Your search keyword '"Crispin, Reverant"' showing total 22 results

1. Controlling the rate of posolyte degradation in all-quinone aqueous organic redox flow batteries by sulfonated nanocellulose based membranes: The role of crossover and Michael addition

Author

Lander, Sanna, Pang, Jiu, Erlandsson, Johan, Vagin, Mikhail, Jafari, Mohammad Javad, Korhonen, Leena, Yang, Hongli, Abrahamsson, Tobias, Ding, Penghui, Gueskine, Viktor, Mehandzhiyski, Aleksandar Y., Ederth, Thomas, Zozoulenko, Igor, Wågberg, Lars, Crispin, Reverant, and Berggren, Magnus

Published

2024

2. Safe and stable Zn-lignin batteries with a biopolymer based hydrogel electrolyte.

Author

Ail, Ujwala, Backe, Jakob, Khan, Zia Ullah, Shu, Rui, Phopase, Jaywant, Berggren, Magnus, and Crispin, Reverant

Abstract

The safety risks associated with organic solvent-based batteries for stationary energy storage have driven scientists to reconsider aqueous electrolytes combined with ultra low-cost materials. In this context, zinc (Zn) metal and biopolymer lignin are certainly among the most abundant and economical electroactive materials on Earth, displaying compatibility in their redox activity to fit the stability window of aqueous electrolytes. But, up to now, the electrolyte solutions in those systems incorporate fluorinated organic salts or bio-ionic liquids, both of which are detrimental to the environment and expensive. In this work we use a state-of-the-art lignin electrode based on catechol functionalized lignin (LC) nano-composited with carbon black (C) and a biopolymer hydrogel electrolyte based on agarose with non-fluorinated Zn salt. The optimization of the hydrogel's composition was realized by reducing the amount of free water by promoting its bonding with additional glycerol. The hydrogel facilitates the growth of Zn in the (002) plane, preventing dendritic formation. The highest discharge capacity of 79.7 mA h gLC−1 was obtained at 0.05 A g−1 charge/discharge rate for the buffered 3% agarose hydrogel electrolyte containing 25% glycerol with 1 M Zn2+. The hydrogel containing 25% glycerol with 1 M Zn2+ and 1 M K+ in the absence of buffering shows the best cycle performance with 78% capacity retention after 26 000 cycles at 1 A g−1 with a capacity of 58 mA h gLC−1 at 0.05 A g−1. This study shows the possibility of a safe, affordable, bio-based environmentally friendly energy storage system that has the potential for large-scale applications. [ABSTRACT FROM AUTHOR]

Published

2025

3. Water‐in‐Polymer Salt Electrolyte for Long‐Life Rechargeable Aqueous Zinc‐Lignin Battery.

Author

Kumar, Divyaratan, Franco, Leandro R., Abdou, Nicole, Shu, Rui, Martinelli, Anna, Araujo, C. Moyses, Gladisch, Johannes, Gueskine, Viktor, Crispin, Reverant, and Khan, Ziyauddin

Subjects

AQUEOUS electrolytes, HYDROGEN evolution reactions, CARBON composites, ENERGY storage, COMPOSITE materials

Abstract

Zinc metal batteries (ZnBs) are poised as the next‐generation energy storage solution, complementing lithium‐ion batteries, thanks to their cost‐effectiveness and safety advantages. These benefits originate from the abundance of zinc and its compatibility with non‐flammable aqueous electrolytes. However, the inherent instability of zinc in aqueous environments, manifested through hydrogen evolution reactions (HER) and dendritic growth, has hindered commercialization due to poor cycling stability. Enter potassium polyacrylate (PAAK)‐based water‐in‐polymer salt electrolyte (WiPSE), a novel variant of water‐in‐salt electrolytes (WiSE), designed to mitigate side reactions associated with water redox processes, thereby enhancing the cyclic stability of ZnBs. In this study, WiPSE was employed in ZnBs featuring lignin and carbon composites as cathode materials. Our research highlights the crucial function of acrylate groups from WiPSE in stabilizing the ionic flux on the surface of the Zn electrode. This stabilization promotes the parallel deposition of Zn along the (002) plane, resulting in a significant reduction in dendritic growth. Notably, our sustainable Zn‐lignin battery showcases remarkable cyclic stability, retaining 80% of its initial capacity after 8000 cycles at a high current rate (1 A g−1) and maintaining over 75% capacity retention up to 2000 cycles at a low current rate (0.2 A g−1). This study showcases the practical application of WiPSE for the development of low‐cost, dendrite‐free, and scalable ZnBs. [ABSTRACT FROM AUTHOR]

Published

2025

4. Utilization of sulfonated cellulose membrane for Zn ion hybrid capacitors

Author

Khan, Ziyauddin, primary, Kumar, Divyaratan, additional, Lander, Sanna, additional, Phopase, Jaywant, additional, and Crispin, Reverant, additional

Published

2024

5. Water‐in‐Polymer Salt Electrolyte for Long‐Life Rechargeable Aqueous Zinc‐Lignin Battery

Author

Kumar, Divyaratan, primary, Franco, Leandro R., additional, Abdou, Nicole, additional, Shu, Rui, additional, Martinelli, Anna, additional, Araujo, C. Moyses, additional, Gladisch, Johannes, additional, Gueskine, Viktor, additional, Crispin, Reverant, additional, and Khan, Ziyauddin, additional

Published

2024

6. TaS2 nanosheets embedded in a polymer ionomer catalyzing hydrogen evolution reaction

Author

Shiraz, Hamid Ghorbani, Vagin, Mikhail, Khan, Zia Ullah, Chmielowski, Radoslaw, Crispin, Reverant, and Berggren, Magnus

Published

2025

7. Switchable Broadband Terahertz Absorbers Based on Conducting Polymer-Cellulose Aerogels

Author

Kuang, Chaoyang, Chen, Shangzhi, Luo, Min, Zhang, Qilun, Sun, Xiao, Han, Shaobo, Wang, Qingqing, Stanishev, Vallery, Darakchieva, Vanya, Crispin, Reverant, Fahlman, Mats, Zhao, Dan, Wen, Qiye, Jonsson, Magnus, Kuang, Chaoyang, Chen, Shangzhi, Luo, Min, Zhang, Qilun, Sun, Xiao, Han, Shaobo, Wang, Qingqing, Stanishev, Vallery, Darakchieva, Vanya, Crispin, Reverant, Fahlman, Mats, Zhao, Dan, Wen, Qiye, and Jonsson, Magnus

Abstract

Terahertz (THz) technologies provide opportunities ranging from calibration targets for satellites and telescopes to communication devices and biomedical imaging systems. A main component will be broadband THz absorbers with switchability. However, optically switchable materials in THz are scarce and their modulation is mostly available at narrow bandwidths. Realizing materials with large and broadband modulation in absorption or transmission forms a critical challenge. This study demonstrates that conducting polymer-cellulose aerogels can provide modulation of broadband THz light with large modulation range from approximate to 13% to 91% absolute transmission, while maintaining specular reflection loss < -30 dB. The exceptional THz modulation is associated with the anomalous optical conductivity peak of conducting polymers, which enhances the absorption in its oxidized state. The study also demonstrates the possibility to reduce the surface hydrophilicity by simple chemical modifications, and shows that broadband absorption of the aerogels at optical frequencies enables de-frosting by solar-induced heating. These low-cost, aqueous solution-processable, sustainable, and bio-friendly aerogels may find use in next-generation intelligent THz devices., Funding Agencies|Swedish Research Council(VR); Swedish Foundation for Strategic Research (SSF); Stellenbosch Institute for Advanced Study (STIAS); Swedish Foundation for International Cooperation in Research and Higher Education (STINT); Knut and Alice Wallenberg Foundation; Swedish Government Strategic Research Area in Materials Science on Functional Materials at Linkping University [61831012]; National Natural Science Foundation of China (NFSC) [62131006, 52003202, 2023YFB381130005, 2021JDTD0026, 2023JDGD0012]; National Key Research and Development Program of China [2019-252]; Sichuan Province Science and Technology Support Program [2020-00287, 2022-00211]; Guangdong Science and Technology Major Special Fund [2022-06214]; Wallenberg Wood Science Center; [2009 00971]; [62311530115]; [62235004]

Published

2024

8. Stretchable and biodegradable plant-based redox-diffusion batteries

Author

Rahmanudin, Aiman, Mohammadi, Mohsen, Isacsson, Patrik, Li, Yuyang, Seufert, Laura, Kim, Nara, Mardi, Saeed, Engquist, Isak, Crispin, Reverant, Tybrandt, Klas, Rahmanudin, Aiman, Mohammadi, Mohsen, Isacsson, Patrik, Li, Yuyang, Seufert, Laura, Kim, Nara, Mardi, Saeed, Engquist, Isak, Crispin, Reverant, and Tybrandt, Klas

Abstract

The redox-diffusion (RD) battery concept introduces an environmentally friendly solution for stretchable batteries in autonomous wearable electronics. By utilising plant-based redox-active biomolecules and cellulose fibers for the electrode scaffold, separator membrane, and current collector, along with a biodegradable elastomer encapsulation, the battery design overcomes the reliance on unsustainable transition metal-based active materials and non-biodegradable elastomers used in existing stretchable batteries. Importantly, it addresses the drawback of limited attainable battery capacity, where increasing the active material loading often leads to thicker and stiffer electrodes with poor mechanical properties. The concept decouples the active material loading from the mechanical structure of the electrode, enabling high mass loadings, while retaining a skin-like young's modulus and stretchability. A stretchable ion-selective membrane facilitates the RD process, allowing two separate redox couples, while preventing crossovers. This results in a high-capacity battery cell that is both electrochemically and mechanically stable, engineered from sustainable plant-based materials. Notably, the battery components are biodegradable at the end of their life, addressing concerns of e-waste and resource depletion. A stretchable battery design that uses sustainable plant-based materials and enables high electrochemical and mechanical performance and is biodegradable at the end-of-life.

Published

2024

9. Metal Ion-/Proton-Coupled Electron Transfer (MPCET) on ortho-Quinone

Author

Kumar, Divyaratan, Gueskine, Viktor, Khan, Ziyauddin, Crispin, Reverant, Vagin, Mikhail, Kumar, Divyaratan, Gueskine, Viktor, Khan, Ziyauddin, Crispin, Reverant, and Vagin, Mikhail

Abstract

Quinol/quinone equilibria are ubiquitous in nature and find multiple technological applications, most recently in electrical charge storage. Much research has been devoted to proton-coupled electron transfer (PCET) in such systems and to bidentate complexation of ortho-quinol (catechol) ligands with multivalent metal ions but rarely to the interplay of these two reactions. Here, we investigate the impact of a redox-inactive metal ion, as a complexing and charge-compensating agent, on redox processes of catechol in aqueous solutions, that is, in the presence of proton equilibria. We pay separate attention to their thermodynamics and kinetics, which can be regulated by the pH and buffer capacity. As the proton buffer concentration decreases, proton equilibria during catechol PCET are slower to establish, thus kinetically prioritizing the participation of the metal ion rather than the proton in the redox charge compensation. Making use of this kinetic interplay can be a general strategy to conceive organic battery cathodes for proton-free metal-ion aqueous batteries., Funding Agencies|Wallenberg Wood Science Center (WWSC); Knut and Alice Wallenberg Foundation [KAW 2019.0604, KAW 2021.0195]; Swedish Energy Agency [52023-1]; Vetenskapradet [2016-05990]

Published

2024

10. Migration-mitigated crossover of organic redox anions across a proton-exchange membrane

Author

Ding, Penghui, Vagin, Mikhail, Jafari, Mohammad Javad, Mehandzhiyski, Alexandar, Gueskine, Viktor, Abrahamsson, Tobias, Zozoulenko, Igor, Ederth, Thomas, Crispin, Reverant, Ding, Penghui, Vagin, Mikhail, Jafari, Mohammad Javad, Mehandzhiyski, Alexandar, Gueskine, Viktor, Abrahamsson, Tobias, Zozoulenko, Igor, Ederth, Thomas, and Crispin, Reverant

Abstract

The two-electron oxygen reduction reaction (ORR), powered by affordable renewable energy, presents a more promising and sustainable approach to hydrogen peroxide production than traditional methods. In this study, we introduce a membrane electrolyzer for ORR-to-H2O2 generation. The conducting polymer poly(3,4-ethylenedioxythiophene):poly(styrene sulfonate) (PEDOT:PSS) acts as the cathode that aids the oxygen reduction reaction through a two-electron pathway to produce H2O2. At the anode, we employed the oxidation of a model organic molecule, 4,5-dihydroxy-1,3-benzenedisulfonic acid disodium salt monohydrate (tiron). This catalyst-free anode process, as an alternative to the sluggish water oxidation reaction commonly used in classical electrolyzers, reduces voltage loss to release protons, cross the membrane, and feed the ORR at the cathode. Our study investigated the often-neglected issue of organic crossover during electrolyzer operation and its significant impact on transport behavior. This research paves the way for the development of crossover-free flow cells, extending the realm of electrochemical devices based on the electrolyte fed and the membrane. We introduce a membrane electrolyzer for the generation of hydrogen peroxide via oxygen reduction and catalyst-free oxidation of quinones. The study reports the effect of the applied coulombic forces on ions, which is the origin of crossover., Funding Agencies|VINNOVA (Digital Cellulose Center) [308634, 308635]; Knut and Alice Wallenberg foundation [KAW 2019.0604, KAW 2021.0195]; Wallenberg Wood Science Center (WWSC); Wallenberg Initiative Materials Science for Sustainability (WISE); Wallenberg Launchpad (WALP), KAW Project Grant; Swedish Energy Agency [52023-1]; Vetenskapradet [2016-05990, 2019-05577]; Swedish Electricity Storage and Balancing Centre (SESBC)

Published

2024

11. Hall measurements reveal band-like transport in high-mobility solution-processed organic semiconductor films

Author

Crispin, Reverant, Zozoulenko, Igor, Crispin, Reverant, and Zozoulenko, Igor

Abstract

n/a

Published

2024

12. Water-in-Polymer Salt Electrolyte for Long-Life Rechargeable Aqueous Zinc-Lignin Battery

Author

Kumar, Divyaratan, Franco, Leandro R., Abdou, Nicole, Shu, Rui, Martinelli, Anna, Araujo, Moyses, Gladisch, Johannes, Gueskine, Viktor, Crispin, Reverant, Khan, Ziyauddin, Kumar, Divyaratan, Franco, Leandro R., Abdou, Nicole, Shu, Rui, Martinelli, Anna, Araujo, Moyses, Gladisch, Johannes, Gueskine, Viktor, Crispin, Reverant, and Khan, Ziyauddin

Abstract

Zinc metal batteries (ZnBs) are poised as the next-generation energy storage solution, complementing lithium-ion batteries, thanks to their cost-effectiveness and safety advantages. These benefits originate from the abundance of zinc and its compatibility with non-flammable aqueous electrolytes. However, the inherent instability of zinc in aqueous environments, manifested through hydrogen evolution reactions (HER) and dendritic growth, has hindered commercialization due to poor cycling stability. Enter potassium polyacrylate (PAAK)-based water-in-polymer salt electrolyte (WiPSE), a novel variant of water-in-salt electrolytes (WiSE), designed to mitigate side reactions associated with water redox processes, thereby enhancing the cyclic stability of ZnBs. In this study, WiPSE was employed in ZnBs featuring lignin and carbon composites as cathode materials. Our research highlights the crucial function of acrylate groups from WiPSE in stabilizing the ionic flux on the surface of the Zn electrode. This stabilization promotes the parallel deposition of Zn along the (002) plane, resulting in a significant reduction in dendritic growth. Notably, our sustainable Zn-lignin battery showcases remarkable cyclic stability, retaining 80% of its initial capacity after 8000 cycles at a high current rate (1 A g-1) and maintaining over 75% capacity retention up to 2000 cycles at a low current rate (0.2 A g-1). This study showcases the practical application of WiPSE for the development of low-cost, dendrite-free, and scalable ZnBs. A dendrite-free and long-life cycle Zn-lignin battery was demonstrated using water-in-polymer salt electrolyte.

Published

2024

13. The Origin of Thermal Gradient-Induced Voltage in Polyelectrolytes

Author

Sultana, Ayesha, Wurger, Alois, Khan, Ziyauddin, Liao, Mingna, Jonsson, Magnus, Crispin, Reverant, Zhao, Dan, Sultana, Ayesha, Wurger, Alois, Khan, Ziyauddin, Liao, Mingna, Jonsson, Magnus, Crispin, Reverant, and Zhao, Dan

Abstract

Ionic thermoelectric materials can generate large thermal voltages under temperature gradients while also being low-cost and environmentally friendly. Many electrolytes with large Seebeck coefficients are reported in recent years, however, the mechanism of the thermal voltage is remained elusive. In this work, three types of polyelectrolytes are studied with different cations and identified a significant contribution to their thermal voltage originating from a concentration gradient. This conclusion is based on studies of the loss and gain of water upon temperature changes, variations in conductivity with water content and temperature, and the voltages induced by changes in water content. The results are analyzed by the "hopping mode" dynamics of charge transport in electrolytes. The hydration of different cations influences the water concentration gradient, which affects the barrier height and ion-induced potential in the electrodes. This work shows that the hydro-voltage in ionic thermoelectric devices can be one order of magnitude larger than the contribution from thermodiffusion-induced potentials, and becomes the main contributor to energy harvesting when implemented into ionic thermoelectric supercapacitors. Together with the rationalized theoretical discussion, this work clarifies the mechanism of thermal voltages in electrolytes and provides a new path for the development of ionic thermoelectric materials. The thermal voltage of polyelectrolyte films largely depends on the water concentration gradient under a temperature difference, which can be optimized to promote the generated total voltage up to over 30 mV K-1.image, Funding Agencies|EU commission [101058284]; Swedish Research Council [VR 2018-04037]; AForsk Foundation [23-220]; Advanced Functional Materials Center at Linkoping University [2009-00971]

Published

2024

14. The enhanced ionic thermal potential by a polarized electrospun membrane

Author

Sultana, Ayesha, primary, Alam, Md. Mehebub, additional, Crispin, Reverant, additional, and Zhao, Dan, additional

Published

2024

15. The Origin of Thermal Gradient‐Induced Voltage in Polyelectrolytes

Author

Sultana, Ayesha, primary, Würger, Alois, additional, Khan, Ziyauddin, additional, Liao, Mingna, additional, Jonsson, Magnus P., additional, Crispin, Reverant, additional, and Zhao, Dan, additional

Published

2023

16. Switchable Broadband Terahertz Absorbers Based on Conducting Polymer‐Cellulose Aerogels

Author

Kuang, Chaoyang, primary, Chen, Shangzhi, additional, Luo, Min, additional, Zhang, Qilun, additional, Sun, Xiao, additional, Han, Shaobo, additional, Wang, Qingqing, additional, Stanishev, Vallery, additional, Darakchieva, Vanya, additional, Crispin, Reverant, additional, Fahlman, Mats, additional, Zhao, Dan, additional, Wen, Qiye, additional, and Jonsson, Magnus P., additional

Published

2023

17. Detection of Ice Formation With the Polymeric Mixed Ionic-Electronic Conductor PEDOT: PSS for Aeronautics

Author

Dongo, Patrice D., Håkansson, Anna, Stoeckel, Marc-Antoine, Pavlopolou, Eleni, Wang, Suhao, Farina, Dario, Queeckers, Patrick, Fabiano, Simone, Iorio, Carlo Saverio, Crispin, Reverant, Dongo, Patrice D., Håkansson, Anna, Stoeckel, Marc-Antoine, Pavlopolou, Eleni, Wang, Suhao, Farina, Dario, Queeckers, Patrick, Fabiano, Simone, Iorio, Carlo Saverio, and Crispin, Reverant

Abstract

Ice formation detection is important in telecommunications and aeronautics, e.g., ice on the wings of an aircraft affects its aerodynamic performance and leads to fatal accidents. While many types of sensors exist, resistive sensors for ice detection have been poorly explored. They are however attractive because of their simplicity and the possibility to install an array of sensors on large areas to map the ice formation on wings. Hygroscopic ionic conductors have been demonstrated for resistive ice sensing but their high resistance prevents the readout of sensor arrays. In this work, mixed ionic-electronic polymer conductors (MIEC) are considered for the first time for ice detection. The polymer blend poly(3,4-ethylenedioxythiophene):polystyrene sulfonate (PEDOT:PSS) is solution deposited on a pair of electrodes. The sensor displays an abrupt rise in electrical resistance during the transition phase between water liquid to solid. It is proposed that the morphology and electronic transport in PEDOT are affected by the freezing event because the absorbed water in the PSS-rich phase undergoes dilatation upon forming ice crystals. For the aeronautics application, successful tests of integration of sensing layer in pre-preg layers of aeronautical grade and freezing detection are carried out to validate the ice detection principle., Funding Agencies|Swedish Research Council [VR 2016-05990, 2016-06146, 2018-04037]; Advanced Functional Materials Center at Linkoping University [2009-00971]

Published

2023

18. Lignin nanoparticles for high-performance organic zinc-ion batteries

Author

Tran, Van Chinh, Morsali, Mohammad, Khan, Ziyauddin, Crispin, Reverant, Sipponen, Mika H., Engquist, Isak, Tran, Van Chinh, Morsali, Mohammad, Khan, Ziyauddin, Crispin, Reverant, Sipponen, Mika H., and Engquist, Isak

19. Decoupling Conductivity, Heterogeneous Electron Transfer Rate, and Diffusion in Organic Molecular Electrocatalysis: Oxygen Reduction Reaction on Poly(3,4-ethylenedioxythiophene).

Author

Sepat N, Vagin M, Carli S, Marchini E, Caramori S, Zhang Q, Braun S, Wu Z, Ding P, Wijeratne K, Petsagkourakis I, Ail U, Pavlopoulou E, Ruoko TP, Fabiano S, Tybrandt K, Fahlman M, Crispin R, Berggren M, Gueskine V, and Engquist I

Abstract

The electrified production of hydrogen peroxide (H 2 O 2 ) by oxygen reduction reaction (ORR) is attractive to increase the sustainability of chemical industry. Here the same chains of intrinsically conductive polymer, poly(3,4-ethylenedioxythiophene) (PEDOT) are utilized, as ORR electrocatalyst, while varying polymeric primary dopants (PSS and Nafion) and the level of secondary doping with DMSO. These changes modulate various properties of the film, such as its microscale organization and electronic conductivity. The aim here is to clearly decouple the rate of the heterogeneous electron transfer (HET) of ORR from the diffusion affected by electronic conductivity and the electrochemically available surface area. It is found that the rate of HET and the double layer capacitance are significantly affected by primary dopant. On the contrary, secondary doping shows very little effect on the rate of HET. However, such secondary doping resulted in the increase of both electrochemically available surface area and the diffusion through the polymer film. This effect is attributed to a few orders increase of the electronic conductivity in the film improving availability of the polymer for electron transfer. The enhancement of diffusion upon the secondary doping of conducting polymer is utilized to improve direct conversion of air into H 2 O 2 on gas diffusion electrode., (© 2024 The Author(s). Small published by Wiley‐VCH GmbH.)

Published

2025

20. Stretchable and biodegradable plant-based redox-diffusion batteries.

Author

Rahmanudin A, Mohammadi M, Isacsson P, Li Y, Seufert L, Kim N, Mardi S, Engquist I, Crispin R, and Tybrandt K

Subjects

Electrodes, Cellulose chemistry, Diffusion, Plants chemistry, Elastomers chemistry, Oxidation-Reduction, Wearable Electronic Devices, Electric Power Supplies

Abstract

The redox-diffusion (RD) battery concept introduces an environmentally friendly solution for stretchable batteries in autonomous wearable electronics. By utilising plant-based redox-active biomolecules and cellulose fibers for the electrode scaffold, separator membrane, and current collector, along with a biodegradable elastomer encapsulation, the battery design overcomes the reliance on unsustainable transition metal-based active materials and non-biodegradable elastomers used in existing stretchable batteries. Importantly, it addresses the drawback of limited attainable battery capacity, where increasing the active material loading often leads to thicker and stiffer electrodes with poor mechanical properties. The concept decouples the active material loading from the mechanical structure of the electrode, enabling high mass loadings, while retaining a skin-like young's modulus and stretchability. A stretchable ion-selective membrane facilitates the RD process, allowing two separate redox couples, while preventing crossovers. This results in a high-capacity battery cell that is both electrochemically and mechanically stable, engineered from sustainable plant-based materials. Notably, the battery components are biodegradable at the end of their life, addressing concerns of e-waste and resource depletion.

Published

2024

21. Metal Ion-/Proton-Coupled Electron Transfer (MPCET) on ortho -Quinone.

Author

Kumar D, Gueskine V, Khan Z, Crispin R, and Vagin M

Abstract

Quinol/quinone equilibria are ubiquitous in nature and find multiple technological applications, most recently in electrical charge storage. Much research has been devoted to proton-coupled electron transfer (PCET) in such systems and to bidentate complexation of ortho -quinol (catechol) ligands with multivalent metal ions but rarely to the interplay of these two reactions. Here, we investigate the impact of a redox-inactive metal ion, as a complexing and charge-compensating agent, on redox processes of catechol in aqueous solutions, that is, in the presence of proton equilibria. We pay separate attention to their thermodynamics and kinetics, which can be regulated by the pH and buffer capacity. As the proton buffer concentration decreases, proton equilibria during catechol PCET are slower to establish, thus kinetically prioritizing the participation of the metal ion rather than the proton in the redox charge compensation. Making use of this kinetic interplay can be a general strategy to conceive organic battery cathodes for proton-free metal-ion aqueous batteries., Competing Interests: The authors declare no competing financial interest., (© 2024 The Authors. Published by American Chemical Society.)

Published

2024

22. The Origin of Thermal Gradient-Induced Voltage in Polyelectrolytes.

Author

Sultana A, Würger A, Khan Z, Liao M, Jonsson MP, Crispin R, and Zhao D

Abstract

Ionic thermoelectric materials can generate large thermal voltages under temperature gradients while also being low-cost and environmentally friendly. Many electrolytes with large Seebeck coefficients are reported in recent years, however, the mechanism of the thermal voltage is remained elusive. In this work, three types of polyelectrolytes are studied with different cations and identified a significant contribution to their thermal voltage originating from a concentration gradient. This conclusion is based on studies of the loss and gain of water upon temperature changes, variations in conductivity with water content and temperature, and the voltages induced by changes in water content. The results are analyzed by the "hopping mode" dynamics of charge transport in electrolytes. The hydration of different cations influences the water concentration gradient, which affects the barrier height and ion-induced potential in the electrodes. This work shows that the hydro-voltage in ionic thermoelectric devices can be one order of magnitude larger than the contribution from thermodiffusion-induced potentials, and becomes the main contributor to energy harvesting when implemented into ionic thermoelectric supercapacitors. Together with the rationalized theoretical discussion, this work clarifies the mechanism of thermal voltages in electrolytes and provides a new path for the development of ionic thermoelectric materials., (© 2023 The Authors. Small published by Wiley‐VCH GmbH.)

Published

2024