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Scanning probe simultaneously captures structural and ion concentration changes

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Scanning probe simultaneously captures structural and ion concentration changes
Volume change monitoring during the CV of the graphite anode by Operando SICM. (a) Scheme of the single point measurement. (b) Time course of the potential, height, state of charge, carbon anode current, and SICM current during the CV. (c) Scheme of the continuous one-line scanning measurement. (d) Time course of the one-line height image, carbon anode current, and SICM current during the CV. The sweep rate was 0.3 mV/s. (e) SICM ion current XZ images, where the image points are shown in Fig. 5d. Hopping amplitude and the falling rate of SICM were 2000 nm and 30 nm/ms, respectively. The nanopipettes radii were 50 nm and filled with 1.0 M LiClO4 in EC / DEC = 1 / 2 (v/v). The height monitoring was acquired by applying the constant voltage of 0.7 V vs. Li/Li+. Credit: Takahashi et al., JACS Au

Lithium ion batteries dominate the energy storage sector from the scale of small portable devices to electric vehicles and even grid-scale electricity suppliers. Research is constantly ongoing to improve their energy density, charging speed, lifetime and safety, among other attributes. Here an understanding of not just the changes that go on in lithium ion batteries but how different parameters might interact can be extremely advantageous.

Now researchers led by Yasufumi Takahashi and Takeshi Fukuma at Kanazawa University in Japan report simultaneous measurements of topography and ion concentration profiles by developing their operando scanning ion conductance microscopy (operando SICM). The combined data they retrieve can enable evaluation of correlations between the two parameters for improving future battery performance.

As Takahashi and Fukuma list in their report on the work, several processes are involved in the charging and discharging of lithium batteries, including the transport, solvation or desolvation, and intercalation of lithium ions, as well as structural changes and expansion in the electrodes, and the formation and deposition of by-products.

These all occur out of equilibrium under applied electric potentials. “Capturing such multi-step and time-dependent changes with a relevant spatiotemporal resolution enables optimizing the operating conditions,” they point out highlighting design features that might benefit such as the structure of electrodes and separator, and tailoring additives to ensure proper solid−electrolyte interphase formation.

As a result, numerous techniques have been used to investigate how both the surface topography and the ion concentration change of the anode/cathode during charging/discharging, all with different limitations.

A key advantage of SICM is that it can measure surface morphology and properties, including changes in ion concentration with depth in the electrolyte. Until now, however, no-one had retrieved simultaneous topographical and ion concentration data of a battery during charging and discharging.

The SICM uses a nanopipette containing an ionic solution as the scanning probe. The nanopipette acts as a probe and monitors changes in ion current from which it is possible to visualize ion concentrations as well as the distance to a surface. To take both measurements simultaneously, the researchers made a number of adjustments to the hardware and software so that they could independently control the battery and scanning probe electrode potentials.

They also had to deal with various complicating factors such as the decrease in effective potential due to uncompensated solution resistance and the different settings of the potentiostat and amplifier used in the adjustments.

With these modifications, they were able to perform simultaneous topography and ion concentration profile measurements with a spatial resolution that exceeds optical microscopy. They were able to identify reversible phase changes during charging and discharging, as well as structural changes that were not restored on discharging the anode—a potential source of degradation.

The researchers conclude that their “Operando SICM has the potential to unveil the lithium ion battery’s non-equilibrium mechanism and bottleneck processes such as dendrite formation by correlative analysis of the dendrite formation and ion concentration for optimizing the separator structure.”

The study is published in the journal JACS Au.

More information:
Yasufumi Takahashi et al, Correlative Analysis of Ion-Concentration Profile and Surface Nanoscale Topography Changes Using Operando Scanning Ion Conductance Microscopy, JACS Au (2023). DOI: 10.1021/jacsau.2c00677

Provided by
Kanazawa University


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Scanning probe simultaneously captures structural and ion concentration changes (2023, March 29)
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