1. Introduction
Photonic sensors based on mid-infrared absorption spectroscopy are promising for chemical sensing due to the high selectivity achieved by probing molecular-specific vibrational absorption features. For field-analysis and portable-electronics applications, one major requirement is the capability to develop miniaturized, fully integrated photonic sensors with a high sensitivity and a small footprint. There are, however, still several challenges for highly integrated photonic sensors including the lack of cheap and powerful narrowband sources in the mid-infrared (quantum-cascade lasers are currently costly and make use exotic materials difficult to integrate into silicon photonics), and the poor sensitivity of typically uncooled detectors needed for low-power applications.
Here we focus on the spectral region around 4.2 µm relevant for CO2 detection. In our previous work we showed the feasibility of CO
2 detection via evanescent-field absorption in slab and strip silicon waveguides, both using an external quantum-cascade laser or an integrated broadband thermal light source [
1,
2,
3]. While our earlier work relied on an external MCT detector detecting gas-induced changes in light intensities, this work focuses on the development of integrated thermal detectors for mid-infrared radiation operating at room temperature. Different concepts of miniaturized mid-infrared detectors have already been proposed [
4,
5,
6,
7]. While high sensitivity can be achieved, such detectors are based on heavy-metal semiconductors such as PbTe or Ge
3Sb
2Te
6, and are thus rather complex to fabricate. In this work, we focus on detectors fabricated using standard MEMS processes, which are therefore easy to produce and integrate in existing fabrication technologies on a high throughput format. Three detector concepts are benchmarked against each other, namely: a resistance-temperature detector (RTD), a planar p-n diode, and a vertical-cavity enhanced resonant detector (VERD) based on the design of a vertical-cavity resonant thermal emitter [
8,
9].
2. Materials and Methods
Figure 1 shows microscope pictures of the three fabricated detectors. The RTD (
Figure 1a) is a wire of n-type amorphous silicon (n-Si). The diode (
Figure 1b) consists of a similar structure as the RTD with a p-n junction located in the middle of the wire. Both structures were fabricated in front of a slab waveguide at a distance of 1 µm from the waveguide. The solid substrate under the detector structure was removed and the structures lie on a 140 nm thick silicon-nitride membrane. Both RTD and diode are broadband thermal detectors. Thermal absorption is read-out resistively for the RTD or by changes in current at a constant bias voltage (1 V) for the diode.
The VERD consists of alternated Si/SiO
2 layers with a structured metallization layer on top (
Figure 1c,d). The fabrication and optimization details are provided elsewhere [
9]. Briefly, the structure function is analogous to that of a Fabry-Perot resonator, with a SiO
2 cavity, whose thickness determines the central operating frequency, and a thin layer stack of Si and SiO
2 beneath it, forming a distributed Bragg reflector. Being highly reflective and slightly absorptive, the metal layer (
Figure 1d) functions simultaneously as the second mirror of the Fabry-Perot resonator and as a detector. In contrast to the RTD and the diode, the VERD structure works as a narrowband detector whose central frequency and bandwidth are determined by the cavity thickness and the distributed Bragg reflector (i.e., design parameter). The VERD is thermally decoupled from the substrate via a backside etch and the change in temperature of the metal layer due to absorption of the mid-infrared radiation is read out resistively.
For each structure the temperature coefficient in the linear regime until 100 °C was determined and was 3.84 Ω/K for the RTD and 0.077 Ω/K for the VERD. Different U-I curves were recorded for the diode and the temperature coefficient for 1 V bias was extracted and found to be 1.51 A/K.
The responsivity and the sensitivity of the three devices were quantified by a continuous wave external-cavity quantum-cascade laser (QCL), tuned to a central wavelength of 4.17 µm. For the RTD and the diode the laser light was coupled to a 500 µm-long slab-waveguide using a fiber and a grating etched on the top surface of the slab (
Figure 2a). The detector response was monitored as a function of the laser power and time. For the VERD structure, which is not yet integrated with the waveguide, the laser light is out coupled from the fiber, collimated and refocused onto the sensor surface through the Si/SiO
2 layer stack (
Figure 2b).
3. Results and Discussion
Figure 3 shows the recorded temperature profile for each structure as a function of incident power and time. To evaluate the responsivity of each detector, which is reported in
Figure 3, the change in signal is plotted as a function of the laser power and a linear fit is used to determine the slope. The noise-equivalent power (NEP) is obtained by measuring the noise level at 1 Hz bandwidth for our detection scheme with a sourcemeter (Keithley SMU 2450). Power levels for the VERD are higher since the light is irradiated by free-space rather than through a (slightly) absorptive waveguide [
10]. Using an integrated detection scheme the NEP is expected to further improve for all detectors.
The diode shows the highest light-induced temperature jump but also the highest noise, which might be partly due to the small measured current. Operation at higher voltages, however, is not recommended as it shows a reverse temperature-current dependence and significant non-linear response. Consequently, both resistive detectors outperform the diode due to the much lower NEP.
While the RTD shows very slow response times, with thermalization times exceeding 20 s, both diode and VERD react to the laser light on a sub-100 ms time scale and have faster recovery times. Additional preliminary measurements reveal that only a fraction of the measured RTD response (decreasing from about 75% to about 55% with increasing laser power) arises from direct light absorption, while the remaining signal arises from a slower temperature change of the membrane. Therefore, the diode and VERD are better detector candidates for field applications, where a quick response to light changes and short acquisition times are required. Additionally, different from the RTD, these structures can be employed to detect modulated signals, making the final device less prone to thermal drifts and other low-frequency noise sources.
4. Conclusions
In this work we present a quantitative comparison between three integrated detector structures for mid-infrared photonic applications. In contrast to other detector structures our designs are solely based on standard MEMS processes. Our results show that the VERD is the most promising detector structure, since it combines a quick response time with a low detection limit and has, additionally, an integrated wavelength-filter function.
Author Contributions
All authors contributed equally to the contents of this paper. C.C. wrote the paper.
Acknowledgments
This work was performed within the Competence Centre ‘ASSIC Austrian Smart Systems Integration Research Center’ and ‘LCMLinz Centre of Mechatronics’, co-funded by the Federal Ministries of Transport, Innovation and Technology (BMVIT) and Digital and Economic Affairs (BMDW) and the Federal Provinces of Carinthia, Styria and Upper Austria within the COMET—Competence Centers for Excellent Technologies Programme.
Conflicts of Interest
The authors declare no conflict of interest. The founding sponsors had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript, and in the decision to publish the results.
References
- Ranacher, C.; Consani, C.; Hedenig, U.; Grille, T.; Lavchiev, V.; Jakoby, B. A photonic silicon waveguide gas sensor using evanescent-wave absorption. In Proceedings of the 2016 IEEE SENSORS, Orlando, FL, USA, 30 October–2 November 2016; pp. 1–3. [Google Scholar] [CrossRef]
- Ranacher, C.; Consani, C.; Tortschanoff, A.; Jannesari, R.; Bergmeister, M.; Grille, T.; Jakoby, B. Mid-infrared absorption gas sensing using a silicon strip waveguide. Sens. Actuators A 2018, 277, 117–123. [Google Scholar] [CrossRef]
- Consani, C.; Ranacher, C.; Tortschanoff, A.; Grille, T.; Irsigler, P.; Jakoby, B. Mid-infrared photonic gas sensing using a silicon waveguide and an integrated emitter. Sens. Actuators B 2018, 274, 60–65. [Google Scholar] [CrossRef]
- Quack, N.; Blunier, S.; Dual, J.; Felder, F.; Arnold, M.; Zogg, H. Mid-Infrared Tunable Resonant Cavity Enhanced Detectors. Sensors 2008, 8, 5466–5478. [Google Scholar] [CrossRef] [PubMed]
- Wang, J.; Hu, J.; Becla, P.; Agarwal, A.M.; Kimerling, L.C. Resonant-cavity-enhanced mid-infrared photodetector on a silicon platform. Opt. Express 2010, 18, 12890. [Google Scholar] [CrossRef] [PubMed]
- Lin, P.T.; Singh, V.; Wang, J.; Lin, H.; Hu, J.; Richardson, K.; Musgraves, J.D.; Luzinov, I.; Hensley, J.; Kimerling, L.C.; et al. Si-CMOS compatible materials and devices for mid-IR microphotonics. Opt. Mater. Express 2013, 3, 1474–1487. [Google Scholar] [CrossRef]
- Tittl, A.; Michel, A.-K.U.; Schäferling, M.; Yin, X.; Gholipour, B.; Cui, L.; Wuttig, M.; Taubner, T.; Neubrach, F.; Giessen, H. A Switchable Mid-Infrared Plasmonic Perfect Absorber with Multispectral Thermal Imaging Capability. Adv. Mater. 2015, 27, 4597–4603. [Google Scholar] [CrossRef] [PubMed]
- Celanovic, I.; Perreault, D.; Kassakian, J. Resonant-Cavity Enhanced Thermal Emission. Phys. Rev. B 2005, 72, 075127. [Google Scholar] [CrossRef]
- Söllradl, T.; Ranacher, C.; Consani, C.; Pühringer, G.; Lodha, S.; Jakoby, B.; Grille, T. Characterisation of a resonant-cavity enhanced thermal emitter for the mid-infrared. In Proceedings of the 2017 IEEE Sensors, Glasgow, UK, 29 October–1 November 2017. [Google Scholar] [CrossRef]
- Ranacher, C.; Consani, C.; Vollert, N.; Tortschanoff, A.; Bergmeister, M.; Grille, T.; Jakoby, B. Characterization of Evanescent Field Gas Sensor Structures Based on Silicon Photonics. IEEE Photonics J. 2018, 10, 2700614. [Google Scholar] [CrossRef]
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