Recent Advances in Thermochemical Energy Storage via Solid–Gas Reversible Reactions at High Temperature

André, Laurie; Abanades, Stéphane

doi:10.3390/en13225859

Cited by 56 publications

(24 citation statements)

References 118 publications

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“…The high reaction temperatures required for the decomposition of SrCO3 and BaCO3 in CO2rich atmospheres render them unsuitable for post-combustion CO2 capture, but they are potential candidates for energy storage applications owing to their relatively high energy densities (reaction enthalpy per mass of alkali oxide) [69], [70].…”

Section: Thermodynamic Properties Of Alkali Metal Oxide Sorbentsmentioning

confidence: 99%

CO2 capture using solid sorbents: Fundamental aspects, mechanistic insights and recent advances

Dunstan¹,

Donat²,

Bork³

et al. 2021

Preprint

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Carbon dioxide capture and mitigation forms a key part of the technological response to combat climate change and reduce CO2 emissions. Solid materials capable of reversibly absorbing CO2 have been the focus of intense research for the past two decades, promising stability and low energy costs to implement and operate compared to the more widely used liquid amines. In this Review, we explore the fundamental aspects underpinning solid CO2 sorbents based on alkali and alkaline earth metal oxides operating at mid- to high temperature: how their structure, chemical composition and morphology impact their performance and long-term use. Various optimization strategies are outlined to improve upon the most promising materials, and we combine recent advances across disparate scientific disciplines including materials discovery, synthesis, and in situ characterization to present a coherent understanding of the mechanisms of CO2 absorption both at surfaces and within solid materials.

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Section: Thermodynamic Properties Of Alkali Metal Oxide Sorbentsmentioning

confidence: 99%

CO2 capture using solid sorbents: Fundamental aspects, mechanistic insights and recent advances

Dunstan¹,

Donat²,

Bork³

et al. 2021

Preprint

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“…Consequently, within NEW-MINE, MgO-stabilized SrO was synthesized and successfully tested for heat storage via the SrO/SrCO 3 cycle [102]. This research was considered outside NEW-MINE with respect to radiation propagation in a heat exchanger transforming solar radiation into high-temperature heat [103], thermochemical energy storage in the CaO/CaCO 3 [104] [105] system and two reviews on thermochemical energy storage [106,107]. The most recent NEW-MINE publication in this field deals with thermochemical heat storage via the CuO/Cu 2 O redox cycle and describes the synthesis of granules with a gravimetric energy storage density in the range of 470 to 615 kJ kg −1 [108].…”

Section: Solar Energy Storagementioning

confidence: 99%

The EU Training Network for Resource Recovery through Enhanced Landfill Mining—A Review

2021

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The “European Union Training Network for Resource Recovery Through Enhanced Landfill Mining (NEW-MINE)” was a European research project conducted between 2016 and 2020 to investigate the exploration of and resource recovery from landfills as well as the processing of the excavated waste and the valorization of the obtained waste fractions using thermochemical processes. This project yielded more than 40 publications ranging from geophysics via mechanical process engineering to ceramics, which have not yet been discussed coherently in a review publication. This article summarizes and links the NEW-MINE publications and discusses their practical applicability in waste management systems. Within the NEW-MINE project in a first step concentrates of specific materials (e.g., metals, combustibles, inert materials) were produced which might be used as secondary raw materials. In a second step, recycled products (e.g., inorganic polymers, functional glass-ceramics) were produced from these concentrates at the lab scale. However, even if secondary raw materials or recycled products could be produced at a large scale, it remains unclear if they can compete with primary raw materials or products from primary raw materials. Given the ambitions of transition towards a more circular economy, economic incentives are required to make secondary raw materials or recycled products from enhanced landfill mining (ELFM) competitive in the market.

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“…As the SHS unit has already been extensively studied (Hänchen et al, 2011;Zanganeh et al, 2012), the present study focusses on the design and experimental investigation of the TCS unit-i.e., the thermochemical reactor-for performing a reversible endothermic/exothermic gassolid dissociation reaction of the form A(s) ↔ B(s) + C(g). Examples are the reduction-oxidation of metal oxides and the calcinationcarbonation of metal carbonates (André and Abanades, 2020). In the scope of this investigation, the calcination-carbonation of limestone:…”

Section: Thermochemical Reactor Designmentioning

confidence: 99%

“…Of special interest is the thermochemical heat storage, which makes use of reversible endothermic-exothermic reactions for storing high-temperature heat for long term and with superior energy storage density (Abedin and Rosen, 2011;André and Abanades, 2020;Carrillo et al, 2019;King et al, 2019;Mette et al, 2012;Peng et al, 2017;Yuan et al, 2018). Reactors for thermochemical heat storage using gas-solid reactions can be classified into directly and indirectly irradiated reactors.…”

Section: Introductionmentioning

confidence: 99%

Experimental Investigation of a Thermochemical Reactor for High-Temperature Heat Storage via Carbonation-Calcination Based Cycles

2021

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We report on the design of a modular, high-temperature thermochemical energy storage system based on endothermic-exothermic reversible gas-solid reactions for application in concentrated solar power and industrial thermal processes. It consists of an array of tubular reactors, each containing an annular packed bed subjected to radial flow, and integrated in series with a thermocline-based sensible thermal energy storage. The calcination-carbonation of limestone, CaCO3 ↔ CaO + CO2, is selected as the reversible thermochemical reaction for the experimental demonstration. Synthetized 4.2 mm-mean size agglomerates and 2 mm-mean size granules of CaO with 42 %wt sintering-inhibitor MgO support attained reaction extents of up to 84.0% for agglomerates and 31.9% for granules, and good cycling stability in pressure-swing and temperature-swing thermogravimetric runs. A lab-scale reactor prototype is fabricated and tested with both formulations for 80 consecutive carbonation-calcination cycles at ambient pressure using a temperature-swing mode between 830°C and 930°C. The reactor exhibited stable cyclic operation and low pressure drop, and yielded specific gravimetric and volumetric heat storage capacities of 866 kJ/kg and 322 MJ/m3 for agglomerates, respectively, and 450 kJ/kg and 134 MJ/m3 for granules, respectively.

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Recent Advances in Thermochemical Energy Storage via Solid–Gas Reversible Reactions at High Temperature

Cited by 56 publications

References 118 publications

CO2 capture using solid sorbents: Fundamental aspects, mechanistic insights and recent advances

CO2 capture using solid sorbents: Fundamental aspects, mechanistic insights and recent advances

The EU Training Network for Resource Recovery through Enhanced Landfill Mining—A Review

Experimental Investigation of a Thermochemical Reactor for High-Temperature Heat Storage via Carbonation-Calcination Based Cycles

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