Perovskite-based time-domain signal-balancing LiDAR sensor with centimeter depth resolution

Gebhard J. Matt , Vitalii Bartosh , Joshua R. S. Lilly , Vincent J.-Y. Lim , Lorenzo J. A. Ferraresi , Daria Proniakova , Yuliia Kominko , Gytis Juška , Laura M. Herz , Sergii Yakunin , Maksym V. Kovalenko

InfoMat ›› 2026, Vol. 8 ›› Issue (4) : e70104

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InfoMat ›› 2026, Vol. 8 ›› Issue (4) :e70104 DOI: 10.1002/inf2.70104
RESEARCH ARTICLE
Perovskite-based time-domain signal-balancing LiDAR sensor with centimeter depth resolution
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Abstract

A novel class of semiconducting compounds, metal-halide perovskites (MHPs), has emerged as a versatile platform for advanced optoelectronic device architectures, offering a unique combination of exceptional physical properties and facile processing. In this study, we present a monolithic high-speed photodetector capable of directly sensing the time delay between two light pulses with a temporal resolution of at least 170 ps, corresponding to a light propagation distance of ~5 cm—making it well suited for Light Detection and Ranging (LiDAR) applications. This outstanding time resolution is achieved through a signal-balancing detection scheme that effectively overcomes the limitations of conventional photodetectors, whose response speed is inherently limited by charge-carrier lifetime and transit time. The device exhibits an exceptionally low noise spectral density, comparable to that of state-of-the-art silicon photodiodes. The fully symmetric device stack comprises a crystalline CsPbBr3 absorber layer tens of microns thick, fabricated via a confined melt process. Comprehensive electro-optical characterization reveals charge-carrier lifetimes and mobilities on both microscopic and macroscopic length scales, using transient photoluminescence, time-resolved photocurrent, time of flight, and terahertz pump–probe spectroscopy. The CsPbBr3 layer exhibits charge-carrier lifetimes exceeding 100 ns, a microscopic electron–hole mobility of 15 ± 1 cm2 V−1 s−1, and a macroscopic non-dispersive hole mobility of 8.5 cm2 V−1 s−1.

Keywords

balanced photodetectors / LIDARS / metal halide perovskites / photodetectors / time of flight

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Gebhard J. Matt, Vitalii Bartosh, Joshua R. S. Lilly, Vincent J.-Y. Lim, Lorenzo J. A. Ferraresi, Daria Proniakova, Yuliia Kominko, Gytis Juška, Laura M. Herz, Sergii Yakunin, Maksym V. Kovalenko. Perovskite-based time-domain signal-balancing LiDAR sensor with centimeter depth resolution. InfoMat, 2026, 8 (4) : e70104 DOI:10.1002/inf2.70104

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References

[1]

Li N, Ho CP, Xue J, et al. A progress review on solid-state LiDAR and nanophotonics-based LiDAR sensors. Laser Photon Rev. 2022; 16:24.

[2]

Heide F, Diamond S, Lindell DB, Wetzstein G. Sub-picosecond photon-efficient 3D imaging using single-photon sensors. Sci Rep. 2018; 8(1):17726.

[3]

Shrestha S, Matt GJ, Osvet A, Niesner D, Hock R, Brabec CJ. Assessing temperature dependence of drift mobility in methylammonium Lead iodide perovskite single crystals. J Phys Chem C. 2018; 122(11): 5935-5939.

[4]

Yamada Y, Kanemitsu Y. Electron-phonon interactions in halide perovskites. NPG Asia Mater. 2022; 14(1):48.

[5]

Sakhatskyi K, Turedi B, Matt GJ, et al. Stable perovskite single-crystal X-ray imaging detectors with single-photon sensitivity. Nat Photon. 2023; 17(6): 510-517.

[6]

Brandt RE, Stevanović V, Ginley DS, Buonassisi T. Identifying defect-tolerant semiconductors with high minority-carrier lifetimes: beyond hybrid lead halide perovskites. MRS Commun. 2015; 5(2): 265-275.

[7]

Stoumpos CC, Kanatzidis MG. Halide perovskites: poor man's high-performance semiconductors. Adv Mater. 2016; 28(28): 5778-5793.

[8]

Green MA, Ho-Baillie A, Snaith HJ. The emergence of perovskite solar cells. Nat Photon. 2014; 8(7): 506-514.

[9]

He Y, Matei L, Jung HJ, et al. High spectral resolution of gamma-rays at room temperature by perovskite CsPbBr3 single crystals. Nat Commun. 2018; 9(1): 1609.

[10]

Shrestha S, Fischer R, Matt GJ, et al. High-performance direct conversion X-ray detectors based on sintered hybrid lead triiodide perovskite wafers. Nat Photon. 2017; 11(7): 436-440.

[11]

Zhao X, Wang S, Zhuge F, et al. High-performance planar-type photodetector based on hot-pressed CsPbBr3 wafer. J Phys Chem Lett. 2022; 13(13): 3008-3015.

[12]

Matt GJ, Levchuk I, Knüttel J, et al. Sensitive direct converting X-ray detectors utilizing crystalline CsPbBr3 perovskite films fabricated via scalable melt processing. Adv Mater Interfaces. 2020; 7(4):1901575.

[13]

Sakhatskyi K, Bhardwaj A, Matt GJ, Yakunin S, Kovalenko MV. A decade of Lead halide perovskites for direct-conversion X-ray and gamma detection: technology readiness level and challenges. Adv Mater. 2025; 37(27):2418465.

[14]

Tsarev S, Proniakova D, Liu X, et al. Vertically stacked monolithic perovskite colour photodetectors. Nature. 2025; 642(8068): 592-598.

[15]

Shen L, Fang Y, Wang D, et al. A self-powered, sub-nanosecond-response solution-processed hybrid perovskite photodetector for time-resolved photoluminescence-lifetime detection. Adv Mater. 2016; 28(48): 10794-10800.

[16]

Morteza Najarian A, Vafaie M, Johnston A, et al. Sub-millimetre light detection and ranging using perovskites. Nat Electron. 2022; 5(8): 511-518.

[17]

Dekorsy T, Pfeifer T, Kütt W, Kurz H. Subpicosecond carrier transport in GaAs surface-space-charge fields. Phys Rev B. 1993; 47(7): 3842-3849.

[18]

Héroux JB, Kuwata-Gonokami M. Photoexcited carrier dynamics in InAs, GaAs, and InSb probed by terahertz excitation spectroscopy. Phys Rev Appl. 2017; 7:054001.

[19]

Stoumpos CC, Malliakas CD, Peters JA, et al. Crystal growth of the perovskite semiconductor CsPbBr3: a new material for high-energy radiation detection. Cryst Growth Des. 2013; 13(7): 2722-2727.

[20]

Chung DY, Lin W, Unal M, et al. Growth of high-purity CsPbBr3 crystals for enhanced gamma-ray detection. Cryst Growth des. 2024; 24(22): 9590-9600.

[21]

Zanatta AR. Revisiting the optical bandgap of semiconductors and the proposal of a unified methodology to its determination. Sci Rep. 2019; 9(1):11225.

[22]

Koiry SP, Jha P, Veerender P, et al. An electrochemical method for fast and controlled etching of fluorine-doped tin oxide coated glass substrates. J Electrochem Soc. 2017; 164(2): E1-E4.

[23]

Kanak A, Kopach O, Kanak L, et al. Melting and crystallization features of CsPbBrperovskite. Cryst Growth Des. 2022; 22(7): 4115-4121.

[24]

Tiwana P, Parkinson P, Johnston MB, Snaith HJ, Herz LM. Ultrafast terahertz conductivity dynamics in mesoporous TiO2: influence of dye sensitization and surface treatment in solid-state dye-sensitized solar cells. J Phys Chem C. 2010; 114(2): 1365-1371.

[25]

Righetto M, Wang Y, Elmestekawy KA, et al. Cation-disorder engineering promotes efficient charge-carrier transport in AgBiS2 nanocrystal films. Adv Mater. 2023; 35(48):202305009.

[26]

Ulatowski AM, Elmestekawy KA, Patel JB, et al. Contrasting charge-carrier dynamics across key metal-halide perovskite compositions through in situ simultaneous probes. Adv Funct Mater. 2023; 33(51):202305283.

[27]

Herz LM. Charge-carrier dynamics in organic-inorganic metal halide perovskites. Annu Rev Phys Chem. 2016; 67(1): 65-89.

[28]

Seifert T, Jaiswal S, Martens U, et al. Efficient metallic spintronic emitters of ultrabroadband terahertz radiation. Nat Photon. 2016; 10(7): 483-488.

[29]

Nienhuys H-K, Sundström V. Intrinsic complications in the analysis of optical-pump, terahertz probe experiments. Phys Rev B. 2005; 71(23):235110.

[30]

Bednorz M, Matt GJ, Głowacki ED, et al. Silicon/organic hybrid heterojunction infrared photodetector operating in the telecom regime. Org Electron. 2013; 14(5): 1344-1350.

[31]

Pope M, Swenberg CE. Electronic Processes in Organic Crystals and Polymers. Oxford University Press; 1999.

[32]

Kasap SO. Photoconductivity and Photoconductive Materials. Wiley; 2022: 179-251.

[33]

Belas E, Betušiak M, Karuppaiya M, Grill R, Praus P. 2024 IEEE Nuclear Science Symposium (NSS), Medical Imaging Conference (MIC) and Room Temperature Semiconductor Detector Conference (RTSD). IEEE; 2024.

[34]

Almora O, Matt GJ, These A, et al. Surface versus bulk currents and ionic space-charge effects in CsPbBrsingle crystals. J Phys Chem Lett. 2022; 13(17): 3824-3830.

[35]

Yan H, Cao G, Wang J, et al. Uncovering the modest hole mobility for the intrinsic single crystal CsPbBr3 by variable-temperature time of flight measurement. Appl Phys Lett. 2025; 126(12):122105.

[36]

Kočka J, Nebel CE, Abel CD. Solution of the μτ problem in a-Si: H. Philos Mag B. 1991; 63(1): 221-246.

[37]

Hornbeck JA, Haynes JR. Trapping of minority carriers in silicon. I.P-type silicon. Phys Rev. 1955; 97(2): 311-321.

[38]

Protesescu L, Yakunin S, Bodnarchuk MI, et al. Nanocrystals of cesium Lead halide perovskites (CsPbX3, X = Cl, Br, and I): novel optoelectronic materials showing bright emission with wide color gamut. Nano Lett. 2015; 15(6): 3692-3696.

[39]

Crothers TW, Milot RL, Patel JB, et al. Photon reabsorption masks intrinsic bimolecular charge-carrier recombination in CH3NH3PbI3 perovskite. Nano Lett. 2017; 17(9): 5782-5789.

[40]

Davies CL, Filip MR, Patel JB, et al. Bimolecular recombination in methylammonium lead triiodide perovskite is an inverse absorption process. Nat Commun. 2018; 9(1): 293.

[41]

Regan BO, Grätzel M. A low-cost, high-efficiency solar cell based on dye-sensitized colloidal TiO2 films. Nature. 1991; 353(6346):737.

[42]

D Beljonne, J Cornil, eds. Multiscale Modelling of Organic and Hybrid Photovoltaics. Springer Berlin Heidelberg; 2014.

[43]

Haynes JR, Shockley W. The mobility and life of injected holes and electrons in germanium. Phys Rev. 1951; 81(5): 835-843.

[44]

Smith RA. Semiconductors. Cambridge University Press; 1964.

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