Black Germanium Photodetector Exceeds External Quantum Efficiency of 160%

Abstract: Inspired by the formation of black Si, [14,15] black Ge with nanospiked structures was achieved by femtosecond laser irradiation in SF 6 environment. [16] However, optical properties of the structure were not characterized. There have been intensive research efforts to fabricate black Ge by using the standard dry etching technique based on sulfur hexafluoride (SF 6 ) and chlorine (Cl 2 ) gases. [17,18] Although Pasanen et al. fabricated black Ge surface by SF 6 -based inductively coupled plasma reactive ion et… Show more

“…So far, though great progress has been made recently, the photoresponsivities of those reported self-powered perovskite photodetectors are still too low for practical applications. , This can be reflected by the low external quantum efficiency (EQE) values for those devices. , With the aim of improving the quantum efficiency, researchers have made efforts to reduce carrier recombination and separate electron–hole pairs effectively via construction of a heterojunction or preparation of high-quality polycrystalline perovskite thin films. − Herein, this work proposes quantum-dot-in-perovskite photodetectors with the aim of enhancing carrier utilization through reducing recombination loss and accelerating carrier transmission.…”

“…Figure c presents the signal recognition ability of photodetectors quantitatively in terms of linear dynamic range (LDR), which was estimated by detecting the photocurrent at the steady state under various incident optical power densities from 74.3 nW cm –2 to 14.7 mW cm –2 . The function of photocurrent density to the intensity of incident light can be expressed with the formula J ph ∝ P in α , where P in represents the power of the light and the value of α is ascribed to the complex processes of charge carrier generation and recombination . The best working device value of α for the SQDP and FPSI-only devices were estimated to be 0.92 and 0.76, respectively.…”

Achieving High Responsivity and Detectivity in a Quantum-Dot-in-Perovskite Photodetector

“…So far, though great progress has been made recently, the photoresponsivities of those reported self-powered perovskite photodetectors are still too low for practical applications. , This can be reflected by the low external quantum efficiency (EQE) values for those devices. , With the aim of improving the quantum efficiency, researchers have made efforts to reduce carrier recombination and separate electron–hole pairs effectively via construction of a heterojunction or preparation of high-quality polycrystalline perovskite thin films. − Herein, this work proposes quantum-dot-in-perovskite photodetectors with the aim of enhancing carrier utilization through reducing recombination loss and accelerating carrier transmission.…”

“…Figure c presents the signal recognition ability of photodetectors quantitatively in terms of linear dynamic range (LDR), which was estimated by detecting the photocurrent at the steady state under various incident optical power densities from 74.3 nW cm –2 to 14.7 mW cm –2 . The function of photocurrent density to the intensity of incident light can be expressed with the formula J ph ∝ P in α , where P in represents the power of the light and the value of α is ascribed to the complex processes of charge carrier generation and recombination . The best working device value of α for the SQDP and FPSI-only devices were estimated to be 0.92 and 0.76, respectively.…”

Achieving High Responsivity and Detectivity in a Quantum-Dot-in-Perovskite Photodetector

“…First, NBGs are suitable for applications in near infrared (NIR) devices ranging from imaging and sensing to communication. [2][3][4][5] Second, the carrier mobility is higher than that of wide band-gap materials, facilitating the development of high-speed devices and circuits. Numerous research studies have been devoted to NBG materials and their device applications.…”

Recent advances in single crystal narrow band-gap semiconductor nanomembranes and their flexible optoelectronic device applications: Ge, GeSn, InGaAs, and 2D materials

“…, black silicon (Si) and germanium (Ge)) effectively reduce the reflection in visible and near-infrared ranges, 10–12 leading to the development of high performance photonic and optoelectronic devices. 13–15 As reported recently, the textured surfaces have the potential to provide efficient antireflection capability in the MIR range. For example, Si nanowires displayed a low reflection below 10% in the wavelength range up to 15 μm.…”

A heavily doped germanium pyramid array for tunable optical antireflection in the broadband mid-infrared range