UltraXRM-L200
Ultra-high Resolution, Non-destructive 3D Imaging
The revolutionary UltraXRM-L200 combines a high-flux laboratory X-ray source with proprietary X-ray optics into a lab based ultra-high resolution CT scanner. The non-destructive imaging with X-rays provides detailed 3D images of internal structures without the need for cutting or sectioning. With a resolution as fine as 50 nm, the UltraXRM-L200 provides insight into microscopic structures and processes previously not accessible with conventional X-ray technology. Operating with 8 keV X-rays, the UltraXRM-L200 enables observation of structures and materials in their natural state. Xradia's integrated phase contrast technology employing the Zernike method enhances the visibility of grain boundaries and material interfaces when absorption contrast is low.
Benefits
- Non-destructive 3D X-ray imaging allows repeated imaging of the same sample under different conditions
- Large working distance and atmospheric sample environment allows in-situ studies
- Automated image alignment for tomographic reconstruction
- Switchable field-of-view ranging from 15 to 60 µm
- Absorption and Zernike phase contrast imaging modes
Applications
Life Science Research
The UltraXRM-L200 offers the ability to visualize the internal structure of biological specimens, such as bone, soft tissue, and biomedical devices with resolution down to 50 nm.
Semiconductor Package Failure Analysis
The UltraXRM-L200 offers visualization of semiconductor samples and wafer-level packaging, such as integrated circuits and through-silicon vias, for defect investigation and failure analysis without the need for physical cross-sectioning.
Advanced Material Development
Characterization capabilities for 3D structures of composite materials, such as paper, foams, and fuel cells. Material of different densities may be segmented through the use of absorption-contrast imaging.
Oil & Gas Drilling Feasibility Studies
Pore and flow modeling on the nano scale; complementary to imaging with the VersaXRM, extending the imaging resolution below 1µm.