The NanoSIMS (Seconday Ion Mass Spectrometer) creates nanoscale maps of elemental composition, combining the high mass resolution, isotopic identification, and subparts-per-million sensitivity of conventional SIMS with spatial resolution down to 50 nm and the identification of up to seven masses in parallel from the same small volume. In energy research, NanoSIMS can characterize the nanostructured materials with complex composition that are increasingly important candidates for energy generation and storage. Stanford's NanoSIMS is one of only 22 NanoSIMS in the world and one of only a very few of the most current versions of this instrument. Only a handful of NanoSIMSs worldwide can be accessed through collaboration with the owners, as Stanford's can. More detail: Secondary ion mass spectrometry (SIMS) is a technique used to analyze the composition of solid surfaces and thin films by sputtering the surface of the specimen with a focused primary ion beam and collecting and analyzing ejected secondary ions. These secondary ions are measured with a mass spectrometer to determine the elemental, isotopic, or molecular composition of the surface. SIMS is a very sensitive surface analysis technique, being able to detect elements present in the parts per billion range. The CAMECA NanoSIMS has a uniquely designed column (a "lens" for ions) that can focus the primary ion beam down to a 50nm spot to provide high lateral resolution analysis. The NanoSIMS also employs a multi-collection detection system to allow for detection of seven different masses simultaneously.
Contact InformationChuck Hitzman
Cognizant Faculty Advisor
Prof. Steven G. Boxer
NanoSIMS imaging of membrane phases: NanoSIMS images of a freeze-dried supported lipid bilayer formed by the fusion of a giant unilamellar vesicle composed of 13C-Cholesterol, 2H-Sphingomyelin, 19F‐Ganglioside GM1, and 15N-DOPC to an SiO2/Si substrate highlighJng each component by isotopic or fluorine label. Color bars repres
Nitrogen utilization by individual phytoplankton in mixed assemblages. NanoSIMS images of individual cells Nitszchia sp. Shown is the total ion counts (SIMS), ion counts for 12C14N, and the 15N/14N ratio of each cell. Image courtesy of Matt Mills (Arriga Group, Stanford).
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