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I.INTRODUCTIONGrowing interest for space missions requiring IR detection is consistent with the constant improvement of IR detectors technologies. Earth observation missions requiring IR imaging capabilities have now reached an excellent level of maturity. IR detectors future developments are more driven by spectroscopic capabilities. The main detector performance drivers for future Earth Observing missions are: linearity at low flux, low noise, medium to high frequency readout, moderate power consumption,… CNES (Centre National d’Etudes Spatiales) is continuously pushing the developments to increase the maturity level of the technologies and enhance the key performances in the field of IR detections for space missions. A.IR detectors main architectureThe Fig.1 below displays a schematic of the main functions of infrared quantum detector. Classical architecture requires a detection circuit with a suitable semiconductor material for IR detection and a readout circuit, assembled together to form a hybrid detector. The detection circuit provides infrared radiation absorption, charge generation and collection. The most commonly used material to detect infrared wavelength is HgCdTe. The photodiode is the best detector architecture as it can be optimized to provide excellent performance. Typical pixel pitch is 15μm for short and medium IR wavelength (from 0.8 to 5μm) and 30μm for long IR wavelength (to 15μm). The resulting signal is processed by a silicon CMOS readout circuit (or ROIC, Readout Integrated Circuit), whose main function is to perform an integration of the charges, conversion to voltage per pixel and signal multiplexing. A CMOS read out circuit takes benefits from the large library of functions. It also offers a large panel of architectural solutions. B.Key technologiesThe technologies associated to the detection circuit are of primary importance. The HgCdTe material requires complex but mature processes. This material is grown on a specific substrate (typically CdZnTe to reach the best performance). The tuning of its composition allows a sensitivity of the material from SWIR (Short wave Infrared, or NIR, near Infrared typically 2.5μm), to VLWIR (Very Long Wave infrared) wavelengths, ie 18+μm, by adjusting the cutoff wavelength (i.e. the gap energy, photons whose energy is higher than the gap is detected). Substrate removal allows sensitivity in visible domain also. An antireflective coating is added to enhance absorption efficiency. CMOS silicon used for the readout circuit must combine good performance and reliability. The important function of the CMOS readout circuit is the input stage, which, combined to the photovoltaic diode drive the input dynamic (and gain), noise, and linearity. Different readout modes are possible, such as integration while read (IWR) or rolling shutter mode. The output stage choice is a compromise between readout frequency, external load, readout noise and power dissipation. Finally, the assembly of both detection circuit and readout circuit is performed with an indium bump hybridization process: this ensures the thermo-mechanical assembly and the electrical contact between detection circuit and readout circuit. The main technologies of HgCdTe infrared detectors for demanding space applications are the followings:
C.Content of the paperThis paper provides a synthesis of the main current developments conducted by CNES and partners in the field of cooled infrared detector for Earth Observation space missions, in order to provide adequate solutions for future space missions. A similar discussion, focused on scientific space missions can be found in [1]. Section II focuses on the driving requirements of future space missions. Section III provides a synthesis on the main issues raised by the requirements. As an example, Section IV gives an overview of current limitation of the existing ROIC based on SFD input stage. Section V and VI are an example of current development on critical technologies (p/n technology and large format arrays). Section VII ends the discussion a brief proposition for future developments. II.Driving requirementsOne of the main requirements driving detector choice is the flux range reaching the detector, which depends on the instrument concept, spectral band and resolution. Indeed, together with the integration time, this requirement gives the amount of charges at pixel level the detector needs to be able to integrate but also the part of dark signal acceptable in order not to be dominated by non-useful signal. The amount of charges that can be integrated depends on the input capacitance of the detector. Beyond this, flux ranges impact the needs in terms of noises to meet the signal to noise ratio requirement. In particular, readout noise can be the main contributor to the signal to noise ratio when measuring low signal level. To illustrate, this section focuses on an example: the Microcarb mission [2]. This mission aims at measure vertically integrated carbon dioxide (CO2) concentration from a space observatory in Low Earth Orbit. The CO2 concentration will be retrieved by measurements of the absorption of reflected sunlight by CO2. The payload consists in a passive spectrometer. The observation is in several narrow spectral windows in addition with dispersive optics providing high spectral resolution that results in low signal at pixel level. Mission’s measurement accuracy is driven by the tiny variability in the CO2 column, variations being around +/- 1ppm out of 380ppm. Beyond signal to noise ratio, one of the main issue for this type of instrument is linearity which is considered as a bias that cannot be corrected and impacts the measurement accuracy. To quantify, the low signal levels of Microcarb mission are in between 1500 and 50 000 electrons/pixel for around 1s integration time. Taking into account a typical flux range of 10 000é/s and an integration time of 1s, to be photon limited, the total noise should be around 100 electrons. Considering a total noise of 120 electrons and allowing equal budget for dark signal noise and readout noise implies 50 electrons per contributor, that is to say, an allocation of 50 electrons for readout noise and 2500 electrons/s for dark signal. III.Main issuesA.CMOS Readout CircuitTwo types of input stage are mainly used for low flux applications: the SFD and the CTIA (Capacitive Trans Impedance Amplifier), see Fig. 2. As a first approach, the consequence of the two input stages on the ROIC performance is given in Table 1. One can stress the fact that each one of the solution consistently result in a coherent set of performance. Table 1
(*)CDS: correlated double sampling The main intrinsic limitation of the SFD input circuit is the relatively small integration capacity (associated with a large potential offset dispersion). This limits its use for medium input fluxes. The architecture is compatible with the implementation of an output amplifier with a cost on the power dissipation. Some specific study have been performed to assess the limitations of SFD ROIC: a discussion is presented section IV. The main limitation of the CTIA based ROIC is it compatibility with input fluxes in the range few 102 to 103 e-/s/pixel. It is still an open issue whether a glow (self-parasitic light) from the ROIC itself and/or current leakage effects can affect the performance, either by degrading the noise budget (parasitic flux), or the linearity at very low level (floor/threshold effect,…). B.APDIn APD (Avalanche Photo-Diode) mode, the photodiode is biased in avalanche mode. In this case, the photo-generated charge, and the thermally generated (the dark signal) charge in the absorbing region of the photodiode are amplified, by the electric filed in the depleted region of the photodiode (note that those charge reach the depleted region by diffusion). The G-R component of the dark signal is partially amplified in the depleted region. The amplification factor is classically noted M. As shown in Fig.3, the higher the cutoff wavelength of the HgCdTe material, the higher the gain. A recent solution implemented by Leonardo (UK) is, for a given gap (and hence a given cutoff wavelength) in the absorbing layer, to increase the gap in the amplification region (the depleted region), in order to increase the gain [3]. The main advantage of the technic is to provide a gain at the first stage of the detection, namely at photodiode level, which has the effects to lower the other noise contributors of the different stages (ROIC noise, electronics noise, etc…), as expressed in electrons. The main issues are the following:
C.Detector cosmetics and defectsCosmetics and defects are mainly due to the detection circuit, and are related to material defects. Other kind of defective pixel is “hard” defects, mainly due to hybridization process. Finally, the ROIC can also contribute to defect budget. Criteria have to be finely tuned in order to classify the defects:
There are continuous improvements on detector material in order to minimize the material defects and cosmetics. However, the best mitigation technics to fulfill the stringent requirements of space missions, together with the radiation environment impact, is currently to implement pixel deselection at ROIC level whenever it is possible. D.A/R coating vs spectral coverageTo improve detection efficiency, Anti Reflective Coating (ARC) is deposited at the backside of the detector. ARC is also a way to reduce reflectivity on the detector surface. Indeed, parasitic light is tracked on every optic part of the instrument in the objective to lower it to avoid parasitic signal. Monolayer quaterwave ARC is mainly used and is part of the standard process of detector manufacture. This type of ARC allows detection efficiency increase of 30% and below 5% reflectivity but in narrow spectral band, below 500nm width. For application like Microcarb described in section II, instrument concept used only one detector for the different spectral bands of interest, which means that the same detector has to be performant in detection efficiency and reflectivity from 0.7μm to 2.5μm. To achieve this goal, multilayer ARC coating is foreseen (see Fig.4 extracted from [6], ESA development). The issue is that multilayer ARC deposition shall not impact detector performances so processes (temperature in particular) and handling are very critical. E.p/n photodiodeThe schematic for a p/n photodiodes is given Fig. 5. The main challenge is to decouple the absorbing region from the depleted region. The performance driver is a low dark current (diffusion limited) together with a high sensitivity and a low number of defective pixels. The definition of the photodiode has to cancel or minimize contributors which degrade the performances i.e.depleted region defect (G-R current contribution) and surface defects from interfaces. Good performance requires finely adjusted processes to get the best definition of the photodiode. IV.SFD limitations for Earth observationSFD seems to be a great solution for low signal levels. As an example, the Microcarb mission is targeted to be compatible with microsatellite platform. In this objective, the instrument is not actively cooled and operates at 150K. SFD detectors are mainly used for astronomical applications that operate below 80K. That is why, CNES decided to conduct a study on SFD detector performances at high temperature at IPNL. The main performance that was expected to be degraded with the temperature increase was the operability with the apparition of hot pixels and even clusters of hot pixels. The study was realized in the range of 100K – 180K. In order to guarantee linear behaviour in the upper dynamic, photodiode bias designed as Vsub-Vreset on was increased. Despite the confirmation that offset dispersion increases with temperature and lower the total dynamic, this study showed that dark current at 150K does not generates big clusters as expected (see Fig.6). To conclude on SFD limitations, it seems that dark current at high temperature can be acceptable but signal dynamic range is limited. Along with low frequency readout, SFD is not naturally adapted for medium range fluxes and high readout frame. Another issue to keep in mind is the persistence phenomenon that is observed for very low signal astronomical applications. The impact of this persistance should be analyzed for higher fluxes range like in Earth observation and planetary applications. In the 103 to 104 e-/s/pixel, CTIA input circuit would be a preferred solution, but we still need to address the limitations pointed in section III.A: floor or threshold effects, ROIC glow,… V.p/n photodiode technology from SWIR to VLWIRSome results have been presented in previous paper. The purpose of this section is to provide a synthesis of the past developments. As criteria of performance evaluation, the rule07 and the diffusion current limit are used. The rule07 has been set as a reference by Teledyne (US): although the rule is an empirical law based on measurements on detectors fabricated by Teledyne, it provides the state-of-the art performance for dark signal with p/n photodiode technology. The diffusion current limit demonstrates that the diode is limited by intrinsic physical phenomenon rather than material and diode imperfections. For earth observation, developments of SWIR technology for high focal plane temperature have been done. The goal is to develop detectors that can be operated at high temperatures in spacecrafts where the system constraints (orbit, mass, electrical power, volume, weight,…) prevent cooling the detectors down to low temperatures. The performance drivers are to lower the dark current and the amount of defective pixel at temperatures above 150K. G-R contribution to the dark signal has to be minimized so that the diode dark current is diffusion current limited. Results are given Fig. 7, from [5]. In the frame of CNES R&T activities, VLWIR was developed first based on p-on-n technology (2005) and then p-on-n technology was introduced at CEA-LETI since 2011 for VLWIR. These activities showed that VLWIR is very sensitive to any default in the process due to the small gap of HgCdTe material. This implies, every issue encountered at lower wavelength has to be mastered before trying to adapt the technology to VLWIR. State of the art dark current has been achieved during the latest development (see Fig.8) but operability and yield are still to be improved [8]. VI.Large Format Arrays developmentsThe developments are focused on two major activities. The first activity is to enhance the production capabilities for 1k² detector format or more (under CNES contract). The second activity aims to demonstrate the capabilities to fabricate 2k detectors. Major achievements have been demonstrated as described extensively in [8]:
VII.Roadmap schematicFuture trends for forthcoming developments are the following, see Fig. 10.
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