High-Temperature Energy Storage: Kinetic Investigations of the CuO/Cu<sub>2</sub>O Reaction Cycle

Deutsch, Markus; Horvath, Florian; Knöll, Christian; Lager, Daniel; Gierl‐Mayer, Christian; Weinberger, P.; Winter, Franz

doi:10.1021/acs.energyfuels.6b02343

Cited by 54 publications

(33 citation statements)

References 38 publications

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“…are important parts of solid oxide fuel cells. [32][33][34][35] To estimate the catalytic activity of Pt 3 Zr, we compare the oxygen doped formation energy between Pt 3 Zr and many metals. As shown in Fig.…”

Section: Structural Predictionmentioning

confidence: 99%

First-principles study of a new structure and oxidation mechanism of Pt₃Zr

et al. 2017

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Zirconia (ZrO 2 )-metal interfaces are interesting for solid oxide fuel cells. Although the oxidation of Pt 3 Zr provides a new route for the formation of ZrO 2 -Pt interfaces, the crystal structure of Pt 3 Zr remains controversial and the oxidation mechanism of Pt 3 Zr is unclear. To solve these problems, we use firstprinciples calculations to explore the crystal structure of Pt 3 Zr. We demonstrate a stable structure of Pt 3 Zr based on phonon dispersion. Importantly, two new Pt 3 Zr structures, Ti 3 Pt-type (Pm 3m) and Fe 3 Al-type (Fm 3m), are predicted. To study the oxidation mechanism, two possible doped models are considered. The calculated results show that the O atom prefers to occupy the tetrahedral interstitial site (TI) in comparison to the octahedral interstitial site (OI). We find that the oxidizing capacity of the Fe 3 Al-type cubic structure is stronger than that of other structures. In particular, we predict that Pt 3 Zr exhibits better oxidation capacity in comparison to other metals because of the strong localized hybridization between Zr and O.

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Section: Structural Predictionmentioning

confidence: 99%

First-principles study of a new structure and oxidation mechanism of Pt₃Zr

et al. 2017

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“…Unusual Arrhenius trends at high temperatures were observed and reported by Kyaw et al [64] in their study "Carbonation of CaO for High Temperature Thermal Energy Storage" and by Schaube et al [65] for the CaO/Ca(OH) 2 system at high H 2 O partial pressures. Deutsch et al found a negative activation energy for the CuO/Cu 2 O system in STA experiments [33].…”

Section: Model Id Type F(α) A1mentioning

confidence: 99%

“…Implementation of the those kinetics investigations in thermochemical energy storage would not be possible due to the impact of support materials on the kinetics of Cu2O/CuO, which should be studied separately. In thermochemical energy storage, the kinetics of the reduction of CuO to Cu2O was reported by Deutsch et al [33] in simultaneous thermal analysis (STA) and in a fixed-bed reactor. They indicated cycle stability of Cu2O/CuO system up to 20 cycles at 950 °C and at an oxygen partial pressure of 0.21 bar for the oxidation reactions, reduction was carried out in a nitrogen atmosphere.…”

Section: Introductionmentioning

confidence: 95%

“…The sample was spun with back loading zero background sample holders and 2θ = 5-90 • at 25 • C. The diffractograms were evaluated with the PANalytical program suite HighScorePlus, version 3.0d. A Background correction and a Kα 2 strip were performed" [33].…”

Section: X-ray Diffraction (Xrd)mentioning

confidence: 99%

“…The metal redox oxides Co 3 O 4 /CoO and Cu 2 O/CuO have been investigated in recent research, because they possess the highest energy density, 844 and 810 kJ/kg, respectively. However, Cu 2 O/CuO have several unresolved challenges regarding application in TCES for this redox system, such as grain growth after thermal cycling, the close reduction temperature of CuO to the Cu 2 O melting point of 1235 • C, and a decrease in the conversion rate with O 2 after the very low number of redox cycles reported by various authors [22,23,[31][32][33]. However, the economic aspect and non-toxicity compared to Co 3 O 4 /CoO make the redox system Cu 2 O/CuO interesting for utilization as a thermochemical energy storage material [6,33].…”

Section: Introductionmentioning

confidence: 99%

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Impact of Partial Pressure, Conversion, and Temperature on the Oxidation Reaction Kinetics of Cu2O to CuO in Thermochemical Energy Storage

et al. 2019

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Metal oxides are promising potential candidates for thermochemical energy storage in concentrated solar power plants. In particular, the Cu2O/CuO system is suitable because of its high energy density, applied temperature interval, and reduced cost compared to the CoO/Co3O4 system. In heterogenous gas-solid reactions, the pressure affects the kinetics significantly. To quantify this effect for oxidation of Cu2O to CuO, isothermal runs between 800 °C and 930 °C at different oxygen partial pressures (0.1, 0.2, 0.5, and 1.0 bar) were conducted with thermogravimetric analysis (TGA). Defined fractions of CuO samples (1–100 µm) were analyzed with X-ray diffraction (XRD), Brunauer-Emmett-Teller (BET) analysis, and scanning electron microscopy (SEM) analysis. The kinetic analyses were performed with extended non-parametric kinetics (NPK), which is applied for the first time to consider the pressure term in the general kinetic equation in addition to the conversion and the temperature term. The results show how the oxygen partial pressure impacts the kinetics and how reparameterization of the pressure term affects the kinetic analysis of the oxidation reaction of Cu2O to CuO. The best conversion model is a two-dimensional Avrami-Erofeev model with an activation energy of 233 kJ/mol. The kinetic models for conversion, temperature, and pressure presented in this work provide one of the most important requirements for reactor designs.

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Oxygen Vacancy‐Rich Defects Porous Cu₂MgO₃/Mg_0.78Cu_0.22O Composite with Sinter‐Resistant and Highly Reactive for Long‐Duration High‐Temperature Thermochemical Energy Storage

Deng,

Gu,

et al. 2024

Adv Funct Materials

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High‐temperature thermochemical energy storage based on metal oxides is the key technology to reducing the levelized costs of electricity of the next‐generation concentrated solar power plants. CuO/Cu2O has wide availability and high energy density, but severe sintering leads to low reactivity. In this study, an innovative approach to modulate the oxygen vacancy content to change the surface properties and crystal structure to enhance the sintering resistance and redox reversibility is proposed. The re‐oxidation degree is increased from 46% to 99%, and the energy release rate is increased by 3.5 times. It remains 99.9% reduction and 97.1% oxidation activity after 3000 cycles, which is very valuable for engineering applications. Cu2MgO3 and Mg0.78Cu0.22O are prone to form oxygen vacancies, which promotes the formation of porous structures. Mg0.78Cu0.22O helps Cu2MgO3/CuO/Cu2O deliver more O through the surface. Mg0.78Cu0.22O is firmly and uniformly dispersed on the CuO/Cu2O surface after long cycling. They have a large binding energy, more charge transfer and enhanced bond energy at the interface. The mechanism of composite in increasing the sintering temperature and long‐term reaction stability is revealed from experimental and theoretical calculations, which provides a new idea for the rational design of thermochemical energy storage materials.

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High-Temperature Energy Storage: Kinetic Investigations of the CuO/Cu₂O Reaction Cycle

Cited by 54 publications

References 38 publications

First-principles study of a new structure and oxidation mechanism of Pt₃Zr

First-principles study of a new structure and oxidation mechanism of Pt₃Zr

Impact of Partial Pressure, Conversion, and Temperature on the Oxidation Reaction Kinetics of Cu2O to CuO in Thermochemical Energy Storage

Oxygen Vacancy‐Rich Defects Porous Cu₂MgO₃/Mg_0.78Cu_0.22O Composite with Sinter‐Resistant and Highly Reactive for Long‐Duration High‐Temperature Thermochemical Energy Storage

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High-Temperature Energy Storage: Kinetic Investigations of the CuO/Cu2O Reaction Cycle

Cited by 54 publications

References 38 publications

First-principles study of a new structure and oxidation mechanism of Pt3Zr

First-principles study of a new structure and oxidation mechanism of Pt3Zr

Impact of Partial Pressure, Conversion, and Temperature on the Oxidation Reaction Kinetics of Cu2O to CuO in Thermochemical Energy Storage

Oxygen Vacancy‐Rich Defects Porous Cu2MgO3/Mg0.78Cu0.22O Composite with Sinter‐Resistant and Highly Reactive for Long‐Duration High‐Temperature Thermochemical Energy Storage

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High-Temperature Energy Storage: Kinetic Investigations of the CuO/Cu₂O Reaction Cycle

First-principles study of a new structure and oxidation mechanism of Pt₃Zr

First-principles study of a new structure and oxidation mechanism of Pt₃Zr

Oxygen Vacancy‐Rich Defects Porous Cu₂MgO₃/Mg_0.78Cu_0.22O Composite with Sinter‐Resistant and Highly Reactive for Long‐Duration High‐Temperature Thermochemical Energy Storage