7 research outputs found
Correlating activity and defects in (photo)electrocatalysts using in-situ transient optical microscopy
(Photo)electrocatalysts capture sunlight and use it to drive chemical
reactions such as water splitting to produce H2. A major factor limiting
photocatalyst development is their large heterogeneity which spatially
modulates reactivity and precludes establishing robust structure-function
relationships. To make such links requires simultaneously probing of the
electrochemical environment at microscopic length scales (nm to um) and broad
timescales (ns to s). Here, we address this challenge by developing and
applying in-situ steady-state and transient optical microscopies to directly
map and correlate local electrochemical activity with hole lifetimes, oxygen
vacancy concentration and the photoelectrodes crystal structure. Using this
combined approach alongside spatially resolved X-Ray absorption measurements,
we study microstructural and point defects in prototypical hematite (Fe2O3)
photoanodes. We demonstrate that regions of Fe2O3, adjacent to microstructural
cracks have a better photoelectrochemical response and reduced back electron
recombination due to an optimal oxide vacancy concentration, with the film
thickness and carbon impurities also dramatically influencing activity in a
complex manner. Our work highlights the importance of microscopic mapping to
understand activity and the impact of defects in even, seemingly, homogeneous
solid-state metal oxide photoelectrodes
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Operando optical tracking of single-particle ion dynamics in batteries.
The key to advancing lithium-ion battery technology-in particular, fast charging-is the ability to follow and understand the dynamic processes occurring in functioning materials under realistic conditions, in real time and on the nano- to mesoscale. Imaging of lithium-ion dynamics during battery operation (operando imaging) at present requires sophisticated synchrotron X-ray1-7 or electron microscopy8,9 techniques, which do not lend themselves to high-throughput material screening. This limits rapid and rational materials improvements. Here we introduce a simple laboratory-based, optical interferometric scattering microscope10-13 to resolve nanoscopic lithium-ion dynamics in battery materials, and apply it to follow cycling of individual particles of the archetypal cathode material14,15, LixCoO2, within an electrode matrix. We visualize the insulator-to-metal, solid solution and lithium ordering phase transitions directly and determine rates of lithium diffusion at the single-particle level, identifying different mechanisms on charge and discharge. Finally, we capture the dynamic formation of domain boundaries between different crystal orientations associated with the monoclinic lattice distortion at the Li0.5CoO2 composition16. The high-throughput nature of our methodology allows many particles to be sampled across the entire electrode and in future will enable exploration of the role of dislocations, morphologies and cycling rate on battery degradation. The generality of our imaging concept means that it can be applied to study any battery electrode, and more broadly, systems where the transport of ions is associated with electronic or structural changes. Such systems include nanoionic films, ionic conducting polymers, photocatalytic materials and memristors.ER
Operando monitoring of single-particle kinetic state-of-charge heterogeneities and cracking in high-rate Li-ion anodes.
To rationalize and improve the performance of newly developed high-rate battery electrode materials, it is crucial to understand the ion intercalation and degradation mechanisms occurring during realistic battery operation. Here we apply a laboratory-based operando optical scattering microscopy method to study micrometre-sized rod-like particles of the anode material Nb14W3O44 during high-rate cycling. We directly visualize elongation of the particles, which, by comparison with ensemble X-ray diffraction, allows us to determine changes in the state of charge of individual particles. A continuous change in scattering intensity with state of charge enables the observation of non-equilibrium kinetic phase separations within individual particles. Phase field modelling (informed by pulsed-field-gradient nuclear magnetic resonance and electrochemical experiments) supports the kinetic origin of this separation, which arises from the state-of-charge dependence of the Li-ion diffusion coefficient. The non-equilibrium phase separations lead to particle cracking at high rates of delithiation, particularly in longer particles, with some of the resulting fragments becoming electrically disconnected on subsequent cycling. These results demonstrate the power of optical scattering microscopy to track rapid non-equilibrium processes that would be inaccessible with established characterization techniques.This work was supported by the Faraday Institution, FIRG012, FIRG024. A.J.M. acknowledges support from the EPSRC Cambridge NanoDTC, EP/L015978/1. C.S. acknowledges financial support by the Royal
Commission of the Exhibition of 1851. We acknowledge financial support from the EPSRC and the Winton Program for the Physics of Sustainability. This project has received funding from the European Research Council (ERC) under the European Unionâs Horizon 2020 research and innovation program (Grant Agreement No. 758826). C.P.G., S.P.E and A.J.M. were supported by an ERC Advanced Investigator Grant for Prof. Clare
Grey (EC H2020 835073). Use of the Advanced Photon Source at Argonne National Laboratory was supported by the U. S. Department of Energy, Office of Science, Office of Basic Energy Sciences, under Contract No.
DE-AC02-06CH11357. We thank S. Nagendran and J. Thuillier for their help with synthesizing the materials and with the PFG-NMR measurements, P. Magusin for advice regarding the PFG-NMR measurements, B. Mockus for help with the code development, and F. Alford for useful discussions regarding analysis of optical data
A mechanistic study of the dopant-induced breakdown in halide perovskites using solid state energy storage devices.
Doping halide perovskites (HPs) with extrinsic species, such as alkali metal ions, plays a critical, albeit often elusive role in optimising optoelectronic devices. Here, we use solid state lithium ion battery inspired devices with a polyethylene oxide-based polymer electrolyte to dope HPs controllably with lithium ions. We perform a suite of operando material analysis techniques while dynamically varying Li doping concentrations. We determine and quantify three doping regimes; a safe regime, with doping concentrations of <1020 cm-3 (2% Liâ:âPb mol%) in which the HP may be modified without detrimental effect to its structure; a minor decomposition regime, in which the HP is partially transformed but remains the dominant species; and a major decomposition regime in which the perovskite is superseded by new phases. We provide a mechanistic description of the processes mediating between each stage and find evidence for metallic Pb(0), LiBr and LiPbBr2 as final decomposition products. Combining results from synchrotron X-ray diffraction measurements with in situ photoluminescence and optical reflection microscopy studies, we distinguish the influences of free charge carriers and intercalated lithium independently. We find that the charge density is equally as important as the geometric considerations of the dopant species and thereby provide a quantitative framework upon which the future design of doped-perovskite energy devices should be based.I have copied a comprehensive list of funding sources below:
EPSRC Graphene CDT EP/L016087/1
ERC Consolidator Grant (MIGHTY, 866005
Deutsche Forschungsgemeinschaft (DFG) under the Emmy Noether Program (Project 387651688
Winton Fellowship from the Winton Programm for the Physics of Sustainabilit
Operando visualisation of kinetically-induced lithium heterogeneities in single-particle layered Ni-rich cathodes
Understanding how lithium-ion dynamics affect the (de)lithiation mechanisms of state-of-the-art nickel-rich layered oxide cathodes is crucial to improving electrochemical performance. Here, we directly observe two distinct kinetically-induced lithium heterogeneities within single-crystal LiNixMnyCo(1-x-y)O2 (NMC) particles using recently developed operando optical microscopy, challenging the notion that uniform (de)lithiation occurs within individual particles. Upon delithiation, a rapid increase in lithium diffusivity at the beginning of charge results in particles with lithium-poor peripheries and lithium-rich cores. The slow ion diffusion at near-full lithiation states â and slow charge transfer kinetics â also leads to heterogeneity at the end of discharge, with a lithium-rich surface preventing complete lithiation. Finite-element modelling confirms that concentration-dependent diffusivity is necessary to reproduce these phenomena. Our results show that diffusion limitations cause first-cycle capacity losses in Ni-rich cathodes
Correlating activities and defects in (photo)electrocatalysts using in-situ multi-modal microscopic imaging
International audiencePhoto(electro)catalysts use sunlight to drive chemical reactions such as water splitting. A major factor limiting photocatalyst development is physicochemical heterogeneity which leads to spatially dependent reactivity. To link structure and function in such systems, simultaneous probing of the electrochemical environment at microscopic length scales and a broad range of timescales (ns to s) is required. Here, we address this challenge by developing and applying in-situ (optical) microscopies to map and correlate local electrochemical activity, with hole lifetimes, oxygen vacancy concentrations and photoelectrode crystal structure. Using this multi-modal approach, we study prototypical hematite (alpha-Fe2O3) photoelectrodes. We demonstrate that regions of alpha-Fe2O3, adjacent to microstructural cracks have a better photoelectrochemical response and reduced back electron recombination due to an optimal oxygen vacancy concentration, with the film thickness and extended light exposure also influencing local activity. Our work highlights the importance of microscopic mapping to understand activity, in even seemingly homogeneous photoelectrodes. Physicochemical heterogeneity poses a significant constraint in photocatalyst advancement. Here the authors introduce a multimodal optical microscopy platform to assess activity and defects concurrently in photoelectrocatalysts, revealing that disorder can unexpectedly enhance local photoelectrocatalytic performance in certain instances
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Correlating activities and defects in (photo)electrocatalysts using in-situ multi-modal microscopic imaging
Acknowledgements: This work acknowledges funding from the Generalitat Valenciana program (APOSTD/2021/251, C.A.M.), MinCiencias Colombia (Fondo Nacional de financiamiento para la ciencia, la tecnologĂa y la innovaciĂłn âFrancisco JosĂ© de Caldasâ, call 848 de 2019, C.A.M.), the CNRS and the French Agence Nationale de la Recherche (ANR; grant ANR-22-CPJ2-0053-01, E.P.), a âla Caixaâ Foundation Fellowshp (ID 100010434 (LCF/BQ/PR22/11920013), E.P.), the EPSRC via the Cambridge NanoDTC, (EP/L015978/1, A.J.M.) and grants (EP/M006360/1 and EP/W017091/1, A.R.), the Winton Program for the Physics of Sustainability (A.R. and R.P.) and Clare College, Cambridge (Junior Research Fellowship, R.P.). The authors (S.G. and C.A.M.) acknowledge support from project PID2020-116093RB-C41 funded through MCIN/AEI/10.13039/501100011033. This work was carried out with the support of Diamond Light Source, instrument I18 (proposal SP30381-1). R.P. additionally thanks Arjun Ashoka (Cambridge) for useful assistance and advice with building of the experimental setup and writing of the data acquisition code.Photo(electro)catalysts use sunlight to drive chemical reactions such as water splitting. A major factor limiting photocatalyst development is physicochemical heterogeneity which leads to spatially dependent reactivity. To link structure and function in such systems, simultaneous probing of the electrochemical environment at microscopic length scales and a broad range of timescales (ns to s) is required. Here, we address this challenge by developing and applying in-situ (optical) microscopies to map and correlate local electrochemical activity, with hole lifetimes, oxygen vacancy concentrations and photoelectrode crystal structure. Using this multi-modal approach, we study prototypical hematite (α-Fe2O3) photoelectrodes. We demonstrate that regions of α-Fe2O3, adjacent to microstructural cracks have a better photoelectrochemical response and reduced back electron recombination due to an optimal oxygen vacancy concentration, with the film thickness and extended light exposure also influencing local activity. Our work highlights the importance of microscopic mapping to understand activity, in even seemingly homogeneous photoelectrodes