Novas tecnologias para detecção infravermelha de alto desempenho / Novel Technologies for High Performance Infrared Detection

Claro, Marcel Santos

26 June 2017

Neste trabalho, foi estudado a aplicação de novas heteroestruturas semicondutoras para detecção de radiação na região do infravermelho médio. Pontos quânticos de submonocamada, detectores de cascateamento quântico e pontos quânticos de InAlAs foram testados como opção para corrigir as deficiências em responsividade, corrente de escuro e temperatura de operação, comuns nas heteroestruturas convencionais baseadas em poços quânticos e pontos quânticos de InAs obtidos no regime de crescimento Stranski-Krastanov. Também foi projetado, fabricado e testado um circuito eletrônico de leitura de sinal misto para integração com matrizes de sensores e produção de imagens. Esse tipo de circuito possui uma série de vantagens em relação aos dispositivos convencionais que costumam ser completamente analógicos. / In this work, we studied the application of new types of semiconductor heterostructures for mid-infrared detection. Submonolayer quantum dots (SML-QDs), quantum-cascade detectors (QCDs) and InAlAs quantum dots were tested as an option to circumvent the common shortcomings of responsivity, dark current and operating temperature of the usual heterestructures based on quantum wells (QWs) and InAs Stranski-Krastanov quantum dots. We also designed, fabricated and tested a mixed-signal read-out circuit aiming the fabrication of focalplane arrays (FPAs) for applications to infrared imaging. This kind of architecture has several advantages over a fully analog design.

circuito de leitura

detector de cascateamento quântico

detectores infravermelhos

epitaxia

epitaxy

infrared photodetector

ponto quântico

quantum dot

quantum-cascade detector

read-out circuit.

submonocamada

submonolayer

Transitions intersousbandes dans les puits quantiques GaN/AlN du proche infrarouge au THz / Intersubband transitions in the GaN/AlN quantum wells in the near infrared to THz frequency

Machhadani, Houssaine

28 March 2011

Les transitions intersousbandes dans les hétérostructures de nitrure d’éléments III ont été intensément étudiées dans le proche infrarouge pour des applications télécoms. L’accordabilité dans le proche infrarouge est rendu possible grâce à la discontinuité de potentiel en bande de conduction qui peut atteindre 1.75 eV pour le système GaN/AlN. Les matériaux nitrures suscitent actuellement un grand intérêt à plus grande longueur d'onde infrarouge. C'est par exemple le développement de détecteurs et d'imageurs rapides à cascade quantique dans la gamme 2-5 µm. C'est aussi l'extension des dispositifs intersousbandes dans le domaine de fréquences THz. Ce travail de thèse porte sur l’étude des transitions intersousbandes dans les puits quantiques GaN/Al(Ga)N épitaxiés par jets moléculaires. Le but est d’accorder ces transitions dans une gamme spectrale très large allant du proche au lointain infrarouge. Je montre que les transitions ISB peuvent être accordées dans la gamme 1-12 µm dans les puits quantiques GaN/AlGaN en phase hexagonale synthétisés selon l'axe polaire c [0001]. Ceci impose l'ingénierie du champ électrique interne, dont la valeur peut atteindre dans le GaN 10 MV/cm. Une solution alternative consiste à utiliser une orientation particulière, dite semipolaire, qui conduit à une réduction du champ électrique interne le long de l'axe de croissance [11-22]. J’ai montré que cette réduction du champ interne permet d’accorder les résonances intersousbandes des puits quantiques GaN/AlN dans le proche infrarouge et j’ai pu estimer le champ en comparant les résultats de spectroscopie et simulations. J’ai d’autre part étudié les propriétés interbandes et intersousbandes des puits quantiques de symétrie cubique, qui par raison de symétrie, ne présentent pas de champ électrique interne. Finalement j’ai mis en évidence les premières transitions intersousbandes aux fréquences THz dans les puits quantiques GaN/AlGaN polaires mais aussi cubiques. / Most of the research on GaN-based intersubband transitions has been focused on near-infrared applications, benefiting from the large conduction band offset between GaN and AlN1.75 eV. Devices such as all-optical switches, electro-optical modulators, quantum cascadedetectors, or light emitters have been demonstrated at short infrared wavelengths. Nitridematerials are currently attracting a great interest at longer infrared wavelengths, for example, forthe development of high-speed quantum cascade detectors and imagers in the range 2-5 µm. Inaddition, there is a great interest to extend the operation of nitride intersubband devices to theTHz frequency range especially for the development of quantum cascade lasers operating at non-cryogenic temperature.This work is focused on the study of intersubband transitions in GaN/Al(Ga)N quantumwells grown by molecular beam epitaxy. The goal is to tune these transitions in a broad spectralrange, from near to far infrared. I show that intersubband transitions may be tuned withinthe range 1-12 µm in the polar GaN/AlGaN quantum wells. This requires the engineering of theinternal electric fields, which can be as high as 10 MV/cm in GaN/AlN quantum wells. Analternative approach is to use a particular orientation, known as semipolar, which leads toa reduction of the internal electric field along the growth axis [11-22]. I show that this reductionof the internal field induces a redshift of the intersubband energy allowing to reach the mid-infrared domain. I was able to estimate the electric field in semi-polar structures by comparingthe results of spectroscopy and simulations. I also investigate interband andintersubband optical properties of cubic GaN/AlN quantum wells, for which the internal field isabsent due to the high symmetry of the cubic crystal. Finally, I report the first observation of theintersubband absorption at terahertz frequencies in polar GaN/AlGaN step quantum wells andin cubic quantum wells.

Transitions intersousbandes

Puits quantiques

Nitrures d'éléments III

Spectroscopie THz

Détecteur à cascade quantique

Intersubband transitions

Quantum wells

GaN AlN

Spectroscopy THz

Quantum cascade detector

Novas tecnologias para detecção infravermelha de alto desempenho / Novel Technologies for High Performance Infrared Detection

Marcel Santos Claro

26 June 2017

Neste trabalho, foi estudado a aplicação de novas heteroestruturas semicondutoras para detecção de radiação na região do infravermelho médio. Pontos quânticos de submonocamada, detectores de cascateamento quântico e pontos quânticos de InAlAs foram testados como opção para corrigir as deficiências em responsividade, corrente de escuro e temperatura de operação, comuns nas heteroestruturas convencionais baseadas em poços quânticos e pontos quânticos de InAs obtidos no regime de crescimento Stranski-Krastanov. Também foi projetado, fabricado e testado um circuito eletrônico de leitura de sinal misto para integração com matrizes de sensores e produção de imagens. Esse tipo de circuito possui uma série de vantagens em relação aos dispositivos convencionais que costumam ser completamente analógicos. / In this work, we studied the application of new types of semiconductor heterostructures for mid-infrared detection. Submonolayer quantum dots (SML-QDs), quantum-cascade detectors (QCDs) and InAlAs quantum dots were tested as an option to circumvent the common shortcomings of responsivity, dark current and operating temperature of the usual heterestructures based on quantum wells (QWs) and InAs Stranski-Krastanov quantum dots. We also designed, fabricated and tested a mixed-signal read-out circuit aiming the fabrication of focalplane arrays (FPAs) for applications to infrared imaging. This kind of architecture has several advantages over a fully analog design.

circuito de leitura

detector de cascateamento quântico

detectores infravermelhos

epitaxia

ponto quântico

submonocamada

epitaxy

infrared photodetector

quantum dot

quantum-cascade detector

read-out circuit.

submonolayer