22 results on '"Humphries, Terry D."'
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2. High-temperature thermochemical energy storage using metal hydrides: Destabilisation of calcium hydride with silicon
- Author
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Griffond, Arnaud C.M., Sofianos, M. Veronica, Sheppard, Drew A., Humphries, Terry D., Sargent, Anna-Lisa, Dornheim, Martin, Aguey-Zinsou, Kondo-Francois, and Buckley, Craig E.
- Published
- 2021
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3. Exploring halide destabilised calcium hydride as a high-temperature thermal battery
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Sofianos, M. Veronica, Randall, Samuel, Paskevicius, Mark, Aguey-Zinsou, Kondo-Francois, Rowles, Matthew R., Humphries, Terry D., and Buckley, Craig E.
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- 2020
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4. Hydrogen storage properties of eutectic metal borohydrides melt-infiltrated into porous Al scaffolds
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Sofianos, M. Veronica, Chaudhary, Anna-Lisa, Paskevicius, Mark, Sheppard, Drew A., Humphries, Terry D., Dornheim, Martin, and Buckley, Craig E.
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- 2019
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5. Regeneration of LiAlH4 at sub-ambient temperatures studied by multinuclear NMR spectroscopy
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Humphries, Terry D., Birkmire, Derek, McGrady, G. Sean, Hauback, Bjørn C., and Jensen, Craig M.
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- 2017
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6. Recent advances in the 18-electron complex transition metal hydrides of Ni, Fe, Co and Ru
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Humphries, Terry D., Sheppard, Drew A., and Buckley, Craig E.
- Published
- 2017
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7. Thermodynamic and kinetic properties of calcium hydride.
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Balakrishnan, Sruthy, Humphries, Terry D., Paskevicius, Mark, and Buckley, Craig E.
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THERMODYNAMICS , *HYDRIDES , *LITERATURE reviews , *HYDROGEN as fuel , *MELTING points , *ACTIVATION energy , *SOLID-liquid equilibrium - Abstract
Calcium hydride has shown great potential as a hydrogen storage material and as a thermochemical energy storage material. To date, its high operating temperature (above 800 °C) has not only hindered its opportunity for technological application but also prevented detailed determination of its thermodynamics of hydrogen sorption. In addition, calcium metal suffers from high volatility, high corrosivity from Ca (and CaH 2), slow kinetics of hydrogen sorption, and the solubility of Ca in CaH 2. In this work, a literature review of the wide-ranging thermodynamic properties of CaH 2 is provided along with a detailed experimental investigation into the thermodynamic properties of molten and solid CaH 2. The thermodynamic values of hydrogen release from both molten and solid CaH 2 were determined as Δ H des (molten CaH 2) = 216 ± 10 kJ mol−1.H 2 , Δ S des (molten CaH 2) = 177 ± 9 J K−1 mol−1.H 2, which equates to a 1 bar hydrogen equilibrium temperature for molten CaH 2 of 947 ± 65 °C. Similarly, in the solid-state: Δ H des (solid CaH 2) = 172 ± 12 kJ mol−1.H 2 , Δ S des (solid CaH 2) = 144 ± 10 J K−1 mol−1.H 2. Moreover, the activation energy of hydrogen release from CaH 2 was also calculated using DSC analysis as E a = 203 ± 12 kJ mol−1. This study provides the first thermodynamics for the Ca–H system in over 60 years, providing more accurate data on this emerging energy storage material. • The thermodynamics for hydrogen desorption of calcium hydride were determined. • This is the first study in over 60 years to determine the thermal properties. • The kinetics of hydrogen release were measured using the Kissinger method. • The melting point of CaH 2 was measured under a hydrogen atmosphere. • A literature review of previous thermodynamic studies on CaH 2 is included. [ABSTRACT FROM AUTHOR]
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- 2023
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8. Complex transition metal hydrides incorporating ionic hydrogen: Synthesis and characterization of Na2Mg2FeH8 and Na2Mg2RuH8
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Humphries, Terry D., Takagi, Shigeyuki, Li, Guanqiao, Matsuo, Motoaki, Sato, Toyoto, Sørby, Magnus H., Deledda, Stefano, Hauback, Bjørn C., and Orimo, Shin-ichi
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- 2015
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9. A structural study of bis-(trimethylamine)alane, AlH 3·2NMe 3, by variable temperature X-ray crystallography and DFT calculations
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Humphries, Terry D., Sirsch, Peter, Decken, Andreas, and Sean McGrady, G.
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- 2009
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10. An operational high temperature thermal energy storage system using magnesium iron hydride.
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Poupin, Lucas, Humphries, Terry D., Paskevicius, Mark, and Buckley, Craig E.
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HEAT storage , *ENERGY storage , *MAGNESIUM hydride , *HEAT transfer fluids , *HIGH temperatures , *THERMAL batteries , *HYDRIDES - Abstract
Metal hydrides have been demonstrated as energy storage materials for thermal battery applications. This is due to the high energy density associated with the reversible thermochemical reaction between metals and hydrogen. Magnesium iron hydride (Mg 2 FeH 6) is one such material that has been identified as a thermal energy storage material due to its reversible hydrogenation reaction at temperatures between 400 and 600 °C. This study demonstates an automated thermal battery prototype containing 900 g of Mg 2 FeH 6 as the thermal energy storage material with pressurised water acting as the heat transfer fluid to charge and discharge the battery. The operating conditions of the system were optimised by assessing the ideal operating temperature, flow rate of the heat transfer fluid, and hydrogen pressures. Overall, excellent cyclic energy storage reversibility was demonstrated between 410 and 450 °C with a maximum energy capacity of 1650 kJ which is 87% of the theoretical value (1890 kJ). [Display omitted] • A prototype thermal battery was developed using Mg 2 FeH 6 as the thermal energy storage material. • The automated battery consisted of a heat transfer fluid system to charge and discharge the material. • Complete optimisation of the operating conditions of the system was established. • Excellent cycle reversibility was demonstrated between 410 and 450 °C. [ABSTRACT FROM AUTHOR]
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- 2021
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11. Regeneration of LiAlH4 at sub-ambient temperatures studied by multinuclear NMR spectroscopy.
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Hauback, Bjørn C., Humphries, Terry D., Birkmire, Derek, Jensen, Craig M., and McGrady, G. Sean
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LITHIUM aluminum hydride , *HYDROGENATION , *CHEMICAL synthesis , *LITHIUM compounds , *NUCLEAR magnetic resonance spectroscopy , *SOLVENTS , *DIMETHYL sulfate , *HYDROGEN storage - Abstract
Lithium aluminium hydride (LiAlH 4 ) has long been identified as a viable hydrogen storage material, due to its high attainable theoretical gravimetric hydrogen capacity of 7.9 wt%. The main impediment to its viability for technical application is its limitation for regeneration. Recently, solvent-mediated regeneration has been achieved at room temperature using dimethyl-ether, Me 2 O, although the reaction pathway has not been determined. This in situ multinuclear NMR spectroscopy study ( 27 Al and 7 Li) has confirmed that the Me 2 O-mediated, direct synthesis of LiAlH 4 occurs by a one-step process in which LiAlH 4 · x Me 2 O is formed, and does not involve Li 3 AlH 6 or any other intermediates. Hydrogenation has been shown to occur below ambient temperatures (at 0 °C) for the first time, and the importance of solvate adducts formed during the process is demonstrated. [ABSTRACT FROM AUTHOR]
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- 2017
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12. NMR spectroscopic and thermodynamic studies of the etherate and the α, α′, and γ phases of AlH3
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Humphries, Terry D., Munroe, Keelie T., DeWinter, Tamara M., Jensen, Craig M., and McGrady, G. Sean
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NUCLEAR magnetic resonance spectroscopy , *THERMODYNAMICS , *ALUMINUM hydride , *HYDROGEN as fuel , *ENERGY storage , *HYDROGEN production , *CHEMICAL decomposition , *CHEMICAL reactions - Abstract
Abstract: Aluminum hydride (alane; AlH3) has been identified as a leading hydrogen storage material by the US Department of Energy. With a high gravimetric hydrogen capacity of 10.1 wt.%, and a hydrogen density of 1.48 g/cm3, AlH3 decomposes cleanly to its elements above 60 °C with no side reactions. This study explores in detail the thermodynamic and spectroscopic properties of AlH3; in particular the α, α′ and γ polymorphs, of which α′-AlH3 is reported for the first time, free from traces of other polymorphs or side products. Thermal analysis of α-, α′-, and γ-AlH3 has been conducted, using DSC and TGA methods, and the results obtained compared with each other and with literature data. All three polymorphs were investigated by 1H MAS-NMR spectroscopy for the first time, and their 27Al MAS-NMR spectra were also measured and compared with literature values. AlH3·nEt2O has also been studied by 1H and 27Al MAS-NMR spectroscopy and DSC and TGA methods, and an accurate decomposition pathway has been established for this adduct. [Copyright &y& Elsevier]
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- 2013
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13. A structural study of bis-(trimethylamine)alane, AlH3·2NMe3, by variable temperature X-ray crystallography and DFT calculations
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Humphries, Terry D., Sirsch, Peter, Decken, Andreas, and Sean McGrady, G.
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MOLECULAR structure , *X-ray crystallography , *DENSITY functionals , *NUCLEAR magnetic resonance spectroscopy , *METHYL groups , *HYDRIDES - Abstract
Abstract: The structure of AlH3·2NMe3 has been investigated by single-crystal X-ray diffraction over the range of 296–173K. Over this temperature range a phase change is observed from Cmca to Pbcm where the methyl groups convert from a statistically disordered conformation to adopt a mutually eclipsed conformation at lower temperatures. Measurement of the unit cell dimensions shows a decrease in the lengths of the a and b axes, and an increase in that of the c axis as the temperature is lowered, with inflections apparent between 223 and 233K in the region of the phase change. Low-temperature DSC measurements reveal the change from Pbcm to Cmca to occur at 218.3K, with an enthalpy of 107.7Jmol−1. The molecular structure of AlH3·2NMe3 is compared with those of related amine adducts of Group 13 hydrides, either measured experimentally or calculated using DFT methods. 1H, 13C and 27Al NMR spectroscopy has also been utilized to characterize AlH3·2NMe3 and its 1:1 counterpart AlH3·NMe3. [Copyright &y& Elsevier]
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- 2009
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14. Simultaneous preparation of sodium borohydride and ammonia gas by ball milling.
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Liu, Yu, Paskevicius, Mark, Humphries, Terry D., and Buckley, Craig E.
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SODIUM borohydride , *AMMONIA gas , *BALL mills , *LITHIUM borohydride , *HYDROGEN storage , *POTENTIAL energy , *WATER temperature - Abstract
Hydrogen and ammonia are both potential energy carriers being considered for large scale energy transport. Sodium borohydride (NaBH 4) has been widely applied as a potential solid-state hydrogen storage material. It can produce hydrogen gas and sodium metaborate (NaBO 2) after hydrolysis with water at room temperature. The regeneration of NaBH 4 from NaBO 2 could significantly reduce the cost of NaBH 4 and enable its wide-spread industrial use. In this work, we demonstrate a simple method for regenerating NaBH 4 from NaBO 2 ·4H 2 O using Mg 2 N 3 , which combines NaBH 4 production with NH 3 gas production in a single step at room temperature. NaBH 4 is successfully synthesized from NaBO 2 ·4H 2 O using the Mg 3 N 2 reducing agent via ball milling under a hydrogen atmosphere. NaBH 4 is formed at a 76.6% yield by planetary ball milling at 600 rpm under 40 bar hydrogen for 12 h. NH 3 gas is also formed, which can be easily separated from the solid products. Therefore, this one-step process could produce two different types of carbon-free hydrogen carriers suitable for energy export from renewable sources. • One step process to store hydrogen in NaBH 4 and NH 3. • Lower cost for NaBH 4 regeneration. • Mg 3 N 2 can be considered as a promising reductant for simultaneous synthesis of NaBH 4 and NH 3. • The hydrogen pressure have a effect on the ball milling. [ABSTRACT FROM AUTHOR]
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- 2022
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15. Thermochemical energy storage in SrCO3 composites with SrTiO3 or SrZrO3.
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Williamson, Kyran, Liu, Yurong, Humphries, Terry D., D'Angelo, Anita M., Paskevicius, Mark, and Buckley, Craig E.
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HEAT storage , *ENERGY storage , *ENERGY density , *SOLAR energy , *CARBON dioxide , *THERMOGRAVIMETRY - Abstract
Thermochemical energy storage offers a cost-effective and efficient approach for storing thermal energy at high temperature (∼1100 °C) for concentrated solar power and large-scale long duration energy storage. SrCO 3 is a potential candidate as a thermal energy storage material due to its high energy density of 205 kJ/mol of CO 2 during reversible CO 2 release and absorption. However, it loses cyclic capacity rapidly due to sintering. This study determined that the cyclic capacity of SrCO 3 was enhanced by the addition of either reactive SrTiO 3 or inert SrZrO 3 , where the molar ratios of SrCO 3 to SrZrO 3 were varied from 1:0.125 to 1:1. Thermogravimetric analysis over 15 CO 2 sorption cycles demonstrated that both materials retained ∼80 % of their maximum cyclic capacity on the milligram scale. Repeated measurements using gram scale samples revealed a decrease in maximum capacity to 11 % using a sample of SrCO 3 – 0.5 SrZrO 3 over 53 cycles, while the use of SrTiO 3 additives allowed for the retention of 80 % maximum capacity over 55 cycles. These findings highlight the potential of reactive additives in enhancing the performance of thermochemical energy storage systems, while providing valuable insights for the development of cost-effective materials. [Display omitted] • SrCO 3 is a cost-effective thermochemical energy storage material. • TGA shows both SrZrO 3 and SrTiO 3 additives increase cyclic capacity up to ∼80 %. • SrTiO 3 reduces sintering whereas SrZrO 3 does not prevent sintering. [ABSTRACT FROM AUTHOR]
- Published
- 2024
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16. What is old is new again.
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Sheppard, Drew A., Humphries, Terry D., and Buckley, Craig E.
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HYDROGEN storage , *HYDRIDES , *FLUORINE , *HIGH temperatures , *HEAT storage - Published
- 2015
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17. Kinetic investigation and numerical modelling of CaCO3/Al2O3 reactor for high-temperature thermal energy storage application.
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Mathew, Arun, Nadim, Nima, Chandratilleke, Tilak. T., Paskevicius, Mark, Humphries, Terry D., and Buckley, Craig E.
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HEAT storage , *GEOTHERMAL reactors , *PEBBLE bed reactors , *CARBON dioxide , *ALUMINUM oxide , *CRYSTALLIZATION kinetics , *THERMAL conductivity , *BATTERY storage plants - Abstract
• Carbonation reaction kinetics of limestone-based CaCO 3 /Al 2 O 3 mixture is estimated. • Numerical modelling of CaCO 3 based reactor for thermal storage application is performed. • The influence of operating parameters on the reactor's performance is examined. • The effect of incorporating graphite fin into the CaCO 3 reactor is studied. This study conducts kinetic analyses of the carbonation reaction of CaCO 3 (doped with Al 2 O 3) as well as parametric analyses of the performance of a thermochemical reactor, which can act as a thermal battery. Kinetic measurements of CO 2 release and absorption were carried out using thermogravimetric analysis (TGA) at 815, 830 and 845 °C on a CaCO 3 /Al 2 O 3 sample that had been previously cycled over 500 times. The rapid reaction kinetics revealed that the Avrami nucleation growth model with exponent 3 fits well to explain the carbonation reaction. The numerical study considered a cylindrical reactor with a height and diameter of 100 mm. According to numerical analysis, at an applied CO 2 pressure of 1 bar, increasing the thermal conductivity of the reactor bed from 1.33 to 5 W/m.K increases the rate of carbonation reaction by 74%. When the applied CO 2 pressure is increased from 1 to 2 bar, the performance of the reactor bed with thermal conductivity of 1.33 W/m.K improves by 42%; however, when the applied CO 2 pressure is increased from 2 to 3 bar, the performance improves by only 18%. Additionally, when the boundary temperature of the reactor was lowered by 30 °C, performance was enhanced by 43% at an applied CO 2 pressure of 1 bar. This study also examined the effect of using a graphite fin as a heat extraction system. The graphite fin allowed for more rapid heat extraction and increased the carbonation reaction by 44% in the reactor bed with poor thermal conductivity (1.33 W/m.K) but had no effect in the reactor with modest thermal conductivity of (5 W/m.K) due to its ability to already transfer heat effectively to the reactor shell. [ABSTRACT FROM AUTHOR]
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- 2022
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18. Investigation of boiling heat transfer for improved performance of metal hydride thermal energy storage.
- Author
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Mathew, Arun, Nadim, Nima, Chandratilleke, Tilak T., Humphries, Terry D., and Buckley, Craig E.
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HEAT storage , *HYDRIDES , *HEAT transfer , *HEAT radiation & absorption , *MAGNESIUM hydride , *HEAT transfer fluids - Abstract
The inherent nature concerning the intermittency of concentrating solar power (CSP) plants can be overcome by the integration of efficient thermal energy storage (TES) systems. Current CSP plants employ molten salts as TES materials although metal hydrides (MH) have proven to be more efficient due to their increased operating temperatures. Nonetheless, the heat exchange between the MH bed and the heat transfer medium used to operate a heat engine is a critical factor in the overall efficiency of the TES system. In this work, a computational study is carried out to investigate the performance of a magnesium hydride TES packed bed using a multiphase (boiling) medium instead of single-phase heat absorption methods. The boiling heat transfer behaviour is simulated by using the Eulerian two-fluid framework. The simulations are conducted at a transient state using SST- k -ω Reynolds-Averaged Navier-Stokes equations. It is observed that, unlike the single-phase heat collection method, the multiphase heat absorption method maintains a constant temperature in the heat transfer fluid throughout the reactor. Consequently, a higher temperature gradient is realised between the MH bed and heat transfer fluid (HTF), leading to improvements in the overall reaction rate of the hydrogenation process. • Performance enhancement of a magnesium hydride reactor due to multiphase heat absorption was studied. • Boiling heat transfer behaviour was simulated using Eulerian two-fluid framework. • The percentage of improvement in reactor performance was variable at different reacted fractions. • Dry out condition was critical in the reactor efficiency. [ABSTRACT FROM AUTHOR]
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- 2021
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19. Performance analysis of a high-temperature magnesium hydride reactor tank with a helical coil heat exchanger for thermal storage.
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Mathew, Arun, Nadim, Nima, Chandratilleke, Tilak T., Humphries, Terry D., Paskevicius, Mark, and Buckley, Craig E.
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MAGNESIUM hydride , *HEAT storage , *HYDRIDES , *HEAT transfer fluids , *HEAT exchangers , *CHEMICAL kinetics - Abstract
Metal hydrides are regarded as one of the most attractive options for thermal energy storage (TES) materials for concentrated solar thermal applications. Improved thermal performance of such systems is vitally determined by the effectiveness of heat exchange between the metal hydride and the heat transfer fluid (HTF). This paper presents a numerical study supported by experimental validation on a magnesium hydride reactor fitted with a helical coil heat exchanger for enhanced thermal performance. The model incorporates hydrogen absorption kinetics of ball-milled magnesium hydride, with titanium boride and expanded natural graphite additives obtained by Sievert's apparatus measurements and considers thermal diffusion within the reactor to the heat transfer fluid for a realistic representation of its operation. A detailed parametric analysis is carried out, and the outcomes are discussed, examining the ramifications of hydrogen supply pressure and its flow rate. The study identifies that the enhancement of thermal conductivity in magnesium hydride has an insignificant impact on current reactor performance. • 3-D validation of MgH 2 reactor with a helical coil heat exchanger was performed. • Reaction kinetics was found out by using Sievert's apparatus. • Effect of operating parameters on MH reactor performance was studied. • Addition of 20% ENG into MH reactor, under the study, proved ineffective. [ABSTRACT FROM AUTHOR]
- Published
- 2021
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20. Future perspectives of thermal energy storage with metal hydrides.
- Author
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Manickam, Kandavel, Mistry, Priyen, Walker, Gavin, Grant, David, Buckley, Craig E., Humphries, Terry D., Paskevicius, Mark, Jensen, Torben, Albert, Rene, Peinecke, Kateryna, and Felderhoff, Michael
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HYDRIDES , *HEAT storage - Abstract
Abstract Thermochemical energy storage materials have advantage of much higher energy densities compared to latent or sensible heat storage materials. Metal hydrides show good reversibility and cycling stability combined with high enthalpies. They can be used for short and long-term heat storage applications and can increase the overall flexibility and efficiency of solar thermal energy production. Metal hydrides with working temperatures less than 500 °C were in the focus of research and development over the last years. For the new generation of solar thermal energy plants new hydrides materials with working temperatures above 600 °C must be developed and characterized. In addition to thorough research on new metal hydrides, the construction and engineering of heat storage systems at these high temperatures are challenging. Corrosion problems, hydrogen embrittlement and selection of heat transfer fluids are significant topics for future research activities. Highlights • Metal hydrides are described concerning their potential for heat storage at different temperatures. • For future thermochemical energy storage useful for the next generation of solar power plants new metal hydrides with working temperatures above 600 °C must be developed. • In this regard challenges of engineering, corrosion, hydrogen embrittlement and heat transfer must be solved. [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
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21. Synthesis of NaAlH4/Al composites and their applications in hydrogen storage.
- Author
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Ianni, Enrico, Sofianos, M. Veronica, Rowles, Matthew R., Sheppard, Drew A., Humphries, Terry D., and Buckley, Craig E.
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HYDROGEN storage , *DESORPTION , *CATALYSTS , *SCANNING electron microscopy , *X-ray scattering - Abstract
In solid-state hydrogen storage in light metal hydrides, nanoconfinement and the use of catalysts represent promising solutions to overcoming limitations such as poor reversibility and slow kinetics. In this work, the morphology and hydrogen desorption kinetics of NaAlH 4 melt-infiltrated into a previously developed Ti-based doped porous Al scaffold is analysed. Small-angle X-ray scattering and scanning electron microscopy analysis of low NaAlH 4 loading in the porous Al scaffold has revealed that mesopores and small macropores are filled first, leaving the larger macropores/voids empty. Temperature-programmed desorption experiments have shown that NaAlH 4 -infiltrated porous Al scaffolds show a higher relative H 2 release, with respect to NaAlH 4 + TiCl 3 , in the temperature range 148–220 °C, with the temperature of H 2 desorption trending to bulk NaAlH 4 with increasing scaffold loading. The Ti-based catalytic effect is reproduced when the dopant is present in the scaffold. Further work is required to increase the mesoporous volume in order to enhance the nanoconfinement effect. [ABSTRACT FROM AUTHOR]
- Published
- 2018
- Full Text
- View/download PDF
22. Novel synthesis of porous aluminium and its application in hydrogen storage.
- Author
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Veronica Sofianos, M., Sheppard, Drew A., Ianni, Enrico, Humphries, Terry D., Rowles, Matthew R., Liu, Shaomin, and Buckley, Craig E.
- Subjects
- *
HYDROGEN storage , *POROUS materials , *ALUMINUM , *LITHIUM borohydride , *CHEMICAL synthesis , *HYDRIDES - Abstract
A novel approach for confining LiBH 4 within a porous aluminium scaffold was applied in order to enhance its hydrogen storage properties, relative to conventional techniques for confining complex hydrides. The porous aluminium scaffold was fabricated by sintering NaAlH 4, which was in the form of a dense pellet, under dynamic vacuum. The final product was a porous aluminium scaffold with the Na and H 2 having been removed from the initial pellet. This technique contributed to achieving highly dispersed LiBH 4 particles that were also destabilised by the presence of the aluminium scaffold. In this study, the effectiveness of this novel fabrication method of confined/destabilised LiBH 4 was extensively investigated, which aimed to simultaneously improve the hydrogen release at lower temperature and the kinetics of the system. These properties were compared with the properties of other confined LiBH 4 samples found in the literature. As-synthesised samples were characterised using Scanning Electron Microscopy (SEM), X-ray Diffraction (XRD) and Nitrogen Adsorption measurements. The hydrogen storage capacity of all samples was analysed using temperature programmed desorption in order to provide a comprehensive survey of their hydrogen desorption properties. The porous aluminium scaffold has a wide pore size distribution with most of the porosity due to pores larger than 50 nm. Despite this the onset hydrogen desorption temperature (T des ) of the LiBH 4 infiltrated into the porous aluminium scaffold was 200 °C lower than that of bulk LiBH 4 and 100 °C lower than that of nanosized LiBH 4 . Partial cycling could be achieved below the melting point of LiBH 4 but the kinetics of hydrogen release decreased with cycle number. [ABSTRACT FROM AUTHOR]
- Published
- 2017
- Full Text
- View/download PDF
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