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
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.
balanced photodetectors / LIDARS / metal halide perovskites / photodetectors / time of flight
| [1] |
|
| [2] |
|
| [3] |
|
| [4] |
|
| [5] |
|
| [6] |
|
| [7] |
|
| [8] |
|
| [9] |
|
| [10] |
|
| [11] |
|
| [12] |
|
| [13] |
|
| [14] |
|
| [15] |
|
| [16] |
|
| [17] |
|
| [18] |
|
| [19] |
|
| [20] |
|
| [21] |
|
| [22] |
|
| [23] |
|
| [24] |
|
| [25] |
|
| [26] |
|
| [27] |
|
| [28] |
|
| [29] |
|
| [30] |
|
| [31] |
|
| [32] |
|
| [33] |
|
| [34] |
|
| [35] |
|
| [36] |
|
| [37] |
|
| [38] |
|
| [39] |
|
| [40] |
|
| [41] |
|
| [42] |
|
| [43] |
|
| [44] |
|
2025 The Author(s). InfoMat published by UESTC and John Wiley & Sons Australia, Ltd.
/
| 〈 |
|
〉 |