Development of Thermochemical Heat Storage Based on CaO/CaCO3 Cycles: A Review

Due to the inconsistency and intermittence of solar energy, concentrated solar power (CSP) cannot stably transmit energy to the grid. Heat storage can maximize the availability of CSP plants. Especially, thermochemical heat storage (TCHS) based on CaO/CaCO3 cycles has broad application prospects due to many advantages, such as high heat storage density, high exothermic temperature, low energy loss, low material price, and good coupling with CSP plants. This paper provided a comprehensive outlook on the integrated system of CaO/CaCO3 heat storage, advanced reactor design, heat storage conditions, as well as the performance of CaO-based materials. The challenges and opportunities faced by current research were discussed, and suggestions for future research and development directions of CaO/CaCO3 heat storage were briefly put forward.


Introduction
In recent years, to deal with global warming and an increasing energy demand, the utilization of renewable resources, such as solar, hydrogen, biofuel, wind energy, and tidal energy, has made strides around the world [1]. Indeed, all countries have reached an agreement to control the temperature rise to 1.5 • C or below [2]. In addition, it has been reported that renewable energy power generation will account for 30% of the total global power generation, surpassing coal-fired power generation for the first time, by 2040 [3]. Nowadays, solar energy is extensively considered to be one of the most promising renewable resources due to its inexhaustibility, safety, and non-pollution. In particular, concentrated solar power (CSP) plants not only have the potential to be integrated into the grid for dispatching power generation [4,5], but have also seen a significant increase in deployment worldwide in recent years [6,7]. However, power production is unstable in the CSP plants due to the intermittent and inconsistent solar energy, which cannot reliably transmit energy to the grid [8,9]. Owing to this, heat storage has become worthy of attention and research that is obligatory, affordable, and efficient [10]. Thermal energy storage (TES) can store heat under sunshine during the day and release heat when there is no solar irradiation. To make solar energy available, it is generally believed that the integration of CSP and TES is a promising and effective option to overcome its limitations [11,12].
There are three forms of TES systems based on different heat storage principles: sensible heat storage (SHS), latent heat storage (LHS), and thermochemical heat storage (TCHS) [13]. SHS takes advantage of the temperature change of the heat storage material to store heat, which is the most mature for industrial applications. The heat storage capacity of SHS depends on the physical properties of the material itself. In addition, SHS materials commonly used in the CSP field mainly include heat transfer oil, molten salts, ceramic, and concrete [14]. LHS is a technology that uses the phase-change process of heat storage materials to store and release heat, so it is also called phase-change heat storage. LHS possesses constant charge/discharge temperature and large heat storage density. Phase change materials (PCMs) mainly include organic, inorganic, and eutectic based on the chemical nature of the materials [15]. However, the traditional PCMs have some problems, such as low thermal conductivity and high energy loss [16]. Thus, the further industrial operation of CSP plants using LHS has been hindered.
In order to improve heat storage efficiency, it is necessary to research and develop new heat storage media with a higher heat storage temperature other than SHS and LHS. Moreover, TCHS absorbs heat through the decomposition of various chemical materials, which store heat energy in the form of chemical energy, and vice versa [17]. TCHS not only achieves a high heat storage density as well as small heat storage volume [12], but can also store energy for a long time at around room temperature [18]. Among the three systems as mentioned above, the special feature of TCHS is that it can store and transmit energy without loss of energy [19]. Therefore, TCHS is considered one of the most promising CSP heat storage technologies [20]. The main characteristics of the abovementioned three heat storage methods are summarized in Table 1 [21]. Table 1. The main characteristics of the three heat storage methods [19][20][21].

SHS LHS TCHS
Heat storage density Low~0.2 GJ/m 3 Medium~0.3-0.5 GJ/m 3 High~0.5-3 GJ/m 3 Among various TCHS systems, high-temperature thermochemical heat storage based on the carbonation/calcination reaction of CaO/CaCO 3 (as exhibited in Equation (1)) is considered to be one of the promising CSP heat storage technologies [32]. CaO/CaCO 3 is one of the systems with the highest heat storage density (approximately 3.2 GJ/m 3 ) [33] and the working temperature is relatively high [34], which is conducive to the realization of large-scale sustainable power generation. The equilibrium temperature of the reaction at atmospheric pressure under pure CO 2 is 895 • C [35]. The reaction equilibrium temperature is determined by the CO 2 partial pressure, as shown in Equation (2) [36].
CaCO 3 (s) + 178 kJ/mol CaCO(s) + CO 2 (g) (1) P eq = 4.137 × 10 7 exp − 20474 T where P eq is the CO 2 partial pressure, bar; T is the equilibrium temperature, K. By changing the CO 2 partial pressure, the carbonator can proceed in the range of 600-900 • C [37]. Additionally, it takes advantage of abundant raw materials and low prices due to natural calcium-based minerals (limestone or dolomite) as the precursors, which can realize efficient heat storage [38].
Recently, many review articles related to TCHS have been published [39,40]. Among them, most of the reviews mainly studied the materials and prospects of a variety of TCHS systems [31,41], and a few focused on CaO/CaCO 3 heat storage systems. Hence, this paper reviews and summarizes the research progress of CaO/CaCO 3 heat storage in system integration, reaction conditions, and material properties, covering the most valuable aspects of such research.

CaO/CaCO 3 TCHS
System design represents a major contribution to the application of CaO/CaCO 3 heat storage in CSP plants. The concept of calcium looping (CaL) TCHS can be traced back to the 1970s [42], but most of the subsequent CaL research has focused on CO 2 capture [43]. Only with the increasing demand for heat storage in recent years has the application of CaL in TCHS been extensively studied. Although the CaO/CaCO 3 heat storage technology and the CO 2 capture technology have the same chemical reaction principle [44], they have remarkable differences in factors, such as reaction conditions and applications [45]. When the CaL process is utilized for CO 2 capture from the flue gas of coal-fired power plants, the carbonation stage of CaO occurs in a carbonator with the flue gas containing about 15 vol% CO 2 to form CaCO 3 at the optimal temperature of 600-700 • C [46,47]. The calcination stage of CaCO 3 occurs in a calciner at above 900 • C under a high concentration of CO 2 (>90 vol%) for CO 2 enrichment, where the required heat is provided by fuel oxygenenriched combustion [48]. When CaL heat storage is implemented in CSP stations, its carbonation and calcination conditions are more flexible. The carbonation reaction is carried out under pure CO 2 for high temperature and power generation efficiency in the exothermic stage. Gases with different concentrations of CO 2 are fed into the carbonator as required, so the exothermic temperature of 600-900 • C can be reached [37]. Increasing the carbonation pressure can improve the limited temperature of the carbonation reaction [49].
In the solar calciner, the reactants generally cannot stay for a long time, so the calcination reaction in the CaO/CaCO 3 system needs to be accomplished as soon as possible [32]. Longer reaction time and higher temperature result in more severe sintering of CaO in the calcination stage, which is not beneficial for the carbonation of CaO [50]. Thus, a shorter time and lower temperature lead to a higher carbonation of CaO due to the slight sintering [51,52]. In addition, the solar calciner at low temperature needs fewer solar reflectors, so the cost is also reduced [53,54]. The calcination kinetics depends not only on the calcination temperature, but also on the calcination atmosphere [55]. The different calcination atmospheres for CaO/CaCO 3 heat storage were investigated, including CO 2 [55,56], steam [57], and inert gases [52]. For the calcination under pure CO 2 at atmospheric pres-sure, CaCO 3 can only be quickly decomposed at a temperature around 930-950 • C due to the limitation of thermodynamic equilibrium calculated by Equation (2) [52,55]. If the CO 2 partial pressure is higher than the equilibrium pressure, the calcination reaction cannot occur. The utilization of superheated steam (SHS) can reduce the calcination temperature to as low as 680 • C to save energy, and the calcined CaO has strong heat storage activity [57]. Nevertheless, the separation of vapor and CO 2 needs energy consumption. That is because the heat for cooling vapor is difficult to utilize. CO 2 after separation and purification is easier to use and store [58]. The calcination temperature of CaCO 3 can be noticeably reduced by using inert gases, such as helium (He) or nitrogen (N 2 ). Compared with pure N 2 , the calcination rate under pure He is faster due to the high diffusivity of CO 2 in He and the high thermal conductivity of He, and the calcination temperature is as low as 725 • C [52]. However, a further issue that needs to be considered is the separation of CO 2 and He. The content related to the reaction conditions will be discussed in detail in the next section. Recently, scholars have conducted lots of research on CaO/CaCO 3 heat storage, continuously optimizing the integrated process of CaO/CaCO 3 heat storage and CSP power generation to improve efficiency [59,60]. Furthermore, reducing the deactivation of CaO during heat storage and improving the heat storage stability have been widely studied.

CSP-CaL Schemes
The integration of CaL-CSP has attracted much attention due to the unique advantages of the CaO/CaCO 3 heat storage system. The system coupling CaO/CaCO 3 heat storage and CSP integrated power generation is developing rapidly, and its basic process is exhibited in Figure 2 [61]. The sunlight is converged on the solar calciner where CaCO 3 decomposes into CaO and CO 2 at a high temperature (~725-950 • C [52,61]). The generated CaO is stored at atmospheric pressure, and the released CO 2 is stored after the compression. According to the needs of power generation, CaO and CO 2 are fed into the carbonator (~850 • C or higher [52]). The heat released during the carbonation means the excess CO 2 is heated to a high temperature, and then CO 2 enters a turbine to achieve power output. Adding heat exchange systems after the heat storage and heat release process can improve the heat utilization rate. Edwards et al. [62] proposed an open CO 2 /air Brayton cycle CaO/CaCO 3 heat storage system, including a pressurized fluidized bed carbonator and a solar calciner, as shown in Figure 3. In the carbonation stage, the compressed CO 2 and high-pressure air entered the reactor together. It assumed that CO 2 was completely consumed in the carbonator, and then only high-temperature and high-pressure air was sent to the turbine to do work. Finally, the air experienced the Brayton cycle was discharged into the atmosphere.
The simulation results showed that when the material conversion rate was 20-40%, the carbonation temperature was 875 • C and the pressure was 6.7 bar. Moreover, the power generation efficiency of the system was maximum, up to 39.9-43.7%. It is worth noting that the complete consumption of CO 2 in the carbonator is an ideal situation. In fact, due to the thermodynamic balance of the reaction, CO 2 cannot completely react with CaO, so eventually the exhaust gas contains a large amount of CO 2 . Chacartegui et al. [63] explored the CO 2 closed-loop Brayton cycle CSP-CaL system, as demonstrated in Figure 4. The excess CO 2 was sent to the carbonator, and the unreacted CO 2 was used as a heat carrier fluid to enter the CO 2 turbine for power generation. The exhausting CO 2 was compressed and stored to start the next cycle. It was also identified that calcium-based materials with high activity, high carbonation temperature, and high inlet pressure of CO 2 turbine were the substantial factors to guarantee high efficiency of the closed heat storage system. The calculation classified that the system efficiency could reach 46% when the ratio of CO 2 pressure to turbine outlet pressure was 3.2. Alovisio et al. [64] utilized the pinch-analysis methodology to optimize the heat transfer design in detail based on the closed CO 2 Brayton system, and the overall efficiency increased by 5% on the original basis.
Karasavvas et al. [65] integrated the Rankine cycle with the CO 2 Brayton cycle heat storage system and designed a scheme of continuous power generation with an efficiency of 31.5%. Tesio et al. [66] optimized the indirect integration of the steam Rankine cycle in CaL-CSP from both energy and economic aspects, which determined the size and operating conditions of the main components. Ortiz et al. [67] conducted an energy and sensitivity analysis on the closed system, and the results showed that various methods could be used to improve the system efficiency by adding gas-solid heat exchangers at both ends of the calciner and carbonator, increasing the turbine inlet temperature, and raising CaO conversion. Karasavvas et al. [68] also studied an exergy analysis on the system and found that most of the exergy loss occurred in the solar receiver (about 36.6%), the calcination section (i.e., 25.8%), and the steam Rankine cycle (about 20.6%). On the contrary, the exergy loss that occurred in the carbonation section was relatively small, about 4.8%. Cannone et al. [69] also used the pinch analysis method to study the integrated system and found that when the conventional Rankine cycle was integrated with CSP equipment, the electrical efficiency increased by about 4%, and its total thermoelectric efficiency reached 51.5%. Ortiz et al. [36] also investigated the integration scheme of a CaO/CaCO 3 heat storage system with other power cycles, including subcritical Rankine cycle (efficiency 35.5%), supercritical CO 2 Brayton cycle (efficiency 32%), and combined cycle (efficiency 40.4%). The research results showed that the closed CO 2 Brayton cycle possessed the highest system efficiency, which could reach 44-45% under ideal conditions. Wu et al. [70] proposed a CSP-CaL system combined with CaCl 2 (>80 mol%) phase change heat storage, in which the reactants were molten during the process from charging to discharging, as exhibited in Figure 5. In the heat storage process, the solid CaCO 3 -CaCl 2 particles from a cold tank were transported into the calciner through pneumatic conveying. The solid CaCO 3 -CaCl 2 was heated in the calciner and then decomposed into CO 2 gas and molten CaO-CaCl 2 , where the required heat was provided by concentrated solar energy. Then, the generated molten CaO-CaCl 2 was stored in a hot tank, and the sensible heat of generated CO 2 was used to preheat the solid CaCO 3 -CaCl 2 . The cooled CO 2 was compressed in multiple stages to high pressure of about 75 bar and stored in a CO 2 tank. In the exothermic process, the stored energy was released through carbonation and solidification of molten CaO-CaCl 2 , in which the released energy was transferred to the CO 2 Brayton cycle to fulfill power generation. The modeling results demonstrated that the overall efficiency of the system could be improved, reaching up to 49% when increasing the molar ratio of CaCl 2 , but at the same time reducing the heat storage density. In addition, Habibi et al. [71] integrated the phase change CaO/CaCO 3 -CaCl 2 heat storage system with the Mg-Cl hydrogen production cycle, so that solar energy was not only used for heat storage, but also utilized for hydrogen production. The simulation results showed that the annual system efficiency of the system could reach up to 63.74%. Chen et al. [72] analyzed the impact of heat utilization on the efficiency of heat storage systems, making full use of the sensible heat of the system could raise the heat storage, energy release, and system efficiency by 45.1%, 32.1%, and 61.59%, respectively. Pascual et al. [73] focused on different operating points in the simulation system to determine and optimize the different discharge/charge ratios of the mass balance during operation, including CaCO 3 , CaO, and CO 2 storage tanks. Peng et al. [74] also simulated the model of CSP-CaL in different seasons and studied its performance. Obermeier et al. [75] pointed out that the preheating process of reactants rising from ambient temperature to reaction temperature had a significant influence on system efficiency, in which high sensible heat recovery and high conversion of reactants were key to achieving high system efficiency. Some pilot-scale CSP-CaL systems are already under construction [65,76], which is also a crucial step for the development of CSP-CaL power generation systems.

CSP-CaL Equipment
The main equipment of the CSP-CaL system includes reactors, heat exchangers, storage systems, and conveying systems, which have been extensively studied in other industrial applications such as the cement industry [58]. The reactor of the CSP-CaL system is mainly used for the solid-gas reaction process, including the solar calciner and the carbonator. Among them, the carbonator has the same basic requirements as the existing CaL-CO 2 capture reactor, which is relatively mature technology [77]. The technology of solar calciner is still immature, although the calciner has been studied since the 1980s [78]. In addition, the solar calciner is the most critical equipment in the CSP-CaL system, and its overall design, especially the heat collection capacity, is sensitive to the efficiency of the system. According to the heat collection method, it can be divided into the surface type and volumetric type whose principles are shown in Figure 6 [79]. Figure 6a exhibits the surface type heat collection, where the sunlight is first absorbed by the surface coating of the reactor, and then the heat is transferred to the tube wall through heat conduction. Finally, the heat of the tube wall is transferred to the reactants in the form of thermal radiation and convection [80]. Figure 6b demonstrates the volumetric heat collection, in which the solar energy is directly radiated to the reactant, thereby eliminating the process for a large amount of heat transfer in the middle, but the ability of the reactant to receive solar radiation is higher [81]. For the surface heat collection, the high-temperature surface coating radiates a large amount of heat to the outside, causing serious heat loss [76]. The thermal resistance between the surface coating and the reactant is large, and the reactant may stick to the tube wall on account of sintering [82]. Thus, it is not suitable for the high-temperature CaO/CaCO 3 heat storage system. The volumetric heat collection in which the reactant directly receives radiant energy is more suitable for this system. Ortiz et al. [32] described in detail the principles that should be followed in the design of the calciner, such as solid residence time, particle size, temperature gradient and so on. Lisbona et al. [83] designed a multi-stage solar calciner that could limit the peak temperatures for the reactors, alleviate the sintering of materials, and achieve the highest heat storage efficiency. In addition, due to the low solar optical absorption capacity of CaCO 3 , it should also be considered in the design of the calciner [78].
The tiny solid particles are used in the solar calciner (particle receiver) to directly absorb the solar energy reflected by the heliostat, so as to rise to a very high temperature (~900 • C [62]). The heat can be stored in the tank or exchanged with the working medium. The temperature distribution in the receiver is related to the particle size and reaction time. Currently, there are many researches on the direct system of particle receivers as shown in Figure 7, mainly including falling particle receivers, fluidized bed receivers, rotary kiln receivers, etc. The falling particle receiver is the most basic type of particle receiver, which receives solar radiation by letting solid particles fall directly. The thermal efficiency and outlet temperature of the working medium have a decisive relationship with the mass flow of particles and the residence time in the heated region [85]. In addition, in order to increase the outlet temperature of the working medium, one way is to increase the residence time of particles, e.g., by setting the particles in the receiver to circulate multiple times [86]. Compared with the falling particle receiver, the solid particles in the fluidized bed receiver are blown by gas and in a suspended state, which is irradiated by concentrated sunlight. At this time, the solid particles are in full contact with the gas, which can effectively promote heat and mass transfer. Tregambi et al. [87] designed and used the CaCO 3 carbonation/calcination reaction in a fluidized bed reactor with direct radiation to maximize solar energy collection. The study found that CaO/CaCO 3 TCHS could be applied to fluidized bed receivers, whose heat storage density reached 1000 J/m 3 in a quarter of the 12 cycles. However, due to uneven radiation, the bed layer was locally overheated, which aggravated the sintering of particles.
The principle of the rotary kiln receiver is to feed particles into the rotary kiln, and a light transmission window is set at one end of the receiver to concentrate sunlight. The centrifugal force of the rotary kiln receiver makes the particles rotate and fall along the wall of the receiver, and then the sunlight is injected through the light transmission window to heat the particles attached to the wall. At present, the rotary kiln has been widely used in the chemical and cement industry and is mostly used for calcination and decomposition reactions [88]. Therefore, it can be used as a solar calciner in a CaO/CaCO 3 TCHS system. Moumin et al. [89] designed a high-temperature solar rotary kiln that was used for limestone calcination. An insulating layer was arranged between the reactor and the shell, and a quartz glass window was arranged to receive solar radiation. The experimental results showed that the total efficiency of the rotary kiln was 19-40%. The advantages and disadvantages of the different solar calciners are summarized in Table 2. Furthermore, the description, schemes, and related issues of the reactor have been elaborated in detail in the literature [90]. Remarkably, the current research on solar calciner is still in its infancy. The structural design, light transmission window, and control system still need further research [91].

CSP-CaL Techno-Economics
At present, the research on the pilot-scale of CSP-CaL is still in its infancy [65,76], so only a rough discussion will cover its techno-economic analysis. When the CaL process is utilized for CO 2 capture from the flue gas of coal-fired power plants, the research on technoeconomic analysis is relatively extensive, which can be used as the reference for CSP-CaL. Hanak et al. [92] assessed the economic cost of retrofitting a 580 MW coal-fired power plant through CaL technology, which may be between 2100-2300 €/kW. Michalski et al. [93] thoroughly evaluated the economic investment of a power plant based on CaL technology by using the break-even electricity price method, and its capital cost was 2573.5 €/kW. Bayon et al. [94] conducted a techno-economic assessment of 17 solid-gas TCES systems. It was found that the cost of raw materials and the energy consumption of auxiliary equipment had the greatest impact on the capital cost of the system. The CaL process was determined to be competitive with molten salt at the lowest cost. Unfortunately, the energy consumption of auxiliary equipment based on carbonate systems was very high, especially the high energy required to compress CO 2 . Tesio et al. [95] conducted an economic analysis on the CaL indirect integrated CSP plant, including the supercritical CO 2 Brayton cycle and steam Rankine cycle. It was found that the calciner and the solar energy sides accounted for 86% of the total investment capital. In addition, not only was the investment cost of each component estimated, but also the economic optimization of the calcination reaction device, including the optimal size of the calciner and compressor components. The results of the economic analysis showed that the supercritical CO 2 Brayton cycle was the optimal choice for indirect integration. Muto et al. [96] studied the heat exchange reactor for waste heat recovery and the reactant transportation method, then optimized and economically analyzed the CaO/CaCO 3 heat storage system. It is estimated that the expected investment cost per kW·h of heat energy stored in a commercial-scale system, including equipment and installation, emergency, heat storage materials, land, and other expenses, is about 47 $/(kW·h).
In the techno-economic analysis of CSP-CaL, the CaL process has advantages due to the low cost of materials (calcium-based precursors such as limestone). The disadvantage of the CaL process is the high energy consumption of auxiliary equipment (including CO 2 compression). Therefore, more effective integration of the CSP-CaL scheme is needed, including storage systems, solids transportation, and gas separation.

Effect of Reaction Conditions on Performance of CaO-Based Materials in CaO/CaCO 3 TCHS
For the CaO/CaCO 3 TCHS system, whether the CaO-based material can maintain high carbonation performance and cyclic stability are key to heat storage. A number of studies have shown that temperature [97], pressure [98,99], atmosphere [100], and particle size [101] have crucial effects on the sintering rate of CaO-based materials. Therefore, it is necessary to study the reaction conditions in the stages of calcination and carbonation.
The heat storage performances of CaO-based materials are evaluated by the effective conversion [97] and heat storage density [98], respectively. The effective conversion denotes the ratio of the mass of CaO reacted during each carbonation cycle to the total mass of the sample before the carbonation, which is defined by Equation (3): where N denotes the number of TCHS cycles; X ef, N is the effective conversion of CaO-based materials after N TCHS cycles; m car, N and m cal, N−1 denote the mass of the sample after the Nth carbonation and the N-1th calcination, respectively, g; m 0 represents the original mass of the sample, g; M CaO and M CO2 represent the molar masses of CaO and CO 2 , respectively, g/mol. Heat storage density represents the maximum heat that can be released per unit mass of CaO-based materials during each carbonation reaction, which is defined by Equation (4): where E g, N is the heat storage density of CaO-based materials, kJ/kg; ∆H 0 denotes the standard reaction heat (178 kJ/mol for 0 • C; 165.5 kJ/mol for 900 • C).

Effect of Calcination Conditions
Calcination conditions, including harsh and mild calcination conditions, usually play an important role in the heat storage properties of CaO-based materials. Valverde et al. [61] found that the thermal pretreatment of limestone could improve heat storage performance. The effective conversion of limestone thermally pretreated for 1 h under N 2 at 760 • C was 0.58 after 20 cycles, which was 90% higher than that of limestone without thermal pretreatment. Sarrión et al. [102] studied the influence of calcination conditions on the heat storage performance of the limestone and the Ca/Al composites. It was found that the effective conversion of the limestone calcined under pure He at 725 • C decreased from 0.70 to 0.21 after 20 cycles. However, when the limestone was calcined under pure CO 2 at 950 • C, its effective conversion dropped from 0.69 to 0.18 after 20 cycles. This was because the calcination at high temperatures under high concentrations of CO 2 aggravated the sintering of CaO, which was more obvious in the study of limestone Ca/Al composites. When the Ca/Al composites were calcined under pure CO 2 at 950 • C, the effective conversion decreased from 0.60 to 0.18 after 20 cycles. However, under pure He at 725 • C, its effective conversion dropped from 0.74 to 0.41 after 20 cycles. This may be because the Tammann temperature (~771 • C) of Ca 3 Al 2 O 6 was lower than the calcination temperature used in the test (950 • C). When the reaction temperature of solid particles reaches a certain temperature, each atom in the crystal lattice begins to show a significant diffusion effect, and the chemical reaction properties become stronger, which is the Tammann temperature [103]. The Tammann temperature is a crucial factor affecting sintering. Valverde et al. [104] demonstrated the effect of SHS in the calcination atmosphere on the heat storage performance of limestone. When 0.03 vol% steam was added into the three calcination atmospheres, i.e., N 2 , He, and CO 2 , respectively, the calcination rates of limestone were all obviously accelerated. The limestone was completely calcined at 700 • C under wet N 2 , while under wet He, the calcination temperature could be reduced to 680 • C. The calcination rate of limestone under wet CO 2 was nearly three times higher than that under dry CO 2 , and the calcination temperature could be reduced to 925 • C. Sarrion et al. [105] proposed a new method to calcine limestone under CO 2 at low pressure. When the CO 2 pressure was 0.01 bar, the decomposition of limestone occurred at 765 • C, and the thermal storage stability of limestone was also noticeably improved. However, it should be noted that to maintain the low pressure of the calciner, more energy consumption would be needed. It is difficult to ensure the flowability of the heat storage material under negative pressure, which may be hardly possible to realize large-scale industrial applications. Champagne et al. [106] pointed out that the presence of high concentration of steam remarkably promoted the cyclic heat storage stability during the calcination stage in a thermogravimetric analyzer (TGA). However, the structure of the generated CaO was changed negatively, suggesting a decrease in the mechanical strength of CaO. It may cause severe particle fragmentation, so the smaller particles easily escape from the reactor, which is not conducive to its application in the fluidized bed reactor [107]. He et al. [47] used density functional theory to study the catalytic effect of steam on the decomposition of CaCO 3 and its mechanism at the molecular level. Obermeier et al. [108] found that the hydration treatment of calcium-based materials during energy storage could reactivate low-activity CaO. After five heat storage cycles, CaO was hydrated in steam at 250 • C, and the heat storage performance of limestone was improved by 39%.

Effect of Carbonation Conditions
At present, the carbonation of CaO/CaCO 3 heat storage research is mostly carried out under atmospheric pressure. Compared with carbonation at atmospheric pressure, CaO/CaCO 3 TCHS benefits from carbonation at increased pressure. Sarrion et al. [109] studied the heat storage performance of limestone and dolomite at the carbonation pressure of 3 bar (calcination under CO 2 at 1000 • C, carbonation under CO 2 at 850 • C). The effective conversion of calcium-based material was lower than that under 1 bar carbonation as the increase of pressure intensified the sintering of CaO. In addition, Sun et al. [98] performed heat storage experiments with limestone in a pressurized fixed bed and found that increasing the carbonation pressure could make carbonation occur at a temperature of 950 • C or higher. At the same time, increasing the carbonation pressure from 0.1 to 1.3 MPa, the heat storage capacity of limestone was also drastically enhanced, as exhibited in Figure 8  Li et al. [110] studied the heat storage properties of CaO pellets under pressurized carbonation (1.3 MPa) and harsh calcination conditions (950 • C, pure CO 2 ). They found that the energy density of CaO pellets carbonated after 10 cycles was 1423 kJ/kg, which was lower than that of limestone powder, but the compressive strength and wear resistance of CaO pellets during the cycles were higher. Furthermore, increasing the pressure and temperature of carbonation was more suitable for practical industrial application conditions. Pressurized carbonation as the reaction condition is used in process simulation [62]. Therefore, the heat storage performance of calcium-based materials under high carbonation pressure is worthy of attention and research.

Effect of Particle Size
Benitez-Guerrero et al. [97] studied the heat storage performances of two kinds of limestone with different particle sizes (<45 µm and >45 µm) and found that the effective conversion of limestone particles (>45 µm) decreased significantly, and its effective conversion dropped from 0.76 to 0.16 in 20 heat storage cycles. However, the effective conversion of the limestone particles (<45 µm) decreased from 0.8 to 0.42, which showed that the particle size of limestone had a significant impact on heat storage. This was because the larger CaO particles were rapidly deactivated due to pore plugging, which limited the carbonation/calcination of the heat storage process. Durán-Martín et al. [111] examined the effect of particle size on the heat storage performance of limestone calcined in pure helium and found that limestone with a smaller particle size (<15 µm) had a higher multicyclic activity in the heat storage cycles. Ma et al. [107] studied the heat storage performance of limestone under bubbling fluidization. They found that with increasing the fluidization velocity from 0.04 to 0.06 m/s, the heat storage capacity of limestone increased by 12%, but the attrition rate was accordingly improved by 96%. When the CO 2 concentration increased from 80% to 100%, the heat storage performance of limestone rose by 11%. Compared with the limestone with a particle size of 0.18-0.25 mm, the limestone with the relatively smaller particle size of 0.125-0.18 mm exhibited slightly higher heat storage capacity. This was because the relatively smaller limestone particles in the fluidization state showed better mass and heat transfer performances, resulting in higher CaO reactivity for heat storage.

Performance of CaO-Based Materials in CaO/CaCO 3 TCHS
It has been a consensus that the effective conversion of CaO plays a decisive role in the CaO/CaCO 3 cycles heat storage. Prieto et al. [112] pointed out that the inactivation of CaO was a major defect for the CSP-CaL system. As the number of CaO/CaCO 3 heat storage cycles increases, the activity of CaO decreases rapidly, and usually reaches a lower conversion over 20 cycles [113]. On the one hand, the carbonation occurs rapidly under high CO 2 pressure at high temperature, so the generated CaCO 3 layer blocks pores of the unreacted CaO [61]. On the other hand, due to the low Tammann temperature of calciumbased materials, CaO grains are sintered under harsh calcination conditions during multiple CaO/CaCO 3 heat storage cycles [50]. The deactivation characteristics of CaO in the heat storage cycles are mainly related to the CaO precursor and the calcination/carbonation conditions. Calcium-based materials include a variety of natural ores, such as limestone, dolomite, and calcium-rich industrial waste such as carbide slag, steel slag, and fly ash [114].

Natural CaO-Based Materials
Benitez-Guerrero et al. [97] compared the cyclic heat storage performance of natural calcium-based materials, such as limestone and dolomite. After the 20 heat storage cycles, the effective conversion of limestone (<45 µm) dropped from 0.8 to 0.42. The cyclic effective conversion of dolomite was more stable, which decreased by 28% after 20 cycles. This was because that the MgO in dolomite could relieve the sintering and pore plugging of CaO. However, the initial effective conversion of dolomite was not high, about 0.6.
In addition, Benitez-Guerrero et al. [115] also compared the cyclic heat storage performance of natural calcium carbonate minerals such as limestone, chalk, and marble, and their thermograms were shown in Figure 9. The initial reaction kinetics and conversion rates of the three calcium-based materials were very similar, as presented in Figure 9a. The carbonation reaction of CaO derived from calcium carbonate minerals was almost completely carried out in the chemical reaction-controlled stage, while that in the diffusioncontrolled stage could be ignored. This provided a crucial reference for the optimization of reactor design. However, as demonstrated in Figure 9b, the inactivation degree of the CaO derived from three calcium carbonate minerals was significantly deference in their crystallinities and sizes of the CaO grains. Limestone had the higher effective conversion (0.51) while marble had the lowest conversion (0.27). Durán-Martín et al. [111] tested the heat storage performance of limestone particles with different particle size distributions in multiple cycles and studied the effect of particle size on the deactivation mechanism of limestone. It was found that when calcined under He at low temperature, the utilization of small particles of limestone was more beneficial for heat storage, but this promotion was only effective for limestone particles below 15 µm.

Waste CaO-Based Materials
Besides natural calcium-based materials, such as limestone and dolomite, another type of industrial waste with high calcium content can also be applied for heat storage through the CaL process [116]. Among them, steel slag is a common industrial waste, most of which is used to pave roads and produce concrete. Carbide slag is a waste produced by polyvinyl chloride and chlor-alkali whose main component is Ca(OH) 2 . A large amount of carbide slag is directly piled-up or buried nearby, resulting in serious environmental damage and waste of resources. The application of calcium-based industrial waste residues for CaO/CaCO 3 heat storage not only saves calcium sources, but also realizes the resource utilization of waste residues. Perejon et al. [117] studied the cyclic heat storage performance of industrial waste steel slag. They found that the treated steel slag with acetic acid achieved an effective conversion rate of 0.8 after 20 heat storage cycles. Thus, the treated steel slag is an ideal heat storage material for CaL-CSP. Valverde et al. [118] compared the heat storage performances of blast furnace slag and calcium-rich steel slag. After acetic acid treatment, the heat storage performances of steel slag and blast furnace slag became more stable, but the maximum effective conversion rate was only about 0.30, which was lower than that of limestone. Although Al and Mg oxides in the waste slag improved its cyclic heat storage stability, the low contents of CaO in the waste slag limited the maximum heat storage capacity. In the abovementioned acetic acid treatment process, a filtration step was added to remove silicon impurities, which could increase the effective conversion of the waste residue after treatment to about 0.60. Bai et al. [119] also reported the influence of different acidification parameters, such as acid concentration, acidification temperature, and acidification time on the heat storage of calcium-based composites derived from steel slag. Among them, after the steel slag was acidified with acetic acid, the contents of Ca and Mg increased, while the contents of Si and Fe decreased, which improved its cyclic stability. Sun et al. [98] examined the cyclic heat storage performance of carbide slag and found that the presence of chlorine resulted in a rapid drop in the heat storage performance in the first two cycles, whereby it remained stable during 30 cycles. Consequently, carbide slag is a promising calcium-based heat storage material. Jahromy et al. [120] studied the heat storage potential of fly ash by using X-ray fluorescence (XRF) spectroscopy, scanning electron microscopy (SEM), and so on. Furthermore, they confirmed that the content of CaO in fly ash was 27%, indicating that it was promising as a heat storage material. However, more experimental studies were still required for the industrial application. Similarly, Maaten et al. [121] also explored the possibility of oil shale ash heat storage through the use of XRF, elemental analysis, and thermal analysis. Troya et al. [122] examined the heat storage properties of CaO derived from biomineralized CaCO 3 , such as snail shells and eggshells. They found that after 20 cycles, the conversion rate was equivalent to that of limestone, indicating that this type of food waste was feasible for heat storage. Utilizing CaO-based waste as heat storage material in CaO/CaCO 3 TCHS can not only save a lot of limestone resources, but also make full use of waste, which greatly solves the practical problem of waste accumulation. Table 3 summarizes the heat storage properties of several common natural and waste CaO-based materials reported in the literature.

Improvement on Cyclic Thermal Storage Stability of CaO-Based Materials in CaO/CaCO 3 TCHS
The heat storage performance of natural calcium-based materials, such as limestone and dolomite, declines rapidly with the number of heat storage cycles, which has an adverse effect on the CaO/CaCO 3 TCHS. The lower the performance of CaO, the higher the inert solid content of the heat storage system for transportation, preheating, and cooling, resulting in a large amount of energy loss [67]. Studies have shown that the overall efficiency of CSP-CaL power plants increased by more than 10%, as the effective conversion of calcium-based materials increased from 0.07 to 0.5 [63]. Thus, it is beneficial to improve the cyclic heat storage performance of calcium-based materials and prepare calcium-based heat storage materials with high efficiency and stable performance, which have become the focus of attention of researchers. Adding a dopant with a high Tammann temperature to calcium-based materials is one of the most common methods to slow down the sintering of CaO-based materials. The supporter dispersed between the CaO grains plays a supporting role, which prevents the agglomeration of the CaO grains at high temperatures to a certain extent and enhances the sintering resistance of the CaO-based material [123].

CaO/SiO 2 Composites
SiO 2 is one of the reliable supporters with a wide range of sources and good application prospects. Studies have found that molecular sieves and nano-structured SiO 2 can be used to improve the structural dispersion of CaO particles and reduce sintering [124,125]. Benitez-Guerrero et al. [126] synthesized cheap porous CaO/SiO 2 composites using the biotemplate (rice husk) method. The heat storage performance of the composite material (70% content of CaO) was significantly better than that of limestone. After 20 cycles, the effective conversion of CaO was about 0.5. In addition, its heat storage density was about 40% higher than that of limestone after 50 cycles. This was because the composite material had a porous structure, in which the evenly dispersed SiO 2 alleviated the sintering and pore plugging of CaO. Chen et al. [127] doped SiO 2 into CaCO 3 by the mechanical mixing method and studied its kinetics, thermodynamics, and cycling stability in TGA. The composite material supplemented with 5 wt.% SiO 2 possessed the best heat storage performance. After the addition of 5 wt.% SiO 2 , the cyclic stability of CaCO 3 was enhanced by 28% and the attenuation rate reached 0.85% per cycle. However, the addition of SiO 2 led to a decrease in the calcination conversion rates of calcium-based materials. The heat release of the CaO/SiO 2 composite was still higher than that of CaO because the specific heat capacity of the composites increased by 20%. This may be because the thermal conductivity of SiO 2 (10.2 W/m·K) was higher than that of CaCO 3 (2.259 W/m·K [128]).
Khosa et al. [129] prepared the composite by wet mixing method with CaCO 3 and nano-SiO 2 (the molar ratio of Ca to Si = 1:1). It was found that the heat storage capacity of the doped sample decreased by 43% after 20 cycles, while that of CaCO 3 dropped by 56%. In addition, due to the high thermal conductivity of SiO 2 , CaO could reach the reaction temperature faster. Therefore, SiO 2 enabled the composite materials to be completely calcined at a lower calcination temperature. For instance, the decarbonation temperature of CaCO 3 could be reduced from 750 • C to 700 • C due to SiO 2 under Ar. Møller et al. [130] studied the influence of 11 different additives such as SiO 2 , Fe 2 O 3 , BaCO 3 , ZnO, etc. on the heat storage performance of limestone. Among them, the most ideal additives were Al 2 O 3 (20 wt%) and ZrO 2 (40 wt%), which could better resist the attenuation of CaCO 3 , so that the capacity degradation rate after 500 cycles was only 20%.

CaO/Al 2 O 3 Composites
Obermeier et al. [109] examined CaO/Al 2 O 3 composites prepared from calcium acetate and aluminum nitrate and found that the heat storage density of the composite with the molar ratio of Ca/Al = 95:5 after 20 cycles was 3.5 times that of the unmodified CaO. Benitez-Guerrero et al. [131] utilized a mechanical mixing method to prepare CaO/Al 2 O 3 composite materials. It was found that Ca 4 Al 6 O 13 was formed in the mild calcination stage of CaO and Al 2 O 3 , which could alleviate the high-temperature sintering of CaO and improve the heat storage stability of the composite. The effective conversion of the sample with the 5 wt% Al 2 O 3 was 0.55 after 20 cycles. Fedunik-Hofman et al. [132] used Ca(NO 3 ) 2 , Al(NO 3 ) 3 , and (NH 4 ) 2 HPO 4 as precursors to prepare a Ca/Al/P composite by using the Pechini method. It was found that for the calcination under pure CO 2 at 1000 • C, the composite still had an effective conversion of 0.67 after 20 heat storage cycles, while that of limestone was only 0.10. It was noted that the apatite was formed during the preparation process, and its melting point was 1650 • C, which effectively alleviated the high-temperature sintering of CaO. In addition, the apatite precursors were cheaper than calcium aluminate precursors, which could be used as a substitute for calcium aluminate to improve the thermal storage stability of calcium-based materials. Han et al. [133] compared the promotion effects of Al 2 O 3 , SiO 2 , and TiO 2 on the heat storage performance of calcium-based materials, and found that, among the three additives, Al 2 O 3 had the best influence on enhancing the heat storage stability of the samples. After 50 cycles, the heat storage density of the composite with 5 mol% Al was 1500 kJ/kg, which was equivalent to 87% of the theoretical maximum. Sun et al. [134] studied composite heat storage materials prepared from limestone (as calcium precursor), calcium aluminate (as supporter), and CeO 2 (as catalyst). They found that CeO 2 could generate oxygen vacancies on the surface of calcium-based materials to promote the transfer of O 2− , which improved the heat storage performance of calcium-based materials. Under the synergistic effect of CeO 2 and Ca 12 Al 14 O 33 , the composite achieved the maximum heat storage capacity when the addition amount of both Al 2 O 3 and CeO 2 was 5 wt%. After 30 heat storage cycles, the effective conversion and heat storage density of the composite were as high as 0.79 and 2500 kJ/kg, respectively. In addition, Sun et al. [135] further used absorbent paper as a template to prepare a Ca/Al/Ce composite heat storage material with a porous hollow tube structure. They found that the optimal addition amounts of Al 2 O 3 and CeO 2 were 2.5 wt% and 1 wt%, respectively. The effective conversion and heat storage density of the Ca/Al/Ce composite with hollow tube after 30 cycles retained 0.92 and 2924 kJ/kg, respectively. Møller et al. [136] studied the energy storage performance and material physical properties of a calcium-based thermochemical energy storage system using a packed bed reactor under three operation scenarios, equipped with 3.2 kg of composite material (0.82 kWh thermal energy) by hand-mixing CaCO 3 and Al 2 O 3 (16.7 wt%). It was found that under the thermodynamic driving force and the pressure driving force scenarios, the energy capacity of the system was maintained at 64% after 10 cycles. The decrease in capacity may be partly attributable to the excessive heating in the reactor bed leading to the massive formation of Ca 12 Al 14 O 33 .

Other CaO-Based Composites
Lu et al. [137] loaded Li 2 SO 4 onto nano-CaCO 3 by the wet impregnation method. The results showed that after 11 cycles, the CaO conversion of the composite loaded with 5 wt% Li 2 SO 4 was 51%, which was 87% higher than that of pure nano-CaO material. Additionally, both the carbonation and calcination reaction rates were improved, and the decomposition temperature was reduced by at least 15 • C. Sarrion et al. [109] prepared CaO/ZrO 2 composites by the mechanical mixing method. However, the improvement of ZrO 2 on the heat storage performance of the doped sample was not obvious. The effective conversion of CaO/ZrO 2 composites with 5% ZrO 2 dropped to below 0.25 after 10 cycles. Khosa et al. [138] doped ZnO into CaCO 3 by the mechanical mixing method and found that the heat storage material with 5 wt.% ZnO showed the highest heat storage capacity of 1478.8 kJ/kg. As the cycle number increased from 20 to 100, the heat storage density did not decrease, and the specific heat capacity of the sample doped with ZnO increased by 68%. They also studied the kinetics of the calcination reaction and found that the incorporation of ZnO could increase the rate of the calcination reaction. Xu et al. [139] prepared CaO/TiO 2 composites by the stirring and mixing method and examined heat storage capacities of the composites in a synchronous thermal analyzer (STA) and a fixed-bed reactor. They found that the heat storage density of the composite containing 2.5 mol% TiO 2 was 798.37 kJ/kg after 30 cycles, which was 2.26 times as high as that of the pure CaCO 3 sample. This indicated that CaO/TiO 2 composite had better sintering resistance.

Organic Acid-Treated CaO-Based Composites
Pretreatment of natural calcium-based materials with organic acids can improve the pore structures of the materials, which enhances heat storage performance. Sánchez-Jiménez et al. [140] treated a mixture of limestone and dolomite with acetic acid to prepare calcium magnesium acetate (CaMgAc) material. CaMgAc possessed a stable porous structure, and nano-MgO grains were uniformly dispersed around CaO, which improved the sintering resistance of CaO. The effects of the acetic acid treatment on the heat storage characteristics of limestone are exhibited in Figure 10a. After 30 energy storage cycles, the effective conversion of natural limestone was only 0.38, while that of modified limestone with acetic acid was as high as 0.56. In addition, the effective conversion of CaMg50Ac after 30 cycles was 0.70, which was much higher than that of limestone, as shown in Figure 10b. Wang et al. [34] used citric acid, with stronger acidity and of lower price, to treat limestone and dolomite to prepare CaO/MgO composite materials. When the molar ratio of Ca 2+ /citric acid/Mg 2+ was 8:7:1, the composite exhibited higher storage cyclic stability in the heat storage cycles. Thermal storage density of the composite achieved 2450 kJ/kg after 20 cycles. Han et al. [141] prepared Ca/Al composite heat storage materials with four different calcium-based precursors (calcium formate, calcium acetate, calcium lactate, calcium gluconate), aluminum acetylacetonate, and citric acid. They found that the Ca/Al composite with the molar ratio of Ca to Al = 9:1 exhibited the largest volumetric heat storage density of 2.35 GJ/m 3 , which only dropped by 12% after 20 cycles.

Improvement on Optical and Thermal Properties of CaO-Based Materials in CaO/CaCO 3 TCHS
The Tammann temperature of calcium-based materials is relatively low, so CaO grains agglomerate and grow up during cyclic heat storage process at high temperature, leading to the blockage of the pore structure, which is manifested as a gradual decline in heat storage performance [43,123]. A large number of researches have focused on slowing down the sintering speed of calcium-based heat storage materials to improve cyclic stability. As mentioned in Section 3.2, the volumetric heat collection is more suitable for CaO/CaCO 3 heat storage system, which requires calcium-based materials with great optical and thermal properties. However, natural calcium-based materials usually have poor optical absorption capacities and thermal conductivity. In recent years, the optical absorption capacity and thermal conductivity of natural calcium-based materials have been given more attention and represent a valuable research direction.
Han et al. [142] prepared composite materials by impregnating in H 3 BO 3 solution with CaCO 3 and adding expanded graphite with high thermal conductivity for heat storage. They found that the thermal conductivity of the composite materials increased by 60% when 3 wt% expanded graphite was added. The expanded graphite exhibited strong sintering resistance. The heat storage density of the composite material was 1313 kJ/kg after 50 cycles, while that of limestone was only 452 kJ/kg. On this basis, Han et al. [143] also studied an effective compression method to make graphite nanosheets better support the pore structure of CaO-based materials, so the obtained composites possessed a higher volumetric energy density. However, it is worth noting that CO 2 attaches to graphite at high temperatures to form CO gas. More consideration should be given when choosing graphite as an additive. Da et al. [79] put forward a new idea to increase the blackness of calcium-based materials to achieve the direct absorption of solar energy in a CaO/CaCO 3 heat storage system. Their experiments showed that adding black FeMnO 3 and Fe 2 O 3 to CaO by the sol-gel method improved the optical absorption properties of the materials. When the molar ratio of Ca/Mn/Fe was 100:4:8, the solar absorption of the composite reached 89.81% as exhibited in Figure 11. In addition, the existence of FeMnO 3 and Fe 2 O 3 also enhanced the sintering resistance of CaO. The effective conversion of Ca/Fe/Mn composites remained as high as 0.8 after 20 cycles. Moreover, Teng et al. [82] optimized the structure of the Ca/Fe/Mn composite by using calcium gluconate as the precursor to prepare a porous Ca/Fe/Mn composite with an optical absorption rate of 90%. The heat storage capacity of the Ca/Fe/Mn composite decreased by 3.31% in 60 cycles. The average heat storage density of the composite after 60 cycles was 1450 kJ/kg, which was 1.76 times as high as that of CaCO 3 , indicating that it had higher cyclic stability. Song et al. [144] used aluminum nitrate and iron nitrate as precursors to dope iron and aluminum into CaCO 3 powder by the sol-gel method. They found that the decomposition rate of the composite increased and the decomposition temperature decreased. After 50 cycles, the heat storage density of the composite only dropped by 4.5%, which was about 87% higher than that of pure CaCO 3 . Similarly, the average optical absorption rate of the composite achieved 45.6%, while that of pure CaCO 3 reached only 8%. Li et al. [145] used Ca(OH) 2 powder, MnC 4 H 6 O 4 ·4H 2 O and SiC by extrusion-spheronization method to prepare Mn/SiC doped CaO pellets. They found that when SiC and MnO 2 were both doped at 5 wt%, CaO pellets exhibited the highest the optical absorption and heat storage capacity. In addition, the effective conversion of the Mn/SiC doped CaO pellets remained 0.48 after 30 cycles, while that of the pure CaO pellets achieved only 0.34. Similarly, the average optical absorption of the Mn/SiC doped CaO pellets reached 53%, while that of the original CaO particles was only 3%. Yang et al. [146] prepared Ca/Fe/Mn composite heat storage materials by utilizing carbonaceous microspheres as templates, which mainly consisted of CaCO 3 and Ca 2 FeMnO 5 . The average spectral absorption rate of the synthetic material with the molar ratio of Ca/Fe/Mn = 100:2:7 reached 76.8%, while that of pure CaCO 3 was only 10.8%. Zheng et al. [147] examined a variety of dark composite calcium-based heat storage materials by the sol-gel method, including Ca/Cu, Ca/Cu/Fe, Ca/Cu/Co, Ca/Cu/Cr, Ca/Cu/Mn, and Ca/Al/Cu/Fe materials. The results showed that Ca/Cu/Co, Ca/Cu/Cr, and Ca/Cu/Mn materials had strong optical absorption capacities, and their average spectral absorption of solar energy was greater than 60%. Table 4 summarizes the heat storage properties of the different CaO-based materials reported in the literature. It is found that adding dopants is still the most effective and common method to improve the heat storage stability of CaO-based materials. However, it is still unavoidable that the activity of CaO-based material decreases during long-term heat storage cycles. Calcium-based materials often need to add enough supporters to maintain relatively stable heat storage performance. This also decreases the content of CaO in the calcium-based material, resulting in a decrease in the heat storage density of the material per unit mass. Thus, how to enhance the heat storage performance and cyclic stability of calcium-based materials remain important. In addition, how to improve the optical and thermal properties of CaO-based materials is also the focus of researchers.

Conclusions
This paper reviewed and summarized the research progress of CaO/CaCO 3 heat storage in terms of system design, reaction conditions, and material properties. By summarizing a variety of integration schemes for CaO/CaCO 3 heat storage and CSP plants, the closed CO 2 Brayton cycle heat storage system is the most ideal integrated scheme. The performance degradation of CaO-based materials is still a major problem that restricts the development of CaO/CaCO 3 heat storage technology. The potential future research works are shown as follows: (1) System integration is currently limited to simulation research, which faces technological challenges, such as the fluctuation of solar radiation, the separation of gas-solid two phases, and so on, to realize industrial applications. The integrated system of CaO/CaCO 3 heat storage and CSP plant should be further designed and optimized to improve the sensible heat recovery network of the system and reduce energy loss. The design and production of equipment that is more compatible with CaO/CaCO 3 heat storage, especially particle receivers, need to meet the main requirements of great scalability and high thermal efficiency. (2) The preparation of CaO-based heat storage materials should be carried out in the direction of high cyclic activity and cyclic stability, and the preparation process of the materials should be optimized. The ideal CaO-based heat storage materials possess high heat storage density, great heat storage stability, and great absorption of sunlight, while economical preparation processes are also required. In addition, the specific application of the material needs to be combined with the reactor design.