Abstract:The interfacial interaction of the colloidal NPs in solution is closely related to the surface charge, which heavily influences the NP synthesis, colloidal stabilization and various applications. [2] In general, the inorganic core of colloidal NPs in solutions possess a net electric charge at the interface, which can attract dissolved heterogeneously-charged crystal-constituting ions and solvent molecules by electrostatic interaction, thus constructing the electrical double layer and rendering the NPs well-di… Show more
“…Similar to Lis et al 4 and Xi et al 26 , we conducted flow experiments at the CaF 2 -water interface under acidic conditions, first at a single position in the channel. Figure 1a illustrates our experiment.…”
Section: Resultsmentioning
confidence: 99%
“…For each flow rate, the increase of the intensity upon applying flow varies monotonically between inlet and outlet. To the best of our knowledge, other spectroscopic flow experiments conducted so far only varied the flow rate in ranges where no dependency has been observed 4 , 26 . Fig.…”
Section: Resultsmentioning
confidence: 99%
“…Figure 4a illustrates this view of the surface chemistry. While Lis et al 4 and Xi et al 26 only considered the charging reaction from Eq. ( 1 ) to qualitatively explain the flow-induced changes in v-SFG spectra, we argue that a consistent and quantitative description of the experimental results also requires to incorporate the dissolution as described by Eq.…”
The charging and dissolution of mineral surfaces in contact with flowing liquids are ubiquitous in nature, as most minerals in water spontaneously acquire charge and dissolve. Mineral dissolution has been studied extensively under equilibrium conditions, even though non-equilibrium phenomena are pervasive and substantially affect the mineral-water interface. Here we demonstrate using interface-specific spectroscopy that liquid flow along a calcium fluoride surface creates a reversible spatial charge gradient, with decreasing surface charge downstream of the flow. The surface charge gradient can be quantitatively accounted for by a reaction-diffusion-advection model, which reveals that the charge gradient results from a delicate interplay between diffusion, advection, dissolution, and desorption/adsorption. The underlying mechanism is expected to be valid for a wide variety of systems, including groundwater flows in nature and microfluidic systems.
“…Similar to Lis et al 4 and Xi et al 26 , we conducted flow experiments at the CaF 2 -water interface under acidic conditions, first at a single position in the channel. Figure 1a illustrates our experiment.…”
Section: Resultsmentioning
confidence: 99%
“…For each flow rate, the increase of the intensity upon applying flow varies monotonically between inlet and outlet. To the best of our knowledge, other spectroscopic flow experiments conducted so far only varied the flow rate in ranges where no dependency has been observed 4 , 26 . Fig.…”
Section: Resultsmentioning
confidence: 99%
“…Figure 4a illustrates this view of the surface chemistry. While Lis et al 4 and Xi et al 26 only considered the charging reaction from Eq. ( 1 ) to qualitatively explain the flow-induced changes in v-SFG spectra, we argue that a consistent and quantitative description of the experimental results also requires to incorporate the dissolution as described by Eq.…”
The charging and dissolution of mineral surfaces in contact with flowing liquids are ubiquitous in nature, as most minerals in water spontaneously acquire charge and dissolve. Mineral dissolution has been studied extensively under equilibrium conditions, even though non-equilibrium phenomena are pervasive and substantially affect the mineral-water interface. Here we demonstrate using interface-specific spectroscopy that liquid flow along a calcium fluoride surface creates a reversible spatial charge gradient, with decreasing surface charge downstream of the flow. The surface charge gradient can be quantitatively accounted for by a reaction-diffusion-advection model, which reveals that the charge gradient results from a delicate interplay between diffusion, advection, dissolution, and desorption/adsorption. The underlying mechanism is expected to be valid for a wide variety of systems, including groundwater flows in nature and microfluidic systems.
“…[ 22,23 ] To verify these accurately, vibrational sum frequency generation (SFG) spectroscopy has been applied to detect molecular adsorption orientation states on the surface. [ 18,24 ] As shown in Figure 2d, as the selfâassembling time increasing from 0 to 360 min, two peak signals at 2940 and 2904 cm â1 assigned to ïŁżCH 2 and ïŁżCH 3 fermi resonance signals appeared gradually and finally got saturated. Along with the immersion time increasing longer, the coverage of organic layer changed little and became quite stable, demonstrating the adsorbed organic layer became saturated and formed a monolayer with subânanosized thickness.…”
Section: Resultsmentioning
confidence: 99%
“…Interfaceâsensitive sum frequency generation spectroscopy (SFG), Xâray photoelectron spectroscopy (XPS) and atomic force microscopy have been exploited to verify the evolution presences and the mechanical property of the organic and inorganic layers, respectively. [ 16â19 ] We demonstrate that the in situ selfâassembled ordered organic/inorganic hybrid SEI on lithium surface shows the advantages in prohibiting the formation of lithium dendrites and the resistance to the adsorption of solvent molecules, which has close relationship with its anticorrosion functionality as evidenced by SFG. As a result, the pretreated lithium metal anode exhibits excellent reversible stability at as high as 10 mA cm â2 , and it also maintains high Coulombic efficiency at the stripping/plating capacity of 3 mA h cm â2 , which is better than most reported literatures.…”
Metallic lithium electrode with high capacity of 3860Â mA h gâ1 is the most promising candidate for rechargeable batteries. However, some inherent problems such as dendrite growth, uneven solid electrolyte interphase (SEI), and high manufacturing risk restraint its practical application. Herein, distinct from the conventional mosaic structure, a facile fabrication of in situ selfâassembled organic/inorganic hybrid SEI with ordered dualâlayer structure on the lithium surface to suppress dendrite formation is proposed. With the aid of moderate active fluoricâcontaining ionic liquid, the asâformed lithium fluoride and robust ordered organic moieties are in situ selfâassembled on the metallic lithium surface. The evolution process of the dualâlayered structure is revealed by Xâray spectroscopy, in situ sum frequency generation spectroscopy, and atomic force microscopy. The formed âdouble protectionâ ordered hybrid interphase layer also exhibits the surprising ability against the corrosion of carbonate electrolyte or dry air. As a consequence, the pretreated metallic lithium electrode represents excellent stripping/plating reversibility of â99% and a long lifespan up to 1200 h without formation of dendrite, and remains high performance at a current density of 10Â mA cmâ2, which is much higher than most reports, showing the facilitating promising to the future utilization.
Spatially random lithium nucleation and sluggish lithium diffusion across the electrode/electrolyte interface lead to uncontrollable lithium deposition and the growth of lithium dendrite on metallic lithium surface, causing severe safety problems. Herein, a functional rapid-ion-diffusion alloy layer on the metallic lithium surface (RIDAL-Li) is designed through a simple chemical reduction reaction. Such a layer efficiently reduces energy barriers for lithium transport and thus significantly homogenizes the lithium atom flux for lateral deposition, which are confirmed by electrochemical tests, theoretical simulations, and spectroscopic analysis. Furthermore, the as-prepared RIDAL layer also displays a much higher corrosion resistance to moisture and oxygen. As a result, in ether-based and carbonate-based electrolytes, the pretreated RIDAL-Li anode can achieve a long stripping/plating lifespan of 900 h and a high Coulombic efficiency of 99% without dendrite growth. Even after being exposed to the ambient environment with relative humidity of 51% for 60 min, the RIDAL-Li can survive for stripping/plating 400 h and exhibit a low overpotential of 18 mV, displaying the superiority for ambient atmosphere battery assembly. Matched with LiFePO 4 or sulfur cathode, the full cells exhibit remarkably improved stability and capacity retention, showing its suitability for applications in lithium metal batteries.
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