Your search keyword '"Kim, Yoon Ho"' showing total 894 results

1. Simultaneous Trapping of Two Optical Pulses in an Atomic Ensemble as Stationary Light Pulses

Author

Kim, U-Shin and Kim, Yoon-Ho

Subjects

Quantum Physics

Abstract

The stationary light pulse (SLP) refers to a zero-group-velocity optical pulse in an atomic ensemble prepared by two counter-propagating driving fields. Despite the uniqueness of an optical pulse trapped within an atomic medium without a cavity, observations of SLP so far have been limited to trapping a single optical pulse due to the stringent SLP phase-matching condition, and this has severely hindered the development of SLP-based applications. In this paper, we first show theoretically that the SLP process in fact supports two phase-matching conditions and we then utilize the result to experimentally demonstrate simultaneous SLP trapping of two optical pulses for the duration from 0.8 $\mu$s to 2.0 $\mu$s. The characteristic dissipation time, obtained by the release efficiency measurement from the SLP trapping state, is 1.22 $\mu$s, which corresponds to an effective Q-factor of $2.9\times 10^9$. Our work is expected to bring forth interesting SLP-based applications, such as, efficient photon-photon interaction, spatially multi-mode coherent quantum memory, creation of exotic photonic gas states, etc.

Published

2022

2. Trapping a Free-propagating Single-photon into an Atomic Ensemble as a Quantum Stationary Light Pulse

Author

Kim, U-Shin, Ihn, Yong Sup, Lee, Chung-Hyun, and Kim, Yoon-Ho

Subjects

Quantum Physics

Abstract

Efficient photon-photon interaction is one of the key elements for realizing quantum information processing. The interaction, however, must often be mediated through an atomic medium due to the bosonic nature of photons, and the interaction time, which is critically linked to the efficiency, depends on the properties of the atom-photon interaction. While the electromagnetically induced transparency effect does offer the possibility of photonic quantum memory, it does not enhance the interaction time as it fully maps the photonic state to an atomic state. The stationary light pulse (SLP) effect, on the contrary, traps the photonic state inside an atomic medium with zero group velocity, opening up the possibility of the enhanced interaction time. In this work, we report the first experimental demonstration of trapping a free-propagating single-photon into a cold atomic ensemble via the quantum SLP (QSLP) process. We conclusively show that the quantum properties of the single-photon state are preserved well during the QSLP process. Our work paves the way to new approaches for efficient photon-photon interactions, exotic photonic states, and many-body simulations in photonic systems.

Published

2022

3. Heisenberg-limited metrology via weak-value amplification without using entangled resources

Author

Kim, Yosep, Yoo, Seung-Yeun, and Kim, Yoon-Ho

Subjects

Quantum Physics

Abstract

Weak-value amplification (WVA) provides a way for amplified detection of a tiny physical signal at the expense of a lower detection probability. Despite this trade-off, due to its robustness against certain types of noise, WVA has advantages over conventional measurements in precision metrology. Moreover, it has been shown that WVA-based metrology can reach the Heisenberg-limit using entangled resources, but preparing macroscopic entangled resources remains challenging. Here we demonstrate a novel WVA scheme based on iterative interactions, achieving the Heisenberg-limited precision scaling without resorting to entanglement. This indicates that the perceived advantages of the entanglement-assisted WVA are in fact due to iterative interactions between each particle of an entangled system and a meter, rather than coming from the entanglement itself. Our work opens a practical pathway for achieving the Heisenberg-limited WVA without using fragile and experimentally-demanding entangled resources., Comment: 6 pages, 4 figures

Published

2021

4. Quantum teleportation is a reversal of quantum measurement

Author

Lee, Seung-Woo, Im, Dong-Gil, Kim, Yoon-Ho, Nha, Hyunchul, and Kim, M. S.

Subjects

Quantum Physics

Abstract

We introduce a generalized concept of quantum teleportation in the framework of quantum measurement and reversing operation. Our framework makes it possible to find an optimal protocol for quantum teleportation enabling a faithful transfer of unknown quantum states with maximum success probability up to the fundamental limit of the no-cloning theorem. Moreover, an optimized protocol in this generalized approach allows us to overcome noise in quantum channel beyond the reach of existing teleportation protocols without requiring extra qubit resources. Our proposed framework is applicable to multipartite quantum communications and primitive functionalities in scalable quantum architectures., Comment: 17 pages, 6 figures

Published

2021

5. Benchmarking quantum tomography completeness and fidelity with machine learning

Author

Teo, Yong Siah, Shin, Seongwook, Jeong, Hyunseok, Kim, Yosep, Kim, Yoon-Ho, Struchalin, Gleb I., Kovlakov, Egor V., Straupe, Stanislav S., Kulik, Sergei P., Leuchs, Gerd, and Sanchez-Soto, Luis L.

Subjects

Quantum Physics

Abstract

We train convolutional neural networks to predict whether or not a set of measurements is informationally complete to uniquely reconstruct any given quantum state with no prior information. In addition, we perform fidelity benchmarking based on this measurement set without explicitly carrying out state tomography. The networks are trained to recognize the fidelity and a reliable measure for informational completeness. By gradually accumulating measurements and data, these trained convolutional networks can efficiently establish a compressive quantum-state characterization scheme by accelerating runtime computation and greatly reducing systematic drifts in experiments. We confirm the potential of this machine-learning approach by presenting experimental results for both spatial-mode and multiphoton systems of large dimensions. These predictions are further shown to improve when the networks are trained with additional bootstrapped training sets from real experimental data. Using a realistic beam-profile displacement error model for Hermite-Gaussian sources, we further demonstrate numerically that the orders-of-magnitude reduction in certification time with trained networks greatly increases the computation yield of a large-scale quantum processor using these sources, before state fidelity deteriorates significantly., Comment: 25 pages, 22 figures, relevant GitHub repository: https://github.com/ACAD-repo/ICCNet-FidNet (Changes since v1: Updated Fig. 8 and caption, new Sec. IV E, updated acknowledgments, new Appendix D, typo corrections)

Published

2021

6. Distance sensing emerging from second-order interference of thermal light

Author

Pepe, Francesco V., Chilleri, Gabriele, Scala, Giovanni, Triggiani, Danilo, Kim, Yoon-Ho, and Tamma, Vincenzo

Subjects

Quantum Physics

Abstract

We introduce and describe a technique for distance sensing, based on second-order interferometry of thermal light. The method is based on measuring correlation between intensity fluctuations on two detectors, and provides estimates of the distances separating a remote mask from the source and the detector, even when such information cannot be retrieved by first-order intensity measurements. We show how the sensitivity to such distances is intimately connected to the degree of correlation of the measured interference pattern in different experimental scenarios and independently of the spectral properties of light. Remarkably, this protocol can be also used to measure the distance of remote reflective objects in the presence of turbulence. We demonstrate the emergence of new critical parameters which benchmark the degree of second-order correlation, describing the counterintuitive emergence of spatial second-order interference not only in the absence of (first-order) coherence at both detectors but also when first order interference is observed at one of the two detectors., Comment: 6 pages, 3 figures

Published

2020

7. Dispersion cancellation in a quantum interferometer with independent single photons

Author

Im, Dong-Gil, Kim, Yosep, and Kim, Yoon-Ho

Subjects

Quantum Physics

Abstract

A key technique to perform a proper quantum information processing is to get a high visibility quantum interference between independent single photons. One of the crucial elements that affects the quantum interference is a group velocity dispersion that occurs when the single photons pass through a dispersive medium. We theoretically and experimentally demonstrate that an effect of group velocity dispersion on the two-photon interference can be cancelled if two independent single photons experience the same amount of pulse broadening. This dispersion cancellation effect can be generalized to a multi-path linear interferometer with multiple independent single photons. As multi-path quantum interferometers are at the heart of quantum communication, photonic quantum computing, and boson sampling applications, our work should find wide applicability in quantum information science., Comment: 5 pages, 5 figures

Published

2020

8. Universal compressive characterization of quantum dynamics

Author

Kim, Yosep, Teo, Yong Siah, Ahn, Daekun, Im, Dong-Gil, Cho, Young-Wook, Leuchs, Gerd, Sanchez-Soto, Luis L., Jeong, Hyunseok, and Kim, Yoon-Ho

Subjects

Quantum Physics

Abstract

Recent quantum technologies utilize complex multidimensional processes that govern the dynamics of quantum systems. We develop an adaptive diagonal-element-probing compression technique that feasibly characterizes any unknown quantum processes using much fewer measurements compared to conventional methods. This technique utilizes compressive projective measurements that are generalizable to arbitrary number of subsystems. Both numerical analysis and experimental results with unitary gates demonstrate low measurement costs, of order $O(d^2)$ for $d$-dimensional systems, and robustness against statistical noise. Our work potentially paves the way for a reliable and highly compressive characterization of general quantum devices., Comment: 10 pages, 6 figures

Published

2020

9. Observing the 'quantum Cheshire cat' effect with noninvasive weak measurement

Author

Kim, Yosep, Im, Dong-Gil, Kim, Yong-Su, Han, Sang-Wook, Moon, Sung, Kim, Yoon-Ho, and Cho, Young-Wook

Subjects

Quantum Physics

Abstract

One of the common conceptions of nature, typically derived from the experiences with classical systems, is that attributes of the matter coexist with the substance. In the quantum regime, however, the quantum particle itself and its physical property may be in spatial separation, known as the quantum Cheshire cat effect. While there have been several reports to date on the observation of the quantum Cheshire cat effect, all such experiments are based on first-order interferometry and destructive projection measurement, thus allowing simple interpretation due to measurement-induced disturbance and also subject to trivial interpretation based on classical waves. In this work, we report a genuine experimental observation of the quantum Cheshire cat effect with noninvasive weak quantum measurement as originally proposed. The use of the weak-measurement probe has allowed us to identify the location of the single-photon and that of the disembodied polarization state in a quantum interferometer. We furthermore elucidate the paradox of the quantum Cheshire cat effect as quantum interference of the transition amplitudes for the photon and the polarization state which are directly obtained from the measurement outcomes or the weak values.

Published

2020

10. A taxonomic study on the Lepidoptera (Insecta) fauna in Kosrae, Federated States of Micronesia. Part 1: Macrolepidoptera

Author

Ko, Jae-Ho, Jung, Sang Woo, Kim, Yoon-Ho, Albert, Austin, and Bayarsaikhan, Ulziijargal

Published

2024

11. Experimental linear optical computing of the matrix permanent

Author

Kim, Yosep, Hong, Kang-Hee, Huh, Joonsuk, and Kim, Yoon-Ho

Subjects

Quantum Physics

Abstract

Linear optical computing (LOC) with thermal light has recently gained attention because the problem is connected to the permanent of a Hermitian positive semidefinite matrix (HPSM), which is of importance in the computational complexity theory. Despite the several theoretical analyses on the computational structure of an HPSM in connection to LOC, the experimental demonstration and the computational complexity analysis via the linear optical system have not been performed yet. We present, herein, experimental LOC for estimating the permanent of an HPSM. From the linear optical experiments and theoretical analysis, we find that the LOC efficiency for a multiplicative error is dependent on the value of the permanent and that the lower bound of the computation time scales exponentially. Furthermore, our results are generalized and applied to LOC of permanents of unitary matrices, which can be implemented with a multi-port quantum interferometer involving single-photons at the input ports. We find that LOC with single-photons, for the permanent estimation, is on average less efficient than the most efficient classical algorithm known to date, even in ideal conditions.

Published

2019

12. Tunable up-conversion single-photon detector at telecom wavelengths

Author

Chae Jin-Woo, Kim Jin-Hun, Jeong Youn-Chang, and Kim Yoon-Ho

Subjects

frequency up-conversion, quantum communication, single-photon detector, sum-frequency generation, telecom c band, Physics, QC1-999

Abstract

Up-conversion single-photon detectors (UCSPD) are based on sum-frequency generation of the telecom band single-photons to near-infrared wavelengths at which efficient and low-noise silicon single-photon detectors are available. Moreover, because of high dynamic range of silicon single-photon detectors, UCSPD is suitable for high-speed quantum communication. UCSPDs reported to date, however, have a very narrow fixed window of detectable wavelengths, severely limiting their applications in wavelength-multiplexed quantum networks. In this work, we report a tunable UCSPD module that covers the complete telecom C band, making it suitable for quantum communication networks based on sharing wavelength-multiplexed entangled photons.

Published

2022

13. Stark Tuning of Single-Photon Emitters in Hexagonal Boron Nitride

Author

Noh, Gichang, Choi, Daebok, Kim, Jin-Hun, Im, Dong-Gil, Kim, Yoon-Ho, Seo, Hosung, and Lee, Jieun

Subjects

Physics - Applied Physics

Abstract

Single-photon emitters play an essential role in quantum technologies, including quantum computing and quantum communications. Atomic defects in hexagonal boron nitride (h-BN) have recently emerged as new room-temperature single-photon emitters in solid-state systems, but the development of scalable and tunable h-BN single-photon emitters requires external methods that can control the emission energy of individual defects. Here, by fabricating van der Waals heterostructures of h-BN and graphene, we demonstrate the electrical control of single-photon emission from atomic defects in h-BN via the Stark effect. By applying an out-of-plane electric field through graphene gates, we observed Stark shifts as large as 5.4 nm per GV/m. The Stark shift generated upon a vertical electric field suggests the existence of out-of-plane dipole moments associated with atomic defect emitters, which is supported by first-principles theoretical calculations. Furthermore, we found field-induced discrete modification and stabilization of emission intensity, which were reversibly controllable with an external electric field., Comment: 6 pages, 5 figures

Published

2018

14. Experimental characterization of quantum polarization of three-photon states

Author

Kim, Yosep, Björk, Gunnar, and Kim, Yoon-Ho

Subjects

Quantum Physics

Abstract

We experimentally investigate various quantum polarization features of three-photon quantum states, including product and entangled states with varying purity. The three-photon quantum states are categorized into six classes based on the rotation symmetry of mean, variance, and skewness of the polarization distribution. The representative three-photon quantum states in each category is prepared from double-pair emission from pulsed spontaneous parametric down-conversion and quantum interferometry. We demonstrate that the three-photon quantum states show interesting quantum polarization properties, such as, maximum sum-uncertainty and hidden polarizations., Comment: 8 pages, 4 figures

Published

2017

15. Observation of second-order temporal interference with thermal light: Interference beyond the coherence time

Author

Ihn, Yong Sup, Kim, Yosep, Tamma, Vincenzo, and Kim, Yoon-Ho

Subjects

Quantum Physics

Abstract

We report observation of a counter-intuitive phenomenon in multi-path correlation interferometry with thermal light. The intensity correlation between the outputs of two unbalanced Mach-Zehnder interferometers (UMZI) with two classically correlated beams of thermal light at the input exhibits genuine second-order interference with the visibility of $1/3$. Surprisingly, the second-order interference does not degrade at all no matter how much the path length difference in each UMZI is increased beyond the coherence length of the thermal light. Moreover, the second-order interference is dependent on the difference of the UMZI phases. These results differ substantially from those of the entangled-photon Franson interferometer which exhibits two-photon interference dependent on the sum of the UMZI phases and the interference vanishes as the path length difference in each UMZI exceeds the coherence length of the pump laser. Our work offers deeper insight into the interplay between interference and coherence in multi-photon interferometry., Comment: accepted for publication in Physical Review Letters

Published

2017

16. Limits on manipulating conditional photon statistics via interference of weak lasers

Author

Hong, Kang-Hee, Jung, Ji-Sung, Cho, Yong-Wook, Han, Sang-Wook, Moon, Sung, Oh, Kyunghwan, Kim, Yong-Su, and Kim, Yoon-Ho

Subjects

Quantum Physics

Abstract

Photon anti-bunching, measured via the Hanbury-Brown-Twiss experiment, is one of the key signatures of quantum light and is tied to sub-Poissonian photon number statistics. Recently, it has been reported that photon anti-bunching or conditional sub-Poissonian photon number statistics can be obtained via second-order interference of mutually incoherent weak lasers and heralding based on photon counting. Here, we report theoretical analysis on the limits of manipulating conditional photon statistics via interference of weak lasers. It is shown that conditional photon number statistics can become super-Poissonian in such a scheme. We, however, demonstrate explicitly that it cannot become sub-Poissonian, i.e., photon anti-bunching cannot be obtained in such a scheme. We point out that incorrect results can be obtained if one does not properly account for seemingly negligible higher-order photon number expansions of the coherent state., Comment: 9 pages, 4 figures

Published

2017

17. Reversed interplay of quantum interference and which-way information in multi-photon entangled states

Author

Ra, Young-Sik, Tichy, Malte C., Lim, Hyang-Tag, Gneiting, Clemens, Mølmer, Klaus, Buchleitner, Andreas, and Kim, Yoon-Ho

Subjects

Quantum Physics

Abstract

We report experimental studies of the multi-photon quantum interference of a two-mode three-photon entangled Fock state $|2, 1\rangle$ + $|1, 2\rangle$ impinging on a two-port balanced beam splitter. When the distinguishability between the two input paths is increased, we observe a reduction followed by a resurgence of the quantum interference signal. We ascribe this unusual behavior to the competition among contributions from distinct numbers of interfering photons. Our theoretical analysis shows that this phenomenon will occur for any entangled Fock-state input of the form $|N, M\rangle$ + $|M, N\rangle$ where M, N > 0. Our results are an indication that wave-particle duality may give rise to a wide range of, largely unexplored, phenomena in multi-particle interference.

Published

2017

18. Long-range distribution of high-quality time-bin entangled photons for quantum communication

Author

Kim, Jin-Hun, Chae, Jin-Woo, Jeong, Youn-Chang, and Kim, Yoon-Ho

Published

2022

19. Generation of a non-zero discord bipartite state with classical second-order interference

Author

Choi, Yujun, Hong, Kang-Hee, Lim, Hyang-Tag, Yune, Jiwon, Kwon, Osung, Han, Sang-Wook, Oh, Kyunghwan, Kim, Yoon-Ho, Kim, Yong-Su, and Moon, Sung

Subjects

Quantum Physics

Abstract

We report investigation on quantum discord in classical second-order interference. In particular, we theoretically show that a bipartite state with D = 0.311 of discord can be generated via classical second-order interference. We also experimentally verify the theory by obtaining D = 0.197 +- 0.060 of non-zero discord state. Together with the fact that non-classicalities originated from physical constraints and information theoretic perspectives are not equivalent, this result provides an insight to understand the nature of quantum discord., Comment: 8 pages, 5 figures

Published

2016

20. Coherent and Dynamic Beam Splitting based on Light Storage in Cold Atoms

Author

Park, Kwang-Kyoon, Zhao, Tian-Ming, Lee, Jong-Chan, Chough, Young-Tak, and Kim, Yoon-Ho

Subjects

Quantum Physics

Abstract

We demonstrate a coherent and dynamic beam splitter based on light storage in cold atoms. An input weak laser pulse is first stored in a cold atom ensemble via electromagnetically-induced transparency (EIT). A set of counter-propagating control fields, applied at a later time, retrieves the stored pulse into two output spatial modes. The high visibility interference between the two output pulses clearly demonstrates that the beam splitting process is coherent. Furthermore, by manipulating the control lasers, it is possible to dynamically control the storage time, the power splitting ratio, the relative phase, and the optical frequencies of the output pulses. The active beam splitter demonstrated in this work is expected to significantly reduce the resource requirement in photonic quantum information and in all-optical information processing as a single cold atom ensemble can functionally replace a variety of optical elements, including beam splitters, mirrors, phase shifters, and optical quantum memories.

Published

2016

21. Einstein-Podolsky-Rosen Entanglement of Narrowband Photons from Cold Atoms

Author

Lee, Jong-Chan, Park, Kwang-Kyoon, Zhao, Tian-Ming, and Kim, Yoon-Ho

Subjects

Quantum Physics

Abstract

Einstein-Podolsky-Rosen (EPR) entanglement introduced in 1935 deals with two particles that are entangled in their positions and momenta. Here we report the first experimental demonstration of EPR position-momentum entanglement of narrowband photon pairs generated from cold atoms. By using two-photon quantum ghost imaging and ghost interference, we demonstrate explicitly that the narrowband photon pairs violate the separability criterion, confirming EPR entanglement. We further demonstrate continuous variable EPR steering for positions and momenta of the two photons. Our new source of EPR-entangled narrowband photons is expected to play an essential role in spatially-multiplexed quantum information processing, such as, storage of quantum correlated images, quantum interface involving hyper-entangled photons, etc.

Published

2016

22. Remote preparation of three-photon entangled states via single-photon measurement

Author

Ra, Young-Sik, Lim, Hyang-Tag, and Kim, Yoon-Ho

Subjects

Quantum Physics

Abstract

Remote state preparation (RSP) provides an indirect way of manipulating quantum information based on the nonlocal effect of quantum measurement. Although RSP has been demonstrated in recent years to remotely prepare multi-photon states, quantum measurement on the same number of photons was required, i.e., to prepare N-photon states via RSP, quantum measurement on the other N-photons was required, hence significantly limiting practicality and applicability of RSP. Here we report the first experimental demonstration of remote preparation of three-photon entangled states by measuring only a single-photon entangled with the three photons. We further generalize our protocol to prepare multi-photon entangled states with arbitrary photon number and purity via single-photon measurement. As our RSP scheme relies on the nonlinearity induced by single-photon measurement, it enables quantum state engineering of multi-photon entangled states beyond the linear optical limit. Our results are expected to have significant impacts on quantum metrology and quantum information processing.

Published

2016

23. DWDM-Based Effective Group Velocity Dispersion Module for Long-Distance Quantum Communication

Author

Chae, Jin-Woo, Seo, Heebong, and Kim, Yoon-Ho

Abstract

Quantum states of light can be used to encode quantum information, and it can be transmitted over free-space or optical fibers for long-distance quantum communication. Since quantum signals or qubits cannot be amplified, long-distance quantum communication often requires pre-conditioning or preparation of the quantum states for a specific group velocity dispersion (GVD) of the desired fiber-optic channel, which is often difficult experimentally. Moreover, in entanglement-based quantum communication, GVD can be used as another degree of freedom to certify an entanglement signature. However, introducing and controlling large GVD with minimal loss is a challenging problem. In this work, we demonstrate a fiber-optic module capable of introducing a desired amount of GVD to the quantum signal and verify its operation using an entangled photon pair at the telecom wavelength. Our GVD module is based on dense wavelength-division multiplexing (DWDM) technology, and it can be easily designed and operated for various quantum communication scenarios, making it a valuable tool in implementing long-distance quantum communication in varying real-world conditions.

Published

2025

24. Quantum discord protection from amplitude damping decoherence

Author

Yune, Jiwon, Hong, Kang-Hee, Lim, Hyang-Tag, Lee, Jong-Chan, Kwon, Osung, Han, Sang-Wook, Kim, Yong-Su, Moon, Sung, and Kim, Yoon-Ho

Subjects

Quantum Physics

Abstract

Entanglement is known to be an essential resource for many quantum information processes. However, it is now known that some quantum features may be acheived with quantum discord, a generalized measure of quantum correlation. In this paper, we study how quantum discord, or more specifically, the measures of entropic discord and geometric discord are affected by the influence of amplitude damping decoherence. We also show that a protocol deploying weak measurement and quantum measurement reversal can effectively protect quantum discord from amplitude damping decoherence, enabling to distribute quantum correlation between two remote parties in a noisy environment., Comment: 7 pages, 3 figures

Published

2015

25. Distance sensitivity of thermal light second-order interference beyond spatial coherence

Author

Pepe, Francesco V., Scala, Giovanni, Chilleri, Gabriele, Triggiani, Danilo, Kim, Yoon-Ho, and Tamma, Vincenzo

Published

2022

26. Thermodynamic and experimental analyses of the oxidation behavior of UO2 pellets in damaged fuel rods of pressurized water reactors

Author

Jung, Tae-Sik, Na, Yeon-Soo, Joo, Min-Jae, Lim, Kwang-Young, Kim, Yoon-Ho, and Lee, Seung-Jae

Published

2020

27. First record of the genus Synchita Hellwig, 1792 (Coleoptera: Zopheridae: Colydiinae) in Korea

Author

Lee, Seung-Gyu, Jung, Sang Woo, and Kim, Yoon-Ho

Published

2020

28. Observation of detection-dependent multi-photon coherence times

Author

Ra, Young-Sik, Tichy, Malte C., Lim, Hyang-Tag, Kwon, Osung, Mintert, Florian, Buchleitner, Andreas, and Kim, Yoon-Ho

Subjects

Quantum Physics

Abstract

The coherence time constitutes one of the most critical parameters that determines whether or not interference is observed in an experiment. For photons, it is traditionally determined by the effective spectral bandwidth of the photon. Here we report on multi-photon interference experiments in which the multi-photon coherence time, defined by the width of the interference signal, depends on the number of interfering photons and on the measurement scheme chosen to detect the particles. A theoretical analysis reveals that all multi-photon interference with more than two particles features this dependence, which can be attributed to higher-order effects in the mutual indistinguishability of the particles. As a striking consequence, a single, well-defined many-particle quantum state can exhibit qualitatively different degrees of interference, depending on the chosen observable. Therefore, optimal sensitivity in many-particle quantum interferometry can only be achieved by choosing a suitable detection scheme.

Published

2015

29. Double-Fock Superposition Interferometry for Differential Diagnosis of Decoherence

Author

Tichy, Malte C., Ra, Young-Sik, Lim, Hyang-Tag, Gneiting, Clemens, Kim, Yoon-Ho, and Mølmer, Klaus

Subjects

Quantum Physics

Abstract

Interferometric signals are degraded by decoherence, which encompasses dephasing, mixing and any distinguishing which-path information. These three paradigmatic processes are fundamentally different, but, for coherent, single-photon and $N00N$-states, they degrade interferometric visibility in the very same way, which impedes the diagnosis of the cause for reduced visibility in a single experiment. We introduce a versatile formalism for many-boson interferometry based on double-sided Feynman diagrams, which we apply to a protocol for differential decoherence diagnosis: Twin-Fock states |N,N> with $N \ge 2$ reveal to which extent decoherence is due to path distinguishability or to mixing, while double-Fock superpositions $|N:M> = (|N,M> + |M,N>)/\sqrt{2} $ with $N > M >0$ additionally witness the degree of dephasing. Hence, double-Fock superposition interferometry permits the differential diagnosis of decoherence processes in a single experiment, indispensable for the assessment of interferometers., Comment: 10 pages, 7 figures, accepted version

Published

2014

30. Comment on 'Non-monotonic projection probabilities as a function of distinguishability'

Author

Ra, Young-Sik, Tichy, Malte C., Lim, Hyang-Tag, Kwon, Osung, Mintert, Florian, Buchleitner, Andreas, and Kim, Yoon-Ho

Subjects

Quantum Physics

Abstract

A recent work (2014 New J. Phys. 16 013006) claims that nonmonotonic structures found in the many-particle quantum-to-classical transition (2013 Proc. Natl Acad. Sci. USA 110 1227-1231; 2011 Phys. Rev. A 83 062111) are not exclusive to the many-body domain, but they also appear for single-photon as well as for semi-classical systems. We show that these situations, however, do not incorporate any quantum-to-classical transition, which makes the claims unsustainable.

Published

2014

31. Experimental realisation of a delayed-choice quantum walk

Author

Jeong, Youn-Chang, Di Franco, Carlo, Lim, Hyang-Tag, Kim, M. S., and Kim, Yoon-Ho

Subjects

Quantum Physics

Abstract

Many paradoxes of quantum mechanics come from the fact that a quantum system can possess different features at the same time, such as in wave-particle duality or quantum superposition. In recent delayed-choice experiments, a quantum mechanical system can be observed to manifest one feature such as the wave or particle nature, depending on the final measurement setup, which is chosen after the system itself has already entered the measuring device; hence its behaviour is not predetermined. Here, we adapt this paradigmatic scheme to multi-dimensional quantum walks. In our experiment, the way in which a photon interferes with itself in a strongly non-trivial pattern depends on its polarisation, that is determined after the photon has already been detected. Multi-dimensional quantum walks are a very powerful tool for simulating the behaviour of complex quantum systems, due to their versatility. This is the first experiment realising a multi-dimensional quantum walk with a single-photon source and we present also the first experimental simulation of the Grover walk, a model that can be used to implement the Grover quantum search algorithm., Comment: 8 pages, 5 figure

Published

2013

32. Observing the quantum Cheshire cat effect with noninvasive weak measurement

Author

Kim, Yosep, Im, Dong-Gil, Kim, Yong-Su, Han, Sang-Wook, Moon, Sung, Kim, Yoon-Ho, and Cho, Young-Wook

Published

2021

33. Optimal teleportation via noisy quantum channels without additional qubit resources

Author

Im, Dong-Gil, Lee, Chung-Hyun, Kim, Yosep, Nha, Hyunchul, Kim, M. S., Lee, Seung-Woo, and Kim, Yoon-Ho

Published

2021

34. Fabrication method for ultra-long optical micro/nano-fibers

Author

Lee, Donghwa, Lee, Kwang Jo, Kim, Jin-Hun, Park, Kyungdeuk, Lee, Dongjin, Kim, Yoon-Ho, and Shin, Heedeuk

Published

2019

35. Scheme for directly observing the non-commutativity of the position and the momentum operators with interference

Author

Lee, Jong-Chan, Kim, Yong-Su, Ra, Young-Sik, Lim, Hyang-Tag, and Kim, Yoon-Ho

Subjects

Quantum Physics

Abstract

Although non-commutativity of a certain set of quantum operators (e.g., creation/annihilation operators and Pauli spin operators) has been shown experimentally in recent years, the commu- tation relation for the position and the momentum operators has not been directly demonstrated to date. In this paper, we propose and analyze an experimental scheme for directly observing the non-commutativity of the position and the momentum operators using single-photon quantum in- terference. While the scheme is studied for the single-photon state as the input quantum state, the analysis applies equally to matter-wave interference, allowing a direct test of the position-momentum commutation relation with a massive particle., Comment: 4 pages, 5 figures

Published

2012

36. Experimental implementation of a fully controllable depolarizing quantum operation

Author

Jeong, Youn-Chang, Lee, Jong-Chan, and Kim, Yoon-Ho

Subjects

Quantum Physics

Abstract

The depolarizing quantum operation plays an important role in studying the quantum noise effect and implementing general quantum operations. In this work, we report a scheme which implements a fully controllable input-state independent depolarizing quantum operation for a photonic polarization qubit.

Published

2012

37. Non-monotonic quantum to classical transition in multiparticle interference

Author

Ra, Young-Sik, Tichy, Malte C., Lim, Hyang-Tag, Kwon, Osung, Mintert, Florian, Buchleitner, Andreas, and Kim, Yoon-Ho

Subjects

Quantum Physics

Abstract

We experimentally demonstrate the non-monotonic dependence of genuine many-particle interference signals on the particles' mutual distinguishability. Our theoretical analysis shows that such non-monotonicity is a generic feature of the quantum to classical transition in multiparticle correlation functions of more than two particles.

Published

2011

38. Gate Fidelities, Quantum Broadcasting, and Assessing Experimental Realization

Author

Lim, Hyang-Tag, Ra, Young-Sik, Kim, Yong-Su, Kim, Yoon-Ho, and Bae, Joonwoo

Subjects

Quantum Physics

Abstract

We relate gate fidelities of experimentally realized quantum operations to the broadcasting property of their ideal operations, and show that the more parties a given quantum operation can broadcast to, the higher gate fidelities of its experimental realization are in general. This is shown by establishing the correspondence between two operational quantities, quantum state shareability and quantum broadcasting. This suggests that, to assess an experimental realization using gate fidelities, the worst case of realization such as noisy operations should be taken into account and then compared to obtained gate fidelities. In addition, based on the correspondence, we also translate results in quantum state shareability to their counterparts in quantum operations., Comment: 5 pages, 1 figure

Published

2011

39. Ultra-low noise single-photon detector based on Si avalanche photodiode

Author

Kim, Yong-Su, Jeong, Youn-Chang, Sauge, Sebastien, Makarov, Vadim, and Kim, Yoon-Ho

Subjects

Physics - Instrumentation and Detectors, Quantum Physics

Abstract

We report operation and characterization of a lab-assembled single-photon detector based on commercial silicon avalanche photodiodes (PerkinElmer C30902SH, C30921SH). Dark count rate as low as 5 Hz was achieved by cooling the photodiodes down to -80 C. While afterpulsing increased as the photodiode temperature was decreased, total afterpulse probability did not become significant due to detector's relatively long deadtime in a passively-quenched scheme. We measured photon detection efficiency higher than 50% at 806 nm., Comment: Fixed a broken figure, updated references. 6 pages, 7 figures, 1 table

Published

2011

40. Realizing Physical Approximation of the Partial Transpose

Author

Lim, Hyang-Tag, Kim, Yong-Su, Ra, Young-Sik, Bae, Joonwoo, and Kim, Yoon-Ho

Subjects

Quantum Physics

Abstract

The partial transpose by which a subsystem's quantum state is solely transposed is of unique importance in quantum information processing from both fundamental and practical point of view. In this work, we present a practical scheme to realize a physical approximation to the partial transpose using local measurements on individual quantum systems and classical communication. We then report its linear optical realization and show that the scheme works with no dependence on local basis of given quantum states. A proof-of-principle demonstration of entanglement detection using the physical approximation of the partial transpose is also reported., Comment: 5 pages with appendix, 3 figures

Published

2011

41. Experimental demonstration of decoherence suppression via quantum measurement reversal

Author

Lee, Jong-Chan, Jeong, Youn-Chang, Kim, Yong-Su, and Kim, Yoon-Ho

Subjects

Quantum Physics

Abstract

Taming decoherence is essential in realizing quantum computation and quantum communication. Here we experimentally demonstrate that decoherence due to amplitude damping can be suppressed by exploiting quantum measurement reversal in which a weak measurement and the reversing measurement are introduced before and after the decoherence channel, respectively. We have also investigated the trade-off relation between the degree of decoherence suppression and the channel transmittance.

Published

2011

42. Four-Photon (In)Distinguishability Transition

Author

Tichy, Malte C., Lim, Hyang-Tag, Ra, Young-Sik, Mintert, Florian, Kim, Yoon-Ho, and Buchleitner, Andreas

Subjects

Quantum Physics

Abstract

We demonstrate the conspiration of many-particle interferences of different degree to determine the transmission of four photons of tunable indistinguishability through a four-port beam splitter array. The probability of certain output events depends non-monotonically on the degree of distinguishability, due to distinct multi-particle interference contributions to the transmission signal., Comment: 4 pages, 3 figures, text improved

Published

2010

43. Observation of Young's Double-Slit Interference with the Three-Photon N00N State

Author

Kim, Yong-Su, Kwon, Osung, Lee, Sang Min, Kim, Heonoh, Choi, Sang-Kyung, Park, Hee Su, and Kim, Yoon-Ho

Subjects

Quantum Physics

Abstract

Spatial interference of quantum mechanical particles exhibits a fundamental feature of quantum mechanics. A two-mode entangled state of N particles known as N00N state can give rise to non-classical interference. We report the first experimental observation of a three-photon N00N state exhibiting Young's double-slit type spatial quantum interference. Compared to a single-photon state, the three-photon entangled state generates interference fringes that are three times denser. Moreover, its interference visibility of $0.49 \pm 0.09$ is well above the limit of 0.1 for spatial super-resolution of classical origin. The demonstration of spatial quantum interference by a N00N state composed of more than two photons represents an important step towards applying quantum entanglement to technologies such as lithography and imaging.

Published

2010

44. Experimental Implementation of the Universal Transpose Operation

Author

Lim, Hyang-Tag, Ra, Young-Sik, Kim, Yong-Su, Bae, Joonwoo, and Kim, Yoon-Ho

Subjects

Quantum Physics

Abstract

The universal transpose of quantum states is an anti-unitary transformation that is not allowed in quantum theory. In this work, we investigate approximating the universal transpose of quantum states of two-level systems (qubits) using the method known as the structural physical approximation to positive maps. We also report its experimental implementation in linear optics. The scheme is optimal in that the maximal fidelity is attained and also practical as measurement and preparation of quantum states that are experimentally feasible within current technologies are solely applied., Comment: 4 pages, 4 figures

Published

2010

45. Atomic vapor quantum memory for a photonic polarization qubit

Author

Cho, Young-Wook and Kim, Yoon-Ho

Subjects

Quantum Physics

Abstract

We report an experimental realization of an atomic vapor quantum memory for the photonic po- larization qubit. The performance of the quantum memory for the polarization qubit, realized with electromagnetically-induced transparency in two spatially separated ensembles of warm Rubidium atoms in a single vapor cell, has been characterized with quantum process tomography. The process fidelity better than 0.91 for up to 16 \mu s of storage time has been achieved., Comment: 8 pages, 4 figures

Published

2010

46. Experimental verification of the commutation relation for Pauli spin operators using single-photon quantum interference

Author

Kim, Yong-Su, Lim, Hyang-Tag, Ra, Young-Sik, and Kim, Yoon-Ho

Subjects

Quantum Physics

Abstract

We report experimental verification of the commutation relation for Pauli spin operators using quantum interference of the single-photon polarization state. By superposing the quantum operations $\sigma_z \sigma_x$ and $\sigma_x \sigma_z$ on a single-photon polarization state, we have experimentally implemented the commutator, $[\sigma_{z}, \sigma_{x}]$, and the anticommutator, $\{\sigma_{z}, \sigma_{x}\}$, and have demonstrated the relative phase factor of $\pi$ between $\sigma_z \sigma_x$ and $\sigma_x \sigma_z$ operations. The experimental quantum operation corresponding to the commutator, $[\sigma_{z}, \sigma_{x}]=k\sigma_y$, showed process fidelity of 0.94 compared to the ideal $\sigma_y$ operation and $|k|$ is determined to be $2.12\pm0.18$., Comment: 4pages, 3 figures

Published

2010

47. Effects of depolarizing quantum channels on BB84 and SARG04 quantum cryptography protocols

Author

Jeong, Youn-Chang, Kim, Yong-Su, and Kim, Yoon-Ho

Subjects

Quantum Physics

Abstract

We report experimental studies on the effect of the depolarizing quantum channel on weak-pulse BB84 and SARG04 quantum cryptography. The experimental results show that, in real world conditions in which channel depolarization cannot be ignored, BB84 should perform better than SARG04., Comment: 4 pages, 4 figures

Published

2010

48. Weak value measurement with an incoherent measuring device

Author

Cho, Young-Wook, Lim, Hyang-Tag, Ra, Young-Sik, and Kim, Yoon-Ho

Subjects

Quantum Physics

Abstract

In the Aharonov-Albert-Vaidman (AAV) weak measurement, it is assumed that the measuring device or the pointer is in a quantum mechanical pure state. In reality, however, it is often not the case. In this paper, we generalize the AAV weak measurement scheme to include more generalized situations in which the measuring device is in a mixed state. We also report an optical implementation of the weak value measurement in which the incoherent pointer is realized with the pseudo-thermal light. The theoretical and experimental results show that the measuring device under the influence of partial decoherence could still be used for amplified detection of minute physical changes and are applicable for implementing the weak value measurement for massive particles., Comment: 6 pages, 4 figures, corrected typo (email address)

Published

2009

49. Observing photonic de Broglie waves without the NOON state

Author

Kwon, Osung, Ra, Young-Sik, and Kim, Yoon-Ho

Subjects

Quantum Physics

Abstract

The photonic de Broglie wave, in which an ensemble of $N$ identical photons with wavelength $\lambda$ reveals $\lambda/N$ interference fringes, has been known to be a unique feature exhibited by the photon number-path entangled state or the NOON state. Here, we report the observation of the photonic de Broglie wave for a pair of photons, generated by spontaneous parametric down-conversion, that are not photon number-path entangled. We also show that the photonic de Broglie wave can even be observed for a pair of photons that are completely separable (i.e., no entanglement in all degrees of freedom) and distinguishable. The experimental and theoretical results suggest that the photonic de Broglie wave is, in fact, not related to the entanglement of the photons, rather it is related to the indistinguishable pathways established by the measurement scheme., Comment: 9 pages, 6 figures

Published

2009

50. Storage and Retrieval of Thermal Light in Warm Atomic Vapor

Author

Cho, Young-Wook and Kim, Yoon-Ho

Subjects

Quantum Physics

Abstract

We report slowed propagation and storage and retrieval of thermal light in warm rubidium vapor using the effect of electromagnetically-induced transparency (EIT). We first demonstrate slowed-propagation of the probe thermal light beam through an EIT medium by measuring the second-order correlation function of the light field using the Hanbury-Brown$-$Twiss interferometer. We also report an experimental study on the effect of the EIT slow-light medium on the temporal coherence of thermal light. Finally, we demonstrate the storage and retrieval of thermal light beam in the EIT medium. The direct measurement of the photon number statistics of the retrieved light field shows that the photon number statistics is preserved during the storage and retrieval process., Comment: 4 pages, 4 figures

Published

2009