The physical laws of diffraction generally limit the spatial resolution of optical systems, being about 250 nm for light in the visible range. That is the reason why we usually cannot directly observe virus, single proteins, or molecules with conventional optical microscopes. Attempts to overcome this limit have led to “super-resolution” techniques, like STED, STORM, PALM, NSOM, etc., all of them based on bulky and expensive optical systems and complex sample preparations.
The approach to optical microscopy of ChipScope is different from existing solutions. In ChipScope, we build a lens-free optical microscope in which we use a set of light sources so small that are well below the diffraction limit. The intensity of light transmitted through the sample is then captured by a camera as each LED is lit, to build up a shadow of the sample pixel by pixel, where each LED denotes a pixel. Although the collected light is diffraction-limited, its origin is the lit LED, and that position is known. As a result, the LED size, not the diffraction limit, determines the resolution. In ChipScope, we have developed arrays of semiconductor nanoLEDs with a pixel-to-pixel spacing of less than the diffraction limit that can be turned on independently. This will be a leap forward in extreme miniaturization. Chipscope technology will make optical microscopes chip-sized, simple, affordable and ubiquitously available, not only for laboratories working in manifold research fields but also in everyday life.
The first challenge of ChipScope was downscaling the size of existing technology on GaN LEDs by a factor of ~100 in order to address the problem of sub-diffraction resolution. The second challenge was operating these nanoLED arrays in full synchronization with a CMOS light sensor. Finally, the third challenge dealed with the advanced theoretical studies regarding the fundamental physics of light-matter interaction at such a small scale that will serve us to better understand the further potential and limitations of the ChipScope approach.
Within the project, the first chip-sized ‘Chip-Scopes’ were developed, tested, calibrated, and compared with state-of-the-art microscopy systems.