SBIR-STTR Award

One of the most important challenges of terahertz time-domain spectroscopy THz-TDS) systems is the low sensitivity and narrow bandwidth of photoconductive terahertz detectors used in these systems. The performance limitations of photoconductive terahertz detectors are mainly due to the inherent tradeoff between high quantum efficiency and ultrafast operation of photoconductors. This tradeoff restricts the number of photogenerated carriers that drift to the contact electrodes in a sub-picosecond time scale; thus, strength of the induced ultrafast photocurrent that is directly proportional to the incident terahertz field on the detector. Light concentrators, such as metasurfaces and plasmonic structures, can mitigate this tradeoff and offer high quantum efficiency and ultrafast operation simultaneously. Lookin, Inc. proposes to develop a novel photoconductive terahertz detector based on plasmonic nanocavities, where light can be trapped in a thin, high-mobility photoconductor that is right below the photoconductor contact electrodes. The plasmonic nanocavity structure is designed to maximize the photogenerated carrier concentration at locations where the induced electric field by the incident terahertz radiation is maximum. Therefore, a significant increase in optical photon-to-collected electron efficiency can be observed, which allows the detector to offer high-performance even at very low optical power levels. The design can be also optimized to offer a broad detection bandwidth and high switching contrast. Our preliminary theoretical and experimental studies predict that the proposed detector can offer more than 109 dB SNR with a data acquisition time of 1s over a 0.1-5.5 THz frequency range, a 3-dB bandwidth of >1 THz, and a switching contrast of more than 107 at a 0.1 mW optical power level. One of the major advantages of the proposed detector is that it consists of terahertz nanoantenna arrays with a scalable active area and, thus, ideally suited for use in a terahertz focal plane array THz-FPA). Our company plans to use the high-performance photoconductive detectors developed during this Phase I project to realize a THz-FPA consisting of more than 1 kpixels for use in THz-TDS systems. During Phase I, Lookin, Inc. will conduct extensive theoretical and experimental studies on the electrical and optical characteristics of plasmonic nanocavities to identify optimized semiconductor superlattice and geometric parameters that enable high-performance photoconductive terahertz detection in THz-TDS systems. After the successful demonstration of the optimized terahertz detector prototypes, the company will build proof-of-concept 3×3 THz-FPAs and explore various data readout approaches to record the FPA output data with a high data acquisition rate, while minimizing the electrical, optical, and packaging complexity of the system through a cost effective solution. The proposed terahertz detector and FPA based on plasmonic nanocavities will have a transformative impact on terahertz science and technology. Although THz-TDS systems offer many unique functionalities for various chemical identification, material characterization, and biomedical imaging applications, their practical utilization for solving real-world problems has been extremely limited because of the lack of high-performance, multi-pixel detectors that can offer both high data quality and fast data acquisition over a broad frequency range. The proposed terahertz detector addresses all of these problems and enables THz-TDS systems to fulfil their true potential to solve many real-world problems of the society.

Performance of existing terahertz time-domain spectroscopy (THz-TDS) systems is still limited by the low sensitivity of photoconductive switches used as terahertz detectors. The sensitivity of conventional photoconductive terahertz detectors is limited due to the trade-off between ultrafast operation and quantum efficiency, which restricts the number of photogenerated carriers that can efficiently contribute to terahertz detection. Another problem of conventional photoconductive terahertz detectors is the necessity of an extremely precise optical alignment. This tight optical alignment requirement also prevents researchers from realizing terahertz detector arrays since it is very challenging to align the optical beam on multiple detectors simultaneously. As a result, conventional THz-TDS systems use single-pixel detectors and raster scanning to capture the image/spectrum of an object, which requires significantly long measurement times. To address all of the limitations of conventional photoconductive terahertz detectors, Lookin, Inc. proposes to develop terahertz focal plane arrays (THz-FPAs) that offer large field-of-view and high-sensitivity operation. The company plans to build two different THz-FPAs; (1) a one-dimensional THz-FPA consisting of 1024 pixels for line scanning, (2) a 256×256 THz-FPA for two-dimensional scanning. To realize these products and demonstrate their capabilities, Lookin, Inc. will adapt new nanofabrication techniques, design read-out circuits/boards, and take terahertz images of various objects with the fabricated THz-FPA prototypes at high scan speeds. Lookin, Inc. will also develop a software that can process the output of the FPA pixels in real time to generate terahertz images and videos. The building block of the proposed THz-FPAs will be the high-performance photoconductive terahertz detector, which was developed by Lookin during the Phase I SBIR program. The detector uses an array of photoconductive nanoantennas integrated with a plasmonic nanocavity, which is specifically designed to increase the optical absorption around the nanoantennas. This approach enabled boosting the efficiency of photoconductive terahertz detectors by three orders of magnitude. As a result, high-SNR THz-TDS operation was achieved even at very low optical pump power levels. In addition, by using nanoantenna arrays and distributing them over a large area, Lookin’s detector requires a much less demanding optical alignment compared to conventional photoconductive detectors. The area of this novel detector based on nanoantenna arrays can be easily scalable to build multi-pixel terahertz detector arrays. Broadband THz-FPAs with high sensitivity and high efficiency would revolutionize the terahertz technology market by addressing the most crucial needs of practical THz-TDS systems. They not only improve the performance of THz-TDS systems in their current applications, but they also enable new applications. Such THz-FPAs would transform THz-TDS systems from a metrology tool with a slow scan speed and limited field-of-view to a high-throughput instrument that can be used in industrial settings for various quality control applications.