Optimizing the light penetration depth in APDs and SPADs for high gain-bandwidth and ultra-wide spectral response

TL;DR

This paper presents a nanostructure design that optimizes light penetration in APDs and SPADs, enhancing their spectral response and gain by controlling light absorption depth across visible and near-infrared wavelengths.

Contribution

The study introduces a novel periodic nanostructure that simultaneously manages light penetration for multiple wavelengths, improving device sensitivity and bandwidth.

Findings

Enhanced light absorption across a broad spectral range.

Reduced reflectance and increased sensitivity due to nanostructures.

Potential applications in high-efficiency photon detection technologies.

Abstract

Controlling light penetration depth in Avalanche Photodiodes (APDs) and Single Photon Avalanche Diodes (SPADs) play a major role in achieving high multiplication gain by delivering light near the multiplication region where the electric field is the strongest. Such control in the penetration depth for a particular wavelength of light has been previously demonstrated using integrated photon-trapping nanostructures. In this paper, we show that an optimized periodic nanostructure design can control the penetration depth for a wide range of visible and near-infrared wavelengths simultaneously. A conventional silicon APD structure suffers from high photocarrier loss due to recombination for shorter wavelengths as they are absorbed near the surface region, while silicon has low absorption efficiency for longer wavelengths. This optimized nanostructure design allows shorter wavelengths of light to penetrate deeper into the device, circumventing recombination sites while trapping the longer wavelengths in the thin silicon device by bending the vertically propagating light into horizontal modes. This manipulation of penetration depth improves the absorption in the device, increasing light sensitivity while nanostructures reduce the reflectance from the top surface. While delivery of light near the multiplication region reduces the photogenerated carrier loss and shortens transit time, leading to high multiplication gain in APDs and SPADs over a wide spectral range. These high gain APDs and SPADs will find their potential applications in Time-Of-Flight Positron Emission Tomography (TOF-PET), Fluorescence Lifetime Imaging Microscopy (FLIM), and pulse oximetry where high detection efficiency and high gain-bandwidth is required over a multitude of wavelengths.