Researchers from the The Institute of Photonic Sciences (ICFO) in Barcelona in collaboration with computer vision firm, Qurv, have developed high-performance infrared photodetectors and a shortwave infrared (SWIR) image sensor operating at room temperature based on non-toxic colloidal quantum dots.
These non-toxic quantum dots pave the way towards CMOS shortwave infrared image sensors for consumer electronics.
The work, published in Nature Photonics, describes a new method for synthesising size tuneable, phosphine-free silver telluride (Ag2Te) quantum dots while preserving the advantageous properties of traditional heavy-metal counterparts paving the way to the introduction of SWIR colloidal quantum dot technology in high-volume markets.
SWIR-sensitive quantum dots often contain heavy metals
Colloidal quantum dots (CQD) based image sensor technology offers a promising technology platform to enable high-volume compatible image sensors in the SWIR. CQDs, nanometric semiconductor crystals, are a solution-processed material platform that can be integrated with CMOS and enables accessing the SWIR range.
However, a fundamental roadblock exists in translating SWIR-sensitive quantum dots into key enabling technology for mass-market applications, as they often contain heavy metals like lead or mercury (IV-VI Pb, Hg-chalcogenide semiconductors).
These materials are subject to regulations by the Restriction of Hazardous Substances (RoHS), a European directive that regulates their use in commercial consumer electronic applications.
A new process to synthesise phosphine-free versions of silver telluride quantum dots
While investigating how to make silver bismuth telluride (AgBiTe2) nanocrystals to extend the spectral coverage of the AsBiS2 technology and enhance the performance of photovoltaic devices, the researchers obtained silver telluride (Ag2Te) as a by-product. This material showed a strong and tuneable quantum confined absorption akin to quantum dots.
They realised its potential for SWIR photodetectors and image sensors and pivoted their efforts to achieve and control a new process to synthesise phosphine-free versions of silver telluride quantum dots, as phosphine was found to have a detrimental impact on the optoelectronic properties of the quantum dots relevant to photodetection.
In their new synthetic method, the team used different phosphine-free complexes such as a tellurium and silver precursors that led them to obtain quantum dots with a well-controlled size distribution and excitonic peaks over a very broad range of the spectrum.
After fabricating and characterising them, the new quantum dots exhibited remarkable performances, with distinct excitonic peaks over 1,500nm - an ‘unprecedented’ achievement compared to previous phosphine-based techniques for quantum dot fabrication, the researchers say.
Non-toxic SWIR photodiodes on par with other heavy-metal containing counterparts
The team decided to implement the obtained phosphine-free quantum dots to fabricate a simple laboratory scale photodetector on the common standard ITO-coated glass substrate to characterise the devices and measure its properties.
“Those lab-scale devices are operated with shining light from the bottom. For CMOS integrated CQD stacks, light comes from the top, whereas the bottom part of the device is taken by the CMOS electronics”, commented Yongjie Wang, postdoc researcher at ICFO and first author of the study. “So, the first challenge we had to overcome was reverting the device setup. A process that in theory sounds simple, but in reality proved to be a challenging task”.
Initially, the photodiode exhibited a low performance in sensing SWIR light, prompting a redesign that incorporated a buffer layer. This adjustment significantly enhanced the photodetector performance, resulting in a SWIR photodiode exhibiting a spectral range from 350nm to 1,600nm, a linear dynamic range exceeding 118dB, a -3dB bandwidth surpassing 110kHz and a room temperature detectivity of the order 1012 Jones.
"To the best of our knowledge, the photodiodes reported here have for the first time realised solution processed, non-toxic shortwave infrared photodiodes with figures of merit on par with other heavy-metal containing counterparts," said Gerasimos Konstantatos, ICREA Professor at ICFO and leading author of the study.
"These results further support the fact that Ag2Te quantum dots emerge as a promising RoHS-compliant material for low-cost, high-performance SWIR photodetectors applications".
Demonstrating the SWIR sensor's potential
With the successful development of this heavy-metal-free quantum dot based photodetector, the researchers went further and teamed up with Qurv, an ICFO spin-off, to demonstrate its potential by constructing a SWIR image sensor as a case study.
The team integrated the new photodiode with a CMOS based read-out integrated circuit (ROIC) focal plane array (FPA) demonstrating for the first time a proof-of-concept, non-toxic, room temperature-operating SWIR quantum dot based image sensor.
The authors of the study tested the imager to prove its operation in the SWIR by taking several pictures of a target object. In particular, they were able to image the transmission of silicon wafers under the SWIR light as well as to visualize the content of plastic bottles that were opaque in the visible light range.
“Accessing the SWIR with a low-cost technology for consumer electronics will unleash the potential of this spectral range with a huge range of applications including improved vision systems for automotive industry (cars) enabling vision and driving under adverse weather conditions”, said Konstantatos. “SWIR band around 1.35-1.40µm, can provide an eye-safe window, free of background light under day/night condition, thus further enabling lidar, three-dimensional imaging for automotive, augmented reality and virtual reality applications”.
Now the researchers want to increase the performance of photodiodes by engineering the stack of layers that comprise the photodetector device. They also want to explore new surface chemistries for the Ag2Te quantum dots to improve the performance and the thermal and environmental stability of the material on its way to the market.