Riccardo Ollearo scite author profile

Metal halide perovskite photodiodes (PPDs) offer high responsivity and broad spectral sensitivity, making them attractive for low-cost visible and near-infrared sensing. A significant challenge in achieving high detectivity in PPDs is lowering the dark current density (JD) and noise current (in). This is commonly accomplished using charge-blocking layers to reduce charge injection. By analyzing the temperature dependence of JD for lead-tin based PPDs with different bandgaps and electron-blocking layers (EBL), we demonstrate that while EBLs eliminate electron injection, they facilitate undesired thermal charge generation at the EBL-perovskite interface. The interfacial energy offset between the EBL and the perovskite determines the magnitude and activation energy of JD. By increasing this offset we realized a PPD with ultralow JD and in of 5 × 10−8 mA cm−2 and 2 × 10−14 A Hz−1/2, respectively, and wavelength sensitivity up to 1050 nm, establishing a new design principle to maximize detectivity in perovskite photodiodes.

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A thin and flexible scanner for fingerprints and documents based on metal halide perovskites

Breemen

Ollearo

Shanmugam

et al. 2021

Nat Electron

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Effect of Co‐Solvents on the Crystallization and Phase Distribution of Mixed‐Dimensional Perovskites

Caiazzo

Datta

Jiang

et al. 2021

Advanced Energy Materials

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Solution‐processed quasi‐2D perovskites are promising for stable and efficient solar cells because of their superior environmental stability compared to 3D perovskites and tunable optoelectronic properties. Changing the number of inorganic layers (n) sandwiched between the organic spacers allows for tuning of the bandgap. However, narrowing the phase distribution around a specific n‐value is a challenge. In‐situ UV–vis–NIR absorption spectroscopy is used to time‐resolve the crystallization dynamics of quasi‐2D butylammonium‐based (BA) perovskites with = 4, processed from N,N‐dimethylformamide (DMF) in the presence of different co‐solvents. By combining with photoluminescence, transient absorption, and grazing‐incidence wide‐angle X‐ray scattering, the crystallization is correlated to the distribution of phases with different n‐values. Infrared spectroscopy and density functional theory reveal that the phase distribution correlates with perovskite precursor—co‐solvent interaction energies and that stronger interactions shift the phase distribution towards smaller n‐values. Careful tuning of the solvent/co‐solvent ratio provides a more homogeneous phase distribution, with highly oriented perovskite crystals and suppressed formation of n = 1–2 phases, providing a power conversion efficiency for BA2MA3Pb4I13 solar cells that increases from 3.5% when processed from DMF to over 11% and 10% when processed from DMF/dimethyl sulfoxide and DMF/N‐methyl‐2‐pyrrolidone mixtures, respectively.

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Multidimensional Perovskites for High Detectivity Photodiodes

Ollearo

Caiazzo

et al. 2022

Advanced Materials

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Low‐dimensional perovskites attract increasing interest due to tunable optoelectronic properties and high stability. Here, it is shown that perovskite thin films with a vertical gradient in dimensionality result in graded electronic bandgap structures that are ideal for photodiode applications. Positioning low‐dimensional, vertically‐oriented perovskite phases at the interface with the electron blocking layer increases the activation energy for thermal charge generation and thereby effectively lowers the dark current density to a record‐low value of 5 × 10−9 mA cm−2 without compromising responsivity, resulting in a noise‐current‐based specific detectivity exceeding 7 × 1012 Jones at 600 nm. These multidimensional perovskite photodiodes show promising air stability and a dynamic range over ten orders of magnitude, and thus represent a new generation of high‐performance low‐cost photodiodes.

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Vitality surveillance at distance using thin-film tandem-like narrowband near-infrared photodiodes with light-enhanced responsivity

Ollearo

Akkerman

et al. 2023

Sci. Adv.

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Remote measurement of vital sign parameters like heartbeat and respiration rate represents a compelling challenge in monitoring an individual’s health in a noninvasive way. This could be achieved by large field-of-view, easy-to-integrate unobtrusive sensors, such as large-area thin-film photodiodes. At long distances, however, discriminating weak light signals from background disturbance demands superior near-infrared (NIR) sensitivity and optical noise tolerance. Here, we report an inherently narrowband solution–processed, thin-film photodiode with ultrahigh and controllable NIR responsivity based on a tandem-like perovskite-organic architecture. The device has low dark currents (<10 −6 mA cm −2 ), linear dynamic range >150 dB, and operational stability over time (>8 hours). With a narrowband quantum efficiency that can exceed 200% at 850 nm and intrinsic filtering of other wavelengths to limit optical noise, the device exhibits higher tolerance to background light than optically filtered silicon-based sensors. We demonstrate its potential in remote monitoring by measuring the heart rate and respiration rate from distances up to 130 cm in reflection.

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