Thin Film AlN Microbolometer for Very Long-Wave Infrared Detection

Daniel Wasserman; Ian Anderson; Ruochen Lu; Vivek Tallavajhula; Yinan Wang; Zarko Sakotic

arxiv: 2604.22301 · v1 · submitted 2026-04-24 · ⚛️ physics.optics · physics.app-ph

Thin Film AlN Microbolometer for Very Long-Wave Infrared Detection

Vivek Tallavajhula , Zarko Sakotic , Ian Anderson , Yinan Wang , Daniel Wasserman , Ruochen Lu This is my paper

Pith reviewed 2026-05-08 10:48 UTC · model grok-4.3

classification ⚛️ physics.optics physics.app-ph

keywords aluminum nitridemicrobolometervery long-wave infrarednarrowband detectionthin filmphonon resonancesuspended membranebolometric response

0 comments

The pith

A suspended 100-nm AlN film over a reflector produces a narrowband microbolometer peaking at 15.48 micrometers in the very long-wave infrared.

A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.

The paper establishes that a thin aluminum nitride membrane can be engineered into a functional microbolometer for detecting narrowband very long-wave infrared light. The design suspends the film above a back reflector to boost absorption at the material's natural phonon resonance frequency around 15.4 micrometers. Perforations in the film lower its heat capacity while keeping absorption high. Resistance measurements confirm that light absorption directly translates to electrical signals in the 14 to 18 micrometer band. Such a device opens paths to simpler, more compact sensors for applications like chemical analysis and thermal imaging.

Core claim

We demonstrate a suspended thin-film aluminum nitride (AlN) microbolometer for narrowband very long-wave infrared detection. The device uses a 100-nm-thick AlN membrane suspended above a Pt back reflector by a 1-um air gap, where resonant absorption is set by the AlN transverse optical phonon near 15.4 um and strengthened by the suspension. A periodic perforation pattern reduces membrane thermal mass and enhances absorption. DC resistance measurements under tunable infrared illumination verify bolometric operation, and the measured spectral response follows the absorption profile from spectroscopic measurements of passive devices, yielding narrowband response in the 14-18 um range with peak

What carries the argument

The suspended perforated thin-film AlN membrane above a Pt reflector with a 1-um air gap, which tunes resonant absorption to the AlN transverse optical phonon mode while reducing thermal mass for bolometric detection.

Load-bearing premise

The measured changes in DC resistance under tunable IR illumination are caused purely by bolometric heating from resonant absorption, without other electrical or optical confounding effects.

What would settle it

A spectral scan of responsivity that fails to show a peak at 15.48 um aligned with the passive absorption profile, or no observable resistance change under illumination at that wavelength, would disprove the narrowband bolometric mechanism.

Figures

Figures reproduced from arXiv: 2604.22301 by Daniel Wasserman, Ian Anderson, Ruochen Lu, Vivek Tallavajhula, Yinan Wang, Zarko Sakotic.

**Figure 2.** Figure 2: Fabrication sequence and material characterization of the view at source ↗

**Figure 3.** Figure 3: (a) Measured and simulated reflection of the AlN thin-film cavity in the unsuspended and (c) suspended case. (b) Simulated reflection view at source ↗

**Figure 4.** Figure 4: Infrared measurement setup and device images. (a) Experi view at source ↗

**Figure 5.** Figure 5: (a) Simulated temperature distribution of the suspended ab view at source ↗

read the original abstract

We demonstrate a suspended thin-film aluminum nitride (AlN) microbolometer for narrowband very long-wave infrared detection. The device uses a 100-nm-thick AlN membrane suspended above a Pt back reflector by a 1-um air gap. Resonant absorption is set by the AlN transverse optical phonon near 15.4 um and is strengthened by suspension above the reflector. A periodic perforation pattern reduces membrane thermal mass and enhances absorption without further thinning the film. DC resistance measurements under tunable infrared illumination verify bolometric operation, and the measured spectral response follows the absorption profile expected from spectroscopic measurement of passive devices. Narrowband response is observed in the 14--18 um range, with peak responsivity of 920.8 ppm/mW at 15.48 um. This platform can enable compact wavelength-selective thermal detectors for multispectral imaging, on-chip infrared spectroscopy, and chemical sensing.

Editorial analysis

A structured set of objections, weighed in public.

Desk editor's note, referee report, simulated authors' rebuttal, and a circularity audit. Tearing a paper down is the easy half of reading it; the pith above is the substance, this is the friction.

Desk Editor's Note private letter to a colleague

AlN microbolometer shows phonon-resonant VLWIR response with measured DC shifts tracking absorption, but verification rests on assuming purely thermal behavior without detailed controls.

read the letter

The paper gives a working example of a thin-film AlN microbolometer tuned for narrowband detection in the 14-18 um range. They use the AlN transverse optical phonon for absorption, boosted by a suspended structure over a Pt reflector with perforations to cut thermal mass. What is new is the specific stack and patterning: 100 nm AlN membrane, 1 um air gap, and periodic holes that help both absorption and thermal properties. The DC resistance measurements under illumination track the expected spectral response from separate passive samples, hitting 920.8 ppm/mW at peak. The work is solid on the device side. It shows the concept can be realized with standard thin-film methods and gives concrete performance numbers for this wavelength band. No overclaiming here; it's presented as a platform for compact detectors in imaging and sensing. The main soft spot is in the verification details. The central claim depends on the resistance change being purely bolometric and the illumination being well-calibrated across wavelengths. Without explicit checks for other electrical effects or source uniformity in the provided summary, there is some uncertainty whether the spectral feature is fully isolated. If the manuscript includes those controls, it would be stronger. Readers in applied optics or sensor development would get the most from this, as it offers a material-based approach rather than purely engineered resonances. It is the kind of incremental but practical advance that fits in a specialized journal. I would send it for peer review. The experimental core is there and the questions are addressable with more data on the measurement setup.

Referee Report

2 major / 1 minor

Summary. The manuscript demonstrates a suspended thin-film aluminum nitride (AlN) microbolometer for narrowband very long-wave infrared (VLWIR) detection. It utilizes a 100-nm-thick AlN membrane suspended above a Pt back reflector with a 1-μm air gap, employing the AlN transverse optical (TO) phonon resonance near 15.4 μm for resonant absorption, enhanced by suspension and a periodic perforation pattern to reduce thermal mass. DC resistance measurements under tunable infrared illumination are used to verify bolometric operation, with the spectral response matching the absorption profile from passive spectroscopic measurements. The device shows narrowband response in the 14–18 μm range, achieving a peak responsivity of 920.8 ppm/mW at 15.48 μm.

Significance. If substantiated, this work offers a promising platform for compact, wavelength-selective thermal detectors applicable to multispectral imaging, on-chip infrared spectroscopy, and chemical sensing. The use of thin-film AlN leveraging its phonon resonance, combined with suspension and perforation for optimized absorption and thermal properties, represents a novel approach in VLWIR detection. Credit is given for the direct experimental comparison to passive absorption profiles, though the limited details hinder full assessment of reproducibility.

major comments (2)

[Abstract] The verification of bolometric operation via DC resistance measurements under tunable IR illumination is central to the claims but lacks essential details including power calibration across wavelengths, use of chopped illumination, extraction of thermal time constants, and comparison to self-heating via Joule effect. This omission raises concerns about potential non-bolometric contributions to the resistance changes, as noted in the skeptic's analysis.
[Abstract] The assertion that the measured spectral response follows the absorption profile from passive devices requires explicit confirmation that the active device geometry (including the 1-μm air gap, Pt reflector, and perforations) produces identical absorption without confounding effects from biasing or contacts. No such controls or error bars are mentioned, weakening the evidence for the narrowband response at 920.8 ppm/mW peak.

minor comments (1)

[Abstract] The responsivity unit 'ppm/mW' should be clarified if it refers to relative resistance change per milliwatt of incident power.

Simulated Author's Rebuttal

2 responses · 0 unresolved

We thank the referee for the careful review and constructive feedback on our manuscript describing the thin-film AlN microbolometer. We address each major comment below and will revise the manuscript to provide the requested clarifications and supporting data.

read point-by-point responses

Referee: [Abstract] The verification of bolometric operation via DC resistance measurements under tunable IR illumination is central to the claims but lacks essential details including power calibration across wavelengths, use of chopped illumination, extraction of thermal time constants, and comparison to self-heating via Joule effect. This omission raises concerns about potential non-bolometric contributions to the resistance changes, as noted in the skeptic's analysis.

Authors: We agree that the current manuscript provides insufficient experimental details on the DC resistance measurements. In the revised version we will expand the methods and results sections to describe the power calibration procedure across the tunable source wavelengths, the use of chopped illumination to extract the thermal time constant, and a direct comparison of the illumination-induced resistance change against Joule self-heating under identical bias conditions. These additions will strengthen the evidence that the observed response is bolometric. revision: yes
Referee: [Abstract] The assertion that the measured spectral response follows the absorption profile from passive devices requires explicit confirmation that the active device geometry (including the 1-μm air gap, Pt reflector, and perforations) produces identical absorption without confounding effects from biasing or contacts. No such controls or error bars are mentioned, weakening the evidence for the narrowband response at 920.8 ppm/mW peak.

Authors: The passive FTIR measurements were performed on suspended AlN structures fabricated with identical geometry, including the 1-μm air gap, Pt back reflector, and periodic perforation pattern. Biasing contacts lie outside the optically active area and were designed to have negligible influence on absorption in the 14–18 μm band. In the revision we will add an explicit statement of this geometric equivalence, overlay the active-device responsivity spectrum on the passive absorption data, and include error bars derived from multiple devices to quantify the match. revision: yes

Circularity Check

0 steps flagged

No significant circularity; experimental claims rest on direct measurements

full rationale

The paper is an experimental demonstration of a fabricated AlN microbolometer device. Its central claims (narrowband VLWIR response with measured responsivity of 920.8 ppm/mW at 15.48 um) are supported by DC resistance shifts under tunable illumination and direct comparison of the resulting spectral response to absorption spectra obtained separately on passive test structures. No equations, derivations, parameter fittings, or self-citations appear in the provided text that would reduce any result to its own inputs by construction. The verification step is a straightforward experimental comparison rather than a self-referential prediction or ansatz.

Axiom & Free-Parameter Ledger

0 free parameters · 2 axioms · 0 invented entities

The demonstration relies on established material properties and device physics rather than new theoretical elements or fitted parameters.

axioms (2)

domain assumption AlN exhibits a transverse optical phonon resonance near 15.4 um that enables resonant absorption
Invoked to explain the narrowband response wavelength.
domain assumption Resistance change in the film is dominated by temperature rise from absorbed IR (bolometric effect)
Basis for interpreting DC measurements as detection signal.

pith-pipeline@v0.9.0 · 5471 in / 1356 out tokens · 74619 ms · 2026-05-08T10:48:01.329121+00:00 · methodology

discussion (0)

Reference graph

Works this paper leans on

4 extracted references · 1 canonical work pages

[1]

1M. I. Saleem, A. K. K. Kyaw, and J. Hur, Adv. Opt. Mat. (2024). 2J. Kozuch, K. Ataka, and J. Heberle, Nat Rev Methods Primers3, 70 (2023). 3J. J. Talghader, A. S. Gawarikar, and R. P. Shea, Light Sci Appl1, e24 (2012). 4L. Nordin, P. Petluru, A. Kamboj, A. J. Muhowski, and D. Wasserman, Optica8, 1545 (2021). 5Y . Wang, A. J. Muhowski, L. Nordin, S. Dev, ...

2024
[2]

Neikirk, IEEE Photonics J.7, 1 (2015). 14J. D. Caldwell, L. Lindsay, V . Giannini, I. Vurgaftman, T. L. Reinecke, S. A. Maier, and O. J. Glembocki, Nanophotonics4, 44 (2014). 15S. Foteinopoulou, G. C. R. Devarapu, G. S. Subramania, S. Krishna, and D. Wasserman, Nanophotonics8, 2129 (2018). 16Z. Sakotic, A. Ware, M. Povinelli, and D. Wasserman, ACS Photoni...

work page doi:10.1063/1.1359162 2015
[3]

Davoyan, Nano Lett.24, 3315 (2024). 29S. Abedini Dereshgi, T. G. Folland, A. A. Murthy, X. Song, I. Tanriover, V . P. Dravid, J. D. Caldwell, and K. Aydin, Nat Commun11, 5771 (2020). 30L. Nordin, O. Dominguez, C. M. Roberts, W. Streyer, K. Feng, Z. Fang, V . A. Podolskiy, A. J. Hoffman, and D. Wasserman, Applied Physics Let- ters111, 091105 (2017). 31A. W...

2024
[4]

Vella, J. Opt. Soc. Am. B34, 1965 (2017). 38C. Chen, C. Li, S. Min, Q. Guo, Z. Xia, D. Liu, Z. Ma, and F. Xia, Nano Lett.21, 8385 (2021). 39T. Guo, S. Chandra, A. Dasgupta, M. W. Shabbir, A. Biswas, and D. Chanda, Nano Lett.24, 14678 (2024)

1965

[1] [1]

1M. I. Saleem, A. K. K. Kyaw, and J. Hur, Adv. Opt. Mat. (2024). 2J. Kozuch, K. Ataka, and J. Heberle, Nat Rev Methods Primers3, 70 (2023). 3J. J. Talghader, A. S. Gawarikar, and R. P. Shea, Light Sci Appl1, e24 (2012). 4L. Nordin, P. Petluru, A. Kamboj, A. J. Muhowski, and D. Wasserman, Optica8, 1545 (2021). 5Y . Wang, A. J. Muhowski, L. Nordin, S. Dev, ...

2024

[2] [2]

Neikirk, IEEE Photonics J.7, 1 (2015). 14J. D. Caldwell, L. Lindsay, V . Giannini, I. Vurgaftman, T. L. Reinecke, S. A. Maier, and O. J. Glembocki, Nanophotonics4, 44 (2014). 15S. Foteinopoulou, G. C. R. Devarapu, G. S. Subramania, S. Krishna, and D. Wasserman, Nanophotonics8, 2129 (2018). 16Z. Sakotic, A. Ware, M. Povinelli, and D. Wasserman, ACS Photoni...

work page doi:10.1063/1.1359162 2015

[3] [3]

Davoyan, Nano Lett.24, 3315 (2024). 29S. Abedini Dereshgi, T. G. Folland, A. A. Murthy, X. Song, I. Tanriover, V . P. Dravid, J. D. Caldwell, and K. Aydin, Nat Commun11, 5771 (2020). 30L. Nordin, O. Dominguez, C. M. Roberts, W. Streyer, K. Feng, Z. Fang, V . A. Podolskiy, A. J. Hoffman, and D. Wasserman, Applied Physics Let- ters111, 091105 (2017). 31A. W...

2024

[4] [4]

Vella, J. Opt. Soc. Am. B34, 1965 (2017). 38C. Chen, C. Li, S. Min, Q. Guo, Z. Xia, D. Liu, Z. Ma, and F. Xia, Nano Lett.21, 8385 (2021). 39T. Guo, S. Chandra, A. Dasgupta, M. W. Shabbir, A. Biswas, and D. Chanda, Nano Lett.24, 14678 (2024)

1965