Nanoscale Three-Dimensional Imaging of Integrated Circuits Using a Scanning Electron Microscope and Transition-Edge Sensor Spectrometer.
Nathan NakamuraPaul SzyprytAmber L DagelBradley K AlpertDouglas A BennettWilliam Bertrand DorieseMalcolm DurkinJoseph W FowlerDylan T FoxJohnathon D GardRyan N GoodnerJames Zachariah HarrisGene C HiltonEdward S JimenezBurke L KernenKurt W LarsonZachary H LevineDaniel McArthurKelsey M MorganGalen C O'NeilNathan J OrtizChristine G PappasCarl D ReintsemaDaniel R SchmidtPeter A SchultzKyle R ThompsonJoel N UllomLeila ValeCourtenay T VaughanChristopher WalkerJoel C WeberJason W WheelerDaniel S SwetzPublished in: Sensors (Basel, Switzerland) (2024)
X-ray nanotomography is a powerful tool for the characterization of nanoscale materials and structures, but it is difficult to implement due to the competing requirements of X-ray flux and spot size. Due to this constraint, state-of-the-art nanotomography is predominantly performed at large synchrotron facilities. We present a laboratory-scale nanotomography instrument that achieves nanoscale spatial resolution while addressing the limitations of conventional tomography tools. The instrument combines the electron beam of a scanning electron microscope (SEM) with the precise, broadband X-ray detection of a superconducting transition-edge sensor (TES) microcalorimeter. The electron beam generates a highly focused X-ray spot on a metal target held micrometers away from the sample of interest, while the TES spectrometer isolates target photons with a high signal-to-noise ratio. This combination of a focused X-ray spot, energy-resolved X-ray detection, and unique system geometry enables nanoscale, element-specific X-ray imaging in a compact footprint. The proof of concept for this approach to X-ray nanotomography is demonstrated by imaging 160 nm features in three dimensions in six layers of a Cu-SiO 2 integrated circuit, and a path toward finer resolution and enhanced imaging capabilities is discussed.