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1. In-situ neutron diffraction during reversible deuterium loading in Ti-rich and Mn-substituted Ti(Fe,Mn)0.90 alloys

Author

Dematteis, Erika Michela, Barale, Jussara, Capurso, Giovanni, Deledda, Stefano, Sørby, Magnus H., Cuevas, Fermin, Latroche, Michel, and Baricco, Marcello

Subjects
Condensed Matter - Materials Science
Abstract

Hydrogen is an efficient energy carrier that can be produced from renewable sources, enabling the transition towards CO2-free energy. Hydrogen can be stored for a long period in the solid-state, with suitable alloys. Ti-rich TiFe0.90 compound exhibits a mild activation process for the first hydrogenation, and Ti(Fe,Mn)0.90 substituted alloys can lead to the fine tuning of equilibrium pressure as a function of the final application. In this study, the crystal structure of TiFe(0.90-x)Mnx alloys (x = 0, 0.05 and 0.10) and their deuterides has been determined by in-situ neutron diffraction, while recording Pressure-Composition Isotherms at room temperature. The investigation aims at analysing the influence of Mn for Fe substitution in Ti-rich Ti(Fe,Mn)0.90 alloys on structural properties during reversible deuterium loading, which is still unsolved and seldom explored. After activation, samples have been transferred into custom-made stainless-steel and aluminium alloy cells used for in-situ neutron diffraction experiments during deuterium loading at ILL and ISIS neutron facilities, respectively. The study enables remarkable understanding on hydrogen storage, basic structural knowledge, and support to the industrial application of TiFe-type alloys for integrated hydrogen tank in energy storage systems by determining the volume expansion during deuteration. Furthermore, the study demonstrates that different contents of Mn do not significantly change the volumetric expansion during phase transitions, affecting only the deuterium content for the {\gamma} phase and the cell evolution for the \b{eta} phase. The study confirms that the deuterated structures of the {\gamma} phase upon absorption, \b{eta} and {\alpha} phase upon desorption, correspond to S.G. Cmmm, P2221 and Pm-3m, respectively., Comment: 34 pages, 5 figures, 4 tables, ESI

Published
2022
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2. Theoretical and Experimental Study of LiBH4-LiBr Phase Diagram

Author

Gulino, Valerio, Dematteis, Erika Michela, Corno, Marta, Palumbo, Mauro, and Baricco, Marcello

Subjects
Condensed Matter - Materials Science
Abstract

Because substitutions of BH4- anion with Br can stabilize the hexagonal structure of the LiBH4 at room temperature, leading to a high Li-ion conductivity, its thermodynamic stability has been investigated in this work. The binary LiBH4-LiBr system has been explored by means of X-ray diffraction and differential scanning calorimetry, combined with an assessment of thermodynamic properties. The monophasic zone of the hexagonal Li(BH4)1-x(Br)x solid solution has been defined from x=0.30 to x=0.55 at room temperature. Solubility limits have been determined by in-situ X-ray diffraction at various temperatures. For the formation of the h-Li(BH4)0.6(Br)0.4 solid solution, a value of the enthalpy of mixing has been determined experimentally equal to 1.0 kJ/mol. In addition, the enthalpy of melting has been measured for various compositions. Lattice stabilities of LiBH4 and LiBr have been determined by ab initio calculations, using CRYSTAL and VASP codes. Combining results of experiments and theoretical calculations, the LiBH4-LiBr phase diagram has been determined in all composition and temperature range by the CALPHAD method., Comment: 32 pages, 5 figures, 6 tables

Published
2021

3. Substitutional effects in TiFe for hydrogen storage: a comprehensive review

Author

Dematteis, Erika Michela, Berti, Nicola, Cuevas, Fermin, Latroche, Michel, and Baricco, Marcello

Subjects
Condensed Matter - Materials Science
Abstract

The search for suitable materials for solid-state stationary storage of green hydrogen is pushing the implementation of efficient renewable energy systems. This involves rational design and modification of cheap alloys for effective storage in mild conditions of temperature and pressure. Among many intermetallic compounds described in the literature, TiFe-based systems have recently regained vivid interest as materials for practical applications since they are low-cost and they can be tuned to match required pressure and operation conditions. This work aims to provide a comprehensive review of publications involving chemical substitution in TiFe-based compounds for guiding compound design and materials selection in current and future hydrogen storage applications. Mono- and multi-substituted compounds modify TiFe thermodynamics and are beneficial for many hydrogenation properties. They will be reviewed and deeply discussed, with a focus on manganese substitution., Comment: 76 pages, 7 Figures, 5 Tables

Published
2021
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4. Fundamental hydrogen storage properties of TiFe-alloy with partial substitution of Fe by Ti and Mn

Author

Dematteis, Erika Michela, Dreistadt, David Michael, Capurso, Giovanni, Jepsen, Julian, Cuevas, Fermin, and Latroche, Michel

Subjects
Condensed Matter - Materials Science
Abstract

TiFe intermetallic compound has been extensively studied, owing to its low cost, good volumetric hydrogen density, and easy tailoring of hydrogenation thermodynamics by elemental substitution. All these positive aspects make this material promising for large-scale applications of solid-state hydrogen storage. On the other hand, activation and kinetic issues should be amended and the role of elemental substitution should be further understood. This work investigates the thermodynamic changes induced by the variation of Ti content along the homogeneity range of the TiFe phase (Ti:Fe ratio from 1:1 to 1:0.9) and of the substitution of Mn for Fe between 0 and 5 at.%. In all considered alloys, the major phase is TiFe-type together with minor amounts of TiFe2 or \b{eta}-Ti-type and Ti4Fe2O-type at the Ti-poor and rich side of the TiFe phase domain, respectively. Thermodynamic data agree with the available literature but offer here a comprehensive picture of hydrogenation properties over an extended Ti and Mn compositional range. Moreover, it is demonstrated that Ti-rich alloys display enhanced storage capacities, as long as a limited amount of \b{eta}-Ti is formed. Both Mn and Ti substitutions increase the cell parameter by possibly substituting Fe, lowering the plateau pressures and decreasing the hysteresis of the isotherms. A full picture of the dependence of hydrogen storage properties as a function of the composition will be discussed, together with some observed correlations., Comment: 39 pages, 9 figure, 4 tables, 3 supplementary figures

Published
2020
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5. Hydrogen storage properties of Mn and Cu for Fe substitution in TiFe0.9 intermetallic compound

Author

Dematteis, Erika Michela, Cuevas, Fermin, and Latroche, Michel

Subjects
Condensed Matter - Materials Science
Abstract

The present study investigates the partial substitutions of Mn and Cu for Fe in the TiFe-system to gain better understanding of the role of elemental substitution on its hydrogen storage properties. The TiFe0.88-xMn0.02Cux (x = 0, 0.02, 0.04) compositions were studied. From X-Ray Diffraction (XRD) and Electron Probe Micro-Analysis (EPMA), it was found that all alloys are multi-phase, with TiFe as a major phase, together with \b{eta}-Ti and Ti4Fe2O-type as secondary precipitates, of all them containing also Mn and Cu. Increasing the Cu content augments the secondary phase amounts. Low quantity of secondary phases helps the activation of the main TiFe phase for the first hydrogen absorption, but on increasing their amounts, harsher activation occurs. Both Mn and Cu substitutions increase the cell parameter of TiFe, thus decreasing the first plateau pressure. However, Cu substitution rises the second plateau pressure revealing the predominancy of electronic effects associated to this substitution. All samples have fast kinetics and high hydrogen capacity making these substituted compounds promising for large scale stationary applications., Comment: 25 pages, 4 Tables, 4 Figures, 5 ESI Figures, 1 ESI Table

Published
2020
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8. Experimental and theoretical studies of the LiBH4-LiI phase diagram

Author

Mazzucco, Asya, Dematteis, Erika Michela, Gulino, Valerio, Corno, Marta, Sgroi, Mauro Francesco, Palumbo, Mauro, Baricco, Marcello, Mazzucco, Asya, Dematteis, Erika Michela, Gulino, Valerio, Corno, Marta, Sgroi, Mauro Francesco, Palumbo, Mauro, and Baricco, Marcello

Abstract

The hexagonal structure of LiBH4 at room temperature can be stabilised by substituting the BH4− anion with I−, leading to high Li-ion conductive materials. A thermodynamic description of the pseudo-binary LiBH4-LiI system is presented. The system has been explored investigating several compositions, synthetized by ball milling and subsequently annealed. X-ray diffraction and Differential Scanning Calorimetry have been exploited to determine structural and thermodynamic features of various samples. The monophasic zone of the hexagonal Li(BH4)1−x(I)x solid solution has been experimentally defined equal to 0.18 ≤ x ≤ 0.60 at 25 °C. In order to establish the formation of the hexagonal solid solution, the enthalpy of mixing was experimentally determined, converging to a value of 1800 ± 410 J mol−1. Additionally, the enthalpy of melting was acquired for samples that differ in molar fraction. By merging experimental results, literature data and ab initio theoretical calculations, the pseudo-binary LiBH4-LiI phase diagram has been assessed and evaluated across all compositions and temperature ranges by applying the CALPHAD method.

Published
2024

9. Experimental and theoretical studies of the LiBH4-LiI phase diagram

Author

Materials Chemistry and Catalysis, Sub Materials Chemistry and Catalysis, Mazzucco, Asya, Dematteis, Erika Michela, Gulino, Valerio, Corno, Marta, Sgroi, Mauro Francesco, Palumbo, Mauro, Baricco, Marcello, Materials Chemistry and Catalysis, Sub Materials Chemistry and Catalysis, Mazzucco, Asya, Dematteis, Erika Michela, Gulino, Valerio, Corno, Marta, Sgroi, Mauro Francesco, Palumbo, Mauro, and Baricco, Marcello

Published
2024

12. Magnesium- and intermetallic alloys-based hydrides for energy storage: Modelling, synthesis and properties

Author

Pasquini, Luca, Sakaki, Kouji, Akiba, Etsuo, Allendorf, Mark D., Alvares, Ebert, Babai, Dotan, Baricco, Marcello, Bereznitsky, Matvey, Buckley, Craig E., Cho, Young Whan, Cuevas, Fermin, De Rango, Patricia, Dematteis, Erika Michela, Denys, Roman V., Dornheim, Martin, Hariyadi, Arif, Heo, Tae Wook, Hirscher, Michael, Humphries, Terry D., Huot, Jacques, Jacob, Isaac, Jensen, Torben R., Jerabek, Paul, Kang, Shin Young, Keilbart, Nathan, Kim, Hyunjeong, Latroche, Michel, Leardini, F., Li, Haiwen, Ling, Sanliang, Lototskyy, Mykhaylo V., Mullen, Ryan, Orimo, Shin Ichi, Paskevicius, Mark, Pistidda, Claudio, Polanski, Marek, Rabkin, Eugen, Sahlberg, Martin, Sartori, Sabrina, Santhosh, Archa, Sato, Toyoto, Shneck, Roni Z., Shang, Yuanyuan, Stavila, Vitalie, Suh, Jin Yoo, Suwarno, Suwarno, Thi Thu, Le, Wan, Liwen F., Webb, Colin J., Witman, Matthew, Wan, Chubin, Wood, Brandon C., and Yartys, Volodymyr A.

Subjects
General Earth and Planetary Sciences, General Environmental Science
Abstract

Hydrides based on magnesium and intermetallic compounds provide a viable solution to the challenge of energy storage from renewable sources, thanks to their ability to absorb and desorb hydrogen in a reversible way with a proper tuning of pressure and temperature conditions. Therefore, they are expected to play an important role in the clean energy transition and in the deployment of hydrogen as an efficient energy vector. This review, by experts of Task 40 'Energy Storage and Conversion based on Hydrogen' of the Hydrogen Technology Collaboration Programme of the International Energy Agency, reports on the latest activities of the working group 'Magnesium- and Intermetallic alloys-based Hydrides for Energy Storage'. The following topics are covered by the review: multiscale modelling of hydrides and hydrogen sorption mechanisms; synthesis and processing techniques; catalysts for hydrogen sorption in Mg; Mg-based nanostructures and new compounds; hydrides based on intermetallic TiFe alloys, high entropy alloys, Laves phases, and Pd-containing alloys. Finally, an outlook is presented on current worldwide investments and future research directions for hydrogen-based energy storage.

Published
2022

13. Hydrogen storage in complex hydrides: past activities and new trends

Author

Dematteis, Erika Michela, primary, Amdisen, Mads B, additional, Autrey, Tom, additional, Barale, Jussara, additional, Bowden, Mark E, additional, Buckley, Craig E, additional, Cho, Young Whan, additional, Deledda, Stefano, additional, Dornheim, Martin, additional, de Jongh, Petra, additional, Grinderslev, Jakob B, additional, Gizer, Gökhan, additional, Gulino, Valerio, additional, Hauback, Bjørn C, additional, Heere, Michael, additional, Heo, Tae Wook, additional, Humphries, Terry D, additional, Jensen, Torben R, additional, Kang, Shin Young, additional, Lee, Young-Su, additional, Li, Hai-Wen, additional, Li, Sichi, additional, Møller, Kasper T, additional, Ngene, Peter, additional, Orimo, Shin-ichi, additional, Paskevicius, Mark, additional, Polanski, Marek, additional, Takagi, Shigeyuki, additional, Wan, Liwen, additional, Wood, Brandon C, additional, Hirscher, Michael, additional, and Baricco, Marcello, additional

Published
2022
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14. Hydrogen storage in complex hydrides: Past activities and new trends

Author

Dematteis, Erika Michela, Amdisen, Mads B., Autrey, Tom, Barale, Jussara, Bowden, Mark E., Buckley, Craig E., Cho, Young Whan, Deledda, Stefano, Dornheim, Martin, De Jongh, Petra, Grinderslev, Jakob B., Gizer, Gökhan, Gulino, Valerio, Hauback, Bjørn C., Heere, Michael, Heo, Tae Wook, Humphries, Terry D., Jensen, Torben R., Kang, Shin Young, Lee, Young Su, Li, Hai Wen, Li, Sichi, Møller, Kasper T., Ngene, Peter, Orimo, Shin Ichi, Paskevicius, Mark, Polanski, Marek, Takagi, Shigeyuki, Wan, Liwen, Wood, Brandon C., Hirscher, Michael, Baricco, Marcello, Dematteis, Erika Michela, Amdisen, Mads B., Autrey, Tom, Barale, Jussara, Bowden, Mark E., Buckley, Craig E., Cho, Young Whan, Deledda, Stefano, Dornheim, Martin, De Jongh, Petra, Grinderslev, Jakob B., Gizer, Gökhan, Gulino, Valerio, Hauback, Bjørn C., Heere, Michael, Heo, Tae Wook, Humphries, Terry D., Jensen, Torben R., Kang, Shin Young, Lee, Young Su, Li, Hai Wen, Li, Sichi, Møller, Kasper T., Ngene, Peter, Orimo, Shin Ichi, Paskevicius, Mark, Polanski, Marek, Takagi, Shigeyuki, Wan, Liwen, Wood, Brandon C., Hirscher, Michael, and Baricco, Marcello

Abstract

Intense literature and research efforts have focussed on the exploration of complex hydrides for energy storage applications over the past decades. A focus was dedicated to the determination of their thermodynamic and hydrogen storage properties, due to their high gravimetric and volumetric hydrogen storage capacities, but their application has been limited because of harsh working conditions for reversible hydrogen release and uptake. The present review aims at appraising the recent advances on different complex hydride systems, coming from the proficient collaborative activities in the past years from the research groups led by the experts of the Task 40 'Energy Storage and Conversion Based on Hydrogen' of the Hydrogen Technology Collaboration Programme of the International Energy Agency. An overview of materials design, synthesis, tailoring and modelling approaches, hydrogen release and uptake mechanisms and thermodynamic aspects are reviewed to define new trends and suggest new possible applications for these highly tuneable materials.

Published
2022

15. Hydrogen storage in complex hydrides: Past activities and new trends

Author

Sub Materials Chemistry and Catalysis, Materials Chemistry and Catalysis, Dematteis, Erika Michela, Amdisen, Mads B., Autrey, Tom, Barale, Jussara, Bowden, Mark E., Buckley, Craig E., Cho, Young Whan, Deledda, Stefano, Dornheim, Martin, De Jongh, Petra, Grinderslev, Jakob B., Gizer, Gökhan, Gulino, Valerio, Hauback, Bjørn C., Heere, Michael, Heo, Tae Wook, Humphries, Terry D., Jensen, Torben R., Kang, Shin Young, Lee, Young Su, Li, Hai Wen, Li, Sichi, Møller, Kasper T., Ngene, Peter, Orimo, Shin Ichi, Paskevicius, Mark, Polanski, Marek, Takagi, Shigeyuki, Wan, Liwen, Wood, Brandon C., Hirscher, Michael, Baricco, Marcello, Sub Materials Chemistry and Catalysis, Materials Chemistry and Catalysis, Dematteis, Erika Michela, Amdisen, Mads B., Autrey, Tom, Barale, Jussara, Bowden, Mark E., Buckley, Craig E., Cho, Young Whan, Deledda, Stefano, Dornheim, Martin, De Jongh, Petra, Grinderslev, Jakob B., Gizer, Gökhan, Gulino, Valerio, Hauback, Bjørn C., Heere, Michael, Heo, Tae Wook, Humphries, Terry D., Jensen, Torben R., Kang, Shin Young, Lee, Young Su, Li, Hai Wen, Li, Sichi, Møller, Kasper T., Ngene, Peter, Orimo, Shin Ichi, Paskevicius, Mark, Polanski, Marek, Takagi, Shigeyuki, Wan, Liwen, Wood, Brandon C., Hirscher, Michael, and Baricco, Marcello

Published
2022

19. Characterisation of powder and pellets

Author

Dematteis, Erika Michela, Cuevas, Fermin, and Latroche, Michel

Subjects
industrial production, TiFe, metal hydride, intermetallic compound, hydrogen storage
Abstract

Summary of deliverable D3.2. In this deliverable the characterisations of powder and pellets produced for the HyCARE system and performed by the partners are discussed. GKN produced at the industrial scale up to 200 kg as a first batch for the prototype tank and afterwards up to 4 tons for the final demonstration tank the powder material of the selected composition. The produced material that includes 2% of binder (Lot IX-20015, 200 kg) has been distributed among the partners in form of powder and pellets for its characterization and the development of a first prototype module of the integrated system. Furthermore, the large 4 t production has been characterized at GKN (Lot 570119000/1-4, 4 tons) and related results are also presented. In details: structure, microstructure, particle size, density, thermal conductivity, heat capacity, composition, hydrogen storage properties (reversible capacity, thermodynamics, kinetics), poisoning and cycling properties have been reported.

Published
2021

20. Processing parameters

Author

Dematteis, Erika Michela, Cuevas, Fermin, Latroche, Michel, Marcello Baricco, Jussara Barale, Bettina Neumann, Giovanni Capurso, and Stefano Deledda

Subjects
industrial production, TiFe, metal hydride, intermetallic compound, hydrogen storage
Abstract

Summary of deliverable D2.3. After the studies conducted at CNRS, the optimised composition was selected by the consortium for the HyCARE project, owing to its easy activation, good thermodynamics, kinetics, high reversible capacity at 55 °C and good cycling performances, as shown in Deliverable 2.2. A first 5 kg industrial batch was produced by GKN. Here details on processing parameters and characteristics of the industrially produced alloy are resumed thanks to a muti-laboratory testing of the material.

Published
2020
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21. Erratum: Hadjixenophontos, E.; et al. A Review of the MSCA ITN ECOSTORE—Novel Complex Metal Hydrides for Efficient and Compact Storage of Renewable Energy as Hydrogen and Electricity. Inorganics 2020, 8, 17

Author

Hadjixenophontos, Efi, primary, Dematteis, Erika Michela, additional, Berti, Nicola, additional, Wołczyk, Anna Roza, additional, Huen, Priscilla, additional, Brighi, Matteo, additional, Le, Thi Thu, additional, Santoru, Antonio, additional, Payandeh, SeyedHosein, additional, Peru, Filippo, additional, Dao, Anh Ha, additional, Liu, Yinzhe, additional, and Heere, Michael, additional

Published
2020
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22. A Review of the MSCA ITN ECOSTORE—Novel Complex Metal Hydrides for Efficient and Compact Storage of Renewable Energy as Hydrogen and Electricity

Author

Hadjixenophontos, Efi, primary, Dematteis, Erika Michela, additional, Berti, Nicola, additional, Wołczyk, Anna Roza, additional, Huen, Priscilla, additional, Brighi, Matteo, additional, Le, Thi Thu, additional, Santoru, Antonio, additional, Payandeh, SeyedHosein, additional, Peru, Filippo, additional, Dao, Anh Ha, additional, Liu, Yinzhe, additional, and Heere, Michael, additional

Published
2020
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24. Characterisation of powder and pellets

Author

Dematteis, Erika Michela, Cuevas, Fermin, and Latroche, Michel

Subjects
industrial production, TiFe, metal hydride, 7. Clean energy, intermetallic compound, hydrogen storage
Abstract

Summary of deliverable D3.2. In this deliverable the characterisations of powder and pellets produced for the HyCARE system and performed by the partners are discussed. GKN produced at the industrial scale up to 200 kg as a first batch for the prototype tank and afterwards up to 4 tons for the final demonstration tank the powder material of the selected composition. The produced material that includes 2% of binder (Lot IX-20015, 200 kg) has been distributed among the partners in form of powder and pellets for its characterization and the development of a first prototype module of the integrated system. Furthermore, the large 4 t production has been characterized at GKN (Lot 570119000/1-4, 4 tons) and related results are also presented. In details: structure, microstructure, particle size, density, thermal conductivity, heat capacity, composition, hydrogen storage properties (reversible capacity, thermodynamics, kinetics), poisoning and cycling properties have been reported.

25. Optimized alloy composition

Author

Dematteis, Erika Michela, Cuevas, Fermin, and Latroche, Michel

Subjects
metal hydrides, 13. Climate action, TiFe, 7. Clean energy, intermetallic compound, hydrogen storage
Abstract

Summary of deliverable D2.1. The increase in air pollution and global temperatures demonstrates how essential it is to look for alternatives to fossil fuels. The efficient storage of renewable energy would enable the transition towards CO2-free energy. Hydrogen can be produced from renewable sources and, as an efficient energy carrier, it can be stored for a long period. Metal hydrides are safe materials for solid-state hydrogen storage under mild conditions. At CNRS, an investigation to define the optimal hydrogen carrier composition was performed at the lab-scale. Different experimental techniques were used for the synthesis and characterisation of different substituted FeTi-alloys. Considering the goals of the project, reversible capacity, PCI, activation and cycling properties have been determined.

26. Experimental and theoretical studies of the LiBH 4 -LiI phase diagram.

Author

Mazzucco A, Dematteis EM, Gulino V, Corno M, Sgroi MF, Palumbo M, and Baricco M

Abstract

The hexagonal structure of LiBH 4 at room temperature can be stabilised by substituting the BH 4 - anion with I - , leading to high Li-ion conductive materials. A thermodynamic description of the pseudo-binary LiBH 4 -LiI system is presented. The system has been explored investigating several compositions, synthetized by ball milling and subsequently annealed. X-ray diffraction and Differential Scanning Calorimetry have been exploited to determine structural and thermodynamic features of various samples. The monophasic zone of the hexagonal Li(BH 4 ) 1- x (I) x solid solution has been experimentally defined equal to 0.18 ≤ x ≤ 0.60 at 25 °C. In order to establish the formation of the hexagonal solid solution, the enthalpy of mixing was experimentally determined, converging to a value of 1800 ± 410 J mol -1 . Additionally, the enthalpy of melting was acquired for samples that differ in molar fraction. By merging experimental results, literature data and ab initio theoretical calculations, the pseudo-binary LiBH 4 -LiI phase diagram has been assessed and evaluated across all compositions and temperature ranges by applying the CALPHAD method., Competing Interests: All authors declare that they have no conflicts of interest., (This journal is © The Royal Society of Chemistry.)

Published
2024
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