亞洲知識產權資訊網為知識產權業界提供一個一站式網上交易平台，協助業界發掘知識產權貿易商機，並與環球知識產權業界建立聯繫。無論你是知識產權擁有者正在出售您的知識產權，或是製造商需要購買技術以提高操作效能，又或是知識產權配套服務供應商，你將會從本網站發掘到有用的知識產權貿易資訊。

返回搜索結果

Uncooled Multifunction Wideband Sensors

技術優勢: Operates at room temperature: 25┬░C Broadband detection: THz, SWIR, MWIR, LWIR High detectivity and sensitivity Multifunction: Detects polarization, static magnetic fields, gas, pressure Optical readout Photon-trapping vertical structures can replace anti-reflection coating

技術應用: Biomedical imaging Military applications Nondestructive testing Manufacturing: process control

詳細技術說明: The 3D sensor structure is fabricated by the use of laser-assisted deposition (LAD) and laser-assisted dopant incorporation (LADI). The laser processing creates an array of conical, pyramidal, or other 3D shapes to enhance surface area and responsivity. The sensor detects a range of wavelengths as specified by means of user-customizable magnetic doping in ring-like sections along the vertical axis of the structure. An array of structures with various dopant materials and concentrations can operate over a wide range of wavelengths and comprise a focal plane array.

*Abstract: UCF researchers have developed a photodetector able to operate at room temperature and measure spectral ranges including microwave, THz, SWIR, MWIR, and LWIR while maintaining image detail. Current commercial photodetectors are limited by the sensorΓÇÖs spectral responsivity, requiring multiple sensors or unique configurations to image and sense a wide spectral range. A new nanostructured sensor design fundamentally improves responsivity while providing a simpler and more cost-effective approach than existing products.Formed on the surface of a silicon wafer by laser processing, 3D nanostructures enhance collection efficiency while enabling multi-wavelength absorption via varyingly doped band sections, each contributing to the total spectrum detectable by the sensor. This high detectivity is coupled with high sensitivity, represented by the sensorΓÇÖs low noise equivalent temperature difference (NETD), providing high signal-to-noise data for uses including: military applications, nondestructive testing, process control in manufacturing, and biomedical imaging.

*Principal Investigation: Name: Aravinda Kar, Ph.D.
Department:

Name: Tariq Manzur, Ph.D
Department:

Name: John Zeller, Ph.D.
Department:

欲了解更多信息，請點擊這裡