The proposed innovation is to apply proven nano-film technology to enable Microchannel plate (MCP) devices to be manufactured on a range of insulating substrates and devices which possess sufficiently high gain and low ion feedback to replace chevron stacks in current NASA detector technologies. … More

The work proposed in this SBIR proposal is intended to follow the basic R&D effort of a consortium of national laboratories, universities, and industry, led by Argonne National Laboratory and the University of Chicago for the development of new, large area, photo-detector devices. This project… More

This Small Business Innovation Research Phase I project proposes a revolutionary approach to extending the lifetime of microchannel plate (MCP) photomultiplier tubes (PMTs) using atomic layer deposited (ALD) nanofilms to suppress the creation of damaging positive ions. The technical and intellectual… More

Atomic layer deposited functional nano-film technology is used to manufacture Microchannel plate (MCP) devices capable of high gain / low ion feedback operation, on glass capillary array substrates, as a means to replace MCP chevron configuration and enable direct photocathode deposition (e.g. GaN)… More

The work proposed in this SBIR proposal is is synergistic with the, DOE funded, basic R & amp;D effort of a consortium of national laboratories, universities, and industry, led by Argonne National Laboratory and the University of Chicago for the development of new, large area, photodetector… More

Microchannel Plate event multipliers capable of operation at cryogenic temperatures are currently not commercially available from any supplier. The proposed development of cryogenic-compatible MCPs will enable photon/electron/ion/alpha detection with high spatial resolution and sub-nanosecond event… More