Computational approaches for diffusive light transport: finite-elements, grid adaption, and error estimation

Sharp, Richard Paul, Jr.

20 September 2006

No description available.

Computer Science

computer graphics

subsurface scattering

near infrared light

finite elements

finite difference

Tunable Mid-Infrared Light Source Based on Difference Frequency Generation in Periodically Poled Lithium Niobate

Han, Ling

January 2007

<p> In this work, tunable Mid-Infrared (IR) light sources based on quasi-phase matched (QPM) difference frequency generation (DFG) by periodically poled lithium niobate (PPLN) crystals are studied. The theory of DFG and the characteristics of lithium niobate crystals are described and analyzed. Characteristics of the wavelength tuning of QPM DFG by PPLN crystals are studied. In order to analyze in detail, simulation and experimental data of the widely tunable mid-IR laser source around 2 1- μm to 5 1- μm wavelength are presented. The simulations of DFG process by PPLN are conducted based on the nonlinear optics reported. In the experiment, a 1.064 μm Nd:YAG laser and a tunable Ti:sapphire laser are employed as the signal and pump lasers, respectively. Based on the studies of the wavelength tuning characteristics at different temperatures, an optimization procedure to achieve a maximum wavelength tuning range is proposed. The potential applications in gas detection of the mid-IR source are also described briefly. Recommendation for future works and potential applications of the PPLN DFG based mid-IR lasers are discussed. </p> / Thesis / Master of Applied Science (MASc)

Mid-Infrared Light

Lithium Niobate

difference frequency generation

periodically poled lithium niobate

Frequency-domain diffuse optical spectroscopy for cardiovascular and respiratory applications

Istfan, Raeef Eric

15 May 2021

Frequency Domain Diffuse Optical Spectroscopy (FD-DOS) is an emerging optical technique that uses near infrared light to probe the hemodynamics of biological tissue. Compared to more common Continuous Wave (CW) methods, FD-DOS uses light that is temporally modulated on the order of MHz to quantify the absorption and scattering of tissue. FD-DOS can also be used to obtain absolute concentration of tissue chromophores such as oxy- and deoxy-hemoglobin, which allow for quantitative measurements of tissue hemodynamics. This dissertation focuses on the evolution of our lab’s custom digital FD-DOS as a platform for taking optical measurement of biological tissue for respiratory and cardiovascular applications. Several important instrumentation improvements will be reviewed that have enhanced the performance of the system while making it more portable and clinic ready. Two translational applications will be described in detail: 1) the use of high-speed FD-DOS for the non-invasive extraction of venous oxygen saturation (SvO2) and 2) the use of FD-DOS to monitor the hemodynamics of the sternocleidomastoid (SCM) muscle towards the non-invasive monitoring of patients on mechanical ventilation. The custom FD-DOS system parameters were adjusted for each application, with a focus on high speed to extract the cardiac signal for the SvO2 project, and a focus on high SNR to measure the highly absorbing SCM. Measurements on healthy volunteers and rabbits were used to assess the feasibility of using FD-DOS for these applications. Finally, preliminary work was conducted to characterize a miniature FD-DOS source and detector with the goal of moving towards a wearable version of FD-DOS. / 2022-05-15T00:00:00Z

Biomedical engineering

Hemoglobin

Monte Carlo

Near-infrared light

Sternocleidomastoid

Venous oxygen saturation

Photo-Induced Carrier Transfer in Heterostructured Semiconductor Nanocrystals for Solar Energy Conversion / 太陽光エネルギー変換を指向したヘテロ構造半導体ナノ結晶における光誘起キャリア移動プロセスの解明 / # ja-Kana

Lian, Zichao

25 September 2018

京都大学 / 0048 / 新制・課程博士 / 博士(理学) / 甲第21333号 / 理博第4429号 / 新制||理||1636(附属図書館) / 京都大学大学院理学研究科化学専攻 / (主査)教授 寺西 利治, 教授 倉田 博基, 教授 時任 宣博 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DGAM

Heterostructured nanocrystals

Plasmon-induced carrier transfer

Solar energy conversion

Photocatalytic Hydrogen evolution

Visible to infrared light

Transient absorption

400

Flow Cytometry Sensor System Targeting Escherichia Coli as an Indicator of Faecal Contamination of Water Sources

Benselfelt, Tobias

January 2014

Poor water quality is a global health concern affecting one billion people around the world. It is important to monitor water sources in order to maintain the quality of our drinking water and to avoid disease outbreaks. Targeting Escherichia coli as a faecal indicator is a widely used procedure, but the current methods are time consuming and not adequate to prevent spreading of faecal influence.   This Master thesis demonstrates the development of a near infrared fluorescence flow cytometer sensor system targeting Escherichia coli, using fluorescently labeled chicken IgY antibodies. The near infrared light was chosen to avoid fluorescence from blue-green algae that are present in the water source.   The hardware was developed with a 785  nm laser line to detect Alexa Fluor 790 labeled antibodies, using a photomultiplier tube or two different CMOS cameras. The antibodies were labeled using a commercial labeling kit, and evaluated using antibody binding assays and the developed hardware.   The IgY antibodies were successfully labeled with Alexa Fluor 790 and the function was maintained after the labeling process. The result demonstrates the principles of the sensor system and how it solved to the problem with fluorescence from blue-green algae. An aperture was used to overcome the suboptimal laser and filter setup, and to increase the sensitivity of the system. However, only a small fraction of the cells could be detected, due to challenges with the focal depth and loss of sensitivity in the photomultiplier tube at near infrared wavelengths. Further development is required to create a working product.

Sensor system

Water quality

Flow cytometry

Faecal contamination

Faecal indicator

Escherichia Coli

Untreated water

Near infrared light

NIR

Antibody

Immunoglobulin

IgY

Alexa Fluor 790

Photomultiplier tube

CMOS

camera.

Design and manufacture of nanometre-scale SOI light sources

Bogalecki, Alfons Willi

11 January 2010

To investigate quantum confinement effects on silicon (Si) light source electroluminescence (EL) properties like quantum efficiency, external power efficiency and spectral emission, thin Si finger junctions with nanometre-scale dimensions were designed and manufactured in a fully customized silicon-on-insulator (SOI) semiconductor production technology. Since commonly available photolithography is unusable to consistently define and align nanometre-scale line-widths accurately and electron-beam lithography (EBL) by itself is too time-expensive to expose complete wafers, the wafer manufacturing process employed a selective combination of photolithography and EBL. The SOI wafers were manufactured in the clean-rooms of both the Carl and Emily Fuchs Institute for Microelectronics (CEFIM) at the University of Pretoria (UP) and the Georgia Institute of Technology’s Microelectronic Research Centre (MiRC), which made a JEOL JBX-9300FS electron-beam pattern generator (EPG) available. As far as is known this was the first project in South Africa (and possibly at the MiRC) that employed EBL to define functional nanometre-scale semiconductor devices. Since no standard process recipe could be employed, the complete design and manufacturing process was based on self-obtained equipment characterization data and material properties. The manufacturing process was unprecedented in both the CEFIM and MiRC clean-rooms. The manufacture of nanometre-scale Si finger junctions not only approached the manufacturing limits of the employed processing machinery, but also had to overcome undesirable physical effects that in larger-scale semiconductor manufacture usually are negligible. The device design, mask layout and manufacturing process therefore had to incorporate various material, equipment limitation and physical phenomena like impurity redistribution occurring during the physical manufacturing process. Although the complicated manufacturing process allowed many unexpected problems to occur, it was expected that at least the simple junction breakdown devices be functional and capable of delivering data regarding quantum confinement effects. Although due to design and processing oversights only 29 out of 505 measured SOI light sources were useful light emitters, the design and manufacture of the SOI light sources was successful in the sense that enough SOI light sources were available to conduct useful optical characterization measurements. In spite of the fact that the functional light sources did not achieve the desired horizontal (width) confinement, measured optical spectra of certain devices indicate that vertical (thickness) confinement had been achieved. All spectrometer-measured thickness-confined SOI light sources displayed a pronounced optical power for 600 nm < λ < 1 μm. The SOI light source with the highest optical power output emitted about 8 times more optical power around λ = 850 nm than a 0.35 μm bulk-CMOS avalanche light-source operating at the same current. Possible explanations for this effect are given. It was shown that the buried oxide (BOX) layer in a SOI process could be used to reflect about 25 % of the light that would usually be lost to downward radiation back up, thereby increasing the external power efficiency of SOI light sources. This document elaborates on the technical objectives, approach, chip and process design, physical wafer manufacture, production process control and measurement of the nanometre-scale SOI light sources. Copyright / Dissertation (MEng)--University of Pretoria, 2010. / Electrical, Electronic and Computer Engineering / unrestricted

Electron-beam lithography

Impurity redistribution

Soi buried oxide light reflection

Soi wafer manufacture

Soi light sources

Silicon light source

Silicon electroluminescence

Silicon infrared light emission

Quantum confinement

Nanometre-scale soi

UCTD

Exploring the potential of Rhodobacter sphaeroides in photodynamic therapy of tumors

Babatunde, Oluwaseun Oyeniyi

10 September 2021

No description available.

Biology

Biomedical Research

Molecular Biology

Oncology

Microbiology

Photodynamic therapy

Rhodobacter sphaeroides

Bacterial Cancer Therapy

Pro-drug

Delivery Vectors

Near-Infrared light

photosensitizer

bacteria photosynthetic growth

5-aminolevulinic acid

PDT

tetrapyrroles

intratumoral conditions

hemA

hemT

A study of optical and structural properties of spin-coated V2O3 thin films on sapphire substrates / En studie av optiska och strukturella egenskaper hos spinnbelagda V2O3 tunnfilmer på safirsubstrat

Silander, Jennifer

January 2022

Many transition metal oxides exhibit a Metal-Insulator Transition (MIT). This is an interesting phenomenon where the material undergoes a structural phase transition, and the electronic charge is redistributed in the crystal lattice. The crystallographic, optical, electrical, and magnetic properties are drastically changed when a material undergoes a MIT. Vanadium oxides are thermochromic materials, which means that the optical properties change with temperature, closely connected to the MIT. Vanadium sesquioxide (V2O3) experiences a MIT at the transition temperature (Tt) 160-170 K. Below the transition temperature, it is a monoclinic ferromagnetic insulator, and above the transition temperature it becomes a paramagnetic rhombohedral corundum-type metal. In the insulating phase, infrared (IR) light is transmitted, whereas in the metallic phase, IR light is reflected. The aim of this Master thesis is to improve the methodology to produce V2O3 thin films, characterize them, and study how different parameters affect the structural and optical properties of the film. V2O3 thin films were synthesized by sol-gel and deposited by spin-coating on sapphire substrates. Thereafter, the resulting films underwent an annealing process in a reducing atmosphere to achieve crystalline V2O3. The obtained crystal phase was examined by X-ray diffraction. The surface structure and morphology were studied with an optical microscope and scanning electron microscope. The optical transmittance in the IR region was examined by Fourier transform infrared spectroscopy. At last, a laser test was performed on one of the samples. In conclusion, a majority of the thin films consisted of polycrystalline V2O3. The MIT was studied with the optical hysteresis loop, which showed great difference among the different samples studied. The thin film that exhibited best optical properties showed a maximum transmission of 66 % below the Tt, and a minimum transmission of 6 % above the Tt. In comparison to this one, the other samples exhibited lower transmission and a decrease in Tt. This difference was attributed to the different morphologies and crystal orientations of the samples.

Optical properties

transmittance

FTIR spectrometry

scanning electron microscopy

x-ray diffraction

metal-insulator transition

crystalline material

sol-gel

spin-coating

vanadium oxide

infrared light

Other Physics Topics

Annan fysik

Achieving Optimal Alignments of IR Source and Detector in Waveguide Based Gas Sensor / Att uppnå optimal placering av IR-källa och detektor i vågledarbaserade gassensorer

Güler, Sefik, Agwu, Agbai Randolph

January 2020

I takt med att tekniken för mikroelektromekaniska system utvecklas uppkommer det nya områden för tillämpning. Ett område är inom gassensorer där icke-dispersiv infraröd strålning används genom att mäta absorptionen hos olika gaser för att bestämma mängden av en specifik gas i luften. I detta projekt var målet att använda en vågledare med en infraröd lysdiod på ena sidan och en fotodetektor på andra sidan där vågledaren har som uppgift att utsätta ljuset för maximal mängd koldioxid innandet träffar fotodetektorn. Motiveringen för valet av koldioxid var att det är en gas som har stor påverkan på både klimat och arbetsmiljö. Metoden som ansågs vara bäst för placeringen av tidigare nämnda komponenter var att använda programmerbara rörelseenheter som kallas hexapod som består av sex ben som möjliggör tredimensionella rörelser och rotationer kring varje axel i det kartesiska koordinatsystemet. Experiment där elektromagnetiska störningar från lysdioden undersöktes vilket visade att det förekom elektromagnetisk störning samt att lysdioden påverkade fotodetektorn genom spridning trots att lysdiod och fotodetektor inte var vända mot varandra. / As the technology for microelectromechanical systems develops, new areas of application are emerging. One area is within gas sensors where non-dispersive infrared radiation is used by measuring the absorption of various gases to determine the concentration of a specific gas in the air. In this project, the goal was to use a waveguide with an infrared LED on one side and a photodetector on the other side where the waveguide has the task of exposing the light to the maximum amount of carbon dioxide before it hits the photodetector. The reason for the choice of carbon dioxide was that it is a gas that has a great impact on both the climate and the working environment. The method that was considered to be best for the placement of the aforementioned components was to use programmable motion units called hexapods which consist of six struts that enable three-dimensional movements and rotations around each axis of the Cartesian coordinate system. Experiments in which the electromagnetic interference from the LED were investigated showed that there was electromagnetic interference and that the LED affected the photodetector by scattering, even though the LED and photodetector were not facing each other.

Non-dispersive infrared technology

microelectromechanical systems

infrared light

electromagnetic spectrum

gas sensor

light emitting diode

photodiode detector

Icke-dispersiv infraröd teknologi

mikroelektromekaniska system

infrarött ljus

elektromagnetiskt spektrum

gassensor

lysdiod

fotodioddetektor

Elektroteknik och elektronik