Your search keyword '"Shearing PR"' showing total 111 results

1. Three-Dimensional Visualization of Conductive Domains in Battery Electrodes with Contrast-Enhancing Nanoparticles

Author

Morelly, SL, Gelb, J, Iacoviello, F, Shearing, PR, Harris, SJ, Alvarez, NJ, and Tang, MH

Abstract

Replacing conductive carbon black with commercial carbon-coated iron nanoparticles yields an effective contrast-enhancing agent to differentiate between active material, conductive additive, and binder in lithium-ion battery electrodes. Nano-XCT resolved the carbon-binder domain with 126 nm voxel resolution, showing partial coatings around the active material particles and interparticle bridges. In a complementary analysis, SEM/EDS determined individual distributions of conductive additives and binder. Surprisingly, the contrast-enhancing agents showed that the effect of preparation parameters on the heterogeneity of conductive additives was weaker than on the binder. Incorporation of such contrast-enhancing additives can improve understanding of processing-structure-function relationships in a multitude of devices for energy conversion and storage.

Published

2018

2. Synergistic Imaging of Battery Materials Using Laboratory and Synchrotron X-Ray Microscopy

Author

Shearing, PR, primary

Published

2022

3. Multi-scale investigations of delta-Ni0.25V2O5 center dot nH(2)O cathode materials in aqueous Zinc-Ion batteries

Author

Li, J, McColl, K, Lu, X, Sathasivam, S, Dong, H, Kang, L, Li, Z, Zhao, S, Kafizas, AG, Wang, R, Brett, DJL, Shearing, PR, Cora, F, He, G, Carmalt, CJ, Parkin, IP, and The Royal Society

Subjects

Technology, cathode, Energy & Fuels, L-EDGE, Materials Science, Materials Science, Multidisciplinary, 0915 Interdisciplinary Engineering, Physics, Applied, V2O5, 3D tomography, LITHIUM, CRYSTAL-STRUCTURE, 0912 Materials Engineering, Science & Technology, ELECTRODE, Chemistry, Physical, Physics, zinc-ion battery, 0303 Macromolecular and Materials Chemistry, CENTER DOT H2O, Chemistry, Physics, Condensed Matter, X-RAY-ABSORPTION, Physical Sciences, VANADIUM-OXIDES, RECHARGEABLE LI, density functional theory calculation, TRANSITION

Abstract

Cost‐effective and environment‐friendly aqueous zinc‐ion batteries (AZIBs) exhibit tremendous potential for application in grid‐scale energy storage systems but are limited by suitable cathode materials. Hydrated vanadium bronzes have gained significant attention for AZIBs and can be produced with a range of different pre‐intercalated ions, allowing their properties to be optimized. However, gaining a detailed understanding of the energy storage mechanisms within these cathode materials remains a great challenge due to their complex crystallographic frameworks, limiting rational design from the perspective of enhanced Zn2+ diffusion over multiple length scales. Herein, a new class of hydrated porous δ‐Ni0.25V2O5.nH2O nanoribbons for use as an AZIB cathode is reported. The cathode delivers reversibility showing 402 mAh g−1 at 0.2 A g−1 and a capacity retention of 98% over 1200 cycles at 5 A g−1. A detailed investigation using experimental and computational approaches reveal that the host “δ” vanadate lattice has favorable Zn2+ diffusion properties, arising from the atomic‐level structure of the well‐defined lattice channels. Furthermore, the microstructure of the as‐prepared cathodes is examined using multi‐length scale X‐ray computed tomography for the first time in AZIBs and the effective diffusion coefficient is obtained by image‐based modeling, illustrating favorable porosity and satisfactory tortuosity.

Published

2020

4. Communication—Prediction of Thermal Issues for Larger Format 4680 Cylindrical Cells and Their Mitigation with Enhanced Current Collection

Author

Tranter, TG, Timms, R, Shearing, PR, and Brett, DJL

Subjects

Materials science, Renewable Energy, Sustainability and the Environment, Thermal, Materials Chemistry, Electrochemistry, Mechanical engineering, Thermal management of electronic devices and systems, Current (fluid), Condensed Matter Physics, Jelly roll, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials

Abstract

The paper numerically explores the electrochemical and thermal behaviour of a larger format 4680 cylindrical cell recently proposed by Tesla and explains the need to go “tabless.” An idealized spiral geometry is used for 2D simulations with the traditional tab-based current collection method and a new continuous current collection method compared. The new design is found to mitigate the ohmic losses experienced around the “jelly-roll” current collectors which are significant for the traditional tabbed case, thus leading to higher efficiency and capacity and reduced heat production.

Published

2020

5. Visualizing the carbon binder phase of battery electrodes in three dimensions

Author

Daemi, SR, Tan, C, Volkenandt, T, Cooper, SJ, Palacios-Padros, A, Cookson, J, Brett, DJL, and Shearing, PR

Subjects

LICOO2 CATHODE, Technology, Science & Technology, Materials Science, Li-ion batteries, Materials Science, Multidisciplinary, MICROSCOPY, POLYMER, multiscale image-based modeling, TORTUOSITY, carbon binder characterization, TOMOGRAPHY, lab-based X-ray computed tomography, MORPHOLOGY, ION, porous materials, DISCHARGE

Abstract

This study presents a technique to directly characterize the carbon and binder domain (CBD) in lithium-ion (Li-ion) battery electrodes in three dimensions and use it to determine the effective transport properties of a LiNi0.33Mn0.33Co0.33O2 (NMC) electrode. X-ray nanocomputed tomography (nano-CT) is used to image an electrode composed solely of carbon and binder, whereas focused ion beam–scanning electron microscopy is used to analyze cross-sections of a NMC electrode to gain morphological information regarding the electrode and CBD porosity. Combining the information gathered from these techniques reduces the uncertainty inherent in segmenting the nano-CT CBD data set and enables effective diffusivity of its porous network to be determined. X-ray microcomputed tomography (micro-CT) is then used to collect a NMC data set that is subsequently segmented into three phases, comprised of active material, pore, and CBD. The effective diffusivity calculated for the nano-CT data set is incorporated for the CBD present in the micro-CT data set to estimate the ensemble tortuosity factor for the NMC electrode. The tortuosity factor greatly increases when compared to the same data set segmented without considering the CBD. The porous network of the NMC electrode is studied with a continuous pore size distribution approach that highlights median radii of 180 nm and 1 μm for the CBD and NMC pores, respectively, and with a pore throat size distribution calculation that highlights median equivalent radii of 350 and 700 nm.

Published

2018

6. Design of experiments to generate a fuel cell electro-thermal performance map and optimise transitional pathways

Author

Meyer, Q, Rasha, L, Koegeler, HM, Foster, S, Adcock, P, Shearing, PR, Brett, DJL, Meyer, Q, Rasha, L, Koegeler, HM, Foster, S, Adcock, P, Shearing, PR, and Brett, DJL

Abstract

The influence of the air cooling flow rate and current density on the temperature, voltage and power density is a challenging issue for air-cooled, open cathode fuel cells. Electro-thermal maps have been generated using large datasets (530 experimental points) to characterise these correlations, which reveal that the amount of cooling, alongside with the load, directly affect the cell temperature. This work uses the design of experiment (DoE) approach to tackle two challenges. Firstly, an S-optimal design plan is used to reduce the number of experiments from 530 to 555 to determine the peak power density in an electro-thermal map. Secondly, the design of experiment approach is used to determine the fastest way to reach the highest power density, yet limiting acute temperature gradients, via three intermediate steps of current density and air cooling rate.

Published

2018

7. Laser-preparation of geometrically optimised samples for X-ray nano-CT

Author

Bailey, JJ, Heenan, TMM, Finegan, DP, Lu, X, Daemi, SR, Iacoviello, F, Backeberg, NR, Taiwo, OO, Brett, DJL, Atkinson, A, Shearing, PR, and Engineering & Physical Science Research Council (EPSRC)

Subjects

Technology, Microscopy, Science & Technology, solid oxide fuel cells, sample preparation, lithium-ion batteries, 0204 Condensed Matter Physics, 0601 Biochemistry And Cell Biology, QUANTIFICATION, FUEL-CELL ANODES, EVOLUTION, shale, NANOSCALE, COMPUTED-TOMOGRAPHY, laser micro-machining, 0912 Materials Engineering, X-ray tomography, ION BATTERY ELECTRODES, TEMPERATURE, MICROSTRUCTURES

Abstract

A robust and versatile sample preparation technique for the fabrication of cylindrical pillars for imaging by X-ray nano-computed tomography (nano-CT) is presented. The procedure employs simple, cost-effective laser micro-machining coupled with focused-ion beam (FIB) milling, when required, to yield mechanically robust samples at the micrometre length-scale to match the field-of-view (FOV) for nano-CT imaging. A variety of energy and geological materials are exhibited as case studies, demonstrating the procedure can be applied to a variety of materials to provide geometrically optimised samples whose size and shape are tailored to the attenuation coefficients of the constituent phases. The procedure can be implemented for the bespoke preparation of pillars for both lab- and synchrotron-based X-ray nano-CT investigations of a wide range of samples.

Published

2017

8. Investigating the effect of thermal gradients on stress in solid oxide fuel cell anodes using combined synchrotron radiation and thermal imaging

Author

Robinson, JB, Brown, LD, Jervis, R, Taiwo, OO, Heenan, TMM, Millichamp, J, Mason, TJ, Neville, TP, Clague, R, Eastwood, DS, Reinhard, C, Lee, PD, Brett, DJL, and Shearing, PR

Subjects

Technology, STEADY-STATE, Thermal imaging, Energy & Fuels, Stress analysis, Materials Science, Infrared imaging, Energy Engineering and Power Technology, Materials Science, Multidisciplinary, RED-OX CYCLE, 09 Engineering, Solid oxide fuel cell, SOFC ANODE, Electrochemistry, FAILURE, Physical and Theoretical Chemistry, Electrical and Electronic Engineering, TEMPERATURE, Science & Technology, Energy, Synchrotron radiation, Chemistry, Physical, Renewable Energy, Sustainability and the Environment, RESIDUAL-STRESSES, MECHANICAL-PROPERTIES, X-ray diffraction, Chemistry, PROBABILITY, Physical Sciences, 03 Chemical Sciences, FINITE-ELEMENT, BEHAVIOR

Abstract

Thermal gradients can arise within solid oxide fuel cells (SOFCs) due to start-up and shut-down, non-uniform gas distribution, fast cycling and operation under internal reforming conditions. Here, the effects of operationally relevant thermal gradients on Ni/YSZ SOFC anode half cells are investigated using combined synchrotron X-ray diffraction and thermal imaging. The combination of these techniques has identified significant deviation from linear thermal expansion behaviour in a sample exposed to a one dimensional thermal gradient. Stress gradients are identified along isothermal regions due to the presence of a proximate thermal gradient, with tensile stress deviations of up to 75 MPa being observed across the sample at a constant temperature. Significant strain is also observed due to the presence of thermal gradients when compared to work carried out at isothermal conditions.

Published

2015

9. Effect of controlled anode flow release on dead-ended anode proton exchange membrane fuel cells

Author

Meyer, Q, Ashton, S, Curnick, O, Reisch, T, Adcock, P, Shearing, PR, Brett, DJL, Meyer, Q, Ashton, S, Curnick, O, Reisch, T, Adcock, P, Shearing, PR, and Brett, DJL

Abstract

Dead-ended anode operation is commonly used in polymer electrolyte fuel cells, but suffers from voltage reduction with time. This study shows how a controlled anode bleed can mitigate against voltage loss and fuel dilution. Performance analysis, along with off-gas analysis, is used to characterize cell performance during dead-ended mode and an optimum bleed rate is identified to minimize voltage drop for this particular 5-cell stack.

Published

2014

10. Correlative Microscopy in the Laboratory: Analysis of the Triple-Phase Boundary in a Solid-Oxide Fuel Cell Electrode Using X-ray Computed Nanotomography and FIB-SEM

Author

Shearing, PR, primary, Gelb, J, additional, and Brandon, NP, additional

Published

2010

11. 2021 roadmap on lithium sulfur batteries

Author

Robinson, JB, Xi, K, Kumar, Ramachandran, Ferrari, Andrea, Au, H, Titirici, MM, Puerto, AP, Kucernak, A, Fitch, SDS, Araez, NG, Brown, ZL, Pasta, M, Furness, L, Kibler, AJ, Walsh, DA, Johnson, LR, Holc, C, Newton, GN, Champness, NR, Markoulidis, F, Crean, C, Slade, RCT, Andritsos, EI, Cai, Q, Babar, S, Zhang, T, Lekakou, C, Kulkarni, N, Rettie, AJE, Jervis, R, Cornish, M, Marinescu, M, Offer, G, Li, Zhuangnan, Bird, L, Grey, Clare, Chhowalla, Manish, Lecce, DD, Owen, RE, Miller, TS, Brett, DJL, Liatard, S, Ainsworth, D, and Shearing, PR

Subjects

polysulfide shuttle, Roadmap, carbon materials, Li-metal anode, lithium sulfur batteries, 7. Clean energy, battery modelling

Abstract

Batteries that extend performance beyond the intrinsic limits of Li-ion batteries are among the most important developments required to continue the revolution promised by electrochemical devices. Of these next-generation batteries, lithium sulfur (Li���S) chemistry is among the most commercially mature, with cells offering a substantial increase in gravimetric energy density, reduced costs and improved safety prospects. However, there remain outstanding issues to advance the commercial prospects of the technology and benefit from the economies of scale felt by Li-ion cells, including improving both the rate performance and longevity of cells. To address these challenges, the Faraday Institution, the UK���s independent institute for electrochemical energy storage science and technology, launched the Lithium Sulfur Technology Accelerator (LiSTAR) programme in October 2019. This Roadmap, authored by researchers and partners of the LiSTAR programme, is intended to highlight the outstanding issues that must be addressed and provide an insight into the pathways towards solving them adopted by the LiSTAR consortium. In compiling this Roadmap we hope to aid the development of the wider Li���S research community, providing a guide for academia, industry, government and funding agencies in this important and rapidly developing research space.

12. 2021 roadmap on lithium sulfur batteries

Author

Robinson, JB, Xi, K, Kumar, RV, Ferrari, AC, Au, H, Titirici, MM, Puerto, AP, Kucernak, A, Fitch, SDS, Araez, NG, Brown, ZL, Pasta, M, Furness, L, Kibler, AJ, Walsh, DA, Johnson, LR, Holc, C, Newton, GN, Champness, NR, Markoulidis, F, Crean, C, Slade, RCT, Andritsos, EI, Cai, Q, Babar, S, Zhang, T, Lekakou, C, Kulkarni, N, Rettie, AJE, Jervis, R, Cornish, M, Marinescu, M, Offer, G, Li, Z, Bird, L, Grey, CP, Chhowalla, M, Lecce, DD, Owen, RE, Miller, TS, Brett, DJL, Liatard, S, Ainsworth, D, and Shearing, PR

Subjects

polysulfide shuttle, carbon materials, Li-metal anode, lithium sulfur batteries, 7. Clean energy, battery modelling

Abstract

Batteries that extend performance beyond the intrinsic limits of Li-ion batteries are among the most important developments required to continue the revolution promised by electrochemical devices. Of these next-generation batteries, lithium sulfur (Li–S) chemistry is among the most commercially mature, with cells offering a substantial increase in gravimetric energy density, reduced costs and improved safety prospects. However, there remain outstanding issues to advance the commercial prospects of the technology and benefit from the economies of scale felt by Li-ion cells, including improving both the rate performance and longevity of cells. To address these challenges, the Faraday Institution, the UK’s independent institute for electrochemical energy storage science and technology, launched the Lithium Sulfur Technology Accelerator (LiSTAR) programme in October 2019. This Roadmap, authored by researchers and partners of the LiSTAR programme, is intended to highlight the outstanding issues that must be addressed and provide an insight into the pathways towards solving them adopted by the LiSTAR consortium. In compiling this Roadmap we hope to aid the development of the wider Li–S research community, providing a guide for academia, industry, government and funding agencies in this important and rapidly developing research space.

13. 2021 roadmap on lithium sulfur batteries

Author

Constantina Lekakou, R. Vasant Kumar, Conrad Holc, Nuria Garcia-Araez, Thomas S. Miller, Nivedita Kulkarni, Alexander J. E. Rettie, Clare P. Grey, Manish Chhowalla, David Ainsworth, Shumaila Babar, Maria-Magdalena Titirici, Mauro Pasta, Liam Bird, Neil R. Champness, Michael Cornish, Darren A. Walsh, Andrea C. Ferrari, Carol Crean, Gregory J. Offer, Paul R. Shearing, Foivos Markoulidis, Samuel D. S. Fitch, James B. Robinson, Daniele Di Lecce, Lee Johnson, Alexander J. Kibler, Rhodri E. Owen, Heather Au, Eleftherios I. Andritsos, Zhuangnan Li, Kai Xi, Dan J. L. Brett, Liam Furness, Zachary L. Brown, Anthony Kucernak, Graham N. Newton, Monica Marinescu, Teng Zhang, Sebastien Liatard, Qiong Cai, Robert C. T. Slade, Andres Parra-Puerto, Rhodri Jervis, Robinson, James B [0000-0002-6509-7769], Xi, Kai [0000-0003-0508-7910], Ferrari, Andrea C [0000-0003-0907-9993], Au, Heather [0000-0002-1652-2204], Titirici, Maria-Magdalena [0000-0003-0773-2100], Parra-Puerto, Andres [0000-0002-1131-1168], Kucernak, Anthony [0000-0002-5790-9683], Fitch, Samuel D S [0000-0002-3681-8985], Garcia-Araez, Nuria [0000-0001-9095-2379], Brown, Zachary L [0000-0003-0772-3159], Pasta, Mauro [0000-0002-2613-4555], Furness, Liam [0000-0003-3538-2929], Kibler, Alexander J [0000-0002-4441-4294], Walsh, Darren A [0000-0003-3691-6734], Johnson, Lee R [0000-0002-1789-814X], Holc, Conrad [0000-0003-4412-3443], Newton, Graham N [0000-0003-2246-4466], Champness, Neil R [0000-0003-2970-1487], Markoulidis, Foivos [0000-0002-3811-0104], Crean, Carol [0000-0003-0756-7504], Slade, Robert C T [0000-0002-5449-5702], Andritsos, Eleftherios I [0000-0002-3289-266X], Cai, Qiong [0000-0002-1677-0515], Zhang, Teng [0000-0002-3657-5151], Lekakou, Constantina [0000-0003-4494-1761], Kulkarni, Nivedita [0000-0002-3115-629X], Rettie, Alexander J E [0000-0002-2482-9732], Jervis, Rhodri [0000-0003-2784-7802], Marinescu, Monica [0000-0003-1641-3371], Offer, Gregory [0000-0003-1324-8366], Li, Zhuangnan [0000-0001-8154-1287], Grey, Clare P [0000-0001-5572-192X], Chhowalla, Manish [0000-0002-8183-4044], Lecce, Daniele Di [0000-0003-1290-1140], Owen, Rhodri E [0000-0002-1246-2988], Miller, Thomas S [0000-0002-2224-5768], Brett, Dan J L [0000-0002-8545-3126], Shearing, Paul R [0000-0002-1387-9531], Apollo - University of Cambridge Repository, Robinson, JB [0000-0002-6509-7769], Xi, K [0000-0003-0508-7910], Ferrari, AC [0000-0003-0907-9993], Au, H [0000-0002-1652-2204], Titirici, MM [0000-0003-0773-2100], Puerto, AP [0000-0002-1131-1168], Kucernak, A [0000-0002-5790-9683], Fitch, SDS [0000-0002-3681-8985], Araez, NG [0000-0001-9095-2379], Brown, ZL [0000-0003-0772-3159], Pasta, M [0000-0002-2613-4555], Furness, L [0000-0003-3538-2929], Kibler, AJ [0000-0002-4441-4294], Walsh, DA [0000-0003-3691-6734], Johnson, LR [0000-0002-1789-814X], Holc, C [0000-0003-4412-3443], Newton, GN [0000-0003-2246-4466], Champness, NR [0000-0003-2970-1487], Markoulidis, F [0000-0002-3811-0104], Crean, C [0000-0003-0756-7504], Slade, RCT [0000-0002-5449-5702], Andritsos, EI [0000-0002-3289-266X], Cai, Q [0000-0002-1677-0515], Zhang, T [0000-0002-3657-5151], Lekakou, C [0000-0003-4494-1761], Kulkarni, N [0000-0002-3115-629X], Rettie, AJE [0000-0002-2482-9732], Jervis, R [0000-0003-2784-7802], Marinescu, M [0000-0003-1641-3371], Offer, G [0000-0003-1324-8366], Li, Z [0000-0001-8154-1287], Grey, CP [0000-0001-5572-192X], Chhowalla, M [0000-0002-8183-4044], Lecce, DD [0000-0003-1290-1140], Owen, RE [0000-0002-1246-2988], Miller, TS [0000-0002-2224-5768], Brett, DJL [0000-0002-8545-3126], Shearing, PR [0000-0002-1387-9531], Kumar, Ramachandran [0000-0001-9223-2332], Ferrari, Andrea [0000-0003-0907-9993], and Grey, Clare [0000-0001-5572-192X]

Subjects

polysulfide shuttle, Technology, Energy & Fuels, Materials Science (miscellaneous), Materials Science, Materials Science, Multidisciplinary, 02 engineering and technology, 010402 general chemistry, lithium sulfur batteries, 7. Clean energy, 01 natural sciences, battery modelling, Research community, Materials Chemistry, Lithium sulfur, Government, Science & Technology, carbon materials, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Economies of scale, Engineering management, General Energy, Roadmap, Li-metal anode, Energy density, 0210 nano-technology, Electrochemical energy storage

Abstract

Batteries that extend performance beyond the intrinsic limits of Li-ion batteries are among the most important developments required to continue the revolution promised by electrochemical devices. Of these next-generation batteries, lithium sulfur (Li–S) chemistry is among the most commercially mature, with cells offering a substantial increase in gravimetric energy density, reduced costs and improved safety prospects. However, there remain outstanding issues to advance the commercial prospects of the technology and benefit from the economies of scale felt by Li-ion cells, including improving both the rate performance and longevity of cells. To address these challenges, the Faraday Institution, the UK’s independent institute for electrochemical energy storage science and technology, launched the Lithium Sulfur Technology Accelerator (LiSTAR) programme in October 2019. This Roadmap, authored by researchers and partners of the LiSTAR programme, is intended to highlight the outstanding issues that must be addressed and provide an insight into the pathways towards solving them adopted by the LiSTAR consortium. In compiling this Roadmap we hope to aid the development of the wider Li–S research community, providing a guide for academia, industry, government and funding agencies in this important and rapidly developing research space.

Published

2021

14. Towards spatially selective efferent neuromodulation: anatomical and functional organization of cardiac fibres in the porcine cervical vagus nerve.

Author

Thompson N, Ravagli E, Mastitskaya S, Challita R, Hadaya J, Iacoviello F, Idil AS, Shearing PR, Ajijola OA, Ardell JL, Shivkumar K, Holder D, and Aristovich K

Abstract

Spatially selective vagus nerve stimulation (sVNS) offers a promising approach for addressing heart disease with enhanced precision. Despite its therapeutic potential, VNS is limited by off-target effects and the need for time-consuming titration. Our research aimed to determine the spatial organization of cardiac afferent and efferent fibres within the vagus nerve of pigs to achieve targeted neuromodulation. Using trial-and-error sVNS in vivo and ex vivo micro-computed tomography fascicle tracing, we found significant spatial separation between cardiac afferent and cardiac efferent fibres at the mid-cervical level and they were localized on average on opposite sides of the nerve cross-section. This was consistent between both in vivo and ex vivo methods. Specifically, cardiac afferent fibres were located near pulmonary fibres, consistent with findings of cardiopulmonary convergent circuits and, notably, cardiac efferent fascicles were exclusive. These cardiac efferent regions were located in close proximity to the recurrent laryngeal regions. This is consistent with the roughly equitable spread across the nerve of the afferent and efferent fibres. Our study demonstrated that targeted neuromodulation via sVNS could achieve scalable heart rate decreases without eliciting cardiac afferent-related reflexes; this is desirable for reducing sympathetic overactivation associated with heart disease. These findings indicate that understanding the spatial organization of cardiac-related fibres within the vagus nerve can lead to more precise and effective VNS therapy, minimizing off-target effects and potentially mitigating the need for titration. KEY POINTS: Spatially selective vagus nerve stimulation (sVNS) presents a promising approach for addressing chronic heart disease with enhanced precision. Our study reveals significant spatial separation between cardiac afferent and efferent fibres in the vagus nerve, particularly at the mid-cervical level. Utilizing trial-and-error sVNS in vivo and micro-computed tomography fascicle tracing, we demonstrate the potential for targeted neuromodulation, achieving therapeutic effects such as scalable heart rate decrease without stimulating cardiac afferent-related reflexes. This spatial understanding opens avenues for more effective VNS therapy, minimizing off-target effects and potentially eliminating the need for titration, thereby expediting therapeutic outcomes in myocardial infarction and related conditions., (© 2024 The Author(s). The Journal of Physiology published by John Wiley & Sons Ltd on behalf of The Physiological Society.)

Published

2024

15. Dynamical Janus Interface Design for Reversible and Fast-Charging Zinc-Iodine Battery under Extreme Operating Conditions.

Author

Zong W, Li J, Zhang C, Dai Y, Ouyang Y, Zhang L, Li J, Zhang W, Chen R, Dong H, Gao X, Zhu J, Parkin IP, Shearing PR, Lai F, Amine K, Liu T, and He G

Abstract

Aqueous zinc (Zn) iodine (I 2 ) batteries have emerged as viable alternatives to conventional metal-ion batteries. However, undesirable Zn deposition and irreversible iodine conversion during cycling have impeded their progress. To overcome these concerns, we report a dynamical interface design by cation chemistry that improves the reversibility of Zn deposition and four-electron iodine conversion. Due to this design, we demonstrate an excellent Zn-plating/-stripping behavior in Zn||Cu asymmetric cells over 1000 cycles with an average Coulombic efficiency (CE) of 99.95%. Moreover, the Zn||I 2 full cells achieve a high-rate capability (217.1 mA h g -1 at 40 A g -1 ; C rate of 189.5C) at room temperature and enable stable cycling with a CE of more than 99% at -50 °C at a current density of 0.05 A g -1 . In situ spectroscopic investigations and simulations reveal that introducing tetraethylammonium cations as ion sieves can dynamically modulate the electrode-electrolyte interface environment, forming the unique water-deficient and chloride ion (Cl - )-rich interface. Such Janus interface accounts for the suppression of side reactions, the prevention of ICl decomposition, and the enrichment of reactants, enhancing the reversibility of Zn-stripping/-plating and four-electron iodine chemistry. This fundamental understanding of the intrinsic interplay between the electrode-electrolyte interface and cations offers a rational standpoint for tuning the reversibility of iodine conversion.

Published

2024

16. Illuminating Polysulfide Distribution in Lithium Sulfur Batteries; Tracking Polysulfide Shuttle Using Operando Optical Fluorescence Microscopy.

Author

Coke K, Johnson MJ, Robinson JB, Rettie AJE, Miller TS, and Shearing PR

Abstract

High-energy-density lithium sulfur (Li-S) batteries suffer heavily from the polysulfide shuttle effect, a result of the dissolution and transport of intermediate polysulfides from the cathode, into the electrolyte, and onto the anode, leading to rapid cell degradation. If this primary mechanism of cell failure is to be overcome, the distribution, dynamics, and degree of polysulfide transport must first be understood in depth. In this work, operando optical fluorescence microscope imaging of optically accessible Li-S cells is shown to enable real-time qualitative visualization of the spatial distribution of lithium polysulfides, both within the electrolyte and porous cathode. Quantitative determinations of spatial concentration are also possible at a low enough concentration. The distribution throughout cycling is monitored, including direct observation of polysulfide shuttling to the anode and consequent dendrite formation. This was enabled through the optimization of a selective fluorescent dye, verified to fluoresce proportionally with concentration of polysulfides within Li-S cells. This ability to directly and conveniently track the spatial distribution of soluble polysulfide intermediates in Li-S battery electrolytes, while the cell operates, has the potential to have a widespread impact across the field, for example, by enabling the influence of a variety of polysulfide mitigation strategies to be assessed and optimized, including in this work the LiNO 3 additive.

Published

2024

17. The Influence of Cathode Degradation Products on the Anode Interface in Lithium-Ion Batteries.

Author

Zhang Z, Said S, Lovett AJ, Jervis R, Shearing PR, Brett DJL, and Miller TS

Abstract

Degradation of cathode materials in lithium-ion batteries results in the presence of transition metal ions in the electrolyte, and these ions are known to play a major role in capacity fade and cell failure. Yet, while it is known that transition metal ions migrate from the metal oxide cathode and deposit on the graphite anode, their specific influence on anode reactions and structures, such as the solid electrolyte interphase (SEI), is still quite poorly understood due to the complexity in studying this interface in operational cells. In this work we combine operando electrochemical atomic force microscopy (EC-AFM), electrochemical quartz crystal microbalance (EQCM), and electrochemical impedance spectroscopy (EIS) measurements to probe the influence of a range of transition metal ions on the morphological, mechanical, chemical, and electrical properties of the SEI. By adding representative concentrations of Ni 2+ , Mn 2+ , and Co 2+ ions into a commercially relevant battery electrolyte, the impacts of each on the formation and stability of the anode interface layer is revealed; all are shown to pose a threat to battery performance and stability. Mn 2+ , in particular, is shown to induce a thick, soft, and unstable SEI layer, which is known to cause severe degradation of batteries, while Co 2+ and Ni 2+ significantly impact interfacial conductivity. When transition metal ions are mixed, SEI degradation is amplified, suggesting a synergistic effect on the cell stability. Hence, by uncovering the roles these cathode degradation products play in operational batteries, we have provided a foundation upon which strategies to mitigate or eliminate these degradation products can be developed.

Published

2024

18. Inhibition of Vanadium Cathodes Dissolution in Aqueous Zn-Ion Batteries.

Author

Dai Y, Zhang C, Li J, Gao X, Hu P, Ye C, He H, Zhu J, Zhang W, Chen R, Zong W, Guo F, Parkin IP, Brett DJL, Shearing PR, Mai L, and He G

Abstract

Aqueous zinc-ion batteries (AZIBs) have experienced a rapid surge in popularity, as evident from the extensive research with over 30 000 articles published in the past 5 years. Previous studies on AZIBs have showcased impressive long-cycle stability at high current densities, achieving thousands or tens of thousands of cycles. However, the practical stability of AZIBs at low current densities (<1C) is restricted to merely 50-100 cycles due to intensified cathode dissolution. This genuine limitation poses a considerable challenge to their transition from the laboratory to the industry. In this study, leveraging density functional theory (DFT) calculations, an artificial interphase that achieves both hydrophobicity and restriction of the outward penetration of dissolved vanadium cations, thereby shifting the reaction equilibrium and suppressing the vanadium dissolution following Le Chatelier's principle, is described. The approach has resulted in one of the best cycling stabilities to date, with no noticeable capacity fading after more than 200 cycles (≈720 h) at 200 mA g -1 (0.47C). These findings represent a significant advance in the design of ultrastable cathodes for aqueous batteries and accelerate the industrialization of aqueous zinc-ion batteries., (© 2024 The Authors. Advanced Materials published by Wiley‐VCH GmbH.)

Published

2024

19. Anatomical and functional organization of cardiac fibers in the porcine cervical vagus nerve allows spatially selective efferent neuromodulation.

Author

Thompson N, Ravagli E, Mastitskaya S, Challita R, Hadaya J, Iacoviello F, Shah Idil A, Shearing PR, Ajijola OA, Ardell JL, Shivkumar K, Holder D, and Aristovich K

Abstract

Cardiac disease progression reflects the dynamic interaction between adversely remodeled neurohumoral control systems and an abnormal cardiac substrate. Vagal nerve stimulation (VNS) is an attractive neuromodulatory option to dampen this dynamic interaction; however, it is limited by off-target effects. Spatially-selective VNS (sVNS) offers a promising solution to induce cardioprotection while mitigating off-target effects by specifically targeting pre-ganglionic parasympathetic efferent cardiac fibers. This approach also has the potential to enhance therapeutic outcomes by eliminating time-consuming titration required for optimal VNS. Recent studies have demonstrated the independent modulation of breathing rate, heart rate, and laryngeal contraction through sVNS. However, the spatial organization of afferent and efferent cardiac-related fibers within the vagus nerve remains unexplored. By using trial-and-error sVNS in vivo in combination with ex vivo micro-computed tomography fascicle tracing, we show the significant spatial separation of cardiac afferent and efferent fibers (179±55° SD microCT, p<0.05 and 200±137° SD, p<0.05 sVNS - degrees of separation across a cross-section of nerve) at the mid-cervical level. We also show that cardiac afferent fibers are located in proximity to pulmonary fibers consistent with recent findings of cardiopulmonary convergent neurons and circuits. We demonstrate the ability of sVNS to selectively elicit desired scalable heart rate decrease without stimulating afferent-related reflexes. By elucidating the spatial organization of cardiac-related fibers within the vagus nerve, our findings pave the way for more targeted neuromodulation, thereby reducing off-target effects and eliminating the need for titration. This, in turn, will enhance the precision and efficacy of VNS therapy in treating cardiac pathology, allowing for improved therapeutic efficacy., Competing Interests: Conflict of Interest The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Published

2024

20. Separation and concentration of CO 2 from air using a humidity-driven molten-carbonate membrane.

Author

Metcalfe IS, Mutch GA, Papaioannou EI, Tsochataridou S, Neagu D, Brett DJL, Iacoviello F, Miller TS, Shearing PR, and Hunt PA

Abstract

Separation processes are substantially more difficult when the species to be separated is highly dilute. To perform any dilute separation, thermodynamic and kinetic limitations must be overcome. Here we report a molten-carbonate membrane that can 'pump' CO 2 from a 400 ppm input stream (representative of air) to an output stream with a higher concentration of CO 2 , by exploiting ambient energy in the form of a humidity difference. The substantial H 2 O concentration difference across the membrane drives CO 2 permeation 'uphill' against its own concentration difference, analogous to active transport in biological membranes. The introduction of this H 2 O concentration difference also results in a kinetic enhancement that boosts the CO 2 flux by an order of magnitude even as the CO 2 input stream concentration is decreased by three orders of magnitude from 50% to 400 ppm. Computational modelling shows that this enhancement is due to the H 2 O-mediated formation of carriers within the molten salt that facilitate rapid CO 2 transport., Competing Interests: Competing interestsThe authors declare no competing interests., (© The Author(s) 2024.)

Published

2024

21. Laboratory-based x-ray dark-field microscopy.

Author

Esposito M, Buchanan I, Massimi L, Ferrara JD, Shearing PR, Olivo A, and Endrizzi M

Abstract

We demonstrate the capability of laboratory-based x-ray microscopes, using intensity-modulation masks, to access the sub-micron length scale in the dark field contrast channel while maintaining micron resolution in the resolved (refraction and attenuation) channels. The dark field contrast channel reveals the presence of ensembles of samples' features below the system resolution. Resolved refraction and attenuation channels provide multi-modal high-resolution imaging down to the micron scale. We investigate the regimes of modulated and un-modulated dark field as well as refraction, quantifying their dependence on the relationship between feature size in the imaged object and aperture size in the intensity-modulation mask. We propose an analytical model to link the measured signal with the sample's microscopic properties. Finally, we demonstrate the relevance of the microscopic dark field contrast channel in applications from both the life and physical sciences, providing proof of concept results for imaging collagen bundles in cartilage and dendritic growth in lithium batteries.

Published

2023

22. Bio-Inspired Polyanionic Electrolytes for Highly Stable Zinc-Ion Batteries.

Author

Dong H, Hu X, Liu R, Ouyang M, He H, Wang T, Gao X, Dai Y, Zhang W, Liu Y, Zhou Y, Brett DJL, Parkin IP, Shearing PR, and He G

Abstract

For zinc-ion batteries (ZIBs), the non-uniform Zn plating/stripping results in a high polarization and low Coulombic efficiency (CE), hindering the large-scale application of ZIBs. Here, inspired by biomass seaweed plants, an anionic polyelectrolyte alginate acid (SA) was used to initiate the in situ formation of the high-performance solid electrolyte interphase (SEI) layer on the Zn anode. Attribute to the anionic groups of -COO - , the affinity of Zn 2+ ions to alginate acid induces a well-aligned accelerating channel for uniform plating. This SEI regulates the desolvation structure of Zn 2+ and facilitates the formation of compact Zn (002) crystal planes. Even under high depth of discharge conditions (DOD), the SA-coated Zn anode still maintains a stable Zn stripping/plating behavior with a low potential difference (0.114 V). According to the classical nucleation theory, the nucleation energy for SA-coated Zn is 97 % less than that of bare Zn, resulting in a faster nucleation rate. The Zn||Cu cell assembled with the SA-coated electrode exhibits an outstanding average CE of 99.8 % over 1,400 cycles. The design is successfully demonstrated in pouch cells, where the SA-coated Zn exhibits capacity retention of 96.9 % compared to 59.1 % for bare Zn anode, even under the high cathode mass loading (>10 mg/cm 2 )., (© 2023 The Authors. Angewandte Chemie International Edition published by Wiley-VCH GmbH.)

Published

2023

23. Evaluating 3D-printed bioseparation structures using multi-length scale tomography.

Author

Johnson TF, Conti M, Iacoviello F, Shearing PR, Pullen J, Dimartino S, and Bracewell DG

Abstract

X-ray computed tomography was applied in imaging 3D-printed gyroids used for bioseparation in order to visualize and characterize structures from the entire geometry down to individual nanopores. Methacrylate prints were fabricated with feature sizes of 500 µm, 300 µm, and 200 µm, with the material phase exhibiting a porous substructure in all cases. Two X-ray scanners achieved pixel sizes from 5 µm to 16 nm to produce digital representations of samples across multiple length scales as the basis for geometric analysis and flow simulation. At the gyroid scale, imaged samples were visually compared to the original computed-aided designs to analyze printing fidelity across all feature sizes. An individual 500 µm feature, part of the overall gyroid structure, was compared and overlaid between design and imaged volumes, identifying individual printed layers. Internal subvolumes of all feature sizes were segmented into material and void phases for permeable flow analysis. Small pieces of 3D-printed material were optimized for nanotomographic imaging at a pixel size of 63 nm, with all three gyroid samples exhibiting similar geometric characteristics when measured. An average porosity of 45% was obtained that was within the expected design range, and a tortuosity factor of 2.52 was measured. Applying a voidage network map enabled the size, location, and connectivity of pores to be identified, obtaining an average pore size of 793 nm. Using Avizo XLAB at a bulk diffusivity of 7.00 × 10 -11 m 2 s -1 resulted in a simulated material diffusivity of 2.17 × 10 -11 m 2 s -1  ± 0.16 × 10 -11 m 2 s -1 ., (© 2023. The Author(s).)

Published

2023

24. Silicon-Based Solid-State Batteries: Electrochemistry and Mechanics to Guide Design and Operation.

Author

Vadhva P, Boyce AM, Patel A, Shearing PR, Offer G, and Rettie AJE

Abstract

Solid-state batteries (SSBs) are promising alternatives to the incumbent lithium-ion technology; however, they face a unique set of challenges that must be overcome to enable their widespread adoption. These challenges include solid-solid interfaces that are highly resistive, with slow kinetics, and a tendency to form interfacial voids causing diminished cycle life due to fracture and delamination. This modeling study probes the evolution of stresses at the solid electrolyte (SE) solid-solid interfaces, by linking the chemical and mechanical material properties to their electrochemical response, which can be used as a guide to optimize the design and manufacture of silicon (Si) based SSBs. A thin-film solid-state battery consisting of an amorphous Si negative electrode (NE) is studied, which exerts compressive stress on the SE, caused by the lithiation-induced expansion of the Si. By using a 2D chemo-mechanical model, continuum scale simulations are used to probe the effect of applied pressure and C-rate on the stress-strain response of the cell and their impacts on the overall cell capacity. A complex concentration gradient is generated within the Si electrode due to slow diffusion of Li through Si, which leads to localized strains. To reduce the interfacial stress and strain at 100% SOC, operation at moderate C-rates with low applied pressure is desirable. Alternatively, the mechanical properties of the SE could be tailored to optimize cell performance. To reduce Si stress, a SE with a moderate Young's modulus similar to that of lithium phosphorous oxynitride (∼77 GPa) with a low yield strength comparable to sulfides (∼0.67 GPa) should be selected. However, if the reduction in SE stress is of greater concern, then a compliant Young's modulus (∼29 GPa) with a moderate yield strength (1-3 GPa) should be targeted. This study emphasizes the need for SE material selection and the consideration of other cell components in order to optimize the performance of thin film solid-state batteries.

Published

2023

25. Multiscale dynamics of charging and plating in graphite electrodes coupling operando microscopy and phase-field modelling.

Author

Lu X, Lagnoni M, Bertei A, Das S, Owen RE, Li Q, O'Regan K, Wade A, Finegan DP, Kendrick E, Bazant MZ, Brett DJL, and Shearing PR

Abstract

The phase separation dynamics in graphitic anodes significantly affects lithium plating propensity, which is the major degradation mechanism that impairs the safety and fast charge capabilities of automotive lithium-ion batteries. In this study, we present comprehensive investigation employing operando high-resolution optical microscopy combined with non-equilibrium thermodynamics implemented in a multi-dimensional (1D+1D to 3D) phase-field modeling framework to reveal the rate-dependent spatial dynamics of phase separation and plating in graphite electrodes. Here we visualize and provide mechanistic understanding of the multistage phase separation, plating, inter/intra-particle lithium exchange and plated lithium back-intercalation phenomena. A strong dependence of intra-particle lithiation heterogeneity on the particle size, shape, orientation, surface condition and C-rate at the particle level is observed, which leads to early onset of plating spatially resolved by a 3D image-based phase-field model. Moreover, we highlight the distinct relaxation processes at different state-of-charges (SOCs), wherein thermodynamically unstable graphite particles undergo a drastic intra-particle lithium redistribution and inter-particle lithium exchange at intermediate SOCs, whereas the electrode equilibrates much slower at low and high SOCs. These physics-based insights into the distinct SOC-dependent relaxation efficiency provide new perspective towards developing advanced fast charge protocols to suppress plating and shorten the constant voltage regime., (© 2023. Springer Nature Limited.)

Published

2023

26. Numerical Design of Microporous Carbon Binder Domains Phase in Composite Cathodes for Lithium-Ion Batteries.

Author

Ge R, Boyce AM, Sun Y, Shearing PR, Grant PS, Cumming DJ, and Smith RM

Abstract

Lithium-ion battery (LIB) performance can be significantly affected by the nature of the complex electrode microstructure. The carbon binder domain (CBD) present in almost all LIB electrodes is used to enhance mechanical stability and facilitate electronic conduction, and understanding the CBD phase microstructure and how it affects the complex coupled transport processes is crucial to LIB performance optimization. In this work, the influence of microporosity in the CBD phase has been studied in detail for the first time, enabling insight into the relationships between the CBD microstructure and the battery performance. To investigate the effect of the CBD pore size distributions, a random field method is used to generate in silico a multiple-phase electrode structure, including bimodal pore size distributions seen in practice and microporous CBD with a tunable pore size and variable transport properties. The distribution of macropores and the microporous CBD phase substantially affected simulated battery performance, where battery specific capacity improved as the microporosity of the CBD phase increased.

Published

2023

27. Understanding and Optimizing Capacitance Performance in Reduced Graphene-Oxide Based Supercapacitors.

Author

Gadipelli S, Guo J, Li Z, Howard CA, Liang Y, Zhang H, Shearing PR, and Brett DJL

Abstract

Reduced graphene-oxide (RGO)-based electrodes in supercapacitors deliver high energy/power capacities compared to typical nanoporous carbon materials. However, extensive critical analysis of literature reveals enormous discrepancies (up to 250 F g -1 ) in the reported capacitance (variation of 100-350 F g -1 ) of RGO materials synthesized under seemingly similar methods, inhibiting an understanding of capacitance variation. Here, the key factors that control the capacitance performance of RGO electrodes are demonstrated by analyzing and optimizing various types of commonly applied electrode fabrication methods. Beyond usual data acquisition parameters and oxidation/reduction properties of RGO, a substantial difference of more than 100% in capacitance values (with change from 190 ± 20 to 340 ± 10 F g -1 ) is found depending on the electrode preparation method. For this demonstration, ≈40 RGO-based electrodes are fabricated from numerous distinctly different RGO materials via typically applied methods of solution (aqueous and organic) casting and compressed powders. The influence of data acquisition conditions and capacitance estimation practices are also discussed. Furthermore, by optimizing electrode processing method, a direct surface area governed capacitance relationship for RGO structures is revealed., (© 2023 The Authors. Small Methods published by Wiley-VCH GmbH.)

Published

2023

28. Deploying Proteins as Electrolyte Additives in Li-S Batteries: The Multifunctional Role of Fibroin in Improving Cell Performance.

Author

Soni R, Spadoni D, Shearing PR, Brett DJL, Lekakou C, Cai Q, Robinson JB, and Miller TS

Abstract

It is widely accepted that the commercial application of lithium-sulfur batteries is inhibited by their short cycle life, which is primarily caused by a combination of Li dendrite formation and active material loss due to polysulfide shuttling. Unfortunately, while numerous approaches to overcome these problems have been reported, most are unscalable and hence further hinder Li-S battery commercialization. Most approaches suggested also only tackle one of the primary mechanisms of cell degradation and failure. Here, we demonstrate that the use of a simple protein, fibroin, as an electrolyte additive can both prevent Li dendrite formation and minimize active material loss to enable high capacity and long cycle life (up to 500 cycles) in Li-S batteries, without inhibiting the rate performance of the cell. Through a combination of experiments and molecular dynamics (MD) simulations, it is demonstrated that the fibroin plays a dual role, both binding to polysulfides to hinder their transport from the cathode and passivating the Li anode to minimize dendrite nucleation and growth. Most importantly, as fibroin is inexpensive and can be simply introduced to the cell via the electrolyte, this work offers a route toward practical industrial applications of a viable Li-S battery system., Competing Interests: The authors declare no competing financial interest., (© 2023 The Authors. Published by American Chemical Society.)

Published

2023

29. Spectroscopic Identification of Active Sites of Oxygen-Doped Carbon for Selective Oxygen Reduction to Hydrogen Peroxide.

Author

Liu L, Kang L, Chutia A, Feng J, Michalska M, Ferrer P, Grinter DC, Held G, Tan Y, Zhao F, Guo F, Hopkinson DG, Allen CS, Hou Y, Gu J, Papakonstantinou I, Shearing PR, Brett DJL, Parkin IP, and He G

Abstract

The electrochemical synthesis of hydrogen peroxide (H 2 O 2 ) via a two-electron (2 e - ) oxygen reduction reaction (ORR) process provides a promising alternative to replace the energy-intensive anthraquinone process. Herein, we develop a facile template-protected strategy to synthesize a highly active quinone-rich porous carbon catalyst for H 2 O 2 electrochemical production. The optimized PCC 900 material exhibits remarkable activity and selectivity, of which the onset potential reaches 0.83 V vs. reversible hydrogen electrode in 0.1 M KOH and the H 2 O 2 selectivity is over 95 % in a wide potential range. Comprehensive synchrotron-based near-edge X-ray absorption fine structure (NEXAFS) spectroscopy combined with electrocatalytic characterizations reveals the positive correlation between quinone content and 2 e - ORR performance. The effectiveness of chair-form quinone groups as the most efficient active sites is highlighted by the molecule-mimic strategy and theoretical analysis., (© 2023 The Authors. Angewandte Chemie International Edition published by Wiley-VCH GmbH.)

Published

2023

30. Organotopic organization of the porcine mid-cervical vagus nerve.

Author

Thompson N, Ravagli E, Mastitskaya S, Iacoviello F, Stathopoulou TR, Perkins J, Shearing PR, Aristovich K, and Holder D

Abstract

Introduction: Despite detailed characterization of fascicular organization of somatic nerves, the functional anatomy of fascicles evident in human and large mammal cervical vagus nerve is unknown. The vagus nerve is a prime target for intervention in the field of electroceuticals due to its extensive distribution to the heart, larynx, lungs, and abdominal viscera. However, current practice of the approved vagus nerve stimulation (VNS) technique is to stimulate the entire nerve. This produces indiscriminate stimulation of non-targeted effectors and undesired side effects. Selective neuromodulation is now a possibility with a spatially-selective vagal nerve cuff. However, this requires the knowledge of the fascicular organization at the level of cuff placement to inform selectivity of only the desired target organ or function., Methods and Results: We imaged function over milliseconds with fast neural electrical impedance tomography and selective stimulation, and found consistent spatially separated regions within the nerve correlating with the three fascicular groups of interest, suggesting organotopy. This was independently verified with structural imaging by tracing anatomical connections from the end organ with microCT and the development of an anatomical map of the vagus nerve. This confirmed organotopic organization., Discussion: Here we show, for the first time, localized fascicles in the porcine cervical vagus nerve which map to cardiac, pulmonary and recurrent laryngeal function ( N = 4). These findings pave the way for improved outcomes in VNS as unwanted side effects could be reduced by targeted selective stimulation of identified organ-specific fiber-containing fascicles and the extension of this technique clinically beyond the currently approved disorders to treat heart failure, chronic inflammatory disorders, and more., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2023 Thompson, Ravagli, Mastitskaya, Iacoviello, Stathopoulou, Perkins, Shearing, Aristovich and Holder.)

Published

2023

31. Mapping internal temperatures during high-rate battery applications.

Author

Heenan TMM, Mombrini I, Llewellyn A, Checchia S, Tan C, Johnson MJ, Jnawali A, Garbarino G, Jervis R, Brett DJL, Di Michiel M, and Shearing PR

Abstract

Electric vehicles demand high charge and discharge rates creating potentially dangerous temperature rises. Lithium-ion cells are sealed during their manufacture, making internal temperatures challenging to probe 1 . Tracking current collector expansion using X-ray diffraction (XRD) permits non-destructive internal temperature measurements 2 ; however, cylindrical cells are known to experience complex internal strain 3,4 . Here, we characterize the state of charge, mechanical strain and temperature within lithium-ion 18650 cells operated at high rates (above 3C) by means of two advanced synchrotron XRD methods: first, as entire cross-sectional temperature maps during open-circuit cooling and second, single-point temperatures during charge-discharge cycling. We observed that a 20-minute discharge on an energy-optimized cell (3.5 Ah) resulted in internal temperatures above 70 °C, whereas a faster 12-minute discharge on a power-optimized cell (1.5 Ah) resulted in substantially lower temperatures (below 50 °C). However, when comparing the two cells under the same electrical current, the peak temperatures were similar, for example, a 6 A discharge resulted in 40 °C peak temperatures for both cell types. We observe that the operando temperature rise is due to heat accumulation, strongly influenced by the charging protocol, for example, constant current and/or constant voltage; mechanisms that worsen with cycling because degradation increases the cell resistance. Design mitigations for temperature-related battery issues should now be explored using this new methodology to provide opportunities for improved thermal management during high-rate electric vehicle applications., (© 2023. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2023

32. Epidermal growth factor receptor inhibition prevents vascular calcifying extracellular vesicle biogenesis.

Author

Bakhshian Nik A, Ng HH, Ashbrook SK, Sun P, Iacoviello F, Shearing PR, Bertazzo S, Mero D, Khomtchouk BB, and Hutcheson JD

Subjects

Humans, Mice, Animals, Caveolin 1 metabolism, Calcium metabolism, Muscle, Smooth, Vascular metabolism, ErbB Receptors genetics, ErbB Receptors metabolism, Membrane Proteins metabolism, Myocytes, Smooth Muscle metabolism, Vascular Calcification genetics, Vascular Calcification prevention & control, Extracellular Vesicles metabolism, Renal Insufficiency, Chronic, Atherosclerosis metabolism

Abstract

Chronic kidney disease (CKD) increases the risk of cardiovascular disease, including vascular calcification, leading to higher mortality. The release of calcifying extracellular vesicles (EVs) by vascular smooth muscle cells (VSMCs) promotes ectopic mineralization of vessel walls. Caveolin-1 (CAV1), a structural protein in the plasma membrane, plays a major role in calcifying EV biogenesis in VSMCs. Epidermal growth factor receptor (EGFR) colocalizes with and influences the intracellular trafficking of CAV1. Using a diet-induced mouse model of CKD followed by a high-phosphate diet to promote vascular calcification, we assessed the potential of EGFR inhibition to prevent vascular calcification. Furthermore, we computationally analyzed 7,651 individuals in the Multi-Ethnic Study of Atherosclerosis (MESA) and Framingham cohorts to assess potential correlations between coronary artery calcium and single-nucleotide polymorphisms (SNPs) associated with elevated serum levels of EGFR. Mice with CKD developed widespread vascular calcification, associated with increased serum levels of EGFR. In both the CKD mice and human VSMC culture, EGFR inhibition significantly reduced vascular calcification by mitigating the release of CAV1-positive calcifying EVs. EGFR inhibition also increased bone mineral density in CKD mice. Individuals in the MESA and Framingham cohorts with SNPs associated with increased serum EGFR exhibit elevated coronary artery calcium. Given that EGFR inhibitors exhibit clinical safety and efficacy in other pathologies, the current data suggest that EGFR may represent an ideal target to prevent pathological vascular calcification in CKD. NEW & NOTEWORTHY Here, we investigate the potential of epidermal growth factor receptor (EGFR) inhibition to prevent vascular calcification, a leading indicator of and contributor to cardiovascular morbidity and mortality. EGFR interacts and affects the trafficking of the plasma membrane scaffolding protein caveolin-1. Previous studies reported a key role for caveolin-1 in the development of specialized extracellular vesicles that mediate vascular calcification; however, no role of EGFR has been reported. We demonstrated that EGFR inhibition modulates caveolin-1 trafficking and hinders calcifying extracellular vesicle formation, which prevents vascular calcification. Given that EGFR inhibitors are clinically approved for other indications, this may represent a novel therapeutic strategy for vascular calcification.

Published

2023

33. Ex Situ Characterization of 1T/2H MoS 2 and Their Carbon Composites for Energy Applications, a Review.

Author

Marinov AD, Bravo Priegue L, Shah AR, Miller TS, Howard CA, Hinds G, Shearing PR, Cullen PL, and Brett DJL

Abstract

The growing interest in the development of next-generation net zero energy systems has led to the expansion of molybdenum disulfide (MoS 2 ) research in this area. This activity has resulted in a wide range of manufacturing/synthesis methods, controllable morphologies, diverse carbonaceous composite structures, a multitude of applicable characterization techniques, and multiple energy applications for MoS 2 . To assess the literature trends, 37,347 MoS 2 research articles from Web of Science were text scanned to classify articles according to energy application research and characterization techniques employed. Within the review, characterization techniques are grouped under the following categories: morphology, crystal structure, composition, and chemistry. The most common characterization techniques identified through text scanning are recommended as the base fingerprint for MoS 2 samples. These include: scanning electron microscopy (SEM), X-ray diffraction (XRD), X-ray photoelectron spectroscopy (XPS), and Raman spectroscopy. Similarly, XPS and Raman spectroscopy are suggested for 2H or 1T MoS 2 phase confirmation. We provide guidance on the collection and presentation of MoS 2 characterization data. This includes how to effectively combine multiple characterization techniques, considering the sample area probed by each technique and their statistical significance, and the benefit of using reference samples. For ease of access for future experimental comparison, key numeric MoS 2 characterization values are tabulated and major literature discrepancies or currently debated characterization disputes are highlighted.

Published

2023

34. Observation of Zn Dendrite Growth via Operando Digital Microscopy and Time-Lapse Tomography.

Author

Du W, Zhang Z, Iacoviello F, Zhou S, Owen RE, Jervis R, Brett DJL, and Shearing PR

Abstract

The zinc-ion battery is one of the promising candidates for next-generation energy storage devices beyond lithium technology due to the earth's abundance of Zn materials and their high volumetric energy density (5855 mA h cm -3 ). To date, the formation of Zn dendrites during charge-discharge cycling still hinders the practical application of zinc-ion batteries. It is, therefore, crucial to understand the formation mechanism of the zinc dendritic structure before effectively suppressing its growth. Here, the application of operando digital optical microscopy and in situ lab-based X-ray computed tomography (X-ray CT) is demonstrated to probe and quantify the morphologies of zinc electrodeposition/dissolution under multiple galvanostatic plating/stripping conditions in symmetric Zn||Zn cells. With the combined microscopy approaches, we directly observed the dynamic nucleation and subsequent growth of Zn deposits, the heterogeneous transportation of charged clusters/particles, and the evolution of 'dead' Zn particles via partial dissolution. Zn electrodeposition at the early stage is mainly attributed to activation, while the subsequent dendrite growth is driven by diffusion. The high current not only facilitates the formation of sharp dendrites with a larger mean curvature at their tips but also leads to dendritic tip splitting and the creation of a hyper-branching morphology. This approach offers a direct opportunity to characterize dendrite formation in batteries with a metal anode in the laboratory.

Published

2023

35. Large-scale physically accurate modelling of real proton exchange membrane fuel cell with deep learning.

Author

Wang YD, Meyer Q, Tang K, McClure JE, White RT, Kelly ST, Crawford MM, Iacoviello F, Brett DJL, Shearing PR, Mostaghimi P, Zhao C, and Armstrong RT

Abstract

Proton exchange membrane fuel cells, consuming hydrogen and oxygen to generate clean electricity and water, suffer acute liquid water challenges. Accurate liquid water modelling is inherently challenging due to the multi-phase, multi-component, reactive dynamics within multi-scale, multi-layered porous media. In addition, currently inadequate imaging and modelling capabilities are limiting simulations to small areas (<1 mm 2 ) or simplified architectures. Herein, an advancement in water modelling is achieved using X-ray micro-computed tomography, deep learned super-resolution, multi-label segmentation, and direct multi-phase simulation. The resulting image is the most resolved domain (16 mm 2 with 700 nm voxel resolution) and the largest direct multi-phase flow simulation of a fuel cell. This generalisable approach unveils multi-scale water clustering and transport mechanisms over large dry and flooded areas in the gas diffusion layer and flow fields, paving the way for next generation proton exchange membrane fuel cells with optimised structures and wettabilities., (© 2023. The Author(s).)

Published

2023

36. In situ chamber for studying battery failure using high-speed synchrotron radiography.

Author

Pfaff J, Fransson M, Broche L, Buckwell M, Finegan DP, Moser S, Schopferer S, Nau S, Shearing PR, and Rack A

Abstract

The investigation of lithium-ion battery failures is a major challenge for personnel and equipment due to the associated hazards (thermal reaction, toxic gases and explosions). To perform such experiments safely, a battery abuse-test chamber has been developed and installed at the microtomography beamline ID19 of the European Synchrotron Radiation Facility (ESRF). The chamber provides the capability to robustly perform in situ abuse tests through the heat-resistant and gas-tight design for flexible battery geometries and configurations, including single-cell and multi-cell assemblies. High-speed X-ray imaging can be complemented by supplementary equipment, including additional probes (voltage, pressure and temperature) and thermal imaging. Together with the test chamber, a synchronization graphical user interface was developed, which allows an initial interpretation by time-synchronous visualization of the acquired data. Enabled by this setup, new meaningful insights can be gained into the internal processes of a thermal runaway of current and future energy-storage devices such as lithium-ion cells., (open access.)

Published

2023

37. Computer-Vision-Based Approach to Classify and Quantify Flaws in Li-Ion Electrodes.

Author

Daemi SR, Tan C, Tranter TG, Heenan TMM, Wade A, Salinas-Farran L, Llewellyn AV, Lu X, Matruglio A, Brett DJL, Jervis R, and Shearing PR

Subjects

Tomography, X-Ray Computed methods, Computers, Electrodes, Image Processing, Computer-Assisted methods, Neural Networks, Computer

Abstract

X-ray computed tomography (X-ray CT) is a non-destructive characterization technique that in recent years has been adopted to study the microstructure of battery electrodes. However, the often manual and laborious data analysis process hinders the extraction of useful metrics that can ultimately inform the mechanisms behind cycle life degradation. This work presents a novel approach that combines two convolutional neural networks to first locate and segment each particle in a nano-CT LiNiMnCoO 2 (NMC) electrode dataset, and successively classifies each particle according to the presence of flaws or cracks within its internal structure. Metrics extracted from the computer vision segmentation are validated with respect to traditional threshold-based segmentation, confirming that flawed particles are correctly identified as single entities. Successively, slices from each particle are analyzed by a pre-trained classifier to detect the presence of flaws or cracks. The models are used to quantify microstructural evolution in uncycled and cycled NMC811 electrodes, as well as the number of flawed particles in a NMC622 electrode. As a proof-of-concept, a 3-phase segmentation is also presented, whereby each individual flaw is segmented as a separate pixel label. It is anticipated that this analysis pipeline will be widely used in the field of battery research and beyond., (© 2022 The Authors. Small Methods published by Wiley-VCH GmbH.)

Published

2022

38. The Time-Dependent Role of Bisphosphonates on Atherosclerotic Plaque Calcification.

Author

Bakhshian Nik A, Ng HH, Garcia Russo M, Iacoviello F, Shearing PR, Bertazzo S, and Hutcheson JD

Abstract

Atherosclerotic plaque calcification directly contributes to the leading cause of morbidity and mortality by affecting plaque vulnerability and rupture risk. Small microcalcifications can increase plaque stress and promote rupture, whereas large calcifications can stabilize plaques. Drugs that target bone mineralization may lead to unintended consequences on ectopic plaque calcification and cardiovascular outcomes. Bisphosphonates, common anti-osteoporotic agents, have elicited unexpected cardiovascular events in clinical trials. Here, we investigated the role of bisphosphonate treatment and timing on the disruption or promotion of vascular calcification and bone minerals in a mouse model of atherosclerosis. We started the bisphosphonate treatment either before plaque formation, at early plaque formation times associated with the onset of calcification, or at late stages of plaque development. Our data indicated that long-term bisphosphonate treatment (beginning prior to plaque development) leads to higher levels of plaque calcification, with a narrower mineral size distribution. When given later in plaque development, we measured a wider distribution of mineral size. These morphological alterations might be associated with a higher risk of plaque rupture by creating stress foci. Yet, bone mineral density positively correlated with the duration of the bisphosphonate treatment.

Published

2022

39. Ultra high-resolution biomechanics suggest that substructures within insect mechanosensors decisively affect their sensitivity.

Author

Dinges GF, Bockemühl T, Iacoviello F, Shearing PR, Büschges A, and Blanke A

Subjects

Animals, Biomechanical Phenomena, Biophysics, Sensilla, Insecta physiology, Mechanotransduction, Cellular

Abstract

Insect load sensors, called campaniform sensilla (CS), measure strain changes within the cuticle of appendages. This mechanotransduction provides the neuromuscular system with feedback for posture and locomotion. Owing to their diverse morphology and arrangement, CS can encode different strain directions. We used nano-computed tomography and finite-element analysis to investigate how different CS morphologies within one location-the femoral CS field of the leg in the fruit fly Drosophila -interact under load. By investigating the influence of CS substructures' material properties during simulated limb displacement with naturalistic forces, we could show that CS substructures (i.e. socket and collar) influence strain distribution throughout the whole CS field. Altered socket and collar elastic moduli resulted in 5% relative differences in displacement, and the artificial removal of all sockets caused differences greater than 20% in cap displacement. Apparently, CS sockets support the distribution of distal strain to more proximal CS, while collars alter CS displacement more locally. Harder sockets can increase or decrease CS displacement depending on sensor location. Furthermore, high-resolution imaging revealed that sockets are interconnected in subcuticular rows. In summary, the sensitivity of individual CS is dependent on the configuration of other CS and their substructures.

Published

2022

40. Disentangling water, ion and polymer dynamics in an anion exchange membrane.

Author

Foglia F, Berrod Q, Clancy AJ, Smith K, Gebel G, Sakai VG, Appel M, Zanotti JM, Tyagi M, Mahmoudi N, Miller TS, Varcoe JR, Periasamy AP, Brett DJL, Shearing PR, Lyonnard S, and McMillan PF

Subjects

Anions, Ion Exchange, Ions, Membranes, Artificial, Polymers chemistry, Water chemistry

Abstract

Semipermeable polymeric anion exchange membranes are essential for separation, filtration and energy conversion technologies including reverse electrodialysis systems that produce energy from salinity gradients, fuel cells to generate electrical power from the electrochemical reaction between hydrogen and oxygen, and water electrolyser systems that provide H 2 fuel. Anion exchange membrane fuel cells and anion exchange membrane water electrolysers rely on the membrane to transport OH - ions between the cathode and anode in a process that involves cooperative interactions with H 2 O molecules and polymer dynamics. Understanding and controlling the interactions between the relaxation and diffusional processes pose a main scientific and critical membrane design challenge. Here quasi-elastic neutron scattering is applied over a wide range of timescales (10 0 -10 3  ps) to disentangle the water, polymer relaxation and OH - diffusional dynamics in commercially available anion exchange membranes (Fumatech FAD-55) designed for selective anion transport across different technology platforms, using the concept of serial decoupling of relaxation and diffusional processes to analyse the data. Preliminary data are also reported for a laboratory-prepared anion exchange membrane especially designed for fuel cell applications., (© 2022. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2022

41. High-speed 4D neutron computed tomography for quantifying water dynamics in polymer electrolyte fuel cells.

Author

Ziesche RF, Hack J, Rasha L, Maier M, Tan C, Heenan TMM, Markötter H, Kardjilov N, Manke I, Kockelmann W, Brett DJL, and Shearing PR

Abstract

In recent years, low-temperature polymer electrolyte fuel cells have become an increasingly important pillar in a zero-carbon strategy for curbing climate change, with their potential to power multiscale stationary and mobile applications. The performance improvement is a particular focus of research and engineering roadmaps, with water management being one of the major areas of interest for development. Appropriate characterisation tools for mapping the evolution, motion and removal of water are of high importance to tackle shortcomings. This article demonstrates the development of a 4D high-speed neutron imaging technique, which enables a quantitative analysis of the local water evolution. 4D visualisation allows the time-resolved studies of droplet formation in the flow fields and water quantification in various cell parts. Performance parameters for water management are identified that offer a method of cell classification, which will, in turn, support computer modelling and the engineering of next-generation flow field designs., (© 2022. The Author(s).)

Published

2022

42. In-Situ Li-Ion Pouch Cell Diagnostics Utilising Plasmonic Based Optical Fibre Sensors.

Author

Gardner C, Langhammer E, Du W, Brett DJL, Shearing PR, Roberts AJ, and Amietszajew T

Subjects

Electric Power Supplies, Electrodes, Ions, Lithium, Optical Fibers

Abstract

As the drive to improve the cost, performance characteristics and safety of lithium-ion batteries increases with adoption, one area where significant value could be added is that of battery diagnostics. This paper documents an investigation into the use of plasmonic-based optical fibre sensors, inserted internally into 1.4 Ah lithium-ion pouch cells, as a real time and in-situ diagnostic technique. The successful implementation of the fibres inside pouch cells is detailed and promising correlation with battery state is reported, while having negligible impact on cell performance in terms of capacity and columbic efficiency. The testing carried out includes standard cycling and galvanostatic intermittent titration technique (GITT) tests, and the use of a reference electrode to correlate with the anode and cathode readings separately. Further observations are made around the sensor and analyte interaction mechanisms, robustness of sensors and suggested further developments. These finding show that a plasmonic-based optical fibre sensor may have potential as an opto-electrochemical diagnostic technique for lithium-ion batteries, offering an unprecedented view into internal cell phenomena.

Published

2022

43. Effective Ultrasound Acoustic Measurement to Monitor the Lithium-Ion Battery Electrode Drying Process with Various Coating Thicknesses.

Author

Zhang YS, Robinson JB, Owen RE, Radhakrishnan ANP, Li J, Majasan JO, Shearing PR, Kendrick E, and Brett DJL

Abstract

The electrode drying process (DP) is a crucial step in the lithium-ion battery manufacturing chain and plays a fundamental role in governing the performance of the cells. The DP is extremely complex, with the dynamics and their implication in the production of electrodes generally being poorly understood. To date, there is limited discussion of these processes in the literature due to the limitation of the existing in situ metrology. Here, ultrasound acoustic measurements are demonstrated as a promising tool to monitor the physical evolution of the electrode coating in situ . These observations are validated by gravimetric analysis to show the feasibility of the technique to monitor the DP and identify the three different drying stages. A possible application of this technique is to adjust the drying rates based upon the ultrasound readings at different drying stages and to speed up the drying time. These findings prove that this measurement can be used as a cost-effective and simple tool to provide characteristic diagnostics of the electrode, which can be applied in large-scale coating manufacturing.

Published

2022

44. Design of Scalable, Next-Generation Thick Electrodes: Opportunities and Challenges.

Author

Boyce AM, Cumming DJ, Huang C, Zankowski SP, Grant PS, Brett DJL, and Shearing PR

Abstract

Lithium-ion battery electrodes are on course to benefit from current research in structure re-engineering to allow for the implementation of thicker electrodes. Increasing the thickness of a battery electrode enables significant improvements in gravimetric energy density while simultaneously reducing manufacturing costs. Both metrics are critical if the transition to sustainable transport systems is to be fully realized commercially. However, significant barriers exist that prevent the use of such microstructures: performance issues, manufacturing challenges, and scalability all remain open areas of research. In this Perspective, we discuss the challenges in adapting current manufacturing processes for thick electrodes and the opportunities that pore engineering presents in order to design thicker and better electrodes while simultaneously considering long-term performance and scalability.

Published

2021

45. Liposome Sterile Filtration Characterization via X-ray Computed Tomography and Confocal Microscopy.

Author

Johnson TF, Jones K, Iacoviello F, Turner S, Jackson NB, Zourna K, Welsh JH, Shearing PR, Hoare M, and Bracewell DG

Abstract

Two high resolution, 3D imaging techniques were applied to visualize and characterize sterilizing grade dual-layer filtration of liposomes, enabling membrane structure to be related with function and performance. Two polyethersulfone membranes with nominal retention ratings of 650 nm and 200 nm were used to filter liposomes of an average diameter of 143 nm and a polydispersity index of 0.1. Operating conditions including differential pressure were evaluated. X-ray computed tomography at a pixel size of 63 nm was capable of resolving the internal geometry of each membrane. The respective asymmetry and symmetry of the upstream and downstream membranes could be measured, with pore network modeling used to identify pore sizes as a function of distance through the imaged volume. Reconstructed 3D digital datasets were the basis of tortuous flow simulation through each porous structure. Confocal microscopy visualized liposome retention within each membrane using fluorescent dyes, with bacterial challenges also performed. It was found that increasing pressure drop from 0.07 MPa to 0.21 MPa resulted in differing fluorescent retention profiles in the upstream membrane. These results highlighted the capability for complementary imaging approaches to deepen understanding of liposome sterilizing grade filtration.

Published

2021

46. Degradation of Layered Oxide Cathode in a Sodium Battery: A Detailed Investigation by X-Ray Tomography at the Nanoscale.

Author

DiLecce D, Marangon V, Isaacs M, Palgrave R, Shearing PR, and Hassoun J

Abstract

The degradation mechanism in a sodium cell of a layered Na 0.48 Al 0.03 Co 0.18 Ni 0.18 Mn 0.47 O 2 (NCAM) cathode with P3/P2 structure is investigated by revealing the changes in microstructure and composition upon cycling. The work aims to rationalize the gradual performance decay and the alteration of the electrochemical response in terms of polarization, voltage signature, and capacity loss. Spatial reconstructions of the electrode by X-ray computed tomography at the nanoscale supported by quantitative and qualitative analyses show fractures and deformations in the cycled layered metal-oxide particles, as well as inorganic side compounds deposited on the material. These irreversible morphological modifications reflect structural heterogeneities across the cathode particles due to formation of various domains with different Na + intercalation degrees. Besides, X-ray photoelectron spectroscopy data suggest that the latter inorganic species in the cycled electrode are mainly composed of NaF, Na 2 O, and NaCO 3 formed by parasitic electrolyte decomposition. The precipitation of these insulating compounds at the electrode/electrolyte interphase and the related structural stresses induced in the material lead to a decrease in cathode particle size and partial loss of electrochemical activity. The retention of the NCAM phase after cycling suggests that electrolyte upgrade may improve the performance of the cathode to achieve practical application for sustainable energy storage., (© 2021 The Authors. Small Methods published by Wiley-VCH GmbH.)

Published

2021

47. Scalable Sacrificial Templating to Increase Porosity and Platinum Utilisation in Graphene-Based Polymer Electrolyte Fuel Cell Electrodes.

Author

Suter TAM, Clancy AJ, Rubio Carrero N, Heitzmann M, Guetaz L, Shearing PR, Mattevi C, Gebel G, Howard CA, Shaffer MSP, McMillan PF, and Brett DJL

Abstract

Polymer electrolyte fuel cells hold great promise for a range of applications but require advances in durability for widespread commercial uptake. Corrosion of the carbon support is one of the main degradation pathways; hence, corrosion-resilient graphene has been widely suggested as an alternative to traditional carbon black. However, the performance of bulk graphene-based electrodes is typically lower than that of commercial carbon black due to their stacking effects. This article reports a simple, scalable and non-destructive method through which the pore structure and platinum utilisation of graphene-based membrane electrode assemblies can be significantly improved. Urea is incorporated into the catalyst ink before deposition, and is then simply removed from the catalyst layer after spraying by submerging the electrode in water. This additive hinders graphene restacking and increases porosity, resulting in a significant increase in Pt utilisation and current density. This technique does not require harsh template etching and it represents a pathway to significantly improve graphene-based electrodes by introducing hierarchical porosity using scalable liquid processes.

Published

2021

48. Influence of Flow Field Design on Zinc Deposition and Performance in a Zinc-Iodide Flow Battery.

Author

ShakeriHosseinabad F, Daemi SR, Momodu D, Brett DJL, Shearing PR, and Roberts EPL

Abstract

Among the aqueous redox flow battery systems, redox chemistries using a zinc negative electrode have a relatively high energy density, but the potential of achieving high power density and long cycle life is hindered by dendrite growth at the anode. In this study, a new cell design with a narrow gap between electrode and membrane was applied in a zinc-iodide flow battery. In this design, some of the electrolyte flows over the electrode surface and a fraction of the flow passes through the porous felt electrode in the direction of current flow. The flow battery was tested under constant current density over 40 cycles, and the efficiency, discharge energy density, and power density of the battery were significantly improved compared to conventional flow field designs. The power density obtained in this study is one of the highest power densities reported for the zinc-iodide battery. The morphology of the zinc deposition was studied using scanning electron microscopy and optical profilometry. It was found that the flow through the electrode led to a thinner zinc deposit with lower roughness on the surface of the electrode, in comparison to the case where there was no flow through the electrode. In addition, inhibition of dendrite formation enabled operation at a higher range of current density. Ex situ tomographic measurements were used to image the zinc deposited on the surface and inside the porous felt. Volume rendering of graphite felt from X-ray computed tomography images showed that in the presence of flow through the electrode, more zinc deposition occurred inside the porous felt, resulting in a compact and thinner surface deposit, which may enable higher battery capacity and improved performance.

Published

2021

49. High-Density Lignin-Derived Carbon Nanofiber Supercapacitors with Enhanced Volumetric Energy Density.

Author

Hérou S, Bailey JJ, Kok M, Schlee P, Jervis R, Brett DJL, Shearing PR, Ribadeneyra MC, and Titirici M

Abstract

Supercapacitors are increasingly used in short-distance electric transportation due to their long lifetime (≈15 years) and fast charging capability (>10 A g -1 ). To improve their market penetration, while minimizing onboard weight and maximizing space-efficiency, materials costs must be reduced (<10 $ kg -1 ) and the volumetric energy-density increased (>8 Wh L -1 ). Carbon nanofibers display good gravimetric capacitance, yet their marketability is hindered by their low density (0.05-0.1 g cm -3 ). Here, the authors increase the packing density of low-cost, free-standing carbon nanofiber mats (from 0.1 to 0.6 g cm -3 ) through uniaxial compression. X-ray computed tomography reveals that densification occurs by reducing the inter-fiber pore size (from 1-5 µm to 0.2-0.5 µm), which are not involved in double-layer capacitance. The improved packing density is directly proportional to the volumetric performances of the device, which reaches a volumetric capacitance of 130 F cm -3 and energy density of 6 Wh L -1 at 0.1 A g -1 using a loading of 3 mg cm -2 . The results outperform most commercial and lab-scale porous carbons synthesized from bioresources (50-100 F cm -3 , 1-3 Wh L -1 using 10 mg cm -2 ) and contribute to the scalable design of sustainable electrodes with minimal 'dead volume' for efficient supercapacitors., (© 2021 The Authors. Advanced Science published by Wiley-VCH GmbH.)

Published

2021

50. In Situ Ultrasound Acoustic Measurement of the Lithium-Ion Battery Electrode Drying Process.

Author

Zhang YS, Pallipurath Radhakrishnan AN, Robinson JB, Owen RE, Tranter TG, Kendrick E, Shearing PR, and Brett DJL

Abstract

The electrode drying process is a crucial step in the manufacturing of lithium-ion batteries and can significantly affect the performance of an electrode once stacked in a cell. High drying rates may induce binder migration, which is largely governed by the temperature. Additionally, elevated drying rates will result in a heterogeneous distribution of the soluble and dispersed binder throughout the electrode, potentially accumulating at the surface. The optimized drying rate during the electrode manufacturing process will promote balanced homogeneous binder distribution throughout the electrode film; however, there is a need to develop more informative in situ metrologies to better understand the dynamics of the drying process. Here, ultrasound acoustic-based techniques were developed as an in situ tool to study the electrode drying process using NMC622-based cathodes and graphite-based anodes. The drying dynamic evolution for cathodes dried at 40 and 60 °C and anodes dried at 60 °C were investigated, with the attenuation of the reflective acoustic signals used to indicate the evolution of the physical properties of the electrode-coating film. The drying-induced acoustic signal shifts were discussed critically and correlated to the reported three-stage drying mechanism, offering a new mode for investigating the dynamic drying process. Ultrasound acoustic-based measurements have been successfully shown to be a novel in situ metrology to acquire dynamic drying profiles of lithium-ion battery electrodes. The findings would potentially fulfil the research gaps between acquiring dynamic data continuously for a drying mechanism study and the existing research metrology, as most of the published drying mechanism research studies are based on simulated drying processes. It shows great potential for further development and understanding of the drying process to achieve a more controllable electrode manufacturing process.

Published

2021