NanoSIMS - high resolution imaging mass-spectrometry : Centre for Microscopy, Characterisation and Analysis : The University of Western Australia

Nano scale Secondary Ion Mass Spectrometry is a high resolution isotope and elemental imaging technique for solid sample surfaces.

Mass range – ¹H to ²³⁸U
Sensitivity – PPB depending on ion and matrix
Resolution – as low as ~40nm
High mass resolution

What can nanoSIMS do?

NanaoSIMS analysis can be used to observe natural or altered surface chemistry elements (specific isotopes) at low concentrations and at high resolution. Below are links to recent applications of nanoSIMS analysis in various disciples;

Medical
Environmental
Geological
Materials

Why Us?

Our fundamental aim is to make nanoSIMS analysis available for any relevant academic or commercial interest and generate high quality data that best answers the ‘questions’ they come with. Our many years of experience working on projects from diverse fields of science enables us to maximize the potential of cutting edge nanoSIMS analysis for your project.

We want your project to succeed meaning we insist on understating your project needs in detail before we begin analysis. We will assist at every stage from experimental design to sample preparation to data analysis and interpretation.

Our Services

Our experienced team have assisted many research projects from inception through to output – be that scientific publication or a detailed commercial report. Every project is unique in some way and will pose a different set of challenges (see below).

Sample preparation

Correct preparation of samples is the single most important part of successful and meaningful nanoSIMS analysis. This includes how the samples are physically prepared and also the need for suitable controls. Samples need to be flat, conductive, dry and able to withstand high vacuum. How this is achieved will depend upon the sample of interest and will differ between projects, i.e., a meteorite samples will differ substantially to a cell line labeled with an isotopically enriched tracer. We suggest contacting us for advice or consulting publications focused on analogous sample types.

Data analysis and interpretation

We constantly monitor data during analysis so as to provide consistent high quality results. Once happy with the ‘raw’ data, we will guide users through data analysis processes to generate the output they desire. Generating, processing and displaying data differs for every project, so it is our goal to provide the tools appropriate to best achieve desired outcomes. For ease of use, we recommend using the OpenMIMS plugin associated with Image J software for initial data extraction and analysis (see Useful links).

Our Instruments

The University of western Australia house the only nanoSIMS instruments in Australia. The two Cameca built instruments are fundamentally the same, except the newer 50L model has some useful upgrades and increased capability.

Cameca NanoSIMS 50

Cs+ sources to <50nm resolution – only detects negative ion species
Multicollection: one Faraday cup, five electron multipliers
Electron gun for charge compensation
Secondary electron detector

Cameca NanoSIMS 50L

Cs+ and O- ion sources to <50nm resolution (O- source is latest generation RF plasma source)
Multicollection: seven Faraday cups, seven electron multipliers
Improved mass separation
Electron gun for charge compensation
Secondary electron detector
Nuclear magnetic resonance (NMR) magnet control

FAQ

How much does analysis cost?

Researchers from academic institutions (UWA, other Australian universities and international universities) all pay $800 per day. Minimum usage is 1 day, but we find most projects tend to occur over week long blocks. We also charge a one time admin fee ($250 for UWA, $500 others). Commercial projects have a different pricing schedule available on request.

How long will analysis take?

This is dependent upon sample numbers, replication, sample size, ion concentrations, matrix effects, standard requirements etc. We will apply our experience to guide users as best as possible given their requirements.

What is the wait time until analysis?

Wait time is usually a few weeks to a few months from receipt of samples. This will depend on instrument demand, project size, instrument maintenance/downtime.

How do I prepare my samples?

Depends on sample type and research aims. The main characteristics of nanoSIMS ready samples are that they have a flat surface, are conductive (can be metal coated) and able to withstand high vacuum (dry). We have a range of sample holders designed to accommodate thin silicon wafers (Ideal for mounting resin embedded sections), polished resin discs (10, 12, 15mm diameter), TEM grids or square microscope slides.

Can I be present during analysis?

Yes. Because of the complexity involved in nanoSIMS operation, all analyses are performed by inhouse staff. We are more than happy to have you present as this often makes it easier for selecting specific analysis areas or tweaking experimental plans as we go. Alternately, if you are unable to accompany your samples, they can be sent to us and we will analyse after consultation with you. Another option is to come for the start of analysis and leave when you are satisfied everything is proceeding well. The choice is yours!

Where do I start?

Define a robust aim or hypothesis for your research.
Consult the literature for analogous analyses and try to understand the science and potential of nanoSIMS.
Determine if nanoSIMS is the correct method for your research.
Contact us with your ideas (at any stage)—we have lots of experience and are here to help.

Is nanoSIMS analysis right for my research?

Ultimately, it comes down to a question of resolution required and concentration of the ion(s) of interest. The schematic below is a simple comparison of analogous methods and shows why nanoSIMS may be a more/less appropriate technique than others. NanoSIMS is a particularly powerful method for analyzing and imaging micro scale heterogeneity of different ions. We are happy to discuss whether (or not) nanoSIMS is right for your research.