Determinação da corrente de escuro em fotodetectores de radiação infravermelha baseados em poços quânticos (QWIPs) / Dark current studies on Quantum Well Infrared Photodetectors (QWIPs)

Marcel Santos Claro

12 March 2013

Neste trabalho, foram estudados os modelos mais comuns para a descrição da corrente de escuro em fotodetectores baseados em poços quânticos (QWIPs). Foram também realizadas as alterações necessárias para tornar estes modelos independentes de ajustes experimentais, possibilitando assim a otimização dos dispositivos antes de sua fabricação. Estas simulações foram comparadas com os dados experimentais de amostras desenvolvidas em nosso laboratório para avaliar a qualidade do sistema de aquisição de curvas I x V recém-instalado, bem como dos dispositivos desenvolvidos. Analisando os resultados experimentais e teóricos, foi possível ainda identificar os diferentes regimes de transporte em cada temperatura e tensão aplicada. / In this work, we analyzed the most common models of the literature aiming to describe the dark current in quantum well based photodetectors (QWIPs), making the necessary changes to make them independent of experimental data, and enabling thus the optimization of the devices before they are fabricated. These simulations were compared to experimental data of sample grown in our laboratory to evaluate the quality of the I-V curve acquisition system recently installed, as well as the performance of the new devices being produced. By analyzing the experimental and theoretical results, it was still possible to identify the different transport regimes at each temperature and applied voltage.

Dark Current

Infrared

Photodetector

Quantum Well

Desenvolvimento do cristal semicondutor de Brometo de Tálio para aplicações como detector de radiação e fotodetector / Development of TIBr semiconductor crystal for applications as radiation detector and photodetector

Icimone Braga de Oliveira

21 February 2006

Neste trabalho, os cristais de TlBr foram crescidos pelo método de Bridgman, a partir de materiais purificados pela técnica de fusão zonal. A eficiência da purificação e avaliação da superfície cristalina em relação ao desempenho como detectores de radiação foi observada. Bons resultados foram obtidos com os aprimoramentos realizados nos processos de purificação, crescimento de cristais e na fabricação dos detectores. A resposta à radiação foi verificada excitando os detectores com fontes de raios gama: 241Am (59 keV), 133Ba (80 e 355 keV), 57Co (122 keV), 22Na (511 keV) e 137Cs (662 keV) à temperatura ambiente. Os valores de resolução em energia mais satisfatórios encontrados nesse trabalho foram a partir de detectores mais puros. Os melhores valores de resolução em energia obtidos foram de 10keV (16%), 12keV (15%), 12keV (10%), 28 keV (8%), 31keV (6%) e 36keV (5%) para as energias de 59, 80, 122, 355, 511 e 662 keV, respectivamente. Também foi realizado um estudo da resposta à detecção a uma temperatura de -20ºC e da estabilidade desses detectores. Nos detectores desenvolvidos não houve diferença significativa na resolução tanto em temperatura ambiente quanto na reduzida. Em relação à estabilidade foi observada uma degradação das características espectrométricas sob operação contínua do detector a temperatura ambiente e esta instabilidade variou para cada detector. Ambas características também foram observadas por outros autores. A viabilidade de utilização do cristal de TlBr como fotodetector para acoplamento em cintiladores também foi estudada neste trabalho. TlBr é um material promissor para ser utilizado como fotodetector devido a sua adequada eficiência quântica na região de 350 a aproximadamente 500 nm. Como uma aplicação para este trabalho foram iniciados estudos para fabricação de sondas cirúrgicas utilizando cristais de TlBr como o meio detector. / In this work, TlBr crystals were grown by the Bridgman method from zone melted materials. The influence of the purification efficiency and the crystalline surface quality on the crystal were studied, evaluating its performance as a radiation detector. Due to significant improvement in the purification and crystals growth, good results have been obtained for the developed detectors. The spectrometric performance of the TlBr detector was evaluated by 241Am (59 keV), 133Ba (80 e 355 keV), 57Co (122 keV), 22Na (511 keV) and 137Cs (662 keV) at room temperature. The best energy resolution results were obtained from purer detectors. Energy resolutions of 10keV (16%), 12keV (15%), 12keV (10%), 28keV (8%), 31keV (6%) and 36keV (5%) to 59, 80, 122, 355, 511 and 662 keV energies, respectively, were obtained. A study on the detection response at -20ºC was also carried out, as well as the detector stability in function of the time. No significant difference was observed in the energy resolution between measurements at both temperatures. It was observed that the detector instability causes degradation of the spectroscopic characteristics during measurements at room temperature and the instability varies for each detector. This behavior was also verified by other authors. The viability to use the developed TlBr crystal as a photodetector coupled to scintillators crystals was also studied in this work. Due to its quantum efficiency in the region from 350 to 500 nm, TlBr shows to be a promising material to be used as a photodetector. As a possible application of this work, the development of a surgical probe has been initiated using the developed TlBr crystal as the radiation detector of the probe.

Brometo de talio

cristal semicondutor

detector de radiação

fotodetector

photodetector

radiation detector

semiconductor crystal

Thallium bromide

Desenvolvimento do cristal semicondutor de Brometo de Tálio para aplicações como detector de radiação e fotodetector / Development of TIBr semiconductor crystal for applications as radiation detector and photodetector

Oliveira, Icimone Braga de

21 February 2006

Neste trabalho, os cristais de TlBr foram crescidos pelo método de Bridgman, a partir de materiais purificados pela técnica de fusão zonal. A eficiência da purificação e avaliação da superfície cristalina em relação ao desempenho como detectores de radiação foi observada. Bons resultados foram obtidos com os aprimoramentos realizados nos processos de purificação, crescimento de cristais e na fabricação dos detectores. A resposta à radiação foi verificada excitando os detectores com fontes de raios gama: 241Am (59 keV), 133Ba (80 e 355 keV), 57Co (122 keV), 22Na (511 keV) e 137Cs (662 keV) à temperatura ambiente. Os valores de resolução em energia mais satisfatórios encontrados nesse trabalho foram a partir de detectores mais puros. Os melhores valores de resolução em energia obtidos foram de 10keV (16%), 12keV (15%), 12keV (10%), 28 keV (8%), 31keV (6%) e 36keV (5%) para as energias de 59, 80, 122, 355, 511 e 662 keV, respectivamente. Também foi realizado um estudo da resposta à detecção a uma temperatura de -20ºC e da estabilidade desses detectores. Nos detectores desenvolvidos não houve diferença significativa na resolução tanto em temperatura ambiente quanto na reduzida. Em relação à estabilidade foi observada uma degradação das características espectrométricas sob operação contínua do detector a temperatura ambiente e esta instabilidade variou para cada detector. Ambas características também foram observadas por outros autores. A viabilidade de utilização do cristal de TlBr como fotodetector para acoplamento em cintiladores também foi estudada neste trabalho. TlBr é um material promissor para ser utilizado como fotodetector devido a sua adequada eficiência quântica na região de 350 a aproximadamente 500 nm. Como uma aplicação para este trabalho foram iniciados estudos para fabricação de sondas cirúrgicas utilizando cristais de TlBr como o meio detector. / In this work, TlBr crystals were grown by the Bridgman method from zone melted materials. The influence of the purification efficiency and the crystalline surface quality on the crystal were studied, evaluating its performance as a radiation detector. Due to significant improvement in the purification and crystals growth, good results have been obtained for the developed detectors. The spectrometric performance of the TlBr detector was evaluated by 241Am (59 keV), 133Ba (80 e 355 keV), 57Co (122 keV), 22Na (511 keV) and 137Cs (662 keV) at room temperature. The best energy resolution results were obtained from purer detectors. Energy resolutions of 10keV (16%), 12keV (15%), 12keV (10%), 28keV (8%), 31keV (6%) and 36keV (5%) to 59, 80, 122, 355, 511 and 662 keV energies, respectively, were obtained. A study on the detection response at -20ºC was also carried out, as well as the detector stability in function of the time. No significant difference was observed in the energy resolution between measurements at both temperatures. It was observed that the detector instability causes degradation of the spectroscopic characteristics during measurements at room temperature and the instability varies for each detector. This behavior was also verified by other authors. The viability to use the developed TlBr crystal as a photodetector coupled to scintillators crystals was also studied in this work. Due to its quantum efficiency in the region from 350 to 500 nm, TlBr shows to be a promising material to be used as a photodetector. As a possible application of this work, the development of a surgical probe has been initiated using the developed TlBr crystal as the radiation detector of the probe.

Brometo de talio

cristal semicondutor

detector de radiação

fotodetector

photodetector

radiation detector

semiconductor crystal

Thallium bromide

Search for heavy Majorana neutrinos in pp collisions at √s = 8 TeV with the CMS detector & photodetector and calorimeter R&D for particle colliders.

Tiras, Emrah

01 January 2017

This thesis contains both physics analysis and hardware studies. It consists of two primary sections: the results of a search for heavy Majorana mass neutrinos, using the event signature of same (like) sign charged electron pairs ($e^{\pm} e^{\pm}$ ) and two jets, and the results of studies to upgrade the Hadronic Forward (HF) and Hadronic Endcap (HE) subdetectors in the Compact Muon Solenoid (CMS) detector in response to the high intensity proton-proton collisions generated at the Large Hadron Collider (LHC) at European Organization for Nuclear Research (CERN, Conseil Europ\'{e}en pour la Recherche Nucl\'{e}aire). In this search for Majorana mass neutrinos, same sign dielectron ($e^{\pm} e^{\pm}$) + dijet events in the final state have been considered as a signature for neutrino particles. The analyzed data corresponds to an integrated luminosity of 19.7 fb\textsuperscript{-1} of proton-proton collisions at a center of mass energy of \begin{math}\sqrt{s} = 8\ TeV \end{math}, collected using the CMS detector during the 2012 operation at the LHC. Monte Carlo simulations accounting for the theoretical expectations of the Standard Model (SM) and the detector limitations are used to prototype the experiment and to test proposed analysis steps. No excess of events is observed in the data beyond the expected SM background. Upper limits are set on the mixing element squared, $|{V}_{eN}|^{2}$, of the heavy Majorana neutrino with standard model neutrinos, as a function of Majorana neutrino mass for masses in the range of 40-500 $GeV/c^2$. The detector upgrade search comprises three sections of this thesis. The first section describes the test results of 1785 multianode Hamamatsu R7600U-200-M4 photomultiplier tubes (PMT) in numerous parameters such as gain, dark current, and timing characteristics, which provide insights on the expected performance of the upgraded CMS-HF detector. These PMTs replaced the previous single anode R7525 PMTs because the glass windows of previous PMTs are the source of Cherenkov radiation, which causes a background noise in the experiment. The second section reports characterization results of two types of PMTs in a novel operation mode for Secondary Emission (SE) Ionization Calorimetry, which is a novel technique to measure electromagnetic shower particles in extreme radiation environments. The third section presents the test results of novel scintillating materials for CMS experiment in specific and future particle accelerators in general. These materials are Polyethylene Naphthalate (PEN), Polyethylene Terephthalate (PET), high efficiency mirror (HEM) and quartz plates with various organic and inorganic coating materials such as p-Terphenyl (pTp), Anthracene and Gallium-doped Zinc Oxide (ZnO:Ga). We have investigated them for radiation hardness, light yield, timing characteristics, and scintillation and transmission properties.

Calorimeter

Majorana neutrino

Photodetector

Photomultiplier Tubes

Physics

SiGeC Near Infrared Photodetectors

Li, Baojun, Chua, Soo-Jin, Fitzgerald, Eugene A., Leitz, Christopher W., Miao, Lingyun

01 1900

A near infrared waveguide photodetector in Si-based ternary Si₁−x−yGexCy alloy was demonstrated for 0.85~1.06 µm wavelength fiber-optic interconnection system applications. Two sets of detectors with active absorption layer compositions of Si₀.₇₉Ge₀.₂C₀.₀₁ and Si₀.₇₀Ge₀.₂₈C₀.₀₂ were designed. The active absorption layer has a thickness of 120~450 nm. The external quantum efficiency can reach ~3% with a cut-off wavelength of around 1.2 µm. / Singapore-MIT Alliance (SMA)

photodetector

quantum efficiency

absorption coefficient

absorption efficiency

band gap

lattice constant

critical thickness

SiGeC

semiconductor

alloy

Near-infrared photodetectors based on Si/SiGe nanostructures

Elfving, Anders

January 2006

Two types of photodetectors containing Ge/Si quantum dots have been fabricated based on materials grown by molecular beam epitaxy and characterized with several experimental techniques. The aim was to study new device architectures with the implementation of Ge nanostructures, in order to obtain high detection efficiency in the near infrared range at room temperature. Heterojunction bipolar phototransistors were fabricated with 10 Ge dot layers in the base-collector (b-c) junction. With the illumination of near infrared radiation at 1.31 to 1.55 µm, the incident light would excite the carriers. The applied field across the b-c junction caused hole transport into the base, leading to a reduced potential barrier between the emitter-base (e-b) junction. Subsequently, this resulted in enhanced injection of electrons across the base into the collector, i.e., forming an amplified photo-induced current. We have therefore obtained significantly enhanced photo-response for the Ge-dot based phototransistors, compared to corresponding quantum dot p-i-n photodiodes. Responsivity values up to 470 mA/W were measured at 1.31 µm using waveguide geometry, and ∼2.5 A/W at 850 nm, while the dark current was as low as 0.01 mA/cm2 at –2 V. Metal-oxide field-effect phototransistors were also studied. These lateral detectors were processed with three terminals for source, drain and gate contacts. The Ge quantum dot layers were sandwiched between pseudomorphically grown SiGe quantum wells. The detector devices were processed using a multi-finger comb structure with an isolated gate contact on top of each finger and patterned metal contacts on the side edges for source and drain. It was found that the photo-responsivity was increased by a factor of more than 20 when a proper gate bias was applied. With VG above threshold, the measured response was 350 and >30 mA/W at 1.31 and 1.55 µm, respectively. Properties of Si/Si1-xGex nanostructures were examined, in order to facilitate proper design of the above mentioned transistor types of photodetectors. The carrier recombination processes were characterized by photoluminescence measurements, and the results revealed a gradual change from spatially indirect to direct transitions in type II Si1-xGex islands with increased measurement temperature. Energy dispersive X-ray spectrometry of buried Ge islands produced at different temperatures indicated a gradual decrease of the Ge concentration with temperature, which was due to the enhanced intermixing of Si and Ge atoms. At a deposition temperature of 730°C the Ge concentration was as low as around 40 %. Finally, the thermal stability of the Si/SiGe(110) material system, which is a promising candidate for future CMOS technology due to its high carrier mobility, was investigated by high resolution X-ray diffraction reciprocal space mapping. Anisotropic strain relaxation was observed with maximum in-plane lattice mismatch in the [001] direction. / On the day of the defence date the status of article IV was Manuscript and the title was "A three-terminal Ge dot/SiGe quantum well MOSFET photodetector for near infrared light detection"; the status of article VI was Submitted and the title was "Band alignment studies in Si/Ge quantum dots based on optical and structural investigations"; the status of article VII was Manuscript and the title was "Thermal stability of SiGe/Si(110) investigated by high-resolution X-ray diffraction reciprocal space mapping".

SiGe

Ge dots

nanostructures

molecular beam epitaxy

photodetector

Semiconductor physics

Halvledarfysik

Type-II interband quantum dot photodetectors

Gustafsson, Oscar

January 2013

Photon detectors based on single-crystalline materials are of great interest for high performance imaging applications due to their low noise and fast response. The major detector materials for sensing in the long-wavelength infrared (LWIR) band (8-14 µm) are currently HgCdTe (MCT) and AlGaAs/GaAs quantum wells (QW) used in intraband-based quantum-well infrared photodetectors (QWIPs). These either suffer from compositional variations that are detrimental to the system performance as in the case of MCT, or, have an efficient dark current generation mechanism that limits the operating temperature as for QWIPs. The need for increased on-wafer uniformity and elevated operating temperatures has resulted in the development of various alternative approaches, such as type-II strained-layer superlattice detectors (SLSs) and intraband quantum-dot infrared photodetectors (QDIPs). In this work, we mainly explore two self-assembled quantum-dot (QD) materials for use as the absorber material in photon detectors for the LWIR, with the aim to develop low-dark current devices that can allow for high operating temperatures and high manufacturability. The detection mechanism is here based on type-II interband transitions from bound hole states in the QDs to continuum states in the matrix material. Metal-organic vapor-phase epitaxy (MOVPE) was used to fabricate (Al)GaAs(Sb)/InAs and In(Ga)Sb/InAs QD structures for the development of an LWIR active material. A successive analysis of (Al)GaAs(Sb) QDs using absorption spectroscopy shows strong absorption in the range 6-12 µm interpreted to originate in intra-valence band transitions. Moreover, record-long photoluminescence (PL) wavelength up to 12 µm is demonstrated in InSb- and InGaSb QDs. Mesa-etched single-pixel photodiodes were fabricated in which photoresponse is demonstrated up to 8 µm at 230 K with 10 In0.5Ga0.5Sb QD layers as the active region. The photoresponse is observed to be strongly temperature-dependent which is explained by hole trapping in the QDs. In the current design, the photoresponse is thermally limited at typical LWIR sensor operating temperatures (60-120 K), which is detrimental to the imaging performance. This can potentially be resolved by selecting a matrix material with a smaller barrier for thermionic emission of photo-excited holes. If such an arrangement can be achieved, type-II interband InGaSb QD structures can turn out to be interesting as a high-operating-temperature sensor material for thermal imaging applications. / <p>QC 20130521</p>

photodetector

quantum dot

infrared

MOVPE

thermal imaging

type-II

photoluminescence

III/V

InSb

InGaSb

InAs

Exciton-plasmon interactions in metal-semiconductor nanostructures

Hellström, Staffan

January 2012

Semiconductor quantum dots and metal nanoparticles feature very strong light-matter interactions, which has led to their use in many photonic applications such as photodetectors, biosensors, components for telecommunications etc.Under illumination both structures exhibit collective electron-photon resonances, described in the frameworks of quasiparticles as exciton-polaritons for semiconductors and surface plasmon-polaritons for metals.To date these two approaches to controlling light interactions have usually been treated separately, with just a few simple attempts to consider exciton-plasmon interactions in a system consisting of both semiconductor and metal nanostructures.In this work, the exciton-polaritons and surface \\plasmon-polaritons are first considered separately, and then combined using the Finite Difference Time Domain numerical method coupled with a master equation for the exciton-polariton population dynamics.To better understand the properties of excitons and plasmons, each quasiparticle is used to investigate two open questions - the source of the Stokes shift between the absorption and luminescence peaks in quantum dots, and the source of the photocurrent increase in quantum dot infrared photodetectors coated by a thin metal film with holes. The combined numerical method is then used to study a system consisting of multiple metal nanoparticles close to a quantum dot, a system which has been predicted to exhibit quantum dot-induced transparency, but is demonstrated to just have a weak dip in the absorption. / <p>QC 20120417</p>

plasmons

excitons

quantum dots

nanoparticles

FDTD

surface plasmon polaritons

QDIP

quantum dot infrared photodetector

polaritons

Colloidal Quantum Dot Schottky Barrier Photodetectors

Clifford, Jason Paul

19 January 2009

Herein, we report the first solution-processed broadband photodetectors to break the past compromise between sensitivity and speed of response. Specifically, we report photodiodes having normalized detectivity (D*) > 1012 Jones and a 3dB bandwidth of > 2.9 MHz. This finding represents a 170,000 fold improvement in response speed over the most sensitive colloidal quantum dot (CQD) photodetector reported1 and a 100,000 fold improvement in sensitivity over the fastest CQD photodetector reported2. At the outset of this study, sensitive, solution-processed IR photodetectors were severely limited by low response speeds1. Much faster response speeds had been demonstrated by solution-processed photodetectors operating in the visible3, but these devices offered no benefits for extending the spectral sensitivity of silicon. No available solution-processed photodetector combined high sensitivity, high operating speed, and response to illumination across the UV, visible and IR. We developed a fast, sensitive, solution-processed photodetector based on a photodiode formed by a Schottky barrier to a CQD film. Previous attempts to form sensitive photodetectors based on CQD photodiodes had demonstrated low quantum efficiencies that limited sensitivity4,5. Efficient, sensitive semiconductor photodiodes are based on two fundamental characteristics: a large built-in potential that separates photogenerated charge carriers and minimizes internal noise generation, and high semiconductor conductivity for efficient collection of photogenerated charge. Schottky barriers to CQD films were developed to provide high, uniform built-in potentials. A multi-step CQD ligand exchange procedure was developed to allow deposition of tightly packed films of CQDs with high mobility and sufficiently well-passivated surfaces to form high-quality metallurgical junctions. The temporal response of the CQD photodiodes showed separate drift and diffusion components. Combined with detailed measurements of the Schottky barrier, these characteristics provided the physical basis for a numerical model of device operation. Based on this understanding, devices that excluded the slow diffusive component were fabricated, exploiting only the sub-microsecond field-driven transient to achieve MHz response bandwidth. These devices are the first to combine megahertz-bandwidth, high sensitivity, and spectral-tunability in photodetectors based on semiconducting CQDs. Record performance is achieved through advances in materials and device architecture based on a detailed understanding the physical mechanisms underlying the operation of CQD photodiodes.

nanotechnology

Schottky barrier

nanocrystal

colloidal quantum dot

solution processed semiconductor

optoelectronic

photovoltaic

photodetector

0544

Colloidal Quantum Dot Schottky Barrier Photodetectors

Clifford, Jason Paul

19 January 2009

Herein, we report the first solution-processed broadband photodetectors to break the past compromise between sensitivity and speed of response. Specifically, we report photodiodes having normalized detectivity (D*) > 1012 Jones and a 3dB bandwidth of > 2.9 MHz. This finding represents a 170,000 fold improvement in response speed over the most sensitive colloidal quantum dot (CQD) photodetector reported1 and a 100,000 fold improvement in sensitivity over the fastest CQD photodetector reported2. At the outset of this study, sensitive, solution-processed IR photodetectors were severely limited by low response speeds1. Much faster response speeds had been demonstrated by solution-processed photodetectors operating in the visible3, but these devices offered no benefits for extending the spectral sensitivity of silicon. No available solution-processed photodetector combined high sensitivity, high operating speed, and response to illumination across the UV, visible and IR. We developed a fast, sensitive, solution-processed photodetector based on a photodiode formed by a Schottky barrier to a CQD film. Previous attempts to form sensitive photodetectors based on CQD photodiodes had demonstrated low quantum efficiencies that limited sensitivity4,5. Efficient, sensitive semiconductor photodiodes are based on two fundamental characteristics: a large built-in potential that separates photogenerated charge carriers and minimizes internal noise generation, and high semiconductor conductivity for efficient collection of photogenerated charge. Schottky barriers to CQD films were developed to provide high, uniform built-in potentials. A multi-step CQD ligand exchange procedure was developed to allow deposition of tightly packed films of CQDs with high mobility and sufficiently well-passivated surfaces to form high-quality metallurgical junctions. The temporal response of the CQD photodiodes showed separate drift and diffusion components. Combined with detailed measurements of the Schottky barrier, these characteristics provided the physical basis for a numerical model of device operation. Based on this understanding, devices that excluded the slow diffusive component were fabricated, exploiting only the sub-microsecond field-driven transient to achieve MHz response bandwidth. These devices are the first to combine megahertz-bandwidth, high sensitivity, and spectral-tunability in photodetectors based on semiconducting CQDs. Record performance is achieved through advances in materials and device architecture based on a detailed understanding the physical mechanisms underlying the operation of CQD photodiodes.

nanotechnology

Schottky barrier

nanocrystal

colloidal quantum dot

solution processed semiconductor

optoelectronic

photovoltaic

photodetector

0544