H. Tostmann scite author profile

We report x-ray reflectivity (XR) and small angle off-specular diffuse scattering (DS) measurements from the surface of liquid Indium close to its melting point of 156 • C. From the XR measurements we extract the surface structure factor convolved with fluctuations in the height of the liquid surface. We present a model to describe DS that takes into account the surface structure factor, thermally excited capillary waves and the experimental resolution. The experimentally determined DS follows this model with no adjustable parameters, allowing the surface structure factor to be deconvolved from the thermally excited height fluctuations. The resulting local electron density profile displays exponentially decaying surface induced layering similar to that previously reported for Ga and Hg. We compare the details of the local electron density profiles of liquid In, which is a nearly free electron metal, and liquid Ga, which is considerably more covalent and shows directional bonding in the melt. The oscillatory density profiles have comparable amplitudes in both metals, but surface layering decays over a length scale of 3.5 ± 0.6Å for In and 5.5 ± 0.4Å for Ga. Upon controlled exposure to oxygen, no oxide monolayer is formed on the liquid In surface, unlike the passivating film formed on liquid Gallium.

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X-ray reflectivity study of temperature-dependent surface layering in liquid Hg

DiMasi

et al. 1998

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We report x-ray reflectivity measurements of liquid mercury between Ϫ36°C and ϩ25°C. The surface structure can be described by a layered density profile convolved with a thermal roughness T . The layering has a spacing of 2.72 Å and an exponential decay length of 5.0 Å. Surprisingly, T is found to increase considerably faster with temperature than the ͱT behavior predicted by capillary wave theory, in contrast with previous measurements on Ga and dielectric liquids. ͓S0163-1829͑98͒52144-3͔The effect of temperature on the surface structure of a liquid is quite different from that of a solid surface. In the liquid, thermal surface waves are excited at all wavelengths from the particle spacing to a long wavelength gravitational cutoff, and produce a surface roughness on the order of the particle spacing. For nonmetallic liquids, these capillary waves broaden the liquid-vapor interface, which is a monotonically decreasing density profile with a width of several Å. 1 Metallic liquids exhibit a more complex surface structure in which the atoms are stratified parallel to the liquid-vapor interface in layers that persist into the bulk for a few atomic diameters. This layering arises from the strongly densitydependent nonlocal interionic potential 2 and is unique to metallic liquids. Nevertheless, the effect of temperature is still expected to be principally in the form of capillary waves, which roughen the surface-normal profile and diminish the layering amplitude. X-ray reflectivity measurements have confirmed the existence of surface layering in liquid Hg, 3 Ga, 4 In, 5 and several alloys. 6,7 Models based on capillary waves as the only mechanism for surface roughening were found to describe the temperature-dependent layering of liquid Ga 8 as well as diffuse scattering measured from the liquid In surface. 5 In previous comparisons of the x-ray reflectivity of liquid Hg and Ga, 9 two important differences were identified. Although reflectivities for both metals exhibit quasi-Bragg peaks indicative of surface layering, the Hg data have a minimum at low-momentum transfer (q z Ϸ0.6 Å Ϫ1 ) not found in Ga ͑see Fig. 2 in Ref. 9͒. To describe this minimum, the model for the surface structure had to be more complex than that of Ga. One successful model incorporated a low density region persisting a few Å into the vapor side of the interface.This feature was taken to be intrinsic to Hg. In addition, the room-temperature layering peak appeared to be broader for Hg than for Ga, leading to the conclusion that in Hg, surface layering decayed over a much shorter length scale.Subsequent measurements yielded variations in this lowq z minimum, prompting us to address the possible effect of impurities at the surface. An important difference between experiments on Hg and Ga is that due to the low vapor pressure, Ga can be measured under ultra-high-vacuum ͑UHV͒ conditions and cleaned in situ by argon sputtering, which is not possible for Hg. In this work, we compare Hg measured in a reducing H 2 atmosphere 10 to measurements taken in a U...

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X-ray study of the liquid potassium surface: Structure and capillary wave excitations

et al. 2003

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We present x-ray reflectivity and diffuse scattering measurements from the liquid surface of pure potassium. They strongly suggest the existence of atomic layering at the free surface of a pure liquid metal with low surface tension. Prior to this study, layering was observed only for metals like Ga, In, and Hg, the surface tensions of which are five-to sevenfold higher than that of potassium, and hence closer to inducing an ideal ''hard wall'' boundary condition. The experimental result requires quantitative analysis of the contribution to the surface scattering from thermally excited capillary waves. Our measurements confirm the predicted form for the differential cross section for diffuse scattering, d/d⍀ϳ1/q xy 2Ϫ where ϭk B Tq z 2 /2␥, over a range of and q xy that is larger than any previous measurement. The partial measure of the surface structure factor that we obtained agrees with computer simulations and theoretical predictions.

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Microscopic Structure of the Wetting Film at the Surface of Liquid Ga-Bi Alloys

et al. 2000

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X-ray reflectivity measurements of the binary liquid Ga-Bi alloy reveal a dramatically different surface structure above and below the monotectic temperature Tmono = 222• C. A Gibbs-adsorbed Bi monolayer resides at the surface at both regimes. However, a 30Å thick, Bi-rich wetting film intrudes between the Bi monolayer and the Ga-rich bulk for T > Tmono. The internal structure of the wetting film is determined withÅ resolution, showing a theoretically unexpected concentration gradient and a highly diffuse interface with the bulk phase.

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H. Tostmann

X-ray study of the oxidation of liquid-gallium surfaces

Surface structure of liquid metals and the effect of capillary waves: X-ray studies on liquid indium

X-ray reflectivity study of temperature-dependent surface layering in liquid Hg

X-ray study of the liquid potassium surface: Structure and capillary wave excitations

Microscopic Structure of the Wetting Film at the Surface of Liquid Ga-Bi Alloys

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