Application Downloads

Sample cleaning using Ar-GCIS

Typical samples are often presented for analysis following transportation in a less than ideal environment. This results in an analysis and measured surface composition that is not representative of the true surface of the original material. There are a limited number of methodologies available that can effectively clean the sample and restore the original surface without inducing some additional chemical changes and thereby changing the very surface that is being investigated. The development of Ar-gas cluster ion source has changed this.

Smart phone screen – depth analysis of alkali and alkali earth metals

In this study we apply the technique of depth profiling to analyse the concentration of elements in the near surface region of smart-phone display glass. We will look at the distribution of alkali and alkali earth metals - in particular K which is a key element in the glass toughening process. Two different depth profiling methods were used, monatomic Ar and Ar cluster, and a comparison is made regarding the ion bombardment effects of these two methods.  We emphasise the importance of ion choice when depth profiling inorganic materials in particular those containing light alkali metals.

Surface analysis of nuclear graphite

In this short study we will explore the differences in surface chemistry between two different graphites used in the nuclear industry. In recent times a wide variety of nanostructured carbon forms have been observed in nuclear graphite which vary the graphitic nature of the material. The nature of these forms can greatly affect the material’s ability to act as an effective moderator. Here we will discuss the elemental composition of the graphite surface and the extent of graphitic sp2 bonding.

Spatial characterisation of immobilised biomolecules on surfaces

Analysis of biomolecules on surfaces is essential to various applications of biosensors and biomolecule engineering. Matrix-assisted laser desorption/ionisation (MALDI) is now an established technique for mass spectrometry of biomolecules. Different matrix-analyte preparation protocols have been shown to influence the desorption or ablation process resulting in either high or low metastable fragmentation. It has been speculated that following laser ablation the velocities of the analyte and matrix can be regarded as a valuable and meaningful characteristic of the MALDI process. However, the interaction and distribution of the analyte with respect to the matrix is poorly understood. Here we study the distribution of a selection of biomolecules as a function of matrix material using high resolution imaging X-ray photoelectron spectroscopy (XPS).

XPS analysis of an ionic liquid

An AXIS spectrometer was used to probe the surface chemistry of a widely used ionic liquid. The elemental surface composition was analysed and information was gained regarding the various chemical environments of the surface elements. Traditional surface analysis techniques such as ARXPS were exploited to determine the orientation of the mobile molecules in the uppermost layer of the liquid. The stability of the liquids under X-ray irradiation was also investigated.

Quantified imaging of SiO2 particles

XPS imaging is an important tool for investigating the lateral distribution of surface chemistry on the micron scale.  Photoelectrons emitted from core electronic levels of surface atoms may be focused to form a two dimensional image on a suitable detector to allow the lateral distribution of the photoelectrons to be determined.  AXIS spectrometers have a pulse counting delay line detector (DLD) system which allows images to be quantified.  Spectra may be generated from every pixel in an image hence the chemical state of a sample surface may be quantitatively determined at high lateral and high energy resolution.  In this example silicon dioxide particles dispersed on the surface of a silicon wafer were analysed to demonstrate the flexibility of XPS imaging.

XPS of medical textiles

Evaluation of Anti-Adhesive Coatings on Medical Textiles by XPS

XPS is a well-established method for the chemical characterisation of material surfaces. Key developments in recent years, including imaging, have resulted in a wider range of applications.  Manufacturers and suppliers of both commercial and technical textiles are now exploiting XPS as an ideal tool to aid the development and optimisation of the types of surface coating/treatment demanded by industry and consumers.

Oxidation of Cobalt Hydroxide

Here we investigate the oxidation of Co(OH)2 using the catalysis cell. The catalysis cell allowed us to treat the sample under high temperature high pressure conditions similar to those found in industrial reactors. Careful analysis of the XPS spectra generated after each successive treatment shows that once calcined above 200 ºC the surface of the catalyst changes from hydroxide to oxide. Peak fitting the Co 2p region identified Co to be present as Co3O4.

Analysis of Ni/Co/Mn alloy using an automated monochromated Ag Lα X-ray source

Overlapping photoelectron lines and Auger features are a common problem in analysis of complex materials.  The standard approach of switching to an achromatic Mg X-ray source is sometimes undesirable due to the introduction of X-ray satellites into the spectrum.  In this example we show how Kratos’ automatic monochromatic Ag Lα X-ray source may be used to excite a satellite free spectrum and allow unambiguous determine the oxidation state of a Ni/Co/Mn alloy.