Thin-film quantum dot photodiode for monolithic infrared image sensors

Imaging in the infrared wavelength range has been fundamental in scientific, military and surveillance applications. Currently, it is a crucial enabler of new industries such as autonomous mobility (for obstacle detection), augmented reality (for eye tracking) and biometrics. Ubiquitous deployment of infrared cameras (on a scale similar to visible cameras) is however prevented by high manufacturing cost and low resolution related to the need of using image sensors based on flip-chip hybridization. One way to enable monolithic integration is by replacing expensive, small-scale III-V-based detector chips with narrow bandgap thin-films compatible with 8- and 12-inch full-wafer processing. This work describes a CMOS-compatible pixel stack based on lead sulfide quantum dots (PbS QD) with tunable absorption peak. Photodiode with a 150-nm thick absorber in an inverted architecture shows dark current of 10(-6) A/cm(2) at 2 V reverse bias and EQE above 20% at 1440 nm wavelength. Optical modeling for top illumination architecture can improve the contact transparency to 70%. Additional cooling (193 K) can improve the sensitivity to 60 dB. This stack can be integrated on a CMOS ROIC, enabling order-of-magnitude cost reduction for infrared sensors

Optimization of charge carrier extraction in colloidal quantum dots short-wave infrared photodiodes through optical engineering

Colloidal quantum dots (QDs) have attracted scientific interest for infrared (IR) optoelectronic devices due to their bandgap tunability and the ease of fabrication on arbitrary substrates. In this work, short-wave IR photodetectors based on lead sulfide (PbS) QDs with high detectivity and low dark current is demonstrated. Using a combination of time-resolved photoluminescence, carrier transport, and capacitance-voltage measurements, it is proved that the charge carrier diffusion length in the QD layer is negligible such that only photogenerated charges in the space charge region can be collected. To maximize the carrier extraction, an optical model for PbS QD-based photodiodes is developed, and through optical engineering, the cavity at the wavelength of choice is optimized. This universal optimization recipe is applied to detectors sensitive to wavelengths above 1.4 mu m, leading to external quantum efficiency of 30% and specific detectivity (D*) in the range of 10(12) Jones

Energy Level Tuning of Non-fullerene Acceptors in Organic Solar Cells

This document is the unedited author's version of a Submitted Work that was subsequently accepted for publication in Journal of the American Chemical Society , copyright © American Chemical Society after peer review. To access the final edited and published work, see http://pubs.acs.org/doi/abs/10.1021/jacs.5b02808The use of non-fullerene acceptors in organic photovoltaic devices could lead to enhanced efficiencies due to increased open-circuit voltages (VOC) and improved absorption of solar light. Here we systematically investigate planar heterojunction devices comprising peripherally substituted subphthalocyanines as acceptor, and correlate device performance with heterojunction energetics. Due to a balance between VOC and photocurrent, tuning of the interface energy gap is necessary to optimize power conversion efficiency in these devices. In addition, we explore the role of the charge transport layers in the device architecture. It is found that non-fullerene acceptors require adjusted buffer layers with aligned electron transport levels to enable efficient charge extraction, while the insertion of an exciton blocking layer at the anode interface further boosts photocurrent generation. These adjustments result in a planar heterojunction OPV device with 6.9% efficiency and a VOC above 1 V.The research leading to these results has received funding from the European Community’s Seventh Framework Programme (FP7/2007-2013) under grant agreement 287818 of the X10D project and from the European Community’s ERC Advanced Grant # 320680 (EPOS CRYSTALLI). This work is also supported by the Spanish MINECO (CTQ-2014-52869-P) and Comunidad de Madrid (S2013/MIT-2841, FOTOCARBON

Monolithic near infrared image sensors enabled by quantum dot photodetector

status: publishe

Near-field interactions between metal nanoparticle surface plasmons and molecular excitons in thin-films: part I: absorption

In this and the following paper (parts I and II, respectively), we systematically study the interactions between surface plasmons of metal nanoparticles (NPs) with excitons in thin-films of organic media. In an effort to exclusively probe near-field interactions, we utilize spherical Ag NPs in a size-regime where far-field light scattering is negligibly small compared to absorption. In part I, we discuss the effect of the presence of these Ag NPs on the absorption of the embedding medium by means of experiment, numerical simulations, and analytical calculations, all shown to be in good agreement. We observe absorption enhancement in the embedding medium due to the Ag NPs with a strong dependence on the medium permittivity, the spectral position relative to the surface plasmon resonance frequency, and the thickness of the organic layer. By introducing a low index spacer layer between the NPs and the organic medium, this absorption enhancement is experimentally confirmed to be a near field effect In part II, we probe the impact of the Ag NPs on the emission of organic molecules by time-resolved and steady-state photoluminescence measurements

Transformations agricoles et agroalimentaires

À l’heure des robots et du numérique, la terre (habitat, agriculture, paysage, planète) et la nourriture (du corps et de l’âme) sont parmi les préoccupations majeures dans les espaces médiatiques et politiques. Le pétrole et l’abondance qui l’a accompagné nous avaient fait oublier qu’elles sont au fondement des sociétés humaines. La « crise alimentaire » de 2008, qui a secoué plusieurs continents, a rappelé aux gouvernements l’enjeu de la sécurité alimentaire. Après des décennies d’excédents, de baisse du prix des produits agricoles de base, la question de la valeur de la terre et de l’agriculture est de retour. La question de la santé et celle des droits humains prennent une place élargie tant dans les politiques publiques et dans la production de normes alimentaires. Des mouvements sociaux transnationaux s’emparent de la question de l’avenir de l’agriculture et de l’alimentation, et de celle de la « bonne vie ». Pour contribuer à cette réflexion sur l’avenir de la terre et de la nourriture, cet ouvrage étudie la socialisation de l’agriculture, c’est-à-dire sa prise en charge tant par les politiques agricoles (essentiellement nationales) que par l’organisation des marchés dans un cadre national et international. Il le fait en prenant un large recul et mobilise trois temporalités. La première est celle de la planète. La seconde, celle des régimes métaboliques, façons dont l’humanité à différents stades de développement, mobilise matériaux et énergie. La troisième est celle du capitalisme, avec la succession de systèmes hégémoniques (ce qui n’exclue pas de multiples polarités). Cet ouvrage réunit des recherches récentes d’économistes, de sociologues, d’historiens et d’agronomes, de différents pays, recherches qui ont en commun de concerner la place de l’agriculture dans l’évolution des capitalismes

Large-area compatible fabrication and optimization of micropump aided by vorticity-based algorithm

status: publishe

Strategies for Increasing the Efficiency of Heterojunction Organic Solar Cells: Material Selection and Device Architecture

Thin-film blends or bilayers of donor- and acceptor-type organic semiconductors form the core of heterojunction organic photovoltaic cells. Researchers measure the quality of photovoltaic cells based on their power conversion efficiency, the ratio of the electrical power that can be generated versus the power of incident solar radiation. The efficiency of organic solar cells has increased steadily in the last decade, currently reaching up to 6%. Understanding and combating the various loss mechanisms that occur in processes from optical excitation to charge collection should lead to efficiencies on the order of 10% in the near future.status: publishe

Carrier Mobility, Lifetime, and Diffusion Length in Optically Thin Quantum Dot Semiconductor Films

We propose a method to measure the fundamental parameters that govern diffusion transport in optically thin quantum dot semiconductor films and apply it to quantum dot materials with different ligands. Thin films are excited optically, and the profile of photogenerated carriers is modeled using diffusion-based transport equations and taking into account the optical cavity effects. Correlation with steady-state photoluminescence experiments on different stacks comprising a quenching layer allows the extraction of the carrier diffusion length accurately from the experimental data. In the time domain, the mapping of the transient PL data with the solutions of the time-dependent diffusion equation leads to accurate calculations of the photogenerated carrier mobility. These findings allow the estimation of the speed limitations for diffusion-based transport in QD absorbers.status: publishe