High-efficiency UV/optical/NIR detectors for large aperture telescopes and UV explorer missions: development of and field observations with delta-doped arrays

Nikzad, Shouleh; Jewell, April D.; Hoenk, Michael E.; Jones, Todd J.; Hennessy, John; Goodsall, Timothy; Carver, Alexander G.; Shapiro, Charles A.; Cheng, Samuel R.; Hamden, Erika; Kyne, Gillian; Martin, D. Christopher; Schiminovich, David; Scowen, Paul A.; McCandliss, Stephan R.; Lupu, Roxana

doi:10.1117/1.jatis.3.3.036002

Cited by 51 publications

(38 citation statements)

References 71 publications

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“…Previous work in our lab has explored the ALD of MgF 2 and AlF 3 for the same UV applications, utilizing anhydrous HF as the fluorine-containing precursor [17,18]. We have also produced preliminary FUV mirror results for Al protected with these materials [19,20] and multilayer filter stacks comprised of Al and metal fluorides for FUV detector-integrated filters [21]. In this work, we expand this anhydrous HF approach to the deposition of LiF and assess the morphology, composition, and optical properties of the resulting thin films.…”

Section: Introductionmentioning

confidence: 99%

Atomic Layer Deposition of Lithium Fluoride Optical Coatings for the Ultraviolet

Hennessy

Nikzad

2018

Inorganics

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Lithium fluoride is an important material for ultraviolet optical systems, possessing among the largest optical bandgaps of dielectric materials. We report on the development of an atomic layer deposition (ALD) process for lithium fluoride that is capable of depositing thin films in a self-limiting manner, with an approximate deposition rate of approximately 0.15 Å per ALD cycle at a substrate temperature of 150 • C. Films are characterized by spectroscopic ellipsometry, atomic force microscopy, X-ray photoelectron spectroscopy, and far ultraviolet reflectometry. For substrate temperatures of 150 • C and greater, films showed significant microroughness with a correlated reduction in effective refractive index. This behavior was mitigated by a reduction in substrate temperature to as low as 100 • C. Films deposited on silicon substrates were subjected to long-term storage testing to evaluate the environmental sensitivity of the deposited layers. Protected aluminum mirrors were also fabricated with ALD LiF overcoats, yielding a reflectance of 84% at a wavelength of 125 nm. The performance relative to state-of-the-art LiF thin films deposited by physical vapor deposition methods is discussed, along with the prospects for future optimization.

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Section: Introductionmentioning

confidence: 99%

Atomic Layer Deposition of Lithium Fluoride Optical Coatings for the Ultraviolet

Hennessy

Nikzad

2018

Inorganics

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“…It has a line density of 2400 lines/mm and angle of incidence of 28 • . 24 The FB-2 UV EMCCD is provided by the Microdevices Laboratory (MDL) at JPL (PI: S. Nikzad [25][26][27] ) as a part of the FB-2 collaboration. A Teledyne e2v CCD201-20 wafer is thinned and δ-doped using a molecular-beam epitaxy, which grows a single layer of boron-doped silicon.…”

Section: Fireball Science Goals and Instrument Descriptionmentioning

confidence: 99%

“…A Teledyne e2v CCD201-20 wafer is thinned and δ-doped using a molecular-beam epitaxy, which grows a single layer of boron-doped silicon. 26 This process significantly increases the quantum efficiency (QE) of the device. An AR coating is added at the end of the process to overcome QE limitations due to the reflectivity of the silicon.…”

Section: Fireball Science Goals and Instrument Descriptionmentioning

confidence: 99%

The FIREBall-2 UV balloon telescope: 2018 flight and improvements for 2020

Hoadley

Hamden

Milliard

et al. 2019

UV, X-Ray, and Gamma-Ray Space Instrumentation for Astronomy XXI

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The Faint Intergalactic-medium Redshifted Emission Balloon (FIREBall-2, FB-2) is designed to discover and map faint UV emission from the circumgalactic medium around low redshift galaxies (z ∼ 0.3 (C IV); z ∼ 0.7 (Lyα); z ∼ 1.0 (O VI)). FIREBall-2's first launch, on September 22nd 2018 out of Ft. Sumner, NM, was abruptly cut short due to a hole that developed in the balloon. FIREBall-2 was unable to observe above its minimum require altitude (25 km; nominal: 32 km) for its shortest required time (2 hours; nominal: 8+ hours). The shape of the deflated balloon, as well as a concurrent full moon close to our observed target field, revealed a severe, off-axis scattered light path directly to the UV science detector. Additional damage to FB-2 added complications to the ongoing effort to prepare FB-2 for a quick re-floght. Upon landing, several mirrors in the optical chain, including the two large telescope mirrors, were damaged, resulting in chunks of material broken off the sides and reflecting surfaces. The magnifying optical element, called the focal corrector, was discovered to be misaligned beyond tolerance after the 2018 flight, with one of its two mirrors damaged from the landing impact. We describe the steps taken thus far to mitigate the damage to the optics, as well as procedures and results from the ongoing efforts to realign the focal corrector and spectrograph optics. We report the throughput of the spectrograph before and after the 2018 flight and plans for improving it. Finally, we describe several methods by which we address the scattered light issues seen from FIREBall-2's 2018 campaign and present the current status of FB-2 to fly during the summer campaign in Palestine, TX in 2020.

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“…8,24,25 This fast scintillation component at 220 nm has potential applications in high rate particle physics calorimetry experiments, but BaF 2 also produces a larger, slower scintillation component at 300 nm. In order to achieve high detection rates, readout devices must therefore suppress this component while maintaining high sensitivity at 220 nm.…”

Section: Application To Silicon Avalanche Photodiodesmentioning

confidence: 99%

“…When operating at high gain the depletion conditions are distinctly different, and the projected 'effective' QE is higher than that measured at unity gain. 25 In this sense, the 70% scaling factor represents a lower limit to the internal QE of the device and/or the relative transmission of the MDDIF structure. Nevertheless, improvements over previous demonstrations are clear, primarily resulting from reductions in the cumulative thermal budget experienced by the MDDIF structure during processing.…”

Section: Application To Silicon Avalanche Photodiodesmentioning

confidence: 99%

Materials and process development for the fabrication of far ultraviolet device-integrated filters for visible-blind Si sensors

et al. 2017

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In this work, we show that the direct integration of ultraviolet metal-dielectric filters with Si sensors can improve throughput over external filter approaches, and yield devices with UV quantum efficiencies greater than 50%, with rejection ratios of visible light greater than 10 3 . In order to achieve these efficiencies, two-dimensional doping methods are used to increase the UV sensitivity of back-illuminated Si sensors. Integrated filters are then deposited by a combination of Al evaporation and atomic layer deposition of dielectric spacer layers. At far UV wavelengths these filters require the use of non-absorbing dielectrics, and we have pursued the development of new atomic layer deposition processes for metal fluorides materials of MgF 2 , AlF 3 and LiF. The performance of the complete multilayer filters on Si photodiodes and CCD imaging sensors, and the design and fabrication challenges associated with this development are demonstrated. This includes the continued development of deep diffused silicon avalanche photodiodes designed to detect the fast 220 nm emission component of barium fluoride scintillation crystals, while optically rejecting a slower component at 300 nm.

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High-efficiency UV/optical/NIR detectors for large aperture telescopes and UV explorer missions: development of and field observations with delta-doped arrays

Cited by 51 publications

References 71 publications

Atomic Layer Deposition of Lithium Fluoride Optical Coatings for the Ultraviolet

Atomic Layer Deposition of Lithium Fluoride Optical Coatings for the Ultraviolet

The FIREBall-2 UV balloon telescope: 2018 flight and improvements for 2020

Materials and process development for the fabrication of far ultraviolet device-integrated filters for visible-blind Si sensors

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