Ye Group Theses
Ye Group Theses
2025
C.. Miller, Spin-Motion Dynamics With Ultracold Polar Molecules, ÂÌñ»»ÆÞ, 2025.
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A.G. Aeppli, Clock With 8 X 10^{-19} Systematic Uncertainty, ÂÌñ»»ÆÞ, 2025.
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C.. Zhang, Thorium-229 Nuclear Clock Using a VUV Frequency Comb, ÂÌñ»»ÆÞ, 2025.
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2024
J.J. Burau, Laser-Cooling and Collisions of Ultracold YO Molecules, University of Colorado, 2024.
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W.. Milner, Advancing Optical Lattice Clocks: From Cryogenic Silicon Cavities to Superexchange Interactions, ÂÌñ»»ÆÞ, 2024.
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T.H. Wright, Stray Fields and The Electron’s Electric Dipole Moment, ÂÌñ»»ÆÞ, 2024.
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2023
K.B. Ng, The ThF+ EEDM Experiment: Concept, Design, and Characterization, ÂÌñ»»ÆÞ, 2023.
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R.B. Hutson, Probing and Controlling Many-Body Interactions in a Simple Cubic Optical Lattice Clock, ÂÌñ»»ÆÞ, 2023.
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N.. Schlossberger, An Apparatus for Measuring the Electron’s Electric Dipole Moment in Trapped ThF+, ÂÌñ»»ÆÞ, 2023.
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J.M. Robinson, Enhancing Optical Clocks With Ultrastable Lasers and Spin-Squeezing, ÂÌñ»»ÆÞ, 2023.
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D.. Kedar, A Fully Crystalline Cryogenic Reference Cavity, ÂÌñ»»ÆÞ, 2023.
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2022
K.. Matsuda, Tunable Dipolar Interactions and Collisional Shielding in a Quantum Gas of Polar Molecules, ÂÌñ»»ÆÞ, 2022.
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W.G. Tobias, Degenerate Polar Molecules With Controlled Interactions and Reactivity, ÂÌñ»»ÆÞ, 2022.
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T.. Bothwell, A Wannier-Stark Optical Lattice Clock With Extended Coherence Times, ÂÌñ»»ÆÞ, 2022.
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2021
L.. Sonderhouse, Quantum Gas Engineering for Atomic Clocks, ÂÌñ»»ÆÞ, 2021.
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Y.. Wu, Creating a Dense Sample of Ultracold YO Molecules in an Optical Lattice, ÂÌñ»»ÆÞ, 2021.
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2020
X.. Xie, Precise Calibrations of Few-Body Physics in Potassium-39: Experiment and Theory, ÂÌñ»»ÆÞ, 2020.
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2019
B.. Changala, High Resolution Infrared Spectroscopy of Complex Polyatomic Molecules, ÂÌñ»»ÆÞ, 2019.
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D.L. Reens, Pushing the Limits for Directly Cooled Molecules, ÂÌñ»»ÆÞ, 2019.
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W.. Cairncross, Searching for Time-Reversal Symmetry Violation With Molecular Ions: Quantum State Control and Photofragment Imaging, ÂÌñ»»ÆÞ, 2019.
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R.. Chapurin, Precise Measurements of Few-Body Physics in Ultracold 39K Bose Gas, ÂÌñ»»ÆÞ, 2019.
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H.. Wu, Achieving a Large Density of Hydroxyl Radicals for Cold Collisions, ÂÌñ»»ÆÞ, 2019.
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2018
A.. Collopy, A Three-Dimensional MOT of YO Towards Narrow-Line Cooling, ÂÌñ»»ÆÞ, 2018.
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S.. Bromley, Many-Body Physics in an Optical Lattice Clock, ÂÌñ»»ÆÞ, 2018.
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2017
J.P. Covey, Enhanced Optical and Electric Manipulation of a Quantum Gas of KRb Molecules, ÂÌñ»»ÆÞ, 2017.
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B.J. Bjork, Elucidating Reaction Kinetics With Time-Resolved Frequency Comb Spectroscopy, ÂÌñ»»ÆÞ, 2017.
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S.L. Campbell, A Fermi-Degenerate Three-Dimensional Optical Lattice Clock, ÂÌñ»»ÆÞ, 2017.
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2016
M.. Grau, Measuring the Electron Electric Dipole Moment With Trapped Molecular Ions, ÂÌñ»»ÆÞ, 2016.
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C.. Benko, Extreme Ultraviolet Frequency Combs for Precision Measurement and Strong-Field Physics, ÂÌñ»»ÆÞ, 2016.
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S.A. Moses, A Quantum Gas of Polar Molecules in an Optical Lattice, ÂÌñ»»ÆÞ, 2016.
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2015
N.D. Oppong, Towards a Degenerate Fermi Gas of Strontium-87 in a 3D Optical Lattice, ÂÌñ»»ÆÞ, 2015.
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M.. Yeo, The Laser Cooling and Magneto-Optical Trapping of the YO Molecule, ÂÌñ»»ÆÞ, 2015.
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T.L. Nicholson, A New Record in Atomic Clock Performance, ÂÌñ»»ÆÞ, 2015.
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2014
M.N. Bishof, Understanding Atomic Interactions in an Optical Lattice Clock and Using Them to Study Many-Body Physics, ÂÌñ»»ÆÞ, 2014.
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K.C. Cossel, Techniques in Molecular Spectroscopy: From Broad Bandwidth to High Resolution, ÂÌñ»»ÆÞ, 2014.
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B.J. Bloom, Building a Better Atomic Clock, ÂÌñ»»ÆÞ, 2014.
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J.G. Bohnet, A Superradiant Laser and Spin Squeezed States: Collective Phenomena in a Rubidium Cavity QED System for Enhancing Precision Measurements, ÂÌñ»»ÆÞ, 2014.
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2013
H.. Loh, Search for an Electron Electric Dipole Moment With Trapped Molecular Ions, ÂÌñ»»ÆÞ, 2013.
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M.J. Martin, Quantum Metrology and Many-Body Physics: Pushing the Frontier of the Optical Lattice Clock, ÂÌñ»»ÆÞ, 2013.
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2012
B.K. Stuhl, Ultracold Molecules for the Masses: Evaporative Cooling and Magneto-Optical Trapping, ÂÌñ»»ÆÞ, 2012.
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L.C. Sinclair, Development of Frequency Comb Velocity-Modulation Spectroscopy, Spectroscopy of HfF+ and the JILA EEDM Experiment, ÂÌñ»»ÆÞ, 2012.
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B.. Neyenhuis, Ultracold Polar KRb Molecules in Optical Lattices, ÂÌñ»»ÆÞ, 2012.
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2011
D.. Yost, Development of an Extreme Ultraviolet Frequency Comb for Precision Spectroscopy, ÂÌñ»»ÆÞ, 2011.
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S.. Blatt, Ultracold Collisions and Fundamental Physics With Strontium, ÂÌñ»»ÆÞ, 2011.
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2010
M.H.G. de Miranda, Control of Dipolar Collisions in the Quantum Regime, ÂÌñ»»ÆÞ, 2010.
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B.C. Sawyer, Cold Polar Molecules for Novel Collision Experiments at Low Energies, ÂÌñ»»ÆÞ, 2010.
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2009
K.-K.. Ni, A Quantum Gas of Polar Molecules, ÂÌñ»»ÆÞ, 2009.
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M.J. Thorpe, Cavity-Enhanced Direct Frequency Comb Spectroscopy, ÂÌñ»»ÆÞ, 2009.
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2008
A.D. Ludlow, The Strontium Optical Lattice Clock: Optical Spectroscopy With Sub-Hertz Accuracy, ÂÌñ»»ÆÞ, 2008.
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M.C. Stowe, Direct Frequency Comb Spectroscopy and High-Resolution Coherent Control, ÂÌñ»»ÆÞ, 2008.
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2007
S.M. Foreman, Femtosecond Frequency Combs for Optical Clocks and Timing Transfer, ÂÌñ»»ÆÞ, 2007.
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M.M. Boyd, High Precision Spectroscopy of Strontium in an Optical Lattice: Towards a New Standard for Frequency and Time, ÂÌñ»»ÆÞ, 2007.
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2006
E.R. Hudson, Experiments on Cold Molecules Produced via Stark Deceleration, ÂÌñ»»ÆÞ, 2006.
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2005
S.. Blatt, Precision Spectroscopy in 1D Optical Lattices, ÂÌñ»»ÆÞ, 2005.
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A.. Marian, Direct Frequency Comb Spectroscopy for Optical Frequency Metrology and Coherent Interactions, ÂÌñ»»ÆÞ, 2005.
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K.W. Holman, Distribution of an Ultrastable Frequency Reference Using Optical Frequency Combs, ÂÌñ»»ÆÞ, 2005.
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L.. Chen, High-Precision Spectroscopy of Molecular Iodine: From Optical Frequency Standards to Global Descriptions of Hyper...Ne Interactions and Associated Electronic Structure, ÂÌñ»»ÆÞ, 2005.
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