Enhancing the volumetric heat storage capacity of Mg(OH)2 by the addition of a cationic surfactant during its synthesis

Piperopoulos, Elpida; Mastronardo, Emanuela; Fazio, M.; Lanza, M.; Galvagno, S.; Milone, Candida

doi:10.1016/j.apenergy.2018.02.047

Cited by 27 publications

(26 citation statements)

References 29 publications

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“…In this study, for a preliminary comparison, the samples were subjected to 3 cycles experiments. To be consistent with previous studies [ 17 , 22 , 23 , 25 ] the materials performances were expressed in terms of reacted fraction ( β (%)) defined by Equation (4):

where Δ m real (%) was the instantaneous real mass change and Δ m th (%) was the theoretical mass change due to the dehydration of 1 mol Mg(OH) 2 , respectively expressed by Equations (5) and (6):

where m in ( g ) and m inst ( g ) were respectively the initial sample mass and the instantaneous mass during TG analysis. While, M Mg ( OH )2 (g/mol) and M MgO (g/mol) were respectively the molecular weight of Mg(OH) 2 and MgO.…”

Section: Methodssupporting

confidence: 92%

“…The almost general behavior of doped samples (MH-Ca and MH-Ni), in fact, reflects a higher density of the material and a lower value of the porosity, except for the MH-Ni1 sample, which morphology ( Figure 4 e) appears to be less stacked than the samples with the highest metal load and more similar to MH-Co1 and MH-Co2 ( Figure 4 h,i), which show a comparable pore volume (Entries 8 and 9 in Table 3 ). The same peculiar morphology was found for Mg(OH) 2 prepared in the presence of CTAB, which promotes the formation of well separated Mg(OH) 2 particles, lowering the hydroxide mean particle diameter and increasing the bulk density likely due to the peculiar stacked configuration of hydroxide particles, reported elsewhere [ 22 ].…”

Section: Resultssupporting

confidence: 78%

“…The pelletized storage material, decreasing the tablets volume required to store the same amount of thermal energy of Mg(OH) 2 pellets of almost 13.6%, increases volume energy density [ 21 ]. In previous studies it was found that, synthesizing Mg(OH) 2 in presence of a cationic surfactant (cetyl trimethyl ammonium bromide—CTAB), an optimum CTAB concentration exists and it exhibits the highest volumetric stored/released heat capacity, ∼560 MJ/m 3 two times higher than that measured over Mg(OH) 2 prepared in absence of CTAB [ 22 ]. The purpose of this work is to investigate the influence of metal (Ca 2+ , Co 2+ and Ni 2+ ) doping in Mg(OH) 2 synthesis on its structural and morphological properties and consequently on its thermochemical behavior.…”

Section: Introductionmentioning

confidence: 99%

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Synthesis of Me Doped Mg(OH)2 Materials for Thermochemical Heat Storage

2018

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In order to investigate the influence of metal (Me) doping in Mg(OH)2 synthesis on its thermochemical behavior, Ca2+, Co2+ and Ni2+ ions were inserted in Mg(OH)2 matrix and the resulting materials were investigated for structural, morphological and thermochemical characterization. The densification of the material accompanied by the loss in porosity significantly influenced the hydration process, diminishing the conversion percentage and the kinetics. On the other hand, it increased the volumetric stored/released heat capacity (between 400 and 725 MJ/m3), reaching almost three times the un-doped Mg(OH)2 value.

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where Δ m real (%) was the instantaneous real mass change and Δ m th (%) was the theoretical mass change due to the dehydration of 1 mol Mg(OH) 2 , respectively expressed by Equations (5) and (6):

Section: Methodssupporting

confidence: 92%

Section: Resultssupporting

confidence: 78%

Section: Introductionmentioning

confidence: 99%

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Synthesis of Me Doped Mg(OH)2 Materials for Thermochemical Heat Storage

2018

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“…In previous studies, several additives, such as cetyl trimethyl ammonium bromide, lithium chloride, and lithium hydroxide-modified Mg(OH) 2 , have been shown to enhance the reactivity of Mg(OH) 2 . 11−15 In particular, LiCl-added Mg(OH) 2 and LiOH-added Mg(OH) 2 were much more efficiently dehydrated at 270–300 °C than pure Mg(OH) 2 . 12−14 Therefore, we believe that the Mg(OH) 2 /MgO system has a significant potential for thermal energy storage at 200–300 °C, which constitutes a large part of the industrial waste heat in Japan.…”

Section: Introductionmentioning

confidence: 99%

Comparison of the Effect of Coaddition of Li Compounds and Addition of a Single Li Compound on Reactivity and Structure of Magnesium Hydroxide

2019

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Mg(OH)2 is a chemical heat storage material that is studied for the utilization of 300–350 °C waste heat. In this study, LiCl and LiOH were coadded to Mg(OH)2, and the reactivity and structural evolution were investigated. In the hydration of samples at 200 °C subsequent to dehydration at 270 °C, Mg(OH)2 with coadded LiCl and LiOH showed excellent hydration reactivity, with a heat output density of 1053 kJ kg–1. The coaddition of LiCl and LiOH enhanced both the dehydration and the hydration reactivity of Mg(OH)2. X-ray diffraction analysis indicated that the addition of LiOH to Mg(OH)2 promoted the decomposition of Mg(OH)2 and the diffusion of water on the surface of Mg(OH)2, whereas the addition of LiCl to Mg(OH)2 promoted these processes in the bulk phase of Mg(OH)2.

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“…Aiming to achieve high efficiency Mg(OH) 2 synthesis production, Kim et al increased the MgO surface area by forming micro-beams on the surface of the millimeter-size MgO pellets by electron beam irradiation [ 34 ]. On the other hand, we enhanced the heat storage aptitude per volume unit of Mg(OH) 2 by adding the cationic surfactant CTAB (cetyl trimethylammonium bromide) during its synthesis, reaching, at an optimal CTAB concentration, the maximum volumetric stored and released heat capacity, ~560 MJ/m 3 [ 35 ], associated to a significant increase of specific surface area and mean particle size reduction. Despite Mg(OH) 2 /MgO systems for TES application having been studied also in larger-scale reactors [ 36 ], the results achieved so far still have the potential to be improved for the applicability of this material at the industrial level.…”

Section: Introductionmentioning

confidence: 99%

Tuning Mg(OH)2 Structural, Physical, and Morphological Characteristics for Its Optimal Behavior in a Thermochemical Heat-Storage Application

et al. 2021

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Thermochemical materials (TCM) are among the most promising systems to store high energy density for long-term energy storage. To be eligible as candidates, the materials have to fit many criteria such as complete reversibility of the reaction and cycling stability, high availability of the material at low cost, environmentally friendliness, and non-toxicity. Among the most promising TCM, the Mg(OH)2/MgO system appears worthy of attention for its properties in line with those required. In the last few decades, research focused its attention on the optimization of attractive hydroxide performance to achieve a better thermochemical response, however, often negatively affecting its energy density per unit of volume and therefore compromising its applicability on an industrial scale. In this study, pure Mg(OH)2 was developed using different synthesis procedures. Reverse deposition precipitation and deposition precipitation methods were used to obtain the investigated samples. By adding a cationic surfactant (cetyl trimethylammonium bromide), deposition precipitation Mg(OH)2 (CTAB-DP-MH) or changing the precipitating precursor (N-DP-MH), the structural, physical and morphological characteristics were tuned, and the results were compared with a commercial Mg(OH)2 sample. We identified a correlation between the TCM properties and the thermochemical behavior. In such a context, it was demonstrated that both CTAB-DP-MH and N-DP-MH improved the thermochemical performances of the storage medium concerning conversion (64 wt.% and 74 wt.% respectively) and stored and released heat (887 and 1041 kJ/kgMg(OH)2). In particular, using the innovative technique not yet investigated for thermal energy storage (TES) materials, with NaOH as precipitating precursor, N-DP-MH reached the highest stored and released heat capacity per volume unit, ~684 MJ/m3.

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Enhancing the volumetric heat storage capacity of Mg(OH)2 by the addition of a cationic surfactant during its synthesis

Cited by 27 publications

References 29 publications

Synthesis of Me Doped Mg(OH)2 Materials for Thermochemical Heat Storage

Synthesis of Me Doped Mg(OH)2 Materials for Thermochemical Heat Storage

Comparison of the Effect of Coaddition of Li Compounds and Addition of a Single Li Compound on Reactivity and Structure of Magnesium Hydroxide

Tuning Mg(OH)2 Structural, Physical, and Morphological Characteristics for Its Optimal Behavior in a Thermochemical Heat-Storage Application

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