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2D GaSe-Based Single-Pixel Spectrometer via Electro-Optical Barrier Co-Modulation

Optics 2026-05-21 v1 Materials Science Applied Physics

Abstract

Driven by the growing demand for miniaturized spectrometers for in-situ analysis, and point-of-care diagnostics, conventional spectrometers are often constrained by bulky architectures and pathlength-limited spectral resolution. Achieving high-resolution, single-pixel computational spectrometers is therefore critical for the realization of compact, on-chip systems. Here, we report a single-pixel spectrometer enabled by a single 2D material; few-layer GaSe-based photodetector, in which the Schottky barrier height modulation, governed jointly by applied bias and optical excitation, provides an efficient mechanism for spectral encoding without the need for bulky dispersive elements. The device exhibits a high peak-wavelength accuracy of ~0.78 nm across a broad operational bandwidth (300-700 nm) within a compact footprint of ~100 um^2 and resolves closely spaced spectral features with separations down to ~5 nm. The device operates at low bias (+/- 4V) with an ultralow dark current density ~0.3 pA/um^2 at 4V bias. These results establish a simple, scalable route toward compact, cost-effective spectroscopic systems for on-chip spectral sensing and portable hyperspectral imaging applications.

Keywords

Cite

@article{arxiv.2605.20375,
  title  = {2D GaSe-Based Single-Pixel Spectrometer via Electro-Optical Barrier Co-Modulation},
  author = {Shibesh Pramanik and Rishabh Sahoo and Arnab Mondal and Tithi Saha and Ankush Bag and Vibhav Bharadwaj Shivakumar and Rishi Maiti},
  journal= {arXiv preprint arXiv:2605.20375},
  year   = {2026}
}

Comments

23 pages, 6 figures