt agglomeration and displays an average of 12 % fluctuation. This illustrates that prepared composites potentially improve storage performance. The MgSO4/Ti3C2Tx nanohybrid exhibit a better radiation absorption and 45 % longer backup than the pristine MgSO4 salt. TEM study revealed that maximum salt contents can be located in the interlayer gaps, predicted sheets thickness of the MgSO4/MXene layer to be 16 Å and the Ti3C2Tx layers to be 7.3 Å. Nanohybrid has stronger water sorption than MgSO4 due to MXene nanosheets larger interlayer gaps. The results conclude that the resultant MgSO4/MXene has excellent long-term thermal energy storage, photo-to-thermal conversion and larger water sorption performance. The study validates the effectiveness of nanohybrid material as a promising candidate for thermochemical heat storage applications and set to pave the way to explore other hybrid systems to improve the efficiency of thermochemical energy storage systems." @default.
W4313254976 created "2023-01-06" @default.
W4313254976 creator A5003791663 @default.
W4313254976 creator A5008317658 @default.
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W4313254976 creator A5040048786 @default.
W4313254976 creator A5055426495 @default.
W4313254976 creator A5089226546 @default.
W4313254976 creator A5089682316 @default.
W4313254976 creator A5091681177 @default.
W4313254976 date "2023-02-01" @default.
W4313254976 modified "2023-09-25" @default.
W4313254976 title "Nanoengineering of MgSO4 nanohybrid on MXene substrate for efficient thermochemical heat storage material" @default.
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W4313254976 doi "https://doi.org/10.1016/j.apenergy.2022.120549" @default.
W4313254976 hasPublicationYear "2023" @default.
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