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1. Ion Intercalation in Lanthanum Strontium Ferrite for Aqueous Electrochemical Energy Storage Devices

Author

Tang, Yunqing, Chiabrera, Francesco, Morata, Alex, Cavallaro, Andrea, Liedke, Maciej O., Avireddy, Hemesh, Maller, Mar, Butterling, Maik, Wagner, Andreas, Stchakovsky, Michel, Baiutti, Federico, Aguadero, Ainara, and Tarancón, Albert

Subjects
Condensed Matter - Materials Science
Abstract

Ion intercalation of perovskite oxides in liquid electrolytes is a very promising method for controlling their functional properties while storing charge, which opens the potential application in different energy and information technologies. Although the role of defect chemistry in the oxygen intercalation in a gaseous environment is well established, the mechanism of ion intercalation in liquid electrolytes at room temperature is poorly understood. In this study, the defect chemistry during ion intercalation of La0.5Sr0.5FeO3-{\delta} thin films in alkaline electrolytes is studied. Oxygen and proton intercalation into the LSF perovskite structure is observed at moderate electrochemical potentials (0.5 V to -0.4 V), giving rise to a change in the oxidation state of Fe (as a charge compensation mechanism). The variation of the concentration of holes as a function of the intercalation potential was characterized by in-situ ellipsometry and the concentration of electron holes was indirectly quantified for different electrochemical potentials. Finally, a dilute defect chemistry model that describes the variation of defect species during ionic intercalation was developed.

Published
2023
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5. Supplementary Materials of the article FeS2 decorated Carbon NanoFibers as a solid phase conversion cathode for Li-S batteries

Author

Jacas Biendicho, Jordi [jjacas@irec.cat], Jacas Biendicho, Jordi, Mazaira, Pedro, Avireddy, Hemesh, Zhang, Chaoqi, Tang, Peng-Yi, Missyul, Alexander, Trilla, Lluis, Arbiol, Jordi, Morante, Joan Ramón, Cabot, Andreu, Jacas Biendicho, Jordi [jjacas@irec.cat], Jacas Biendicho, Jordi, Mazaira, Pedro, Avireddy, Hemesh, Zhang, Chaoqi, Tang, Peng-Yi, Missyul, Alexander, Trilla, Lluis, Arbiol, Jordi, Morante, Joan Ramón, and Cabot, Andreu

Published
2023

6. FeS2-Decorated Carbon NanoFiber as Solid Phase Conversion-Type Cathode for Li-S Batteries

Author

Generalitat de Catalunya, Ministerio de Economía y Competitividad (España), Ministerio de Ciencia, Innovación y Universidades (España), Agencia Estatal de Investigación (España), European Commission, Ministerio de Ciencia e Innovación (España), Consejo Superior de Investigaciones Científicas (España), Jacas Biendicho, Jordi [0000-0001-5981-6168], Mazaira, Pedro [0009-0002-6314-4725], Zhang, Chaoqi [0000-0002-0357-235X], Missyul, Alexander [0000-0002-0577-4481], Arbiol, Jordi [0000-0002-0695-1726], Jacas Biendicho, Jordi, Mazaira, Pedro, Avireddy, Hemesh, Zhang, Chaoqi, Tang, Peng-Yi, Missyul, Alexander, Trilla, Lluis, Arbiol, Jordi, Morante, Joan Ramón, Cabot, Andreu, Generalitat de Catalunya, Ministerio de Economía y Competitividad (España), Ministerio de Ciencia, Innovación y Universidades (España), Agencia Estatal de Investigación (España), European Commission, Ministerio de Ciencia e Innovación (España), Consejo Superior de Investigaciones Científicas (España), Jacas Biendicho, Jordi [0000-0001-5981-6168], Mazaira, Pedro [0009-0002-6314-4725], Zhang, Chaoqi [0000-0002-0357-235X], Missyul, Alexander [0000-0002-0577-4481], Arbiol, Jordi [0000-0002-0695-1726], Jacas Biendicho, Jordi, Mazaira, Pedro, Avireddy, Hemesh, Zhang, Chaoqi, Tang, Peng-Yi, Missyul, Alexander, Trilla, Lluis, Arbiol, Jordi, Morante, Joan Ramón, and Cabot, Andreu

Abstract

A new cathode material, FeS2-decorated carbon nanofiber (CNF), is proposed for Li-S batteries. The structure and physicochemical properties of the material have been engineered to enhance the poor cycling stability typically displayed by sulfur composites. The composite material shows a complex architecture with a matrix of CNF hosting the sulfur and core-shell FeS2 nanoparticles acting as a catalyst for a solid phase conversion-type reaction. This cathode delivers high discharge capacities of 864, 798, 689, 595 and 455 mAhg−1 at C/10, C/5, C/2, 1C and 2C, respectively, with a stable capacity retention of 87% at 2C after 300 cycles. FeS2-decorated CNF has been characterised using several techniques, including in-situ battery measurements at the ALBA synchrotron facility and high-throughput microscopy, giving valuable insights into its charge/discharge reaction mechanism. The excellent performance obtained is combined with the use of just low-cost and abundant elements such as iron, sulfur and carbon, which makes this battery highly promising for the next generation of electrochemical energy storage devices.

Published
2023

7. FeS 2 -Decorated Carbon NanoFiber as Solid Phase Conversion-Type Cathode for Li-S Batteries.

Author

Jacas Biendicho, Jordi, Mazaira, Pedro, Avireddy, Hemesh, Zhang, Chaoqi, Tang, Pengyi, Missyul, Alexander, Trilla, Lluis, Arbiol, Jordi, Morante, Joan Ramon, and Cabot, Andreu

Subjects
LITHIUM sulfur batteries, CATHODES, SUPERIONIC conductors, IRON, COMPOSITE materials, ENERGY storage, CARBON nanofibers
Abstract

A new cathode material, FeS2-decorated carbon nanofiber (CNF), is proposed for Li-S batteries. The structure and physicochemical properties of the material have been engineered to enhance the poor cycling stability typically displayed by sulfur composites. The composite material shows a complex architecture with a matrix of CNF hosting the sulfur and core-shell FeS2 nanoparticles acting as a catalyst for a solid phase conversion-type reaction. This cathode delivers high discharge capacities of 864, 798, 689, 595 and 455 mAhg−1 at C/10, C/5, C/2, 1C and 2C, respectively, with a stable capacity retention of 87% at 2C after 300 cycles. FeS2-decorated CNF has been characterised using several techniques, including in-situ battery measurements at the ALBA synchrotron facility and high-throughput microscopy, giving valuable insights into its charge/discharge reaction mechanism. The excellent performance obtained is combined with the use of just low-cost and abundant elements such as iron, sulfur and carbon, which makes this battery highly promising for the next generation of electrochemical energy storage devices. [ABSTRACT FROM AUTHOR]

Published
2023
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8. Contact resistance stability and cation mixing in a Vulcan-based LiNi1/3Co1/3Mn1/3O2 slurry for semi-solid flow batteries

Author

Jordi Jacas Biendicho, Cristina Flox, Victor Izquierdo, Joan Ramon Morante, and Avireddy Hemesh

Subjects
Inorganic Chemistry, symbols.namesake, Materials science, Chemical engineering, Rietveld refinement, Scanning electron microscope, Contact resistance, symbols, Slurry, Raman spectroscopy, Electrochemistry, Flow battery, Dielectric spectroscopy
Abstract

The Semi-Solid Flow Battery (SSFB) is an interesting energy storage system (ESS) for stationary applications but, in spite of the significant work presented on this technology so far, understanding the chemical and physical factors limiting its electrochemical performance is still blurred by measurements under static conditions rather than under real operando conditions. In this study, we have used Vulcan carbon as a conductive additive to formulate LiNi1/3Co1/3Mn1/3O2 (NCM) based slurries as the catholyte to characterize electrical and electrochemical performances using a 3-electrode flow cell by electrochemical impedance spectroscopy (EIS) and galvanostatic charge/discharge (GCD), respectively. The results are correlated with post-mortem analyses of recovered slurries using Scanning Electron Microscopy (SEM), Raman spectroscopy and Rietveld refinement of the NCM crystal structure. Due to the improved electrochemical cycling stability of the Vulcan-based NCM slurry and cell configuration used for measurements, we have been able to characterize the system in terms of electrical contributions and correlate them with particle degradation as well as detect antisite defect formation on cycling. The electrical stability of the contact resistance and cation mixing are identified as factors limiting the performance of the semi-solid slurry. The latter is frequently reported in porous electrodes for Li-ion batteries but, to our knowledge, it has not been reported for SSFBs to date.

Published
2021

9. Temperature-Driven Chemical Segregation in Co-Free Li-Rich-Layered Oxides and Its Influence on Electrochemical Performance

Author

Rajappa Prakasha, Kunkanadu, Grins, Jekabs, Jaworski, Aleksander, Thersleff, Thomas, Svensson, Gunnar, Jøsang, Leif Olav, Dalager Dyrli, Anne, Paulus, Andreas, De Sloovere, Dries, D'Haen, Jan, Van Bael, Marlies K., Hardy, An, Avireddy, Hemesh, Ramon Morante, Joan, Jacas Biendicho, Jordi, Rajappa Prakasha, Kunkanadu, Grins, Jekabs, Jaworski, Aleksander, Thersleff, Thomas, Svensson, Gunnar, Jøsang, Leif Olav, Dalager Dyrli, Anne, Paulus, Andreas, De Sloovere, Dries, D'Haen, Jan, Van Bael, Marlies K., Hardy, An, Avireddy, Hemesh, Ramon Morante, Joan, and Jacas Biendicho, Jordi

Abstract

Co-free Li-rich layered oxides are gaining interest as feasible positive electrode materials in lithium-ion batteries (LIBs) in terms of energy density, cost reduction, and alleviating safety concerns. Unfortunately, their commercialization is hindered by severe structural degradation that occurs during electrochemical operation. The study at hand demonstrates advanced structural engineering of a Li-rich Co-free oxide with composition Li1.1Ni0.35Mn0.55O2 by spray pyrolysis and subsequent calcination of an aqueous precursor, creating a segregated structure of two distinct layered phases with space groups R3̅m (rhombohedral) and C2/m (monoclinic). This particular structure was investigated with powder neutron diffraction, high-resolution analytical transmission electron microscopy imaging, and electron energy loss spectroscopic characterization. This complex structure contributes to the high electrochemical stability and good rate capability observed for this compound (160 mAh/g at C/3 and 100 mAh/g at 1C). These results provide new insights into the feasibility of developing and commercializing cobalt-free positive electrode materials for LIBs.

Published
2022
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10. Ion Intercalation in Lanthanum Strontium Ferrite for Aqueous Electrochemical Energy Storage Devices

Author

Tang, Yunqing, primary, Chiabrera, Francesco, additional, Morata, Alex, additional, Cavallaro, Andrea, additional, Liedke, Maciej O., additional, Avireddy, Hemesh, additional, Maller, Mar, additional, Butterling, Maik, additional, Wagner, Andreas, additional, Stchakovsky, Michel, additional, Baiutti, Federico, additional, Aguadero, Ainara, additional, and Tarancón, Albert, additional

Published
2022
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11. Temperature-Driven Chemical Segregation in Co-Free Li-Rich-Layered Oxides and Its Influence on Electrochemical Performance

Author

Rajappa Prakasha, Kunkanadu, primary, Grins, Jekabs, additional, Jaworski, Aleksander, additional, Thersleff, Thomas, additional, Svensson, Gunnar, additional, Jøsang, Leif Olav, additional, Dyrli, Anne Dalager, additional, Paulus, Andreas, additional, De Sloovere, Dries, additional, D’Haen, Jan, additional, Van Bael, Marlies K., additional, Hardy, An, additional, Avireddy, Hemesh, additional, Morante, Joan Ramon, additional, and Jacas Biendicho, Jordi, additional

Published
2022
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15. Enhancing electrochemical performances of supercapacitors

Author

Avireddy, Hemesh, Morante i Lleonart, Joan Ramon, Flox Donoso, Cristina, and Universitat de Barcelona. Facultat de Física

Subjects
Nanotecnología, Elèctrodes, Soluciones electrolíticas, Nanotecnologia, Electrolyte solutions, Electrodos, Nanotechnology, Solucions electrolítiques, Electrodes, Ciències Experimentals i Matemàtiques
Abstract

[eng] The thesis is focused on the development and enhancement of the electrochemical properties of the carbon based supercapacitors and pseudocapacitors. To overcome the capacitance loss at the condition of fast charging in the carbon-based supercapacitors, a metal-oxide embedded porous carbon nanofiber with a 3-D electrode architecture is designed. This electrode reduces the electrode resistance and at the same time increases the associated values of capacitance at high rates. The investigation also indicates an essential role in the concentration of the metal oxide precursor towards the electrochemical behavior of the electrodes. This correlation could be useful to design better electrodes for supercapacitor, functioning with better energy and power density capabilities. Whereas, in the case of the water-based pseudocapacitors, it is shown that they suffer from low voltages. Two strategies were used to overcome this issue. (i) Exploring and improving the electrode material based non-carbon materials. In this regard, new materials from the family of MXenes are introduced, to achieve higher cell voltages. Under this frame, a new 2-D MXene based on Molybdenum Vanadium Carbide is proposed and its electrochemical characteristics were investigated. According to its characteristics, its coupling with 2-D Titanium Carbide MXene exhibits a higher cell voltage. The investigation reveals that the charge storage in 2-D molybdenum vanadium carbide MXene has the dependence on the type of electrolyte cations. For the case in point, small size monovalent cations, such as lithium and sodium ions, demonstrate lower hindrance to the charge storage, while large size monovalent potassium ions and bivalent magnesium ions suffer from hindrance effect, causing them to have lower charge storage than lithium and sodium ions. Therefore, the selection of appropriate electrolyte ions especially in the case of MXene based materials appears to be important, which is here found to be with the protonic and sodium ion based electrolytes. (ii) the proposed approach is based on the use of water-based super-concentrated salt solutions which are promising electrolytes to contribute to widening the cell voltage of aqueous pseudocapacitors. Likewise, besides this, it is also proposed that the coupling of 2-D Titanium Carbide MXene with the tunnel structures of Manganese Oxide using this super-concentrated electrolyte water in salt can enable a high voltage aqueous pseudocapacitive energy storage device. The investigation using this approach reveals that the concentration of the salt electrolyte plays a significant role in the values of charge storage in 2-D titanium carbides. Although an extremely high concentration of salt electrolytes widens the potential window, the electrolyte ions in such high concentration face difficulty to insert within the 2-D layers of titanium carbide MXene. On the contrary, the use of low concentrated salt solutions is not recommended, as they provide narrow potential windows. Consequently, during the cell assembling using super-concentrated electrolytes, a moderate concentration of salt electrolyte needs to be taken into attention. On this way, both wider potential window and high charge storage, can be achieved with pseudocapacitive materials like 2-D titanium carbides MXenes. The crystallographic tunnel size of manganese oxide plays a vital role in the charge storage. For instance, tunnel structures, both smaller and larger than the size of the electrolyte ions store fewer charges. As both of these tunnel phases of manganese oxide face difficulty for the insertion of the electrolyte ions. Therefore, manganese oxide with adequate tunnel size needs to be taken into account. Besides this, it is also essential to consider the electronic conductivity of the manganese oxide phase, as high electronic conductivity allows it to store more charges during the condition of fast charging. In regards of the cell assembly, after considering the above-mentioned understanding the practice of applying the voltage-hold test to determine the realistic cell voltage is helpful, as the cell assembled with such realistic voltages permits the cell to have long cycle life. Besides these understanding, remarkable performances were witnesses with the technologies developed in this thesis. For example: (i) the carbon-based electric double layer supercapacitor shows faster responses than the existing carbon-based supercapacitors, (ii) the pseudocapacitors shows high volumetric capacitances (> 35 F cm-3) than carbon-based supercapacitors. Besides this, pseudocapacitors also exhibit higher cells voltages than the existing pseudocapacitors. The pseudocapacitor cells developed in this exhibits high electrochemical stability (> 95 %) over thousands of cycles. Furthermore, the pseudocapacitor is more favorable than EDLCs in applications as they provide slower self-discharges than EDLCs. The above understanding, such as the selection of the electrode, electrode processing and the cell assembly is a tool for designing better supercapacitors., [spa] La tesis se centra en el desarrollo del conocimiento orientado y conducido a la mejora de las propiedades electroquímicas de los supercapacitores, ya que sufren bajos valores de densidad de energía. Este inconveniente limita a los supercapacitores en las aplicaciones donde son necesarios tanto alta potencia como densidad de energía. Entonces, en este escenario, se identificaron dos problemas principales importantes: (a) las limitaciones de rendimiento del supercapacitor debido a la condición de carga rápida, y (b) el bajo voltaje de celda de los pseudocapacitores en electrolitos acuosos en comparación con los electrolitos orgánicos. Para superar la limitación de rendimiento en el primer problema, se muestra una alternativa original a través del electrospinning para diseñar nanofibras de carbono porosas con incrustaciones de óxido metálico con una arquitectura de electrodo 3D que contribuyen a reducir la resistencia del electrodo y al mismo tiempo aumentan los valores asociados de capacidad. La investigación indica un papel esencial en la concentración del precursor de óxido metálico hacia el comportamiento electroquímico de los electrodos. Esta correlación podría ser útil para diseñar mejores electrodos para supercapacitadores, funcionando con mejores capacidades de densidad de energía y potencia. En lo que respecta al problema relacionado con los bajos voltajes celulares en el pseudocapacitor acuoso, en lugar de utilizar materiales basados en carbono más estándar, se toma una metodología en términos de exploración y mejora basada en las propiedades del material del electrodo. Así, se introducen nuevos materiales de la familia de MXenes, para lograr voltajes de celda más altos. Bajo este marco, se propone un nuevo MXene 2-D basado en carburo de vanadio y molibdeno y se han investigado sus características electroquímicas. De acuerdo con sus características, su acoplamiento con carburo de titanio 2-D MXene exhibe un voltaje más alto en una celda pseudocapacitiva todo en MXene. Además de esto, el problema del bajo voltaje de la celda también se resuelve aplicando otro enfoque basado en la modificación del electrólito. El enfoque propuesto se basa en el uso de soluciones salinas superconcentradas a base de agua que son electrolitos prometedores en la ampliación del voltaje celular de los pseudocapacitores acuosos. Del mismo modo, también se propone que el acoplamiento del carburo de titanio 2-D MXene con las estructuras del túnel de óxido de manganeso utilizando este electrolito súper concentrado o agua en sal permite lograr una celda de pseudocapacitador acuoso de alto voltaje. En conjunto, la estrategia presentada a través de esta tesis en términos de preparación de electrodos, selección de materiales, ensamblaje celular y su evaluación de las propiedades electroquímicas es una herramienta para diseñar supercapacitores con mejores capacidades de energía y potencia.

Published
2019

16. Highly Sensitive Self‐Powered H2 Sensor Based on Nanostructured Thermoelectric Silicon Fabrics.

Author

Pujadó, Mercè Pacios, Gordillo, Jose Manuel Sojo, Avireddy, Hemesh, Cabot, Andreu, Morata, Alex, and Tarancón, Albert

Subjects
EXOTHERMIC reactions, NANOSILICON, WIRELESS sensor networks, NANOTUBES, HYDROGEN detectors, HYDROGEN oxidation, DETECTORS
Abstract

Self‐powered sensors running on small differences of temperature are considered promising candidates to cover the increasing demand of sustainable and maintenance‐free wireless sensor networks for the Internet of Things (IoT). Under this context, a cost‐effective and self‐powered hydrogen thermoelectric sensor is presented here as a proof of concept for battery‐less IoT nodes. The device is based on low‐density paper‐like fabrics made of functionalized thermoelectric silicon nanotubes able to harvest energy from the heat released by exothermic reactions, such as the hydrogen catalytic oxidation. This gives an accurate value of the reacting gas concentration without any external power requirement. Experimental results confirm that this self‐powered sensor can autonomously measure concentrations as low as 250 ppm of hydrogen in air while generating power densities up to 0.5 μW cm−2 for 3% H2 at room temperature that can be eventually used to store or send the reading. Due to the universality of the concept, this new class of devices will positively contribute toward the development of other advanced self‐powered sensor nodes in the advent of the Internet of things to be used in different safety scenarios. [ABSTRACT FROM AUTHOR]

Published
2021
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