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Articles 1 - 8 of 8
Full-Text Articles in Physical Sciences and Mathematics
Signal Processing Algorithms For Doppler Lidar Sensors, Samantha Grubb
Signal Processing Algorithms For Doppler Lidar Sensors, Samantha Grubb
Physics and Astronomy Honors Papers
Light detection and ranging (LiDAR) is a remote sensing technology that obtains relative distance and velocity measurements between a sensor and a defined target by using light transmitted and received from the target. FMCW Doppler LiDAR, a particular variant of LiDAR, functions by analyzing the frequency shift in the reflected light to determine the target's range and velocity. This technology plays a crucial role across various sectors including defense, aerospace, and automotive. This paper presents signal processing algorithms designed to optimize data obtained from Doppler LiDAR sensors. By applying various window functions to time domain data, the Signal-to-Noise Ratio (SNR) …
Novel As-S-Se Compositions Of Solution-Processed Chalcogenide Thin Films For Infrared Optics, Annabella Orsini
Novel As-S-Se Compositions Of Solution-Processed Chalcogenide Thin Films For Infrared Optics, Annabella Orsini
Physics and Astronomy Honors Papers
Chalcogenide glasses (ChGs) have a wide range of interdisciplinary applications. In industry, ChGs are used to vastly improve infrared sight abilities. There are, however, improvements that can be made to the films’ stability, cost, and flexibility. Our project seeks to produce thin films that have these improvements, with capabilities comparable or better than what is widely used in the field. Thin films created through solution-based processes have proven to be much more flexible in comparison to bulk glass versions. Other elements in Group 16, such as Sulfur and Selenium have shown across literature to be a cost-effective alternative to Tellurium …
Simulating Many Body Localization With Rydberg Atoms, Alicia Handian
Simulating Many Body Localization With Rydberg Atoms, Alicia Handian
Physics and Astronomy Honors Papers
In thermodynamics, interacting systems are expected to achieve equilibrium with one another over the course of time. However, there are exceptions to this rule. When systems localize, or fail to reach equilibrium, information about the initial state of the system is preserved and locally observable after long periods of time. Many-body localization focuses on systems of interacting particles that fail to thermalize. We have developed a simulation that models the behavior of a many-body quantum system. The simulation is inspired by experiments conducted by Liu, et al., in their recent publication “Time Dependence of Few Body Forster Interactions Among Ultracold …
Single-Neutron States In 51ti Via Neutron Transfer Reaction To 50ti, Jessica Nebel-Crosson
Single-Neutron States In 51ti Via Neutron Transfer Reaction To 50ti, Jessica Nebel-Crosson
Physics and Astronomy Honors Papers
My project clarifies previous measurements made for the high excitation states of titanium isotopes, specifically 51Ti. We used a single-neutron transfer reaction from a deuterium source and measured the energy difference between the initial energy of the deuterium source, the transferred neutron, and the free proton. Our analysis included creating angular distribution plots of the proton momentum and the loose assignments of the single-particle state nature for each excitation state. We took these measurements via the Super-Enge Split-Pole Spectrograph at Florida State University.
Microwave Assisted Dipole-Dipole Transitions, Jacob T. Paul
Microwave Assisted Dipole-Dipole Transitions, Jacob T. Paul
Physics and Astronomy Honors Papers
We explore this two photon assisted transition through computational and numerical analysis of possible energy levels. We calculate the matrix elements of the energy transition in detail discussing constants and the quantum mechanical possibilities of energy exchanges in these systems.
The goal is to better understand the energy exchange, so that moving forward we can control it. This paper covers the theoretical ends to controlling the energy transition by the way of two photon assisted transitions. The energy transitions take place between a dipole-dipole interaction, and a microwave photon.
Quantum Mechanical Interference In The Field Ionization Of Rydberg Atoms, Jacob A. Hollingsworth
Quantum Mechanical Interference In The Field Ionization Of Rydberg Atoms, Jacob A. Hollingsworth
Physics and Astronomy Honors Papers
Rydberg atoms are traditionally alkali metal atoms with their valence electron excited to a state of very large principle quantum number. They possess exaggerated properties, and are consequently an attractive area of study for physicists. An example of their exaggerated properties is seen in their response to the presence of an applied electric field. In this work, we study the energy distribution of Rydberg atoms when subjected to a dynamic electric field intended to ionize them.
We excite 85Rb atoms to a superposition of the 46D5/2 |mj| = 1/2 and |mj| = 3/2 states …
The Role Of Continuum States In The Field Ionization Of Rydberg Atoms, Michael P. Vennettilli
The Role Of Continuum States In The Field Ionization Of Rydberg Atoms, Michael P. Vennettilli
Physics and Astronomy Honors Papers
In an experiment performed by our collaborators at Bryn Mawr, we excite rubidium-85 to a coherent superposition of the different |mj| splittings of the 37d5/2 state induced by a small electric field. After waiting for some variable delay time, we apply a time-dependent electric field to ionize the atom and record the ionized current that arrives at the detector. Due to the initial superposition, we observe an interference pattern that depends on the delay time. This thesis describes my continued work with Dr. Carroll to develop a computational model of this experiment. Our initial method …
Using A Genetic Algorithm To Optimize An Electric Field Ionization Pulse, Tamas Budner
Using A Genetic Algorithm To Optimize An Electric Field Ionization Pulse, Tamas Budner
Physics and Astronomy Honors Papers
Experimentally, we would like to demonstrate the process of selective field ionization of electrons as evidence of quantum control in a system of ultracold rubidium-85 Rydberg atoms. In order to accomplish this, an electric field pulse which is optimized to take an initial Rydberg electron state and produce the desired ionization spectra is necessary. We utilize techniques from artificial intelligence to develop a genetic algorithm for the optimization process. Our algorithm is computationally tested on an artificially constructed quantum system consisting of four energy states. In evaluating the viability of any given field pulse, we calculate the probability of an …