TRANSFORMATIVE TECH: SHORTWAVE INFRARED


Quantum dots to spark new SWIR wave


Imec’s Paweł Malinowski on the breakthroughs happening in SWIR imaging


A


cquiring information in the shortwave infrared (SWIR) wavelength range has been for decades limited to


niche applications. SWIR is used in the military, to identify targets in adverse lighting conditions, for instance; in machine vision, such as in solar cell inspection; and in scientific and space systems. Tese are typically high-end applications with a cumulative annual number of units sold in the tens of thousands globally. SWIR cameras are traditionally based on


focal plane arrays, with a resolution rarely exceeding 1 megapixel, and a pixel size an order of magnitude larger than what’s found in CMOS image sensors (CIS) used in consumer devices – a typical pitch in a SWIR detector is 15-20µm versus sub- micron pixels for CIS. Imagers are made by hybrid bonding detector chips based on III-V materials – usually InGaAs, sometimes HgCdTe – to the readout chip using solder bump connections and die-to-die flip- chip techniques. All those elements in the fabrication process result in a very high price point for these sensors, easily exceeding several thousand euros per chip. A recent innovation reported by Sony in 2019 uses Cu-Cu bonding of an InGaAs detector chip, which resulted in scaling down the pixel pitch to 5µm. Te IMX990 and IMX991 chips are finding their way into more and more products, especially in machine vision, as they enable not only higher image quality, but also easier integration. Even with a premium price point, this sensor family opens up SWIR imaging to new use cases. A technology that promises to lower the


implementation barrier even further are SWIR sensors based on thin films, with quantum dots playing the lead role as a new


www.imveurope.com | @imveurope


type of absorber. Te technology has been investigated for almost two decades; the first academic papers were published at the beginning of the 21st century by Professor Sargent’s group at the University of Toronto, with pioneering work since then. Now, the first products are being brought


to market. Emberion announced its VS20 camera with a broad spectral range, from 400 to 2,000nm. Meanwhile, SWIR Vision Systems offers its Acuros series of cameras, with the highest SWIR resolution on the market (1,920 x 1,080 pixels). Tese are


‘ST’s announcement… should reassure the industry that quantum dot image sensors are a credible technology’


disruptive products in the infrared imaging field and prove the maturity of quantum dot technology is sufficient to deploy commercial products. In parallel, research centres such as Imec


continue to explore the QD pixel stacks, readout architectures, and the integration process to improve performance and enable upscaled fabrication. At the same time, new application fields are opening up for end users that didn’t consider SWIR imaging before because it was simply beyond their reach, in terms of cost but also size and complexity. In 2019, Imec presented a 5µm pixel pitch


QD SWIR image sensor, and in 2020 topped that with a 1.82µm proof-of-concept device – both state-of-the-art pixel density for SWIR image sensors at the time of introduction.


At the 67th International Electron Devices


Meeting (IEDM) at the end of 2021, the tone-setting event for the semiconductor industry, STMicroelectronics announced QD image sensors. Te 1.62µm pixel pitch sets a new record, and the external quantum efficiency of 60 per cent at 1,400nm inches ever closer to the values found in the incumbent technologies. Te most exciting feature is that these


results come from chips fabricated using a 300mm wafer platform – this means that the QD technology has made significant strides in making it ready to manufacture. Upscaling to a wafer-level process promises extraordinary throughput and thus cost evolution. New sensor products based on this process will disrupt the market further, and act as a critical enabler for SWIR imaging in applications that never considered it before, including consumer products. Imaging in the SWIR range offers features


such as improved eye safety for devices using laser light like lidar – eye sensitivity to radiation at wavelengths above 1,400nm compared to 940nm is around six orders of magnitude lower – as well as for low-light imaging and cameras that can see through adverse weather conditions. Looking forward, there are still


technological challenges to address. Moving away from lead sulphide-based QDs to lead-free material systems will encourage more players to accept this type of sensor. Improving deposition throughput of the quantum dot layers by going to one-step coating – instead of the standard layer- by-layer coating used currently to achieve the desired final thickness of the absorber – will significantly increase the takt time in volume production. Moreover, thorough investigation of


reliability metrics according to industry standards will set further iterations of QD improvement to optimise long-term stability, and enable even the most harsh applications such as those demanded by the automotive sector. STMicroelectronics’ announcement in


this space should reassure the industry that quantum dot image sensors are a credible technology with excellent potential that can be upscaled to manufacturing in semiconductor foundries. Tis should fuel further investment in research of these fascinating devices, and spark a new wave of applications for more accessible SWIR camera systems. O


Paweł Malinowski is program manager at Belgian R&D institute, Imec. He has more than 10 years’ experience in developing photonics technologies, and is currently working in the thin-film electronics group of Imec.


IMAGING AND MACHINE VISION EUROPE VISION YEARBOOK 2022/23 33


Page 1  |  Page 2  |  Page 3  |  Page 4  |  Page 5  |  Page 6  |  Page 7  |  Page 8  |  Page 9  |  Page 10  |  Page 11  |  Page 12  |  Page 13  |  Page 14  |  Page 15  |  Page 16  |  Page 17  |  Page 18  |  Page 19  |  Page 20  |  Page 21  |  Page 22  |  Page 23  |  Page 24  |  Page 25  |  Page 26  |  Page 27  |  Page 28  |  Page 29  |  Page 30  |  Page 31  |  Page 32  |  Page 33  |  Page 34  |  Page 35  |  Page 36  |  Page 37  |  Page 38  |  Page 39  |  Page 40  |  Page 41  |  Page 42  |  Page 43  |  Page 44