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305 results on '"Jo, Gyu-Boong"'

1. Apparatus for producing single strontium atoms in an optical tweezer array

Author

Wen, Kai, Chen, Huijin, Yan, Xu, Ren, Zejian, He, Chengdong, Hajiyev, Elnur, Wong, Preston Tsz Fung, and Jo, Gyu-Boong

Subjects
Physics - Applied Physics
Abstract

We outline an experimental setup for efficiently preparing a tweezer array of $^{88}$Sr atoms. Our setup uses permanent magnets to maintain a steady-state two-dimensional magneto-optical trap (MOT) which results in a loading rate of up to $10^{8}$ s$^{-1}$ at 5 mK for the three-dimensional blue MOT. This enables us to trap $2\times10^{6}$ $^{88}$Sr atoms at 2 $\mu$K in a narrow-line red MOT with the $^{1}$S$_{0}$ $\rightarrow$ $^{3}$P$_{1}$ intercombination transition at 689 nm. With the Sisyphus cooling and pairwise loss processes, single atoms are trapped and imaged in 813 nm optical tweezers, exhibiting a lifetime of 2.5 minutes. We further investigate the survival fraction of a single atom in the tweezers and characterize the optical tweezer array using a release and recapture technique. Our platform paves the way for potential applications in atomic clocks, precision measurements, and quantum simulations., Comment: 7 pages, 5 figures

Published
2024

2. Thermodynamics of Spin-Imbalanced Fermi Gases with SU(N) Symmetric Interaction

Author

He, Chengdong, Gao, Xin-Yuan, Pak, Ka Kwan, Liu, Yu-Jun, Ren, Peng, Guo, Mengbo, Zhao, Entong, Yan, Yangqian, and Jo, Gyu-Boong

Subjects
Condensed Matter - Quantum Gases, Physics - Atomic Physics, Quantum Physics
Abstract

Thermodynamics of degenerate Fermi gases has been extensively studied through various aspects such as Pauli blocking effects, collective modes, BCS superfluidity, and more. Despite this, multi-component fermions with imbalanced spin configurations remain largely unexplored, particularly beyond the two-component scenario. In this work, we generalize the thermodynamic study of SU($N$) fermions to spin-imbalanced configurations based on density fluctuations. Theoretically, we provide closed-form expressions of density fluctuation across all temperature ranges for general spin population setups. Experimentally, after calibrating the measurements with deeply degenerate $^{173}$Yb Fermi gases under spin-balanced configurations ($N\leq$~6), we examine the density fluctuations in spin-imbalanced systems. Specifically, we investigate two-species and four-species configurations to validate our theoretical predictions. Our analysis indicates that interaction enhancement effects can be significant even in highly spin-imbalanced systems. Finally, as an application, we use this approach to examine the decoherence process. Our study provides a deeper understanding of the thermodynamic features of spin-imbalanced multi-component Fermi gases and opens new avenues for exploring complex quantum many-body systems., Comment: 6 pages, 4 figures, supplementary

Published
2024

3. Multi-reservoir enhanced loading of tweezer atom arrays

Author

Yan, Xu, He, Chengdong, Wen, Kai, Ren, Zejian, Wong, Preston Tsz Fung, Hajiyev, Elnur, and Jo, Gyu-Boong

Subjects
Physics - Atomic Physics, Condensed Matter - Quantum Gases, Quantum Physics
Abstract

We introduce a species-independent method for improved loading into a single-atom optical tweezer array, utilizing iterative loading with multiple reservoir tweezers. Demonstrated with dual wavelength tweezer arrays of $^{88}$Sr atoms, our approach achieves a 96$\%$ loading rate after four reload cycles. This method can significantly enhance existing tweezer rearrangement protocols, potentially reducing iteration time and optical power consumption, thereby enabling a larger number of atoms in a quantum logic device., Comment: 6 pages, 4 figures ; supplementary materials

Published
2024

4. Exploring the Berezinskii-Kosterlitz-Thouless Transition in a Two-dimensional Dipolar Bose Gas

Author

He, Yifei, Chen, Ziting, Zhen, Haoting, Huang, Mingchen, Parit, Mithilesh K, and Jo, Gyu-Boong

Subjects
Condensed Matter - Quantum Gases, Condensed Matter - Other Condensed Matter, Quantum Physics
Abstract

Long-range and anisotropic dipolar interactions induce complex order in quantum systems. It becomes particularly interesting in two-dimension (2D), where the superfluidity with quasi-long-range order emerges via Berezinskii-Kosterlitz-Thouless (BKT) mechanism, which still remains elusive with dipolar interactions. Here, we observe the BKT transition from a normal gas to the superfluid phase in a quasi-2D dipolar Bose gas of erbium atoms. Controlling the orientation of dipoles, we characterize the transition point by monitoring extended coherence and measuring the equation of state. This allows us to gain a systematic understanding of the BKT transition based on an effective short-range description of dipolar interaction in 2D. Additionally, we observe anisotropic density fluctuations and non-local effects in the superfluid regime, which establishes the dipolar nature of the 2D superfluid. Our results lay the ground for understanding the behavior of dipolar bosons in 2D and open up opportunities for examining complex orders in a dipolar superfluid., Comment: 8 pages, 4 figues, supplementary information

Published
2024

5. Complete Interband Transitions for Non-Hermitian Spin-Orbit-Coupled Cold-Atom Systems

Author

Liu, Dong, Ren, Zejian, Wong, Wai Chun, Zhao, Entong, He, Chengdong, Pak, Ka Kwan, Jo, Gyu-Boong, and Li, Jensen

Subjects
Quantum Physics, Physics - Applied Physics
Abstract

Recently, synthetic spin-orbit coupling has been introduced into cold-atom systems for more flexible control of the Hamiltonian, which was further made time-varying through two-photon detuning to achieve dynamic control of the cold-atom state. While an intraband transition can be adiabatically obtained, a complete interband transition, rather than a superposition of different bands, obtained through fast sweeping is usually guaranteed by having the positions of the initial and final states be far away from any band gap in the quasimomentum space. Here, by introducing an additional non-Hermitian parameter through an atom-loss contrast together with two-photon detuning as two controllable external parameters, both intraband and complete interband transitions can be achieved independent of the positions of the initial and final states. In addition, a point-source diagram approach in the 2D external parameter space is developed to visualize and predict the locations of any nonadiabatic transitions. This control protocol can have potential applications in quantum state control and quantum simulations using cold-atom systems., Comment: 21 pages, 4 figures

Published
2024

6. Creation of a tweezer array for cold atoms utilizing a generative neural network

Author

Ren, Zejian, Yan, Xu, Wen, Kai, Chen, Huijin, Hajiyev, Elnur, He, Chengdong, and Jo, Gyu-Boong

Subjects
Physics - Optics, Physics - Atomic Physics
Abstract

Optical tweezers have become essential tools for dynamically manipulating objects, ranging from microspheres or biological molecules to neutral atoms. In this study, we demonstrate the creation of tweezer arrays using a generative neural network, which allows for the trapping of neutral atoms with tunable atom arrays. We have successfully loaded cold strontium atoms into various optical tweezer patterns generated by a spatial light modulator (SLM) integrated with generative models. Our approach shortens the process time to control the SLM wtih minimal time delay, eliminating the need for repeated re-optimization of the hologram for the SLM., Comment: 5 pages, 4 figures

Published
2024

7. Two-dimensional non-Hermitian skin effect in an ultracold Fermi gas

Author

Zhao, Entong, Wang, Zhiyuan, He, Chengdong, Poon, Ting Fung Jeffrey, Pak, Ka Kwan, Liu, Yu-Jun, Ren, Peng, Liu, Xiong-Jun, and Jo, Gyu-Boong

Subjects
Condensed Matter - Quantum Gases, Condensed Matter - Other Condensed Matter, Quantum Physics
Abstract

The concept of non-Hermiticity has expanded the understanding of band topology leading to the emergence of counter-intuitive phenomena. One example is the non-Hermitian skin effect (NHSE), which involves the concentration of eigenstates at the boundary. However, despite the potential insights that can be gained from high-dimensional non-Hermitian quantum systems in areas like curved space, high-order topological phases, and black holes, the realization of this effect in high dimensions remains unexplored. Here, we create a two-dimensional (2D) non-Hermitian topological band for ultracold fermions in spin-orbit-coupled optical lattices with tunable dissipation, which exhibits the NHSE. We first experimentally demonstrate pronounced nonzero spectral winding numbers in the complex energy plane with non-zero dissipation, which establishes the existence of 2D skin effect. Further, we observe the real-space dynamical signature of NHSE in real space by monitoring the center of mass motion of atoms. Finally, we also demonstrate that a pair of exceptional points (EPs) are created in the momentum space, connected by an open-ended bulk Fermi arc, in contrast to closed loops found in Hermitian systems. The associated EPs emerge and shift with increasing dissipation, leading to the formation of the Fermi arc. Our work sets the stage for further investigation into simulating non-Hermitian physics in high dimensions and paves the way for understanding the interplay of quantum statistics with NHSE., Comment: 13 pages, 5 figures with supplementary information

Published
2023

8. Magnetic field regression using artificial neural networks for cold atom experiments

Author

Chen, Ziting, Wong, Kin To, Seo, Bojeong, Huang, Mingchen, Parit, Mithilesh K., Zhen, Haoting, Li, Jensen, and Jo, Gyu-Boong

Subjects
Physics - Instrumentation and Detectors
Abstract

Accurately measuring magnetic fields is essential for magnetic-field sensitive experiments in fields like atomic, molecular, and optical physics, condensed matter experiments, and other areas. However, since many experiments are conducted in an isolated vacuum environment that is inaccessible to experimentalists, it can be challenging to accurately determine the magnetic field. Here, we propose an efficient method for detecting magnetic fields with the assistance of an artificial neural network (NN). Instead of measuring the magnetic field directly at the desired location, we detect magnetic fields at several surrounding positions, and a trained NN can accurately predict the magnetic field at the target location. After training, we achieve a relative error of magnetic field magnitude (magnitude of error over the magnitude of magnetic field) below 0.3$\%$, and we successfully apply this method to our erbium quantum gas apparatus. This approach significantly simplifies the process of determining magnetic fields in isolated vacuum environments and can be applied to various research fields across a wide range of magnetic field magnitudes., Comment: 7 pages, 4 figures

Published
2023

9. Mirror symmetry breaking of superradiance in a dipolar BEC

Author

Seo, Bojeong, Huang, Mingchen, Chen, Ziting, Parit, Mithilesh K., He, Yifei, Chen, Peng, and Jo, Gyu-Boong

Subjects
Condensed Matter - Quantum Gases, Physics - Atomic Physics, Quantum Physics
Abstract

Dicke superradiance occurs when two or more emitters cooperatively interact via the electromagnetic field. This collective light scattering process has been extensively studied across various platforms, from atoms to quantum dots and organic molecules. Despite extensive research, the precise role of direct interactions between emitters in superradiance remains elusive, particularly in many-body systems where the complexity of interactions poses significant challenges. In this study, we investigate the effect of dipole-dipole interaction between 18,000 atoms in dipolar Bose-Einstein condensates (BECs) on the superradiance process. In dipolar BECs, we simplify the complex effect of anisotropic magnetic dipole-dipole interaction with Bogoliubov transformation. We observe that anisotropic Bogoliubov excitation breaks the mirror symmetry in decay modes of superradiance., Comment: 5 pages, 4 figures

Published
2022

10. Observing a topological phase transition with deep neural networks from experimental images of ultracold atoms

Author

Zhao, Entong, Mak, Ting Hin, He, Chengdong, Ren, Zejian, Pak, Ka Kwan, Liu, Yu-Jun, and Jo, Gyu-Boong

Subjects
Condensed Matter - Quantum Gases, Physics - Data Analysis, Statistics and Probability, Quantum Physics
Abstract

Although classifying topological quantum phases have attracted great interests, the absence of local order parameter generically makes it challenging to detect a topological phase transition from experimental data. Recent advances in machine learning algorithms enable physicists to analyze experimental data with unprecedented high sensitivities, and identify quantum phases even in the presence of unavoidable noises. Here, we report a successful identification of topological phase transitions using a deep convolutional neural network trained with low signal-to-noise-ratio (SNR) experimental data obtained in a symmetry-protected topological system of spin-orbit-coupled fermions. We apply the trained network to unseen data to map out a whole phase diagram, which predicts the positions of the two topological phase transitions that are consistent with the results obtained by using the conventional method on higher SNR data. By visualizing the filters and post-convolutional results of the convolutional layer, we further find that the CNN uses the same information to make the classification in the system as the conventional analysis, namely spin imbalance, but with an advantage concerning SNR. Our work highlights the potential of machine learning techniques to be used in various quantum systems., Comment: 7 pages, 5 figures

Published
2022
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11. Chiral control of quantum states in non-Hermitian spin-orbit-coupled fermions

Author

Ren, Zejian, Liu, Dong, Zhao, Entong, He, Chengdong, Pak, Ka Kwan, Li, Jensen, and Jo, Gyu-Boong

Subjects
Condensed Matter - Quantum Gases, Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics
Abstract

Spin-orbit coupling is an essential mechanism underlying quantum phenomena such as the spin Hall effect and topological insulators. It has been widely studied in well-isolated Hermitian systems, but much less is known about the role dissipation plays in spin-orbit-coupled systems. Here, we implement dissipative spin-orbit-coupled bands filled with ultracold fermions, and observe parity-time symmetry breaking as a result of the competition between the spin-orbit coupling and dissipation. Tunable dissipation, introduced by state-selective atom loss, enables us to tune the energy gap and close it at the critical dissipation value, the so-called exceptional point. In the vicinity of the critical point, the state evolution exhibits a chiral response, which enables us to tune the spin-orbit coupling and dissipation dynamically, revealing topologically robust chiral spin transfer when the quantum state encircles the exceptional point. This demonstrates that we can explore non-Hermitian topological states with spin-orbit coupling., Comment: 8 pages, 4 figures with supplemenary information

Published
2021

12. Active control of a diode laser with injection locking

Author

Chen, Ziting, Seo, Bojeong, Huang, Mingchen, Parit, Mithilesh K., Chen, Peng, and Jo, Gyu-Boong

Subjects
Physics - Optics, Physics - Instrumentation and Detectors
Abstract

We present a simple and effective method to implement an active stabilization of a diode laser with injection locking, which requires minimal user intervenes. The injection locked state of the diode laser is probed by a photodetector, of which sensitivity is enhanced by a narrow laser-line filter. Taking advantage of the characteristic response of laser power to spectral modes from the narrow laser-line filter, we demonstrate that high spectral purity and low intensity noise of the diode can be simultaneously maintained by an active feedback to the injected laser. Our method is intrinsically cost-effective, and does not require bulky devices, such as Fabry-Perot interferometers or wavemeters, to actively stabilize the diode laser. Based on successful implementation of this method in our quantum gas experiments, it is conceivable that our active stabilization will greatly simplify potential applications of injection locking of diode lasers in modularized or integrated optical systems., Comment: 5 pages, 5 figures

Published
2021
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14. Heuristic machinery for thermodynamic studies of SU(N) fermions with neural networks

Author

Zhao, Entong, Lee, Jeongwon, He, Chengdong, Ren, Zejian, Hajiyev, Elnur, Liu, Junwei, and Jo, Gyu-Boong

Subjects
Condensed Matter - Quantum Gases, Physics - Data Analysis, Statistics and Probability, Quantum Physics
Abstract

The power of machine learning (ML) provides the possibility of analyzing experimental measurements with an unprecedented sensitivity. However, it still remains challenging to probe the subtle effects directly related to physical observables and to understand physics behind from ordinary experimental data using ML. Here, we introduce a heuristic machinery by using machine learning analysis. We use our machinery to guide the thermodynamic studies in the density profile of ultracold fermions interacting within SU($N$) spin symmetry prepared in a quantum simulator. Although such spin symmetry should manifest itself in a many-body wavefuction, it is elusive how the momentum distribution of fermions, the most ordinary measurement, reveals the effect of spin symmetry. Using a fully trained convolutional neural network (NN) with a remarkably high accuracy of $\sim$94$\%$ for detection of the spin multiplicity, we investigate how the accuracy depends on various less-pronounced effects with filtered experimental images. Guided by our machinery, we directly measure a thermodynamic compressibility from density fluctuations within the single image. Our machine learning framework shows a potential to validate theoretical descriptions of SU($N$) Fermi liquids, and to identify less-pronounced effects even for highly complex quantum matter with minimal prior understanding., Comment: 11 pages, 5 figures, 1 table

Published
2020
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15. Effective statistical fringe removal algorithm for high-sensitivity imaging of ultracold atoms

Author

Song, Bo, He, Chengdong, Ren, Zejian, Zhao, Entong, Lee, Jeongwon, and Jo, Gyu-Boong

Subjects
Condensed Matter - Quantum Gases, Electrical Engineering and Systems Science - Image and Video Processing, Physics - Optics, Quantum Physics
Abstract

High-sensitivity imaging of ultracold atoms is often challenging when interference patterns are imprinted on the imaging light. Such image noises result in low signal-to-noise ratio and limit the capability to extract subtle physical quantities. Here we demonstrate an advanced fringe removal algorithm for absorption imaging of ultracold atoms, which efficiently suppresses unwanted fringe patterns using a small number of sample images without taking additional reference images. The protocol is based on an image decomposition and projection method with an extended image basis. We apply this scheme to raw absorption images of degenerate Fermi gases for the measurement of atomic density fluctuations and temperatures. The quantitative analysis shows that image noises can be efficiently removed with only tens of reference images, which manifests the efficiency of our protocol. Our algorithm would be of particular interest for the quantum emulation experiments in which several physical parameters need to be scanned within a limited time duration., Comment: 6 pages, 5 figures, supplementary materials

Published
2020
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16. Efficient production of a narrow-line erbium magneto-optical trap with two-stage slowing

Author

Seo, Bojeong, Chen, Peng, Chen, Ziting, Yuan, Weijun, Huang, Mingchen, Du, Shengwang, and Jo, Gyu-Boong

Subjects
Condensed Matter - Quantum Gases, Physics - Atomic Physics, Quantum Physics
Abstract

We describe an experimental setup for producing a large cold erbium (Er) sample in a narrow-line magneto-optical trap (MOT) in a simple and efficient way. We implement a pair of angled slowing beams with respect to the Zeeman slower axis, and further slow down atoms exiting from the Zeeman slower. The second-stage slowing beams enable the narrow-line MOT to trap atoms exiting from the Zeeman slower with higher velocity. This scheme is particularly useful when the Zeeman slower is at low optical power without the conventional transverse cooling between an oven and a Zeeman slower, in which case we significantly improve the loading efficiency into the MOT and are able to trap more than $10^8$ atoms in the narrow-line MOT of $^{166}$Er. This work highlights our implementation, which greatly simplifies laser cooling and trapping of Er atoms and also should benefit other similar elements., Comment: 5 pages, 4 figures

Published
2019
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17. Evidence for Bosonization in a three-dimensional gas of SU($N$) fermions

Author

Song, Bo, Yan, Yangqian, He, Chengdong, Ren, Zejian, Zhou, Qi, and Jo, Gyu-Boong

Subjects
Condensed Matter - Quantum Gases, Condensed Matter - Other Condensed Matter, Quantum Physics
Abstract

Blurring the boundary between bosons and fermions lies at the heart of a wide range of intriguing quantum phenomena in multiple disciplines, ranging from condensed matter physics and atomic, molecular and optical physics to high energy physics. One such example is a multi-component Fermi gas with SU($N$) symmetry that is expected to behave like spinless bosons in the large $N$ limit, where the large number of internal states weakens constraints from the Pauli exclusion principle. However, bosonization in SU($N$) fermions has never been established in high dimensions where exact solutions are absent. Here, we report direct evidence for bosonization in a SU($N$) fermionic ytterbium gas with tunable $N$ in three dimensions (3D). We measure contacts, the central quantity controlling dilute quantum gases, from the momentum distribution, and find that the contact per spin approaches a constant with a 1/$N$ scaling in the low fugacity regime consistent with our theoretical prediction. This scaling signifies the vanishing role of the fermionic statistics in thermodynamics, and allows us to verify bosonization through measuring a single physical quantity. Our work delivers a highly controllable quantum simulator to exchange the bosonic and fermionic statistics through tuning the internal degrees of freedom in any generic dimensions. It also suggests a new route towards exploring multi-component quantum systems and their underlying symmetries with contacts., Comment: 12 pages, 9 figures

Published
2019
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18. Collective excitations in two-dimensional SU($N$) Fermi gases with tunable spin

Author

He, Chengdong, Ren, Zejian, Song, Bo, Zhao, Entong, Lee, Jeongwon, Zhang, Yi-Cai, Zhang, Shizhong, and Jo, Gyu-Boong

Subjects
Condensed Matter - Quantum Gases, Condensed Matter - Other Condensed Matter, Condensed Matter - Strongly Correlated Electrons
Abstract

We measure collective excitations of a harmonically trapped two-dimensional (2D) SU($N$) Fermi gas of $^{173}$Yb confined to a stack of layers formed by a one-dimensional optical lattice. Quadrupole and breathing modes are excited and monitored in the collisionless regime $\lvert\ln(k_F a_{2D})\rvert\gg 1$ with tunable spin. We observe that the quadrupole mode frequency decreases with increasing number of spin components due to the amplification of the interaction effect by $N$ in agreement with a theoretical prediction based on 2D kinetic equations. The breathing mode frequency, however, is measured to be twice the dipole oscillation frequency regardless of $N$. We also follow the evolution of collective excitations in the dimensional crossover from two to three dimensions and characterize the damping rate of quadrupole and breathing modes for tunable SU($N$) fermions, both of which reveal the enhanced inter-particle collisions for larger spin. Our result paves the way to investigate the collective property of 2D SU($N$) Fermi liquid with enlarged spin., Comment: 7 pages, 4 figures

Published
2019
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19. All Optical Neural Network with Nonlinear Activation Functions

Author

Zuo, Ying, Li, Bohan, Zhao, Yujun, Jiang, Yue, Chen, You-Chiuan, Chen, Peng, Jo, Gyu-Boong, Liu, Junwei, and Du, Shengwang

Subjects
Physics - Optics, Condensed Matter - Disordered Systems and Neural Networks
Abstract

Artificial neural networks (ANNs) have now been widely used for industry applications and also played more important roles in fundamental researches. Although most ANN hardware systems are electronically based, optical implementation is particularly attractive because of its intrinsic parallelism and low energy consumption. Here, we propose and demonstrate fully-functioned all optical neural networks (AONNs), in which linear operations are programmed by spatial light modulators and Fourier lenses, and optical nonlinear activation functions are realized with electromagnetically induced transparency in laser-cooled atoms. Moreover, all the errors from different optical neurons here are independent, thus the AONN could scale up to a larger system size with final error still maintaining in a similar level of a single neuron. We confirm its capability and feasibility in machine learning by successfully classifying the order and disorder phases of a typical statistic Ising model. The demonstrated AONN scheme can be used to construct various ANNs of different architectures with the intrinsic parallel computation at the speed of light., Comment: 6 pages, 4 figures

Published
2019
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20. Collective dipole oscillations of a spin-orbit coupled Fermi gas

Author

Zhang, Shanchao, He, Chengdong, Hajiyev, Elnur, Ren, Zejian, Song, Bo, and Jo, Gyu-Boong

Subjects
Condensed Matter - Quantum Gases
Abstract

The collective dipole mode is induced and measured in a spin-orbit (SO) coupled degenerate Fermi gas of $^{173}$Yb atoms. Using a differential optical Stark shift, we split the degeneracy of three hyperfine states in the ground manifold, and independently couple consecutive spin states with the equal Raman transitions. A relatively long-lived spin-orbit-coupled Fermi gas, readily being realized with a narrow optical transition, allows to explore a single-minimum dispersion where three minima of spin-1 system merge into and to monitor collective dipole modes of fermions in the strong coupling regime. The measured oscillation frequency of the dipole mode is compared with the semi-classical calculation in the single-particle regime. Our work should pave the way towards the characterization of spin-orbit-coupled fermions with large spin $s>\frac{1}{2}$ in the strong coupling regime., Comment: 5 pages, 3 figures

Published
2018

21. Observation of nodal-line semimetal with ultracold fermions in an optical lattice

Author

Song, Bo, He, Chengdong, Niu, Sen, Zhang, Long, Ren, Zejian, Liu, Xiong-Jun, and Jo, Gyu-Boong

Subjects
Condensed Matter - Quantum Gases, Physics - Atomic Physics, Quantum Physics
Abstract

Observation of topological phases beyond two-dimension (2D) has been an open challenge for ultracold atoms. Here, we realize for the first time a 3D spin-orbit coupled nodal-line semimetal in an optical lattice and observe the bulk line nodes with ultracold fermions. The realized topological semimetal exhibits an emergent magnetic group symmetry. This allows to detect the nodal lines by effectively reconstructing the 3D topological band from a series of measurements of integrated spin textures, which precisely render spin textures on the parameter-tuned magnetic-group-symmetric planes. The detection technique can be generally applied to explore 3D topological states of similar symmetries. Furthermore, we observe the band inversion lines from topological quench dynamics, which are bulk counterparts of Fermi arc states and connect the Dirac points, reconfirming the realized topological band. Our results demonstrate the first approach to effectively observe 3D band topology, and open the way to probe exotic topological physics for ultracold atoms in high dimensions., Comment: 6 pages, 4 figures, supplementary information

Published
2018
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24. Observation of symmetry-protected topological band with ultracold fermions

Author

Song, Bo, Zhang, Long, He, Chengdong, Poon, Ting Fung Jeffrey, Hajiyev, Elnur, Zhang, Shanchao, Liu, Xiong-Jun, and Jo, Gyu-Boong

Subjects
Condensed Matter - Quantum Gases, Condensed Matter - Strongly Correlated Electrons, Quantum Physics
Abstract

Symmetry plays a fundamental role in understanding complex quantum matter, particularly in classifying topological quantum phases, which have attracted great interests in the recent decade. An outstanding example is the time-reversal invariant topological insulator, a symmetry-protected topological (SPT) phase in the symplectic class of the Altland-Zirnbauer classification. We report the observation for ultracold atoms of a noninteracting SPT band in a one-dimensional optical lattice and study quench dynamics between topologically distinct regimes. The observed SPT band can be protected by a magnetic group and a nonlocal chiral symmetry, with the band topology being measured via Bloch states at symmetric momenta. The topology also resides in far-from-equilibrium spin dynamics, which are predicted and observed in experiment to exhibit qualitatively distinct behaviors in quenching to trivial and nontrivial regimes, revealing two fundamental types of spin-relaxation dynamics related to bulk topology. This work opens the way to expanding the scope of SPT physics with ultracold atoms and studying nonequilibrium quantum dynamics in these exotic systems., Comment: 22 pages, 5 figures (main text); 10 pages, 6 figures (supplementary)

Published
2017
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25. Mean-field scaling of the superfluid to Mott insulator transition in a 2D optical superlattice

Author

Thomas, Claire K., Barter, Thomas H., Leung, Tsz-Him, Okano, Masayuki, Jo, Gyu-Boong, Guzman, Jennie, Kimchi, Itamar, Vishwanath, Ashvin, and Stamper-Kurn, Dan M.

Subjects
Condensed Matter - Quantum Gases, Physics - Atomic Physics, Quantum Physics
Abstract

The mean-field treatment of the Bose-Hubbard model predicts properties of lattice-trapped gases to be insensitive to the specific lattice geometry once system energies are scaled by the lattice coordination number $z$. We test this scaling directly by comparing coherence properties of $^{87}$Rb gases that are driven across the superfluid to Mott insulator transition within optical lattices of either the kagome ($z=4$) or the triangular ($z=6$) geometries. The coherent fraction measured for atoms in the kagome lattice is lower than for those in a triangular lattice with the same interaction and tunneling energies. A comparison of measurements from both lattices agrees quantitatively with the scaling prediction. We also study the response of the gas to a change in lattice geometry, and observe the dynamics as a strongly interacting kagome-lattice gas is suddenly "hole-doped" by introducing the additional sites of the triangular lattice.

Published
2017
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27. Multipolar Kondo Effect in $^1$S$_0$-$^3$P$_2$ Mixture of $^{173}$Yb Atoms

Author

Kuzmenko, Igor, Kuzmenko, Tetyana, Avishai, Yshai, and Jo, Gyu Boong

Subjects
Condensed Matter - Quantum Gases
Abstract

Whereas in the familiar Kondo effect the exchange interaction is dipolar, it can also be multipolar, as has been realized in a recent experiment. Here we study multipolar Kondo effect in a Fermi gas of cold $^{173}$Yb atoms. Making use of different AC polarizability of the electronic ground state Yb($^{1}$S$_{0}$) and the long-lived metastable state Yb$^{*}$($^{3}$P$_{2}$), it is suggested that the latter atoms can be localized and serve as a dilute concentration of magnetic impurities while the former ones remain itinerant. The exchange mechanism between the itinerant Yb and the localized Yb$^{*}$ atoms is analyzed and shown to be antiferromagnetic. The quadruple and octuple interactions act to enhance the Kondo temperature $T_K$ that is found to be experimentally accessible. The bare exchange Hamiltonian needs to be decomposed into dipole ($d$), quadruple ($q$) and octuple ($o$) interactions in order to retain its form under renormalization group (RG) analysis, in which the corresponding exchange constants ($\lambda_{\mathrm{d}}$, $\lambda_{\mathrm{q}}$ and $\lambda_{\mathrm{o}}$) flow independently. Numerical solution of the RG scaling equations reveals a few finite fixed points, indicating an over-screening, which suggests a non-Fermi liquid phase. The impurity contribution to the magnetic susceptibility is calculated in the weak coupling regime (${T}\gg{T}_{K}$)., Comment: 31 pages, 14 figures

Published
2016
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28. Spin-orbit coupled two-electron Fermi gases of ytterbium atoms

Author

Song, Bo, He, Chengdong, Zhang, Shanchao, Hajiyev, Elnur, Huang, Wei, Liu, Xiong-Jun, and Jo, Gyu-Boong

Subjects
Condensed Matter - Quantum Gases, Condensed Matter - Strongly Correlated Electrons, Physics - Atomic Physics
Abstract

We demonstrate all-optical implementation of spin-orbit coupling (SOC) in a two-electron Fermi gas of $^{173}$Yb atoms by coupling two hyperfine ground states with a narrow optical transition. Due to the SU($N$) symmetry of the $^1$S$_0$ ground-state manifold which is insensitive to external magnetic fields, an optical AC Stark effect is applied to split the ground spin states, which exhibits a high stability compared with experiments on alkali and lanthanide atoms, and separate out an effective spin-1/2 subspace from other hyperfine levels for the realization of SOC. The dephasing spin dynamics when a momentum-dependent spin-orbit gap being suddenly opened and the asymmetric momentum distribution of the spin-orbit coupled Fermi gas are observed as a hallmark of SOC. The realization of all-optical SOC for ytterbium fermions should offer a new route to a long-lived spin-orbit coupled Fermi gas and greatly expand our capability in studying novel spin-orbit physics with alkaline-earth-like atoms., Comment: 5 pages, 4 figures

Published
2016
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29. Coqblin-Schrieffer Model for an Ultra-cold Gas of Ytterbium atoms with Metastable States

Author

Kuzmenko, Igor, Kuzmenko, Tetyana, Avishai, Yshai, and Jo, Gyu-Boong

Subjects
Condensed Matter - Quantum Gases
Abstract

Motivated by the impressive recent advance in manipulating cold ytterbium atoms we explore and substantiate the feasibility of realizing the Coqblin-Schrieffer model in a gas of cold fermionic $^{173}$Yb atoms. Making use of different AC polarizabillity of the electronic ground state (electronic configuration $^1S_0$) and the long lived metastable state (electronic configuration $^3P_0$), it is substantiated that the latter can be localized and serve as a magnetic impurity while the former remains itinerant. The exchange mechanism between the itinerant $^1S_0$ and the localized $^3P_0$ atoms is analyzed and shown to be antiferromagnetic. The ensuing SU(6) symmetric Coqblin-Schrieffer Hamiltonian is constructed, and, using the calculated exchange constant $J$, perturbative RG analysis yield the Kondo temperature $T_K$ that is experimentally accessible. A number of thermodynamic measurable observables are calculated in the weak coupling regime $T>T_K$ (using perturbative RG analysis) and in the strong coupling regime $T

Published
2015
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30. Magnetic field regression using artificial neural networks for cold atom experiments

Author

Chen, Ziting, Wong, Kin To, Seo, Bojeong, Huang, Mingchen, Parit, Mithilesh Kumar, He, Yifei, Zhen, Haoting, Li, Jensen Tsan Hang, Jo, Gyu-Boong, Chen, Ziting, Wong, Kin To, Seo, Bojeong, Huang, Mingchen, Parit, Mithilesh Kumar, He, Yifei, Zhen, Haoting, Li, Jensen Tsan Hang, and Jo, Gyu-Boong

Abstract

Accurately measuring magnetic fields is essential for magnetic-field sensitive experiments in areas like atomic, molecular, and optical physics, condensed matter experiments, and other areas. However, since many experiments are often conducted in an isolated environment that is inaccessible to experimentalists, it can be challenging to accurately determine the magnetic field at the target location. Here, we propose an efficient method for detecting magnetic fields with the assistance of an artificial neural network (NN). Instead of measuring the magnetic field directly at the desired location, we detect fields at several surrounding positions, and a trained NN can accurately predict the magnetic field at the target location. After training, we achieve a below 0.3% relative prediction error of magnetic field magnitude at the center of the vacuum chamber, and successfully apply this method to our erbium quantum gas apparatus for accurate calibration of magnetic field and long-term monitoring of environmental stray magnetic field. The demonstrated approach significantly simplifies the process of determining magnetic fields in isolated environments and can be applied to various research fields across a wide range of magnetic field magnitudes.

Published
2024

31. One-dimensional sawtooth and zigzag lattices for ultracold atoms

Author

Zhang, Ting and Jo, Gyu-Boong

Subjects
Condensed Matter - Quantum Gases, Condensed Matter - Other Condensed Matter
Abstract

We describe tunable optical sawtooth and zigzag lattices for ultracold atoms. Making use of the superlattice generated by commensurate wavelengths of light beams, tunable geometries including zigzag and sawtooth configurations can be realised. We provide an experimentally feasible method to fully control inter- ($t$) and intra- ($t'$) unit-cell tunnelling in zigzag and sawtooth lattices. We analyse the conversion of the lattice geometry from zigzag to sawtooth, and show that a nearly flat band is attainable in the sawtooth configuration by means of tuning the lattice parameters. The bandwidth of the first excited band can be reduced up to 2$\%$ of the ground bandwidth for a wide range of lattice setting. A nearly flat band available in a tunable sawtooth lattice would offer a versatile platform for the study of interaction-driven quantum many-body states with ultracold atoms., Comment: 7 pages, 4 figures

Published
2015
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32. Subwavelength Transportation of Light with Atomic Resonances

Author

Chui, Siu-Tat, Du, Shengwang, and Jo, Gyu-Boong

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics
Abstract

We propose and investigate a new type of optical waveguide made by an array of atoms without involving conventional Bragg scattering or total internal reflection. A finite chain of atoms collectively coupled through their intrinsic resonance supports a propagating mode with minimal radiative loss when the array spacing $a$ is around 0.6$\lambda_0/2\pi$ where $\lambda_0$ is the wavelength of the nearly resonant optical transition. We find that the transportation is robust with respect to position fluctuation and remains possible when the atoms are placed on a circle. Our result paves the way to implement the subwavelength transportation of light in integrated optical circuits with cold atoms., Comment: 6 pages, 4 figures

Published
2015
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35. Ultracold Atoms in a Tunable Optical Kagome Lattice

Author

Jo, Gyu-Boong, Guzman, Jennie, Thomas, Claire K., Hosur, Pavan, Vishwanath, Ashvin, and Stamper-Kurn, Dan M.

Subjects
Condensed Matter - Quantum Gases, Physics - Atomic Physics, Quantum Physics
Abstract

Geometrically frustrated systems with a large degeneracy of low energy states are of central interest in condensed-matter physics. The kagome net - a pattern of corner-sharing triangular plaquettes - presents a particularly high degree of frustration, reflected in the non-dispersive orbital bands. The ground state of the kagome quantum antiferromagnet, proposed to be a quantum spin liquid or valence bond solid, remains uncertain despite decades of work. Solid-state kagome magnets suffer from significant magnetic disorder or anisotropy that complicates the interpretation of experimental results. Here, we realize the kagome geometry in a two-dimensional optical superlattice for ultracold $^{87}$Rb atoms. We employ atom optics to characterize the lattice as it is tuned between various geometries, including kagome, one-dimensional stripe, and decorated triangular lattices, allowing for a sensitive control of frustration. The lattices implemented in this work offer a near-ideal realization of a paradigmatic model of many-body quantum physics., Comment: 5 pages, 4 figures, 1 table

Published
2011
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36. Response to comment by Tin-Lun Ho on 'Itinerant Ferromagnetism in a Strongly Interacting Fermi Gas of Ultracold Atoms', Science 325, 1521 (2009)

Author

Jo, Gyu-Boong, Lee, Ye-Ryoung, Choi, Jae-Hoon, Christensen, Caleb A., Kim, Tony H., Thywissen, Joseph H., Pritchard, David E., and Ketterle, Wolfgang

Subjects
Condensed Matter - Quantum Gases, Condensed Matter - Strongly Correlated Electrons
Abstract

Ho claims in his comment that our experiment is direct evidence that itinerant ferromagnetism does not exist in ultracold Fermi gases. This claim is incorrect and based on an invalid estimate of relaxation times and an erroneous interpretation of the detectability of ferromagnetic domains. We point out that the experimental evidence is consistent with the existence of ferromagnetism, but further experiments are needed to distinguish a ferromagnetic ground state from a non-magnetic ground state with ferromagnetic correlations., Comment: 3 pages, 0 figures; Science decided not to publish the technical comment and the reply

Published
2009

37. Itinerant Ferromagnetism in a Fermi Gas of Ultracold Atoms

Author

Jo, Gyu-Boong, Lee, Ye-Ryoung, Choi, Jae-Hoon, Christensen, Caleb A., Kim, Tony H., Thywissen, Joseph H., Pritchard, David E., and Ketterle, Wolfgang

Subjects
Condensed Matter - Quantum Gases, Condensed Matter - Strongly Correlated Electrons
Abstract

Can a gas of spin-up and spin-down fermions become ferromagnetic due to repulsive interactions? This question which has not yet found a definitive theoretical answer was addressed in an experiment with an ultracold two-component Fermi gas. The observation of non-monotonic behavior of lifetime, kinetic energy, and size for increasing repulsive interactions provides strong evidence for a phase transition to a ferromagnetic state. It implies that itinerant ferromagnetism of delocalized fermions is possible without lattice and band structure and validates the most basic model for ferromagnetism introduced by Stoner., Comment: 17 pages, 5 figures (incl. Supplemental Material)

Published
2009
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38. Trapping of Ultracold Atoms in a Hollow-core Photonic Crystal Fiber

Author

Christensen, Caleb A., Will, Sebastian, Saba, Michele, Jo, Gyu-Boong, Shin, Yong-Il, Ketterle, Wolfgang, and Pritchard, David

Subjects
Condensed Matter - Other Condensed Matter
Abstract

Ultracold sodium atoms have been trapped inside a hollow-core optical fiber. The atoms are transferred from a free space optical dipole trap into a trap formed by a red-detuned gaussian light mode confined to the core of the fiber. We show that at least 5% of the atoms held initially in the free space trap can be loaded into the core of the fiber and retrieved outside., Comment: 4 pages, 3 figures, corrected author list, added refs, changed figs, changed content, accepted by PRA

Published
2008
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46. Observation of exceptional points and skin effect in a 2D non-Hermitian topological band

Author

Zhao, Entong, He, Chengdong, Pak, Ka Kwan, Liu, Yujun, Ren, Peng, Jo, Gyu Boong, Zhao, Entong, He, Chengdong, Pak, Ka Kwan, Liu, Yujun, Ren, Peng, and Jo, Gyu Boong

Abstract

The open quantum system, which can be effectively described by a non-Hermitian Hamiltonian, often shows a spectral singularity known as exceptional points. Recently, the concept of non-Hermitian has also been generalized to the lattice system in which the exceptional points are created in the band structure in momentum space and many intriguing phenomena have been theoretically explored. In this talk, we report the realization of a 2D non-Hermitian topological band in an optical Raman lattice with tunable dissipation for ultracold fermions. Within this platform, we observe the emergence and shift of the exceptional points in our 2D topological band when the spin-dependent dissipation increases. With momentum-dependent Rabi spectroscopy, the band gap information can be reconstructed from the time evolution of spin texture. The reconstructed spectral topology in the complex energy plane further indicates the existence of skin effect in our optical Raman lattice system. It is expected that this platform would allow us to further expand the possibilities to explore the unique phenomena in non-Hermitian lattice systems.

Published
2023

47. Realization of a quasi-two dimensional dipolar Bose gas

Author

Chen, Ziting, He, Yifei, Huang, Mingchen, Parit, Mithilesh Kumar, Zhen, Haoting, Jo, Gyu Boong, Chen, Ziting, He, Yifei, Huang, Mingchen, Parit, Mithilesh Kumar, Zhen, Haoting, and Jo, Gyu Boong

Abstract

Lanthanide atoms with a large magnetic dipole moment, such as erbium and dysprosium, have attracted significant attention in quantum simulation benefitting from strong dipole-dipole interactions. Such long-ranged and anisotropic interaction gives rise to novel quantum states including quantum droplets and dipolar supersolids. However, while many predictions have been made on quasi-two dimensional dipolar Bose gases, such as anisotropic excitation spectrum and anisotropic coherence properties of superfluid, to date, experimental realization remains challenging. Here, we present the realization of quasi-two-dimensional dipolar Bose gas of erbium, where tight confinement is provided by an optical sheet trap and kinematically two-dimensional conditions are satisfied. To assess two-dimensional superfluidity arising from the Berezinsky-Kosterlitz-Thouless transition, we systematically monitor the momentum information of the sample by means of a momentum-focusing technique. Preliminary results will be discussed.

Published
2023

48. Observation of superradiant light scattering from a phase fluctuating dipolar Bose-Einstein condensate

Author

Huang, Mingchen, Seo, Bojeong, Chen, Ziting, Parit, Mithilesh Kumar, He, Yifei, Zhen, Haoting, Jo, Gyu Boong, Huang, Mingchen, Seo, Bojeong, Chen, Ziting, Parit, Mithilesh Kumar, He, Yifei, Zhen, Haoting, and Jo, Gyu Boong

Abstract

Collective light scattering in a Bose-Einstein condensate (BEC) has been extensively studied by using its unique coherence property. However, most experiments have explored superradiant light scattering with closed-shell atoms (e.g. alkali and alkaline-earth-like atoms) in the regime where only s-wave interactions are present. Here, we experimentally combine tunable s-wave scattering with dipolar interactions in a BEC of Er atoms. By tuning s-wave interaction strength through the Feshbach resonance, we tune the superradiance threshold with increasing phase fluctuations. We also observe an asymmetric superradiant scattering in a dipolar BEC by changing the direction of the external magnetic field. This collective light scattering opens a new way of probing dipolar quantum liquids in a BEC.

Published
2023

49. Superradiance in a many-body system of tilted dipoles of erbium atoms

Author

Parit, Mithilesh Kumar, Huang, Mingchen, Seo, Bojeong, Chen, Ziting, He, Yifei, Zhen, Haoting, Jo, Gyu Boong, Parit, Mithilesh Kumar, Huang, Mingchen, Seo, Bojeong, Chen, Ziting, He, Yifei, Zhen, Haoting, and Jo, Gyu Boong

Abstract

Superradiance is the coherent spontaneous emission from a many-body system, owing to its origin in the simultaneous cooperative interaction among its constituents, initially predicted by R. H. Dicke in 1954. It has been a subject of intense study in various systems, especially in atomic systems. In this poster, we will present our recent observation on superradiant light scattering in a dipolar Bose-Einstein condensate (BEC) of Er atoms [1]. We systematically investigate how s-wave and dipolar interactions affect superradiant light scattering. Our finding opens a new way of characterizing many-body quantum states with light scattering. As an example, we examine the collective light scatter across the phase transition from a dipolar BEC to a quantum droplet.

Published
2023

50. Density fluctuation dynamics in SU(N)-symmetric fermions

Author

He, Chengdong, Zhao, Entong, Pak, Ka Kwan, Liu, Yujun, Ren, Peng, Jo, Gyu Boong, He, Chengdong, Zhao, Entong, Pak, Ka Kwan, Liu, Yujun, Ren, Peng, and Jo, Gyu Boong

Abstract

Spin multiplicity N affects thermodynamics in a SU(N)-symmetric Fermi gas, in which intriguing properties have been extensively studied theoretically and experimentally. However, there is still a lack of study about thermodynamics in imbalanced SU(N) fermions, especially when a system undergoes non-equilibrium dynamics. In this talk, we will introduce our studies about the imbalanced SU(N) degenerate Fermi gas of tunable spin configuration through density fluctuation measurements. This approach enables monitoring non-equilibrium dynamics of imbalanced SU(N) fermions after the sudden quench of spin configuration. Our findings may extend our understanding of SU(N)-symmetric Fermi liquid and its spin diffusion.

Published
2023

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