Your search keyword '"Narasimha S"' showing total 144 results

1. Optical characteristics of radiated multifunctional optical materials

Author

Narasimha S. Prasad, Eric Bowman, Meghan Brandt, Amalthea G. Trobare, Ching Hua Su, Bradley Arnold, Fow-Sen Choa, and Narsingh B. Singh

Published

2023

2. Interpersonal Trust and Technology Trust in Information Systems Research

Author

Narasimha S. Paravastu and Sam S. Ramanujan

Subjects

General Engineering

Abstract

Trust is a crucial factor in personal as well as online exchanges due to their impersonal nature. In the information systems discipline, past research proposed and tested interpersonal trust formation as well as continuance in several contexts. Extending beyond interpersonal relationships, trust has been extrapolated as technology trust and applied to various technology contexts such as recommendation agents, inanimate software, and objects. This paper presents a comprehensive review of interpersonal and technology trust constructs as applicable to ecommerce and technology contexts. Based on findings from past research this paper synthesizes research on interpersonal trust, trustworthiness, and trust modes, and proposes a combined model of trust constructs. Based on the literature review and results from past research, this paper identifies an important gap in literature and proposes bases of technology trust constructs as an important contribution to literature. The theoretical and managerial implications are presented.

Published

2021

3. Where lies the quantumness behind detecting electromagnetic waves for frequencies from infrared and up?

Author

ChandraSekhar Roychoudhuri, Narasimha S. Prasad, and Gayanath Fernando

Published

2022

4. Thermal, Physical, and Optical Properties of the Solution and Melt Synthesized Single Crystal CsPbBr3 Halide Perovskite

Author

Kirti Agrawal, Syed Mohammad Abid Hasan, Joanna Blawat, Nishir Mehta, Yuming Wang, Rafael Cueto, Miriam Siebenbuerger, Orhan Kizilkaya, Narasimha S. Prasad, James Dorman, Rongying Jin, and Manas Ranjan Gartia

Subjects

perovskite, CsPbBr3, single crystal, X-ray, gamma ray detector, PALS, Physical and Theoretical Chemistry, Analytical Chemistry

Abstract

Inorganic lead-halide perovskite, cesium lead bromide (CsPbBr3), shows outstanding optoelectronic properties. Both solution- and melt-based methods have been proposed for CsPbBr3 crystal growth. The solution-based growth was done at low-temperature, whereas the melt-based growth was done at high-temperature. However, the comparison of optical, physical, and defect states using these two different growth conditions has been scarcely studied. Here, we have compared the thermal and optical properties of solution-grown and melt-grown single crystals of CsPbBr3. Positron Annihilation Lifetime Spectroscopy (PALS) analysis showed that melt-grown crystal has a relatively smaller number of defects than the chemical synthesis method. In addition, crystals grown using the chemical method showed a higher fluorescence lifetime than melt-grown CsPbBr3.

Published

2022

5. Separation and Characterization of New Forced Degradation Products of Dasatinib in Tablet Dosage Formulation Using LC–MS and Stability-Indicating HPLC Methods

Author

Raviteja Yarra, Narasimha S. Lakka, Chandrasekar Kuppan, and Kona S Srinivas

Subjects

Chromatography, 010405 organic chemistry, Chemical structure, 010401 analytical chemistry, Organic Chemistry, Clinical Biochemistry, 01 natural sciences, Biochemistry, High-performance liquid chromatography, 0104 chemical sciences, Analytical Chemistry, Dasatinib, chemistry.chemical_compound, chemistry, Liquid chromatography–mass spectrometry, Potassium phosphate, hemic and lymphatic diseases, Ultrapure water, Forced degradation, medicine, Acetonitrile, medicine.drug

Abstract

Dasatinib is a protein kinase inhibitor used for the treatment of chronic myelogenous leukemia and acute lymphoblastic leukemia. Dasatinib along with its six known organic impurities were separated using the reversed-phase high performance liquid chromatography with C18 column and mobile phases consisting of gradient mixture of 20 mM potassium phosphate buffer at pH 6.0 with 1-octanesulphonic acid sodium salt (0.1%, w/v), acetonitrile and ultrapure water. This method was successfully tested with liquid chromatography coupled mass-spectrometry to elucidate the chemical structure of newly formed degradation product of Dasatinib which was identified by comparing its retention time and mass-spectra with literature data. Stability-indicating characteristics of developed HPLC method was assessed using stress testing [5 N HCl at 90 °C/1 h, 5 N NaOH at 90 °C/1 h, H2O at 90 °C/1 h, 30% H2O2 (w/w) at 25 °C ± 5 °C/1 h, dry heat at 105 °C/24 h and UV (200 W h m−2) and fluorescent light (1.2 million lux-h)] and was validated as per ICH Q2(R1). For Dasatinib and its six impurities, the quantification limits, linearity and recoveries were found in range of 0.19–0.21 μg/mL, 0.2–3.0 μg mL−1 (R2 > 0.995) and 85.5–107.0%, respectively. The developed HPLC method will also suffice the suitability for impurity profiling and assay of Dasatinib in bulk drugs and pharmaceutical formulations.

Published

2020

6. Development and validation of liquid chromatography–tandem mass spectrometry method for the estimation of a potential genotoxic impurity 2‐(2‐chloroethoxy)ethanol in hydroxyzine

Author

Narasimha S. Lakka, Chandrasekar Kuppan, Poornima Ravinathan, and Ashok Kumar Palakurthi

Subjects

Pharmacology, Ethanol, Clinical Biochemistry, General Medicine, Biochemistry, Analytical Chemistry, Ethyl Ethers, Tandem Mass Spectrometry, Hydroxyzine, Drug Discovery, Solvents, Humans, Molecular Biology, Chromatography, High Pressure Liquid, Chromatography, Liquid, DNA Damage

Abstract

2-(2-Chloroethoxy)ethanol (CEE) belongs to the so-called cohort of concerns which were classified as highly potent mutagenic carcinogens by the World Health Organization. It is widely used in the synthesis of the essential anti-histamine drug hydroxyzine. In addition, it is used as a primary solvent in dyes, nitrocellulose, paints, inks and resins. Owing to its potential genotoxicity, an efficient liquid chromatography-tandem mass spectrometry method was developed for the quantitative estimation of CEE traces in an active pharmaceutical ingredients and in tablet dosage forms of hydroxyzine-free base. The chromatographic separation was achieved on a C

Published

2022

7. Impurity profiling and stability-indicating method development and validation for the estimation of assay and degradation impurities of midostaurin in softgel capsules using HPLC and LC-MS

Author

Narasimha S. Lakka, Poornima Ravinathan, and Chandrasekar Kuppan

Subjects

Resolution (mass spectrometry), Clinical Biochemistry, Capsules, Biochemistry, High-performance liquid chromatography, Mass Spectrometry, Analytical Chemistry, chemistry.chemical_compound, Liquid chromatography–mass spectrometry, Limit of Detection, Drug Discovery, medicine, Ammonium formate, Midostaurin, Molecular Biology, Chromatography, High Pressure Liquid, Pharmacology, Detection limit, Chromatography, Reproducibility of Results, General Medicine, Reversed-phase chromatography, Staurosporine, chemistry, Linear Models, Softgel, Drug Contamination, medicine.drug

Abstract

Midostaurin (MDS) is used for the treatment of acute myeloid leukemia, myelodysplastic syndrome, and advanced systemic mastocytosis. MDS softgel capsule samples were subjected to stress testing per International Conference on Harmonisation of Technical Requirements for Registration of Pharmaceuticals for Human Use guidelines for impurity profiling study. MDS underwent extensive degradation under stress testing (acid, alkaline, oxidative, photolytic, thermolytic, and hydrolysis conditions) and formed four degradation products (DPs). MDS and its DPs were separated well from one another with good resolution using reserved-phase HPLC using an Inertsil ODS-3V column (250 × 4.6 mm, 5 μm) and a mobile phase of ammonium formate (40 mM) and acetonitrile. The stability-indicating characteristic of the newly developed method was proven for the estimation of MDS assay, and its organic impurities were free from interference. The validated method exhibited excellent linearity, accuracy, precision, specificity, detection limit, and quantitation limit within 25 min run time. Stress testing, robustness, and solution stability were performed to ensure the continuous performance of the developed method. The peak fractions of DPs formed under stress testing were isolated and characterized using LC-MS, 1 H and 13 C NMR, IR, and UV-Vis. The structure of the major DPs was predicted as DP1 based on the spectral data. The proposed method is effectively used for MDS in bulk drug and finished formulations in the pharmaceutical industry.

Published

2021

8. Surface characteristics of polymer nanocomposites

Author

Narasimha S. Prasad, Narsingh B. Singh, Ian Emge, Brett Setera, Leslie Scheurer, Ryan Grant, Lisa A. Kelly, Bradley Arnold, and Fow-Sen Choa

Subjects

chemistry.chemical_compound, Materials science, Polymer nanocomposite, chemistry, Nucleation, Polishing, Nanotechnology, Polystyrene, Wetting, Thin film, Nanoscopic scale, Titanium oxide

Abstract

SPIE Defense + Commercial Sensing, 2021, Online Only, The performance of optical and electronic detectors and sensors are affected by surface and bulk impurities. In some cases, nanoscale thin films are used as detectors and their life cycle is significantly decreased. In the case of conformal shapes, surfaces with different polishing, decoration and geometries exhibit unusual wetting and nucleation characteristics for impurities and this requires continuous attention for cleaning. The situation for space borne components and vehicles surfaces exposed to wetting liquids requires remote cleaning. In the present paper, we report the effect of surface topographies of substrates with nanoengineered titanium oxide and copper oxide nanoparticles embodied in polystyrene and study the effect of the composites to create different hydrophobic characteristics with great potential for detectors and sensors operating in ultra-violet and infrared regions.

Published

2021

9. Nanoengineered Coating; Lotus Effect, Morphology, Contact Angles and Wettability

Author

Christopher Cooper, Lisa A. Kelly, Brett Setera, Fow-Sen Choa, Narsingh Bahadur Singh, Stacey Sova, Narasimha S. Prasad, Bradley Arnold, and David Sachs

Subjects

chemistry.chemical_classification, Nanocomposite, Materials science, Nanoparticle, Polymer, engineering.material, Contact angle, Coating, chemistry, Chemical engineering, engineering, Particle size, Wetting, Lotus effect

Abstract

The understanding of the surface behavior, interaction, wettability, and topographies of surfaces with fluids is very important to remove impurities from the devices and components and to develop washing fluids to clean large area surfaces. We synthesized nano particle filled composites by wet and semi-wet techniques to achieve hydrophobicity and hence the lotus effect. Nanocomposites with different composition of polymers doped with titania nanoparticles were studied to evaluate effects on wettability. Light scattering methods were used to study the absorptions and particle size. The contact angle and hydrophobic characteristics were very composition dependent in thin film composites. At certain compositions, we observed that material showed very high anisotropy in droplet shapes which diminished with loadings of nanoparticles. These composites did not show any change in hydrophobic characteristics when exposed with ultraviolet radiation.

Published

2021

10. A three-beam aerosol backscatter correlation lidar for wind profiling

Author

Anand Radhakrishnan Mylapore and Narasimha S. Prasad

Subjects

Pulse repetition frequency, General Engineering, Velocimetry, Wind profiler, Laser, Atomic and Molecular Physics, and Optics, Wind speed, Article, Aerosol, law.invention, Lidar, Anemometer, law, Geology, Physics::Atmospheric and Oceanic Physics, Remote sensing

Abstract

In this paper, the development of a three-beam aerosol backscatter correlation (ABC) lidar to measure wind characteristics for wake vortex and plume tracking applications is discussed. This is a direct detection elastic lidar that uses three laser transceivers, operating at 1030 nm wavelength with ~10 kHz pulse repetition frequency and nanosec class pulse widths, to directly obtain three components of wind velocities. By tracking the motion of aerosol structures along and between three near-parallel laser beams, three-component wind speed profiles along the field-of-view of laser beams are obtained. With three 8-inch transceiver modules, placed in a near-parallel configuration on a two-axis pan-tilt scanner, the lidar measures wind speeds up to 2 km away. Optical flow algorithms have been adapted to obtain the movement of aerosol structures between the beams. Aerosol density fluctuations are cross-correlated between successive scans to obtain the displacements of the aerosol features along the three axes. Using the range resolved elastic backscatter data from each laser beam, which is scanned over the volume of interest, a 3D map of aerosol density in a short time span is generated. The performance of the ABC wind lidar prototype, validated using sonic anemometer measurements, is discussed.

Published

2020

11. Multifunctional semiconductors for radiation sensors: crystal growth and characterization

Author

Charmain Su, Ian Emge, Narasimha S. Prasad, Fow-Sen Choa, Narsingh B. Singh, Brett Setera, Bradley Arnold, and K. D. Mandal

Subjects

Materials science, business.industry, Analytical chemistry, chemistry.chemical_element, Crystal growth, Crystal, Semiconductor, chemistry, Electrical resistivity and conductivity, Impurity, Melting point, Thallium, business, Ternary operation

Abstract

Heavy metal selenides have shown very good properties including wavelength conversion in MWIR and LWIR regions, acousto-optic and great potential for radiation detection. We have extensively studied thallium-based compounds for variety of applications. Studies were performed for crystal growth, fabricability and radiation detection characteristics of ternary congruent compounds of thallium mercury iodide system from the melt by Bridgman method. The congruency and phase transition was studied by DTA. Material melts congruently between 300-400 0C and do not show any other phases between room temperature and melting point. Crystal slabs were fabricated as bulk detector to demonstrate good characteristics for detectivity of X-ray and gamma-rays. Effect of impurities on performance were evaluated by using source materials of different purity for synthesis. Crystals with high purity source materials and mixed by vibrating method were determined for resistivity in range of 1012ohm-cm.

Published

2020

12. Principles of Chromatography Method Development

Author

Narasimha S. Lakka and Chandrasekar Kuppan

Subjects

Chromatography, Chemistry, Method development

Published

2020

13. Picosecond pulsewidth direct detection lidar for imaging applications

Author

Narasimha S. Prasad and Anand Radhakrishnan Mylapore

Subjects

Scanner, Materials science, Backscatter, business.industry, Instrumentation, Velocimetry, Laser, law.invention, Optics, Lidar, law, Picosecond, Fiber laser, business

Abstract

In this paper, the development of a novel picosecond pulsewidth direct detection lidar for velocimetry and hard target imaging applications is discussed. The lidar system comprises of a high-speed fiber coupled laser, novel interleaved three-dimensional (3D) scanner, fiber coupled receiver with optical pre-amp module and a high-speed digitizer. The laser is a pulsed Erbium-doped fiber laser that operates at 1.55 microns wavelength, 10 MHz PRF, 60 picosecond pulse width and 8 W of output average power. The scanner is a multi-faceted polygon type that operates at scan speeds of 10000 lines per second. The system utilizes a state-of-the art 40 GS/s digitizer. The picosecond lidar allows high resolution volumetric measurement of temporally and spatially resolved 3D airspeeds in wind tunnels for capturing a 3D time-accurate map of aerosols or other seeding particles in the airflow using elastic backscatter from a rapidly scanned lidar beam with a narrow field-of-view. Preliminary testing inside wind tunnel has generated promising results for aerodynamic applications including visualizing flow characteristics around test targets. The lidar provided dynamic measurements of complex flow, including the downstream evolution of a wing tip vortex. A 3D image processing algorithm was used to correlate the motion of aerosol features between successive frames and to extract 3D airflow profiles. In this paper, details of lidar instrumentation configuration is discussed followed by results of high-speed 3D hard target imaging of various test targets.

Published

2020

14. Advanced SWIR photon-sensing integrated circuit hetero-junction phototransistor based focal plane array for space applications

Author

Jie Yao, Feng Sun, Narasimha S. Prasad, and Yin Liu

Subjects

Physics, business.industry, Detector, Integrated circuit, Specific detectivity, Avalanche photodiode, Noise (electronics), Photodiode, law.invention, Readout integrated circuit, law, Optoelectronics, business, Dark current

Abstract

Uncooled focal plane arrays (FPA) with reduced size, weight, and power consumption (SWaP) features and coupled with enhanced characteristics have the potential to significantly benefit a wide range of imaging applications including space surveillance from terrestrial and space-based platforms and planetary composition mapping for space exploration missions. Recently, an innovative, uncooled Photon-Sensing Integrated Circuit (PSIC) hetero-junction phototransistor (HPT) device has been developed. This InGaAs based PSIC HPT device is a room temperature detector and imager that is of 320 x 256 pixel format with 30 micron pixels, and operates in the short-wave infrared (SWIR) spectral region of 0.9 to 1.7 microns. It is a continuously operating (i.e., zero recovery time), zero-excess-noise and linear-mode (i.e., capable of representing photon numbers) photon-sensing detector and imager. Enabled by its hetero-junction phototransistor (HPT) amplification instead of the conventional avalanche multiplication mechanism, this InGaAs HPT simultaneously exhibits signal amplification gain of >1000, namely, >20 x higher gain, and

Published

2020

15. Contrasting quantum sensing light source properties, which generate different photocurrent pulse-statistics

Author

Chandrasekhar Roychoudhuri, Narasimha S. Prasad, Gayanath Fernando, and Negussie Tirfessa

Subjects

Physics, Superposition principle, Photon, business.industry, Wave packet, Quantum sensor, Electron, Photonics, business, Quantum, Pulse (physics), Computational physics

Abstract

We are developing a semi-classical model to explain the physical processes behind the origin of the statistical variations in the photoelectron current pulses that we register for different kinds of light. They are: super-Poissonian thermal light, Poissonian laser light and sub-Poissonian nonlinearly generated light. Einstein’s photoelectron equation is an energy balancing equation. It does not incorporate the E-vector stimulation process before the quantum mechanically bound electrons can be released, which constitutes a key objective of physics. To introduce physics, we postulate that the photons are hybrid entities. They are discrete packets of energy hνmn at the moment of emission. Then they immediately evolve into spatially spreading diffractive wave packets to accommodate Huygens-Fresnel principle. HF principle has been behind the sustained progress in classical optics and photonics engineering. Thus a spatially spread out single wave-packet cannot any more deliver the necessary quantum cupful of energy hνmn to Angstrom-size detecting atoms. We need simultaneous stimulation of the same quantum entity by multiple wave packets. This model of physical interaction process naturally brings into play the significance of the degree of mutual coherence between different photon wave packets, along with their time varying amplitudes that are simultaneously stimulating the detecting quantum entities during any time-interval selected for the detection system. The superposition effects on the detector due to these phase and amplitude fluctuations are the physics-reasons behind the generation of different statistical variations in the photoelectron counts due to different kinds of sources even though the original photons are released randomly by all quantum sources.

Published

2020

16. High-speed wide-angle interleaved scanning technique for a 3D imaging lidar

Author

Anand Radhakrishnan Mylapore and Narasimha S. Prasad

Subjects

Scanner, Materials science, business.industry, Angular displacement, Statistical and Nonlinear Physics, Field of view, Velocimetry, Galvanometer, Atomic and Molecular Physics, and Optics, symbols.namesake, Optics, Lidar, Data acquisition, symbols, business, Image resolution

Abstract

In this paper, we describe a novel interleaved scanner for an eye-safe 3D scanning lidar system to measure aerodynamic phenomena in a wind tunnel using elastic backscatter from seeding particles. The scanner assembly consists of a rotating polygon scanner for line scanning along the fast axis, a galvanometer (galvo) scanner for scanning along the slow axis, angular position sensors, and motor controllers. The polygon scanner sweeps the lidar beam at up to 10,000 lines/s across a 27 deg angular field of regard in the fast axis, while the galvo scanner covers an angular range of 20 deg in the slow axis. Using this scanner, the lidar can perform nonintrusive flow visualization, velocimetry, and hard target mapping at millimeter-scale spatial resolution to a standoff range of 5 m at an update rate of 50 Hz for the full field of regard. An interleaved scanning methodology for the acquisition of two snapshots of 3D lidar intensity data with a 100 µs time offset is discussed. The design of the control and data acquisition electronics is described. The effects of rapid scanning on the response of a narrow field-of-view lidar are addressed. The design of the scanner is scalable and can be tailored to meet the requirements of other applications by increasing or decreasing the standoff range, angular field of regard, and scan rate.

Published

2021

17. Room-Temperature Processing of TiOx Electron Transporting Layer for Perovskite Solar Cells

Author

Mool C. Gupta, Joshua J. Choi, Narasimha S. Prasad, George C. Wilkes, Alexander Z. Chen, and Xiaoyu Deng

Subjects

Materials science, business.industry, Energy conversion efficiency, Nanotechnology, 02 engineering and technology, Hybrid solar cell, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Amorphous solid, Solar cell efficiency, Optoelectronics, General Materials Science, Electrical measurements, Physical and Theoretical Chemistry, Thin film, 0210 nano-technology, business, Layer (electronics), Perovskite (structure)

Abstract

In order to realize high-throughput roll-to-roll manufacturing of flexible perovskite solar cells, low-temperature processing of all device components must be realized. However, the most commonly used electron transporting layer in high-performance perovskite solar cells is based on TiO2 thin films processed at high temperature (>450 °C). Here, we demonstrate room temperature solution processing of the TiOx layer that performs as well as the high temperature TiO2 layer in perovskite solar cells, as evidenced by a champion solar cell efficiency of 16.3%. Using optical spectroscopy, electrical measurements, and X-ray diffraction, we show that the room-temperature processed TiOx is amorphous with organic residues, and yet its optical and electrical properties are on par with the high-temperature TiO2. Flexible perovskite solar cells that employ a room-temperature TiOx layer with a power conversion efficiency of 14.3% are demonstrated.

Published

2017

18. Importance of lotus effect on surface sensing

Author

Christopher Cooper, Brian M. Cullum, Stacey Sova, Bradley Arnold, Narasimha S. Prasad, Narsingh Bahadur Singh, Lisa A. Kelly, and Fow-Sen Choa

Subjects

chemistry.chemical_classification, Solvent, Contact angle, chemistry.chemical_compound, Materials science, Morphology (linguistics), Chemical engineering, chemistry, Polystyrene, Polymer, Lotus effect, Irradiation, Thin film

Abstract

Superhydrophobic polymer films are a material of interest for aircraft deicing fluids to achieve the selfcleaning lotus effect. Hydrophobic polymer films were obtained by a solvent selective method composed of hydrophilic polymethylmethacrylate (PMMA) and hydrophobic polystyrene (PS) and hydrophilic titania nanoparticles. The addition of titania nanoparticles changed the surface of the thin films from an anisotropic morphology to a spherical isotropic surface due to hydrophobic and hydrophilic repulsion. Irradiation of UV responsive titania nanoparticles retained the same surface morphology. Water contact angle measurements will be completed to determine the hydrophobic nature of the polymer films.

Published

2019

19. Complex interaction processes we need to visualize that successfully fill the quantum cup of a detector

Author

Chandrasekhar Roychoudhuri and Narasimha S. Prasad

Subjects

Diffraction, Causality (physics), Superposition principle, Photon, Classical mechanics, Physics - General Physics, General Physics (physics.gen-ph), Computer science, FOS: Physical sciences, Wave equation, Interference (wave propagation), Quantum, Duality (electricity and magnetism)

Abstract

Sensors are measuring tools. In any measurement, we have at least two different kinds of interactants. We never know all there are to know about any one of these interactants and the interaction processes that are mostly invisible. Yet, our engineering innovation driven evolution is persisting for over five million years. It is then important to articulate explicitly our Interaction Process Mapping Thinking, or IPMT, which we keep applying in the real world without formally recognizing it. We present how the systematic application of IPMT removes century old wave-particle duality by introducing a model of hybrid photon. It seamlessly bridges the quantum and the classical worlds. Photons are discrete energy packets only at the moment of emission; then they evolve diffractively and propagate as classical waves. We apply IPMT to improve the photoelectric equation & we obtain Non-Interaction of Wave, or NIW. NIW was recognized by Huygens when postulating his secondary spherical wavelets, which is now integrated into Huygens-Fresnel diffraction integral, a staple for modern optical science and engineering. Maxwell wave equation accepts HF integral as its solution. Systematic application of IPMT to our causal and working mathematical equations, along with NIW in interferometric experiments, reveal that Superposition Effects can emerge only when the interacting material dipoles respond, whether classically or quantum mechanically, to the joint stimulations due to all the simultaneously superposed waves. This indicates the non-causality of our belief that a single indivisible photon can interfere by itself. We would not have a causally evolving universe had any stable elementary particle were to change itself through self-interference. Further, our working superposition equations always contain two or more terms representing two or more independently evolving entities., 13 pages. Six figures. To be presented at the 2019 SPIE Photonics West Conference

Published

2019

20. Polarimetric hyperspectral imaging with acousto-optic tunable filter in the visible to shortwave infrared range

Author

Feng Jin, Susan Kutcher, Sudhir B. Trivedi, Narasimha S. Prasad, Jolanta Soos, Emir Y. Haskovic, Chein-I. Chang, and Bai Xue

Subjects

Spectrum analyzer, Materials science, Uniaxial crystal, business.industry, Polarimetry, Physics::Optics, Hyperspectral imaging, Polarization (waves), law.invention, symbols.namesake, chemistry.chemical_compound, Optics, chemistry, law, symbols, Stokes parameters, Tellurium dioxide, business, Beam splitter

Abstract

Tellurium dioxide is the most widely used uniaxial crystal for acousto-optic devices. Acousto-optic tunable filters based on this material can cover spectral range from UV to MWIR in a non-collinear configuration. The diffracted narrow band output beams have orthogonal linear polarizations, propagating in different directions, allowing the filter to act as polarizing beam splitter/analyzer as well. To achieve full electronic tuning, two liquid crystal variable retarders are used to measure all six polarization states used in the calculation of Stokes vector. We will present the design of the instrument, test results, and performance considerations.

Published

2018

21. Recent advances in wind lidar technologies for characterization of wake vortices

Author

Narasimha S. Prasad

Subjects

Wind lidar, Environmental science, Wake, Characterization (materials science), Vortex, Remote sensing

Published

2018

22. Acousto-optic tunable filter based spectrapolarimeter for extraction of Stokes and Mueller matrices

Author

Jolanta Soos, Emir Y. Haskovic, Feng Jin, Sudhir B. Trivedi, Susan Kutcher, and Narasimha S. Prasad

Subjects

Materials science, business.industry, Polarimetry, Spectral bands, Polarization (waves), Wavelength, chemistry.chemical_compound, Optics, chemistry, Liquid crystal, Tellurium dioxide, Mercury cadmium telluride, business, Graphical user interface

Abstract

We report on the development of an acousto-optic tunable filter (AOTF) based novel, high speed spectropolarimeter system operating over the visible and near-IR spectral bands to extract Stokes and Mueller matrices. Developed primarily for planetary composition and analysis applications, the wavelength tunable polarimetric system is configured with tellurium dioxide based AOTF and liquid crystal based variable retarders (LCVR) with no movable mechanical parts. Fitted with a standard silicon camera for operation up to 900 nm and a Mercury Cadmium Telluride (MCT) camera for operation up to 2500 nm, the spectropolarimetric system is currently configured for passive operation. The operation of this spectropolarimetric system is fully automated with an interactive and user friendly graphical user interface, and accordingly provides a snapshot polarimetric measurement capability in minutes.

Published

2018

23. Effect of additives: Organic-metal oxide nanocomposites for γ-ray sensors

Author

Narasimha S. Prasad, Ching Hua Su, Christopher Cooper, Puneet Gill, Paul J. Smith, Brian M. Cullum, Lisa A. Kelly, Fow-Sen Choa, Stacey Sova, Bradley Arnold, Vishall Dayal, and Narsingh Bahadur Singh

Subjects

chemistry.chemical_compound, Materials science, Nanocomposite, Transition metal, chemistry, Nickel oxide, Composite number, Oxide, Nanoparticle, Irradiation, Composite material, Photoelectric effect

Abstract

The transition metal oxide embodied organic composites have great promise for high energy radiation detection. The interaction of high energy radiation such as γ-rays with the organic composite can generate photoelectric responses, Compton scattering and electron hole pairs, which can provide favorable properties to enhance the radiation detectivity of the composite. These effects along with changes of oxidation state of metal oxides, provide significant change in the electrical characteristics of composites due to radiation exposure. We have developed nickel oxide (NiO2) nanoparticles embodied urea composite (urea-NiO2), and determined effect of γ-radiation on the current – voltage characteristics in the frequency range of 100 Hz to 100,000Hz. In this paper, we describe the results of effect of additional oxidizing agent MnO2 (urea-NiO2-MnO2) on the morphology, processing and current voltage characteristics due to exposure of Cs-137 γ-radiation. It was observed that addition of MnO2 in urea-NiO2 composite decreases the sensitivity of detection. However, urea-NiO2-MnO2 composite recovers to original properties after irradiation much faster than urea-NiO2 composite.

Published

2018

24. Reliability testing of ultra-low noise InGaAs quad photoreceivers

Author

Abhay M. Joshi, M. Sivertz, Shubhashish Datta, and Narasimha S. Prasad

Subjects

Materials science, business.industry, Ranging, Laser, Capacitance, law.invention, Photodiode, Interferometry, law, Absorbed dose, Operational amplifier, Optoelectronics, Equivalent input, business

Abstract

We have developed ultra-low noise quadrant InGaAs photoreceivers for multiple applications ranging from Laser Interferometric Gravitional Wave Detection, to 3D Wind Profiling. Devices with diameters of 0.5 mm, 1mm, and 2 mm were processed, with the nominal capacitance of a single quadrant of a 1 mm quad photodiode being 2.5 pF. The 1 mm diameter InGaAs quad photoreceivers, using a low-noise, bipolar-input OpAmp circuitry exhibit an equivalent input noise per quadrant of

Published

2018

25. Optical characteristics of novel bulk and nanoengineered laser host materials

Author

Narsingh Bahadur Singh, Christopher Cooper, Stacey Sova, Lisa A. Kelly, Bradley Arnold, Talon Bevan, Fow-Sen Choa, and Narasimha S. Prasad

Subjects

inorganic chemicals, Materials science, chemistry.chemical_element, Crystal growth, dopants, transition metal, Apatite, law.invention, Absorbance, chemistry.chemical_compound, symbols.namesake, Lanthanum aluminate, law, crystals, Lanthanum, transparency, Dopant, Laser, laser, optical emission, chemistry, Chemical engineering, apatite, visual_art, visual_art.visual_art_medium, symbols, Raman spectroscopy

Abstract

The hexagonal apatite single crystals have been investigated for their applications as laser host materials. Czochralksi and flux growth methods have been utilized to obtain single crystals. For low temperature processing (

Published

2018

26. Short pulse characterization requires recognizing inseparability of auto-correlation and spectral measurements

Author

Chandrasekhar Roychoudhuri and Narasimha S. Prasad

Subjects

Physics, Superposition principle, Photon, Amplitude, Autocorrelation, Detector, Observable, Statistical physics, Square (algebra), Pulse (physics)

Abstract

We present a mathematical approach to appreciate that short pulse characterization requires recognizing inseparability of the measurements of the amplitude envelope-correlation and spectral measurements and then use a suitable iterative approach to derive the real characteristics. We will use a standard Michelson interferometer, as usual, to introduce the autocorrelation function of a pulse containing single and multiple frequencies. In the process, we also underscore that detectors play the key role in generating measurable Superposition Effects (SE), recognized as fringes after the detectors carry out the square modulus operation. Simple mathematical summation of amplitude factors, the Superposition Principle (SP), is not directly observable. We underscore this by mentioning that we present EM waves as classical and detectors as quantum mechanical. This semi-classical approach has been established by Lamb and Jaynes, which is indirectly supported by Glauber’s comment, “A photon is what a detector detects”. The semi-classical approach helps us separate the phenomenological difference between the absorbed detected energy by a detector (SE) from the energy supplied by the simultaneously present multiple wave amplitudes (SP). As in atomic and molecular physics, we use the detector’s dipolar stimulation as the product of its linear dipolar polarizability multiplied by all the EM fields stimulating it simultaneously. The analysis also demonstrates that for a pulse containing multiple frequencies, the two-beam autocorrelation function becomes a product of the traditional amplitude correlation factor and a frequency-comb correlation factor. Hence, the spectral interpretation of a short pulse and two-beam autocorrelation are inseparable. Therefore, the detailed characterization would require iterative computational approach by guessing the most plausible functional forms. This deeper understanding can be applied to rapid re-calibration of pulsed lasers that need to be maintained at single mode but has the tendency to move to multimode behavior. If the newly measured autocorrelation function differs from the original amplitude correlation factor, then one should check for the spectral characteristics first, before assuming that only the pulse shape has changed.

Published

2018

27. Room-Temperature Processing of TiO

Author

Xiaoyu, Deng, George C, Wilkes, Alexander Z, Chen, Narasimha S, Prasad, Mool C, Gupta, and Joshua J, Choi

Abstract

In order to realize high-throughput roll-to-roll manufacturing of flexible perovskite solar cells, low-temperature processing of all device components must be realized. However, the most commonly used electron transporting layer in high-performance perovskite solar cells is based on TiO

Published

2017

28. CONTROLLED RELEASE OF GABAPENTIN THROUGH RETICULATED CHITOSAN AND HYDROXYETHYL CELLULOSE HYDROGEL MATRIX TABLETS

Author

Narasimha S. Managoli, Raghavendra V. Kulkarni, Nadendla Ramarao, and Iranna S. Muchandi

Subjects

lcsh:Pharmacy and materia medica, hydroxyethyl cellulose, gabapentin, hydrogel tablets, technology, industry, and agriculture, lcsh:RS1-441, macromolecular substances, controlled release, tr crosslinked chitosan

Abstract

The aim of the present work was to prepare hydrogel matrix tablets using crosslinked chitosan and hydroxyethyl cellulose (HEC) for controlled release of gabapentin. The chitosan was crosslinked with acetaldehyde and used for the preparation of hydrogel matrix tablets along with hydroxylethyl cellulose by wet granulation method. The samples were characterized by FTIR, DSC, TGA, XRD, SEM and evaluated drug content, swelling pattern and drug release. The matrix tablets were capable of releasing the drug for 24h depending upon the formulation variables. It was observed that as the concentration of HEC increased in the tablets, the drug release was also increased. On the other hand, as the crosslinking of chitosan was increased, the drug release was decreased. Drug release mechanism followed non-Fickian transport. This study demonstrated that the blend hydrogel matrix tablets of crosslinked chitosan and HEC could be a versatile drug delivery system for controlled release of gabapentin.

Published

2014

29. Non-Contact Cardiac Activity Monitoring using Pulsed Laser Vibrometer

Author

Chen Chia WANG, Sudhir TRIVEDI, Susan KUTCHER, Ponciano RODRIGUEZ, Feng JIN, V. SWAMINATHAN, Frank WALTERS, and Narasimha S. PRASAD

Subjects

Laser vibrometer, Laser remote sensing, lcsh:Technology (General), Cardiology, lcsh:T1-995, Non-contact evaluation

Abstract

We demonstrate experimentally the detection of detailed human cardiac mechanical activity in a remote, non-contacting, and non-ionizing manner using a pulsed laser vibrometer. The highly sensitive pulsed laser vibrometer allows the detection of the temporally-phased mechanical events occurring in individual cardiac cycles even from the surface of clothing-covered extremities of the subjects. Fine structures of the detected cardiac traces are identified with their meanings assigned and corroborated using accelerometer and electrocardiogram measurements obtained concurrently with the pulsed laser vibrometer studies.

Published

2014

30. Ultra high molecular weight polyethylene (UHMWPE) fiber epoxy composite hybridized with Gadolinium and Boron nanoparticles for radiation shielding

Author

Narasimha S. Prasad, Ajit D. Kelkar, and Venkat Mani

Subjects

Materials science, chemistry.chemical_element, 02 engineering and technology, Epoxy, Boron carbide, Neutron radiation, Radiation, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, chemistry.chemical_compound, chemistry, visual_art, Electromagnetic shielding, visual_art.visual_art_medium, Neutron, Composite material, 0210 nano-technology, Boron, Sandwich-structured composite

Abstract

Deep space radiations pose a major threat to the astronauts and their spacecraft during long duration space exploration missions. The two sources of radiation that are of concern are the galactic cosmic radiation (GCR) and the short lived secondary neutron radiations that are generated as a result of fragmentation that occurs when GCR strikes target nuclei in a spacecraft. Energy loss, during the interaction of GCR and the shielding material, increases with the charge to mass ratio of the shielding material. Hydrogen with no neutron in its nucleus has the highest charge to mass ratio and is the element which is the most effective shield against GCR. Some of the polymers because of their higher hydrogen content also serve as radiation shield materials. Ultra High Molecular Weight Polyethylene (UHMWPE) fibers, apart from possessing radiation shielding properties by the virtue of the high hydrogen content, are known for extraordinary properties. An effective radiation shielding material is the one that will offer protection from GCR and impede the secondary neutron radiations resulting from the fragmentation process. Neutrons, which result from fragmentation, do not respond to the Coulombic interaction that shield against GCR. To prevent the deleterious effects of secondary neutrons, targets such as Gadolinium are required. In this paper, the radiation shielding studies that were carried out on the fabricated sandwich panels by vacuum-assisted resin transfer molding (VARTM) process are presented. VARTM is a manufacturing process used for making large composite structures by infusing resin into base materials formed with woven fabric or fiber using vacuum pressure. Using the VARTM process, the hybridization of Epoxy/UHMWPE composites with Gadolinium nanoparticles, Boron, and Boron carbide nanoparticles in the form of sandwich panels were successfully carried out. The preliminary results from neutron radiation tests show that greater than 99% shielding performance was achieved with these sandwich panels. Moreover, the mechanical testing and thermo-physical analysis performed show that core materials can preserve their thermo-physical and mechanical integrity after radiation.

Published

2016

31. Probing organic residues on Martian regolith simulants using a long-wave infrared Laser-induced breakdown spectroscopy linear array detection system

Author

Sudhir Trivedi, Yingqing Jia, Narasimha S. Prasad, Alan C. Samuels, Eric A. DeCuir, Clayton S.-C. Yang, Priyalal S. Wijewarnasuriya, Uwe Hommerich, Feng Jin, Ken Jia, and E. Brown

Subjects

Spectral signature, Materials science, business.industry, 010401 analytical chemistry, Analytical chemistry, medicine.disease_cause, 01 natural sciences, 0104 chemical sciences, 010309 optics, Optics, Impurity, 0103 physical sciences, medicine, Martian regolith simulant, Sample preparation, Laser-induced breakdown spectroscopy, Emission spectrum, Spectroscopy, business, Ultraviolet

Abstract

Recently, a mercury-cadmium-telluride (MCT) linear array detection system that is capable of rapidly capturing (~1-5 second) a broad spectrum of atomic and molecular laser-induced breakdown spectroscopy (LIBS) emissions in the longwave infrarμed region (LWIR, ~5.6 to 10 μm) has been developed. Similar to the conventional Ultraviolet (UV)-Visible (Vis) LIBS, a broad band emission spectrum of condensed phase samples covering the entire 5.6 to 10 μm region can be acquired from just a single laser-induced micro-plasma or averaging a few single laser-induced micro-plasmas. This setup has enabled probing samples “as is” without the need for extensive sample preparation and also offers the possibility of a simultaneous UV-Vis and LWIR LIBS measurement. A Martian regolith simulant (JSC Mars-1A) was studied with this novel Vis + LWIR LIBS array system. A broad SiO2 vibrational emission feature around 9.5 μm and multiple strong emission features between 6.5 to 8 μm can be clearly identified. The 6.5 to 8 μm features are possibly from biological impurities of the simulant. JSC Mars-1A samples with organic methyl salicylate (MeS, wintergreen oil) and Dimethyl methyl-phosphonate (DMMP) residues were also probed using the LWIR LIBS array system. Both molecular spectral signature around 6.5 μm and 9.5 μm of Martian regolith simulant and MeS and DMMP molecular signature emissions, such as Aromatic CC stretching band at 7.5 μm, C-CH3O asymmetric deformation at 7.6 μm, and P=O stretching band at 7.9 μm, are clearly observed from the LIBS emission spectra in the LWIR region.

Published

2016

32. Innovative fiber-laser architecture-based compact wind lidar

Author

Allen J. Tracy, Richard Higgins, Steve Vetorino, Narasimha S. Prasad, and Russ Sibell

Subjects

010308 nuclear & particles physics, Computer science, business.industry, Instrumentation, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Laser, 01 natural sciences, GeneralLiterature_MISCELLANEOUS, Trace gas, law.invention, 010309 optics, Lidar, law, Fiber laser, 0103 physical sciences, Systems architecture, Photonics, Wake turbulence, business, Beam (structure), Remote sensing

Abstract

This paper describes an innovative, compact and eyesafe coherent lidar system developed for use in wind and wake vortex sensing applications. This advanced lidar system is field ruggedized with reduced size, weight, and power consumption (SWaP) configured based on an all-fiber and modular architecture. The all-fiber architecture is developed using a fiber seed laser that is coupled to uniquely configured fiber amplifier modules and associated photonic elements including an integrated 3D scanner. The scanner provides user programmable continuous 360 degree azimuth and 180 degree elevation scan angles. The system architecture eliminates free-space beam alignment issues and allows plug and play operation using graphical user interface software modules. Besides its all fiber architecture, the lidar system also provides pulsewidth agility to aid in improving range resolution. Operating at 1.54 microns and with a PRF of up to 20 KHz, the wind lidar is air cooled with overall dimensions of 30” x 46” x 60” and is designed as a Class 1 system. This lidar is capable of measuring wind velocities greater than 120 +/- 0.2 m/s over ranges greater than 10 km and with a range resolution of less than 15 m. This compact and modular system is anticipated to provide mobility, reliability, and ease of field deployment for wind and wake vortex measurements. The current lidar architecture is amenable for trace gas sensing and as such it is being evolved for airborne and space based platforms. In this paper, the key features of wind lidar instrumentation and its functionality are discussed followed by results of recent wind forecast measurements on a wind farm.

Published

2016

33. Mathematical Modeling of the Kinetics of Gibbsite Extraction and Kaolinite Dissolution/Desilication in the Bayer Process

Author

Narasimha S. Raghavan and George Dennison Fulford

Subjects

Bauxite, Materials science, Mass transfer, Diffusion, engineering, Thermodynamics, Kaolinite, Mineralogy, Orthogonal collocation, engineering.material, Gibbsite, Bayer process, Dissolution

Abstract

An unsteady-state mathematical model incorporating the rates of external mass transfer, intraparticle diffusion and chemical reaction has been developed to describe the extraction of gibbsite from bauxite particles allowing for the competitive reactions — gibbsite and free caustic, and kaolinite and free caustic accompanied by the reprecipitation of the dissolved silica (as sodalite). The governing partial differential equations have been reduced to ordinary differential equations by the method of orthogonal collocation and solved using a standard variable step integration algorithm in terms of two parameters characteristic of the nature of the bauxite. The usefulness of the model is demonstrated by providing examples of cases where it has been applied to elucidate process performance under conditions that are envisaged for the future, or to gain ar insight into reasons for certain apparently anomalous trends in process stream quality in terms of silica concentrations.

Published

2016

34. Shock-Wave Consolidation of Nanostructured Bismuth Telluride Powders

Author

Jan Beck, Manuel Alvarado, David C. Nemir, Lawrence E Murr, Narasimha S. Prasad, and Mathew Nowell

Subjects

Shock wave, Diffraction, Materials science, Nanostructure, Scanning electron microscope, Alloy, Metallurgy, engineering.material, Condensed Matter Physics, Electronic, Optical and Magnetic Materials, chemistry.chemical_compound, Grain growth, chemistry, Thermoelectric effect, Materials Chemistry, engineering, Bismuth telluride, Electrical and Electronic Engineering

Abstract

Nanostructured thermoelectric powders can be produced using a variety of techniques. However, it is very challenging to build a bulk material from these nanopowders without losing the nanostructure. In the present work, nanostructured powders of the bismuth telluride alloy system are obtained in kilogram quantities via a gas atomization process. These powders are characterized using a variety of methods including scanning electron microscopy, transition electron microscopy, and x-ray diffraction analysis. Then the powders are consolidated into a dense bulk material using a shock-wave consolidation technique whereby a nanopowder-containing tube is surrounded by explosives and then detonated. The resulting shock wave causes rapid fusing of the powders without the melt and subsequent grain growth of other techniques. We describe the test setup and consolidation results.

Published

2012

35. Adaptation to larval malnutrition does not affect fluctuating asymmetry in Drosophila melanogaster

Author

Vijendravarma RK, Narasimha S, and Kawecki TJ

Abstract

Both stress during development and response to directional selection were proposed to lead to reduced developmental stability of an organism commonly measured as fluctuating asymmetry. Here we investigated the direct physiological (plastic) effect of larval malnutrition and the effect of evolutionary adaptation to this form of stress on developmental stability measured as fluctuating asymmetry of several wing measurements. The measurements were made on female Drosophila melanogaster from populations which in the course of 84 generations of experimental evolution adapted to malnutrition and from non adapted controls raised either under standard conditions or under nutritional stress. We detected no changes in the levels of fluctuating asymmetry as either a plastic or an evolutionary response. Thus neither nutritional stress within lifetime nor directional selection it imposes seems to affect developmental stability in flies.

Published

2011

36. Phase I and Correlative Biology Study of Cilengitide in Patients With Recurrent Malignant Glioma

Author

Tom Mikkelsen, Steven S. Rosenfeld, Yu Zhang, Stuart A. Grossman, Kathryn A. Carson, Gretchen A. Cloud, Fred H. Hochberg, L. Burt Nabors, Narasimha S. Akella, Joy D. Fisher, Sabine M. Wittemer, and A. Dimitrios Colevas

Subjects

Cancer Research, medicine.medical_specialty, Maximum Tolerated Dose, Antineoplastic Agents, Cilengitide, Hypoglycemia, Gastroenterology, Article, Cohort Studies, chemistry.chemical_compound, Recurrence, Internal medicine, Glioma, medicine, Humans, Bone pain, medicine.diagnostic_test, Brain Neoplasms, business.industry, Magnetic resonance imaging, medicine.disease, Magnetic Resonance Imaging, Surgery, Clinical trial, Oncology, chemistry, Toxicity, medicine.symptom, Hyponatremia, business, Snake Venoms

Abstract

Purpose This multi-institutional phase I trial was designed to determine the maximum-tolerated dose (MTD) of cilengitide (EMD 121974) and to evaluate the use of perfusion magnetic resonance imaging (MRI) in patients with recurrent malignant glioma. Patients and Methods Patients received cilengitide twice weekly on a continuous basis. A treatment cycle was defined as 4 weeks. Treatment-related dose-limiting toxicity (DLT) was defined as any grade 3 or 4 nonhematologic toxicity or grade 4 hematologic toxicity of any duration. Results A total of 51 patients were enrolled in cohorts of six patients to doses of 120, 240, 360, 480, 600, 1,200, 1,800, and 2,400 mg/m2 administered as a twice weekly intravenous infusion. Three patients progressed early and were inevaluable for toxicity assessment. The DLTs observed were one thrombosis (120 mg/m2), one grade 4 joint and bone pain (480 mg/m2), one thrombocytopenia (600 mg/m2) and one anorexia, hypoglycemia, and hyponatremia (800 mg/m2). The MTD was not reached. Two patients demonstrated complete response, three patients had partial response, and four patients had stable disease. Perfusion MRI revealed a significant relationship between the change in tumor relative cerebral blood flow (rCBF) from baseline and area under the plasma concentration versus time curve after 16 weeks of therapy. Conclusion Cilengitide is well tolerated to doses of 2,400 mg/m2, durable complete and partial responses were seen in this phase I study, and clinical response appears related to rCBF changes.

Published

2007

37. Tabletop demonstration of non-Interaction of photons and non-interference of waves

Author

Chandra Roychoudhuri and Narasimha S. Prasad

Subjects

Physics, Photon, business.industry, Scattering, Interference (wave propagation), Laser, Electromagnetic radiation, law.invention, Superposition principle, Amplitude, Optics, law, business, Beam (structure)

Abstract

Recently, Non- Interaction of Waves or the NIW property has been proposed as a generic property of all propagating electromagnetic waves by one of the authors (CR). In other words, optical beams do not interact with each other to modify or re-distribute their field energy distribution in the absence of interacting materials. In this paper, path taken to re-create CR's original demonstration of the NIW-property as an on-site tabletop experiment is discussed. Since 1975, when the NIW demonstration was first reported, several advances in lasers and optical component design architecture have occurred. With the goal of using low cost components and having agility in setting up on non-conformable platforms for general viewing, a compact arrangement for demonstrating the NIW property was envisioned. In our experimental arrangement, a beam multiplier element was utilized to generate a set of spatially separate parallel beams out of an incident laser beam. The emerging parallel beams from the beam multiplier element were then focused on a one-sided ground glass, the flat side being towards the beam multiplier. This flat side reflects off all the incident focused beams as fanning out independent laser beams, remaining unperturbed even though they are reflecting out of a common superposed spot. It is clear that there is neither "interference between different photons", nor "a photon interferes with itself", even within a region of superposed beams. In contrast, the ground glass surface (same silica molecules but granular or lumpy) was anticipated to generate a set of crisp spatial fringes on its surface as in the original experiment. The fringes are due to granulated individual silica lumps responding simultaneously to the local resultant E-vectors due to all the superposed beams and are scattering energy proportional to the square modulus of the sum of all the simultaneous dipolar amplitude stimulations. The dark fringe locations imply zero resultant amplitude stimulation and hence no scattering. Due to multi-longitudinal mode nature of laser module, the fringes appeared washed out at the backside of the ground glass plate. Experimental refinements followed by our views on whether the fundamental physics behind the generation of superposition fringes by photo detectors different from those due to a ground glass are briefly discussed.

Published

2015

38. An all-fiber, modular, compact wind lidar for wind sensing and wake vortex applications

Author

Allen J. Tracy, Narasimha S. Prasad, Russel Sibell, Richard Higgins, and Steven Vetorino

Subjects

Azimuth, Scanner, Lidar, business.industry, Fiber laser, Environmental science, Modular design, business, Wake turbulence, Slip ring, Vortex, Remote sensing

Abstract

This paper discusses an innovative, compact and eyesafe coherent lidar system developed for wind and wake vortex sensing applications. With an innovative all-fiber and modular transceiver architecture, the wind lidar system has reduced size, weight and power requirements, and provides enhanced performance along with operational elegance. This all-fiber architecture is developed around fiber seed laser coupled to uniquely configured fiber amplifier modules. The innovative features of this lidar system, besides its all fiber architecture, include pulsewidth agility and user programmable 3D hemispherical scanner unit. Operating at a wavelength of 1.5457 microns and with a PRF of up to 20 KHz, the lidar transmitter system is designed as a Class 1 system with dimensions of 30"(W) x 46"(L) x 60"(H). With an operational range exceeding 10 km, the wind lidar is configured to measure wind velocities of greater than 120 m/s with an accuracy of +/- 0.2 m/s and allow range resolution of less than 15 m. The dynamical configuration capability of transmitted pulsewidths from 50 ns to 400 ns allows high resolution wake vortex measurements. The scanner uses innovative liquid metal slip ring and is built using 3D printer technology with light weight nylon. As such, it provides continuous 360 degree azimuth and 180 degree elevation scan angles with an incremental motion of 0.001 degree. The lidar system is air cooled and requires 110 V for its operation. This compact and modular lidar system is anticipated to provide mobility, reliability, and ease of field deployment for wind and wake vortex measurements. Currently, this wind lidar is undergoing validation tests under various atmospheric conditions. Preliminary results of these field measurements of wind characteristics that were recently carried out in Colorado are discussed.

Published

2015

39. Inhomogeneous thermoelectric materials: improving overall zT by localized property variations

Author

Jay R. Maddux, Patrick J. Taylor, Jan Beck, David C. Nemir, and Narasimha S. Prasad

Subjects

Grain growth, Thermoelectric generator, Thermal conductivity, Materials science, Electrical resistivity and conductivity, Seebeck coefficient, Thermoelectric effect, Nanotechnology, Composite material, Thermoelectric materials, Grain size

Abstract

The search for improved thermoelectric materials is driven in part by the desire to convert otherwise wasted low-temperature heat into useful electricity. In this work, we demonstrate a new path towards materials having higher overall zT, and consequently improved capacity to obtain more electrical power from a given content of heat. We produced alloys of (Bi,Sb) 2 Te 3 using a special gas atomization process that is capable of producing source powder material having nanometer-scale grain size. When impulse-compacted by shockwave consolidation, the obtained dense solid will retain its nanostructure because insufficient time and temperature are available for the kinetics of any appreciable grain growth to proceed. However, if there is initial non-uniformity in the properties of the source powder, or if there is stress non-symmetries during shockwave consolidation, then the obtained consolidated material may have locally inhomogeneous properties distributed throughout the material. Thermoelectric property measurements from selected regions within the consolidated sample indicate a wide distribution of properties. For example, the thermal conductivity at room temperature ranged from as low as 1.30 Watts/m-K in one region to higher than 3.00 Watts/m-K in a neighboring region. The electrical resistivity showed similar variation from as low as 0.5 m : -cm to as high as 1.5 m : -cm. Individually, those regions exhibited thermoelectric material figure- of-merit, zT values ranging between 0.3 and 0.4. However, when combined into a dense nanocomposite, the overall ensemble zT approaches 0.7 which is nearly a factor of 2 higher.

Published

2015

40. Growth and morphology of lead tin selenide for MWIR detectors

Author

Pietro Strobbia, Bradley Arnold, Narasimha S. Prasad, Narsingh B. Singh, Fow-Sen Choa, Emily Schultheis, and Christopher Cooper

Subjects

Materials science, Silicon, Annealing (metallurgy), business.industry, Band gap, Tin selenide, Nucleation, chemistry.chemical_element, chemistry.chemical_compound, chemistry, Optoelectronics, Mercury cadmium telluride, Thin film, business, Lead selenide

Abstract

A great deal of research has been performed on developing room temperature mid wave infrared (MWIR) and long wave infrared (LWIR) detectors to replace very costly mercury cadmium telluride based detectors. Among the more studied materials for high operating temperature detectors, PbSe and PbSe-type heavy metal selenides have been grown in the bulk, thin film and nano crystal morphologies. To better understand the effects of the substrate on the properties of these thin films, we have deposited lead selenide by physical vapor transport (PVT) method on highresistivity Si substrates and studied the characteristics of the film. Growth on silicon and glass substrates showed different morphologies compared to pure lead selenide material. It was seen that materials grown on a glass substrate possessed different morphology after annealing. FTIR was used to calculate bandgap information comparison with undoped PbSe. We will describe the details of the growth method, effect of substrate on nucleation and morphology of the pure and lead selenide material and band gap comparisons between substrates.

Published

2015

41. Optical communications in the mid-wave IR spectral band

Author

Narasimha S. Prasad

Subjects

3D optical data storage, business.industry, Computer science, Transmitter, Detector, Optical communication, Spectral bands, Condensed Matter Physics, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, Optics, Transmission (telecommunications), Modulation, Infrared window, Electrical and Electronic Engineering, business

Abstract

The mid-wave IR (MWIR) spectral band extending from 3 to 5 microns is considered to be a low loss atmospheric window. The MWIR wavelengths are eye safe and are attractive for several free-space applications including remote sensing of chemical and biological species, hard target imaging, range finding, target illumination, and free-space communications. Due to the nature of light-matter interaction characteristics, MWIR wavelength based systems can provide unique advantages over other spectral bands for these applications. The MWIR wavelengths are found to effectively penetrate natural and anthropogenic obscurants. Consequently, MWIR systems offer increased range performance at reduced power levels. Free-space, line-of-sight optical communication links for terrestrial as well as space based platforms using MWIR wavelengths can be designed to operate under low visibility conditions. Combined with high-bandwidth, eye-safe, covert and jam proof features, a MWIR wavelength based optical communication link could play a vital role in hostile environments. A free-space optical communication link basically consists of a transmitter, a receiver and a scheme for directing the beam towards a target. Coherent radiation in the MWIR spectral band can be generated using various types of lasers and nonlinear optical devices. Traditional modulation techniques are applicable to these optical sources. Novel detector and other subcomponent technologies with enhanced characteristics for a MWIR based system are advancing. Depending on the transmitter beam characteristics, atmospheric conditions may adversely influence the beam propagation and thereby increasing the bit error rate. For satisfactory transmission over a given range, the influence of atmosphere on beam propagation has to be analyzed. In this chapter, salient features of atmospheric modeling required for wavelength selection and performance prediction is presented. Potential optical sources and detectors for building a practical MWIR communication link are surveyed. As an illustration, the design configuration and experimental results of a recently demonstrated free-space, obscurant penetrating optical data communication link suitable for battlefield applications is discussed. In this case, the MWIR wavelength was derived using an all solid-state, compact, optical parametric oscillator device. With this device, weapon codes pertaining to small and large weapon platforms were transmitted over a range of 5 km. Furthermore, image transmission through light fog, accomplished using this hardware, is also presented. Advances in source and detector technologies are contributing to the development of cost effective systems compatible with various platforms requirements. In coming years, MWIR wavelengths are anticipated to play a vital role in various human endeavors.

Published

2005

42. Nanomorphology and performance of pure and doped lead selenide for infrared detector

Author

Christopher Cooper, Bradley Arnold, Narasimha S. Prasad, Ching Hua Su, Pietro Strobbia, Fow-Sen Choa, and Narsingh B. Singh

Subjects

Materials science, Silicon, Cadmium selenide, Annealing (metallurgy), General Engineering, Analytical chemistry, chemistry.chemical_element, Atomic and Molecular Physics, and Optics, Nanocrystalline material, chemistry.chemical_compound, chemistry, Selenide, Nanorod, Thin film, Lead selenide

Abstract

Lead selenide (PbSe) has been studied as a promising material for room temperature midwave infrared detection. We have investigated pure PbSe, as well as tin (Tn) and cadmium (Cd)-doped PbSe, nanocrystalline materials produced using physical vapor transport methods on glass and high-resistivity silicon substrates. The morphologies were investigated by scanning electron microscopy and energy-dispersive x-ray analysis. Pure PbSe layers consisted of nanocrystals that change into cubes and cuboids upon annealing. Cuboids generally grew in [100] orientation and ultimately developed in nanorods. Growth on silicon and glass substrates showed different morphologies of pure PbSe material. Parabolic and elongated morphologies resulted in nanowires on the top of thin layers of PbSe nanofilm, which acted as the substrate. Under low gradient annealing conditions (

Published

2017

43. Shockwave consolidation of nanostructured thermoelectric materials

Author

David C. Nemir, Narasimha S. Prasad, and Patrick J. Taylor

Subjects

chemistry.chemical_compound, Thermoelectric generator, Thermal conductivity, Materials science, Consolidation (soil), chemistry, Seebeck coefficient, Thermoelectric effect, Bismuth telluride, Composite material, Thermoelectric materials, Amorphous solid

Abstract

Nanotechnology based thermoelectric materials are considered attractive for developing highly efficient thermoelectric devices. Nano-structured thermoelectric materials are predicted to offer higher ZT over bulk materials by reducing thermal conductivity and increasing electrical conductivity. Consolidation of nano-structured powders into dense materials without losing nanostructure is essential towards practical device development. Using the gas atomization process, amorphous nano-structured powders were produced. Shockwave consolidation is accomplished by surrounding the nanopowder-containing tube with explosives and then detonating. The resulting shock wave causes rapid fusing of the powders without the melt and subsequent grain growth. We have been successful in generating consolidated nano-structured bismuth telluride alloy powders by using the shockwave technique. Using these consolidated materials, several types of thermoelectric power generating devices have been developed. Shockwave consolidation is anticipated to generate large quantities of nanostructred materials expeditiously and cost effectively. In this paper, the technique of shockwave consolidation will be presented followed by Seebeck Coefficient and thermal conductivity measurements of consolidated materials. Preliminary results indicate a substantial increase in electrical conductivity due to shockwave consolidation technique.

Published

2014

44. Post-flight test results of acousto-optic modulator devices subjected to space exposure

Author

Sudhir Trivedi, Jolanta Rosemeier, Narasimha S. Prasad, and Mark Diestler

Subjects

Engineering, Laser diode, business.industry, Laser, Flight test, law.invention, Semiconductor laser theory, law, Fiber laser, International Space Station, Aerospace engineering, business, Space Transportation System, Remote sensing, Space environment

Abstract

The objective of the Materials International Space Station Experiment (MISSE) is to study the performance of novel materials when subjected to the synergistic effects of the harsh space environment for several months. MISSE missions provide an opportunity for developing space qualifiable materials. Several laser and lidar components were sent by NASA Langley Research Center (LaRC) as a part of the MISSE 7 mission. The MISSE 7 module was transported to the international space station (ISS) via STS 129 mission that was launched on Nov 16, 2009. Later, the MISSE 7 module was brought back to the earth via the STS 134 that landed on June 1, 2011. The MISSE 7 module that was subjected to exposure in a space environment for more than one and a half years included fiber laser, solid-state laser gain materials, detectors, and semiconductor laser diode. Performance testing of these components is now progressing. In this paper, the results of performance testing of a laser diode module sent by NASA Langley Research Center on MISSE 7 mission will be discussed. This paper will present the comparison of pre-flight and post-flight performance of two different COTS acousto-optic modulator (AOM) devices. Post-flight measurements indicate that these two devices did not undergo any significant performance degradation.

Published

2014

45. A three-beam aerosol backscatter correlation lidar for three-component wind profiling

Author

Konstantin P. Novoselov, Anand Radhakrishnan Mylapore, Coorg R. Prasad, Sangwoo Lee, Geary K. Schwemmer, Nikhil Mehta, In Heon Hwang, Alexander Achey, Mikhail Yakshin, and Narasimha S. Prasad

Subjects

business.industry, Field of view, Velocimetry, Wind profiler, Wind speed, symbols.namesake, Lidar, Optics, Anemometer, Wind shear, symbols, Environmental science, business, Doppler effect, Remote sensing

Abstract

In this paper, we describe the development of a three-beam elastic lidar that utilizes aerosol backscatter correlation to measure three-component wind profiles for detecting and tracking aircraft wake vortices; turbulence intensity and wind shear profiles. High-resolution time-resolved wind information can currently be obtained with ultrasonic or hot-wire anemometers suitable for local point measurements, or with Doppler wind lidars that only measure line-of-sight wind speeds and have to be scanned over large measurement cone angles for obtaining three-component winds. By tracking the motion of aerosol structures along and between three near-parallel laser beams, our lidar obtains three-component wind speed profiles along the field of view (FOV) of the lidar beams. Our prototype lidar wind profiler (LWP) has three 8-inch transceiver modules placed in a near-parallel configuration on a two-axis pan-tilt scanner to measure winds up to 2km away. Passively q-switched near-infrared (1030nm) Yb:YAG lasers generate 12 - 18ns wide pulses at high repetition rate (about 10KHz) that are expanded and attenuated to eye-safe levels. Sensitive low noise detection is achieved even in daytime using a narrow FOV receiver, together with narrowband interference filters and single photoncounting Geiger-mode Si detectors. A multi-channel scaler retrieves the lidar return with 7.8ns bins (∼1.2m spatial resolution) and stores accumulated counts once every 50ms (20 profiles/sec). We adapted optical flow algorithms to obtain the movement of aerosol structures between the beams. The performance of our prototype LWP was validated using sonic anemometer measurements.

Published

2014

46. Watt-level short-length holmium-doped ZBLAN fiber lasers at 1.2 μm

Author

Jie Zong, Kort Wiersma, Xiushan Zhu, Michael D. Obland, Robert A. Norwood, N. Peyghambarian, Narasimha S. Prasad, and Arturo Chavez-Pirson

Subjects

Optical fiber, Materials science, business.industry, Lasers, Slope efficiency, Equipment Design, Laser, Atomic and Molecular Physics, and Optics, law.invention, Equipment Failure Analysis, chemistry.chemical_compound, Holmium, Optics, chemistry, Energy Transfer, law, Brillouin scattering, Fiber laser, ZBLAN, Dispersion-shifted fiber, Optoelectronics, Fiber Optic Technology, Fiber, business

Abstract

In-band core-pumped Ho3+-doped ZBLAN fiber lasers at the 1.2 μm region were investigated with different gain fiber lengths. A 2.4 W 1190 nm all-fiber laser with a slope efficiency of 42% was achieved by using a 10 cm long gain fiber pumped at a maximum available 1150 nm pump power of 5.9 W. A 1178 nm all-fiber laser was demonstrated with an output power of 350 mW and a slope efficiency of 6.5%. High Ho3+ doping in ZBLAN is shown to be effective in producing single-frequency fiber lasers and short-length fiber amplifiers immune from stimulated Brillouin scattering.

Published

2014

47. Eye-safe compact Raman light detection and ranging temperature profiler

Author

Geary K. Schwemmer, Russell Philbrick, Jie Lei, Sangwoo Lee, Coorg R. Prasad, Guangkun Li, In Heon Hwang, and Narasimha S. Prasad

Subjects

Materials science, Eye, Spectrum Analysis, Raman, law.invention, Photometry, symbols.namesake, Optics, Radiation Protection, law, Humans, Electrical and Electronic Engineering, Engineering (miscellaneous), Physics::Atmospheric and Oceanic Physics, Remote sensing, Lenses, Stray light, business.industry, Atmosphere, Lasers, Temperature, Ranging, Equipment Design, Laser, Atmospheric temperature, Atomic and Molecular Physics, and Optics, Wavelength, Lidar, Thermography, symbols, Raman spectroscopy, business, Raman scattering, Environmental Monitoring

Abstract

The vertical profile of atmospheric temperature is a principal state variable to study atmospheric stability. A lidar system, constructed using a 355 nm Nd:YAG laser transmitter, measures the temperature profile using the rotational Raman technique. In comparison with traditional Raman lidar, the major innovations are the use of a low peak power and high repetition rate laser to achieve eye-safe operation in a compact reliable instrument and the use of an angle tuning filter to select operating wavelengths. We demonstrate the capability of both nighttime and daytime measurements as a step toward a future stand-alone capability for routine measurements of important meteorological properties in the lower atmosphere.

Published

2014

48. Watt-level fluoride fiber lasers and amplifiers in the 1.2 μm region

Author

Nasser Peyghambarian, Kort Wiersma, Narasimha S. Prasad, Robert A. Norwood, Michael D. Obland, Arturo Chavez-Pirson, Xiushan Zhu, and Jie Zong

Subjects

Materials science, Optical fiber, business.industry, Polarization-maintaining optical fiber, law.invention, chemistry.chemical_compound, Optics, chemistry, Fiber Bragg grating, law, ZBLAN, Fiber laser, Optoelectronics, Dispersion-shifted fiber, business, Plastic optical fiber, Photonic-crystal fiber

Abstract

Holmium-doped ZBLAN fiber has proven to be an efficient high gain material in the 1.2 μm region. In this paper, single-mode fiber lasers and amplifiers at 1178 nm, 1190 nm, and 1200 nm are reported. Over 2 watts of continuous wave output power was achieved with a 10-cm long gain fiber.

Published

2014

49. Understanding beam alignment in a coherent lidar system

Author

Chandrasekhar Roychoudhari and Narasimha S. Prasad

Subjects

Physics, Wavefront, business.industry, Local oscillator, Detector, Single-mode optical fiber, law.invention, Lens (optics), Optics, Lidar, law, Poynting vector, Light beam, business

Abstract

Optical beam alignment in a coherent lidar (or ladar) receiver system plays a critical role in optimizing its performance. Optical alignment in a coherent lidar system dictates the wavefront curvature (phase front) and Poynting vector) matching of the local oscillator beam with the incoming receiver beam on a detector. However, this alignment is often not easy to achieve and is rarely perfect. Furthermore, optical fibers are being increasingly used in coherent lidar system receivers for transporting radiation to achieve architectural elegance. Single mode fibers also require stringent mode matching for efficient light coupling. The detector response characteristics vary with the misalignment of the two pointing vectors. Misalignment can lead to increase in DC current. Also, a lens in front of the detector may exasperate phase front and Poynting vector mismatch. Non-Interaction of Waves, or the NIW property indicates the light beams do not interfere by themselves in the absence of detecting dipoles. In this paper, we will analyze the extent of misalignment on the detector specifications using pointing vectors of mixing beams in light of the NIW property.

Published

2013

50. Does the coherent lidar system corroborate non-interaction of waves (NIW)?

Author

Narasimha S. Prasad and Chandrasekhar Roychoudhari

Subjects

Physics, Dipole, Lidar, Classical mechanics, Wavelet, Optics, business.industry, Electric field, Elliptical polarization, Polarization (waves), business, Anisotropy, Circular polarization

Abstract

The NIW (non-interaction of waves) property has been proposed by one of the coauthors. The NIW property states that in the absence of any "obstructing" detectors, all the Huygens-Fresnel secondary wavelets will continue to propagate unhindered and without interacting (interfering) with each other. Since a coherent lidar system incorporates complex behaviors of optical components with different polarizations including circular polarization for the transmitted radiation, then the question arises whether the NIW principle accommodate elliptical polarization of light. Elliptical polarization presumes the summation of orthogonally polarized electric field vectors which contradicts the NIW principle. In this paper, we present working of a coherent lidar system using Jones matrix formulation. The Jones matrix elements represent the anisotropic dipolar properties of molecules of optical components. Accordingly, when we use the Jones matrix methodology to analyze the coherent lidar system, we find that the system behavior is congruent with the NIW property.

Published

2013