Your search keyword '"Department of Applied Physics, Graduate School of Engineering, The University of Tokyo"' showing total 37 results

1. Liquid crystal mesophases beyond commensurate four-layer periodicity

Author

Ron Pindak, Yuji Sasaki, Kenji Ema, Shun Wang, P. Barois, B. K. McCoy, Z. Q. Liu, Cheng-Cher Huang, LiDong Pan, School of Physics and Astronomy [Minneapolis], University of Minnesota [Twin Cities] (UMN), University of Minnesota System-University of Minnesota System, Key Laboratory of Artificial Structures and Quantum Control, Shanghai Jiao Tong University [Shanghai], Department of Physics and Astronomy [Baltimore], Johns Hopkins University (JHU), Department of Mathematics, Physics, and Staitistics [Azusa], Azusa Pacific University, Department of Applied Physics, Graduate School of Engineering, The University of Tokyo, Centre de recherches Paul Pascal (CRPP), Institut de Chimie du CNRS (INC)-Centre National de la Recherche Scientifique (CNRS), Photon Sciences Directorate, Brookhaven National Laboratory [Upton, NY] (BNL), U.S. Department of Energy [Washington] (DOE)-UT-Battelle, LLC-Stony Brook University [SUNY] (SBU), State University of New York (SUNY)-State University of New York (SUNY)-U.S. Department of Energy [Washington] (DOE)-UT-Battelle, LLC-Stony Brook University [SUNY] (SBU), State University of New York (SUNY)-State University of New York (SUNY), Contract N° DE-AC02-98CH10886, School of Physics and Astronomy, University of Minnesota [Minneapolis], Johns Hopkins University ( JHU ), Department of Physics and Astronomy, St. Cloud State University, Department of Mathematics and Physics, Azusa Pacific University, Centre de recherches Paul Pascal ( CRPP ), Centre National de la Recherche Scientifique ( CNRS ), and Brookhaven National Laboratory

Subjects

Diffraction, Materials science, Theoretical models, 02 engineering and technology, 01 natural sciences, resonant X-ray diffraction, SmC∗, SmC∗d6, [ CHIM.CRIS ] Chemical Sciences/Cristallography, null-transmission ellipsometry, Liquid crystal, Ellipsometry, Phase (matter), Physical phenomena, 0103 physical sciences, [CHIM.CRIS]Chemical Sciences/Cristallography, General Materials Science, 010306 general physics, Mesophase, General Chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, variant phases, Crystallography, Chemical physics, 0210 nano-technology, Ternary operation

Abstract

International audience; For more than one decade, SmC∗d4, SmC∗d3, andSmC∗ A were the only three confirmed commensurate SmC* variant phases with periodicities less than or equal four layers. In 2006, employing ellipsometry and resonant X-ray diffraction (RXRD), our research team first discovered a new liquid crystal mesophase having a six-layer periodicity in one ternary mixture which includes one sulfur-containing compound. From our ellipsometric results, this phase showed antiferroelectric-like optical response. This novel discovery inspired renewed interest to search for liquid crystal mesophases with commensurateperiodicities greater than four layers. Soon after, another mesophase having a six-layer structure and showing a ferrielectric-like dielectric response, instead, was uncovered by RXRD measurements on a different binary mixture which has one bromine-containing compound. Meanwhile mesophases having a 5-, 8-, 12- or 15-layer periodicity were reported. However, numerous questions remain to be addressed associated with these unusual reported phases. Theoretical models giving rise to mesophases with periodicities greater than four layers have been developed; but, to date, none of them haveprovided satisfactory explanations of all the physical phenomena related to the mesophases exhibiting a six-layer structure. Moreover, the question “what is the source of long-range interactions between liquid-like smectic layers, which are responsible for establishing mesophases with long periodicities and mean-field behavior of the smectic-A–smectic-C transition?” remains unanswered for more than three decades.

Published

2015

2. Lamb-Dicke spectroscopy of atoms in a hollow-core photonic crystal fibre

Author

Shoichi Okaba, Thomas D. Bradley, Z. A. Maizelis, V. A. Yampol'skii, Franco Nori, Hidetoshi Katori, Fetah Benabid, Luca Vincetti, Tetsushi Takano, Department of Applied Physics, Graduate School of Engineering, The University of Tokyo, PHOTONIQUE (XLIM-PHOTONIQUE), XLIM (XLIM), Université de Limoges (UNILIM)-Centre National de la Recherche Scientifique (CNRS)-Université de Limoges (UNILIM)-Centre National de la Recherche Scientifique (CNRS), Department of Information Engineering [Modena], Università degli Studi di Modena e Reggio Emilia (UNIMORE), Kharkov National University, RIKEN Center for Advanced Photonics [Wako] (RIKEN RAP), and RIKEN - Institute of Physical and Chemical Research [Japon] (RIKEN)

Subjects

Optical fiber, Photon, Atomic Physics (physics.atom-ph), General Physics and Astronomy, Physics::Optics, FOS: Physical sciences, Nanotechnology, Quantum metrology, 01 natural sciences, Molecular physics, Article, General Biochemistry, Genetics and Molecular Biology, Physics - Atomic Physics, law.invention, 010309 optics, law, 0103 physical sciences, Atom, Physics::Atomic and Molecular Clusters, Physics::Atomic Physics, 010306 general physics, Spectroscopy, ComputingMilieux_MISCELLANEOUS, Optical lattice clock, Physics, Condensed Matter::Quantum Gases, Optical lattice, Multidisciplinary, General Chemistry, Atomic clock, Photonic crystal fibers, [SPI.OPTI]Engineering Sciences [physics]/Optics / Photonic, Coherence (physics), Photonic-crystal fiber

Abstract

Unlike photons, which are conveniently handled by mirrors and optical fibres without loss of coherence, atoms lose their coherence via atom-atom and atom-wall interactions. This decoherence of atoms deteriorates the performance of atomic clocks and magnetometers, and also hinders their miniaturisation. Here we report a novel platform for precision spectroscopy. Ultracold strontium atoms inside a kKagome-lattice hollow-core photonic crystal fibre (HC-PCF) are transversely confined by an optical lattice to prevent atoms from interacting with the fibre wall. By confining at most one atom in each lattice site, to avoid atom-atom interactions and Doppler effect, a 7.8-kHz-wide spectrum is observed for the $^1 S_0-{}^3P_1$ (m=0) transition. Atoms singly trapped in a magic lattice in hollow-core photonic crystal fibresHC-PCFs improve the optical depth while preserving atomic coherence time., Comment: 31 pages, 8 figures

Published

2014

3. New Limits on Coupling of Fundamental Constants to Gravity Using $^{87}$Sr Optical Lattice Clocks

Author

Blatt, S., Ludlow, A. D., Campbell, G. K., Thomsen, J. W., Zelevinsky, T., Boyd, M. M., Ye, J., Baillard, X., Fouch��, M., Targat, R. Le, Brusch, A., Lemonde, P., Takamoto, M., Hong, F. -L., Katori, H., Flambaum, V. V., University of Colorado, Joint Institute for Laboratory Astrophysics (JILA), Systèmes de Référence Temps Espace (SYRTE), Université Pierre et Marie Curie - Paris 6 (UPMC)-Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire de Paris, Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Centre National de la Recherche Scientifique (CNRS), Métrologie des fréquences optiques, Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire de Paris, Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire de Paris, Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS), Department of Applied Physics, Graduate School of Engineering, The University of Tokyo, and School of physics, University of New South Wales

Subjects

General Physics (physics.gen-ph), Physics - General Physics, Atomic Physics (physics.atom-ph), FOS: Physical sciences, [PHYS.ASTR]Physics [physics]/Astrophysics [astro-ph], Physics - Atomic Physics

Abstract

The $^1\mathrm{S}_0$-$^3\mathrm{P}_0$ clock transition frequency $\nu_\text{Sr}$ in neutral $^{87}$Sr has been measured relative to the Cs standard by three independent laboratories in Boulder, Paris, and Tokyo over the last three years. The agreement on the $1\times 10^{-15}$ level makes $\nu_\text{Sr}$ the best agreed-upon optical atomic frequency. We combine periodic variations in the $^{87}$Sr clock frequency with $^{199}$Hg$^+$ and H-maser data to test Local Position Invariance by obtaining the strongest limits to date on gravitational-coupling coefficients for the fine-structure constant $\alpha$, electron-proton mass ratio $\mu$ and light quark mass. Furthermore, after $^{199}$Hg$^+$, $^{171}$Yb$^+$ and H, we add $^{87}$Sr as the fourth optical atomic clock species to enhance constraints on yearly drifts of $\alpha$ and $\mu$., Comment: Published version. 4 pages, 4 figures

Published

2008

4. Demonstration of microwave single-shot quantum key distribution.

Author

Fesquet F, Kronowetter F, Renger M, Yam WK, Gandorfer S, Inomata K, Nakamura Y, Marx A, Gross R, and Fedorov KG

Abstract

Security of modern classical data encryption often relies on computationally hard problems, which can be trivialized with the advent of quantum computers. A potential remedy for this is quantum communication which takes advantage of the laws of quantum physics to provide secure exchange of information. Here, quantum key distribution (QKD) represents a powerful tool, allowing for unconditionally secure quantum communication between remote parties. At the same time, microwave quantum communication is set to play an important role in future quantum networks because of its natural frequency compatibility with superconducting quantum processors and modern near-distance communication standards. To this end, we present an experimental realization of a continuous-variable QKD protocol based on propagating displaced squeezed microwave states. We use superconducting parametric devices for generation and single-shot quadrature detection of these states. We demonstrate unconditional security in our experimental microwave QKD setting. The security performance is shown to be improved by adding finite trusted noise on the preparation side. Our results indicate feasibility of secure microwave quantum communication with the currently available technology in both open-air (up to  ~ 80 m) and cryogenic (over 1000 m) conditions., (© 2024. The Author(s).)

Published

2024

5. Laser spectroscopy of triply charged 229 Th isomer for a nuclear clock.

Author

Yamaguchi A, Shigekawa Y, Haba H, Kikunaga H, Shirasaki K, Wada M, and Katori H

Abstract

Thorium-229 ( 229 Th) possesses an optical nuclear transition between the ground state ( 229g Th) and low-lying isomer ( 229m Th). A nuclear clock based on this nuclear-transition frequency is expected to surpass existing atomic clocks owing to its insusceptibility to surrounding fields 1-5 . In contrast to other charge states, triply charged 229 Th ( 229 Th 3+ ) is the most suitable for highly accurate nuclear clocks because it has closed electronic transitions that enable laser cooling, laser-induced fluorescence detection and state preparation of ions 1,6-8 . Although laser spectroscopic studies of 229 Th 3+ in the nuclear ground state have been performed 8 , properties of 229m Th 3+ , including its nuclear decay lifetime that is essential to specify the intrinsic linewidth of the nuclear-clock transition, remain unknown. Here we report the trapping of 229m Th 3+ continuously supplied by a 233 U source and the determination of nuclear decay half-life of the isolated 229m Th 3+ to be 1,400 - 300 + 600 s through nuclear-state-selective laser spectroscopy. Furthermore, by determining the hyperfine constants of 229m Th 3+ , we reduced the uncertainty of the sensitivity of the 229 Th nuclear clock to variations in the fine-structure constant by a factor of four. These results offer key parameters for the 229 Th 3+ nuclear clock and its applications in the search for new physics., (© 2024. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2024

6. Comprehensive Application of XFEL Microcrystallography for Challenging Targets in Various Organic Compounds.

Author

Takaba K, Maki-Yonekura S, Inoue I, Tono K, Fukuda Y, Shiratori Y, Peng Y, Morimoto J, Inoue S, Higashino T, Sando S, Hasegawa T, Yabashi M, and Yonekura K

Abstract

There is a growing demand for structure determination from small crystals, and the three-dimensional electron diffraction (3D ED) technique can be employed for this purpose. However, 3D ED has certain limitations related to the crystal thickness and data quality. We here present the application of serial X-ray crystallography (SX) with X-ray free electron lasers (XFELs) to small (a few μm or less) and thin (a few hundred nm or less) crystals of novel compounds dispersed on a substrate. For XFEL exposures, two-dimensional (2D) scanning of the substrate coupled with rotation enables highly efficient data collection. The recorded patterns can be successfully indexed using lattice parameters obtained through 3D ED. This approach is especially effective for challenging targets, including pharmaceuticals and organic materials that form preferentially oriented flat crystals in low-symmetry space groups. Some of these crystals have been difficult to solve or have yielded incomplete solutions using 3D ED. Our extensive analyses confirmed the superior quality of the SX data regardless of crystal orientations. Additionally, 2D scanning with XFEL pulses gives an overall distribution of the samples on the substrate, which can be useful for evaluating the properties of crystal grains and the quality of layered crystals. Therefore, this study demonstrates that XFEL crystallography has become a powerful tool for conducting structure studies of small crystals of organic compounds.

Published

2024

7. Probing the symmetry breaking of a light-matter system by an ancillary qubit.

Author

Wang SP, Ridolfo A, Li T, Savasta S, Nori F, Nakamura Y, and You JQ

Abstract

Hybrid quantum systems in the ultrastrong, and even more in the deep-strong, coupling regimes can exhibit exotic physical phenomena and promise new applications in quantum technologies. In these nonperturbative regimes, a qubit-resonator system has an entangled quantum vacuum with a nonzero average photon number in the resonator, where the photons are virtual and cannot be directly detected. The vacuum field, however, is able to induce the symmetry breaking of a dispersively coupled probe qubit. We experimentally observe the parity symmetry breaking of an ancillary Xmon artificial atom induced by the field of a lumped-element superconducting resonator deep-strongly coupled with a flux qubit. This result opens a way to experimentally explore the novel quantum-vacuum effects emerging in the deep-strong coupling regime., (© 2023. The Author(s).)

Published

2023

8. All-Microwave Manipulation of Superconducting Qubits with a Fixed-Frequency Transmon Coupler.

Author

Shirai S, Okubo Y, Matsuura K, Osada A, Nakamura Y, and Noguchi A

Subjects

Quantum Theory, Computing Methodologies, Microwaves

Abstract

All-microwave control of fixed-frequency superconducting quantum computing circuits is advantageous for minimizing the noise channels and wiring costs. Here we introduce a swap interaction between two data transmons assisted by the third-order nonlinearity of a coupler transmon under a microwave drive. We model the interaction analytically and numerically and use it to implement an all-microwave controlled-Z gate. The gate based on the coupler-assisted swap transition maintains high drive efficiency and small residual interaction over a wide range of detuning between the data transmons.

Published

2023

9. Near-Quantum-Noise Axion Dark Matter Search at CAPP around 9.5  μeV.

Author

Kim J, Kwon O, Kutlu Ç, Chung W, Matlashov A, Uchaikin S, van Loo AF, Nakamura Y, Oh S, Byun H, Ahn D, and Semertzidis YK

Abstract

We report the results of an axion dark matter search over an axion mass range of 9.39-9.51  μeV. A flux-driven Josephson parametric amplifier (JPA) was added to the cryogenic receiver chain. A system noise temperature of as low as 200 mK was achieved, which is the lowest recorded noise among published axion cavity experiments with phase-insensitive JPA operation. In addition, we developed a two-stage scanning method which boosted the scan speed by 26%. As a result, a range of two-photon coupling in a plausible model for the QCD axion was excluded with an order of magnitude higher in sensitivity than existing limits.

Published

2023

10. Axion Dark Matter Search around 4.55  μeV with Dine-Fischler-Srednicki-Zhitnitskii Sensitivity.

Author

Yi AK, Ahn S, Kutlu Ç, Kim J, Ko BR, Ivanov BI, Byun H, van Loo AF, Park S, Jeong J, Kwon O, Nakamura Y, Uchaikin SV, Choi J, Lee S, Lee M, Shin YC, Kim J, Lee D, Ahn D, Bae S, Lee J, Kim Y, Gkika V, Lee KW, Oh S, Seong T, Kim D, Chung W, Matlashov A, Youn S, and Semertzidis YK

Abstract

We report an axion dark matter search at Dine-Fischler-Srednicki-Zhitnitskii sensitivity with the CAPP-12TB haloscope, assuming axions contribute 100% of the local dark matter density. The search excluded the axion-photon coupling g_{aγγ} down to about 6.2×10^{-16}  GeV^{-1} over the axion mass range between 4.51 and 4.59  μeV at a 90% confidence level. The achieved experimental sensitivity can also exclude Kim-Shifman-Vainshtein-Zakharov axion dark matter that makes up just 13% of the local dark matter density. The CAPP-12TB haloscope will continue the search over a wide range of axion masses.

Published

2023

11. Balanced-imbalanced transitions in indirect reciprocity dynamics on networks.

Author

Oishi K, Miyano S, Kaski K, and Shimada T

Abstract

Here we investigate the dynamics of indirect reciprocity on networks, a type of social dynamics in which the attitude of individuals, either cooperative or antagonistic, toward other individuals changes over time based upon their actions and mutual monitoring. We observe an absorbing state phase transition as we change the network's link or edge density. When the edge density is either small or large enough, opinions quickly reach an absorbing state, from which opinions never change anymore once reached. In contrast, if the edge density is in the middle range, the absorbing state is not reached and the state keeps changing, thus being active. The result shows an effect of social networks on spontaneous group formation.

Published

2021

12. Finite-size security of continuous-variable quantum key distribution with digital signal processing.

Author

Matsuura T, Maeda K, Sasaki T, and Koashi M

Abstract

In comparison to conventional discrete-variable (DV) quantum key distribution (QKD), continuous-variable (CV) QKD with homodyne/heterodyne measurements has distinct advantages of lower-cost implementation and affinity to wavelength division multiplexing. On the other hand, its continuous nature makes it harder to accommodate to practical signal processing, which is always discretized, leading to lack of complete security proofs so far. Here we propose a tight and robust method of estimating fidelity of an optical pulse to a coherent state via heterodyne measurements. We then construct a binary phase modulated CV-QKD protocol and prove its security in the finite-key-size regime against general coherent attacks, based on proof techniques of DV QKD. Such a complete security proof is indispensable for exploiting the benefits of CV QKD.

Published

2021

13. Author Correction: Butterfly-shaped magnetoresistance in triangular-lattice antiferromagnet Ag 2 CrO 2 .

Author

Taniguchi H, Watanabe M, Tokuda M, Suzuki S, Imada E, Ibe T, Arakawa T, Yoshida H, Ishizuka H, Kobayashi K, and Niimi Y

Abstract

An amendment to this paper has been published and can be accessed via a link at the top of the paper.

Published

2020

14. Butterfly-shaped magnetoresistance in triangular-lattice antiferromagnet Ag 2 CrO 2 .

Author

Taniguchi H, Watanabe M, Tokuda M, Suzuki S, Imada E, Ibe T, Arakawa T, Yoshida H, Ishizuka H, Kobayashi K, and Niimi Y

Abstract

Spintronic devices using antiferromagnets (AFMs) are promising candidates for future applications. Recently, many interesting physical properties have been reported with AFM-based devices. Here we report a butterfly-shaped magnetoresistance (MR) in a micrometer-sized triangular-lattice antiferromagnet Ag 2 CrO 2 . The material consists of two-dimensional triangular-lattice CrO 2 layers with antiferromagnetically coupled S = 3/2 spins and Ag 2 layers with high electrical conductivity. The butterfly-shaped MR appears only when the magnetic field is applied perpendicularly to the CrO 2 plane with the maximum MR ratio (≈15%) at the magnetic ordering temperature. These features are distinct from those observed in conventional magnetic materials. We propose a theoretical model where fluctuations of partially disordered spins with the Ising anisotropy play an essential role in the butterfly-shaped MR in Ag 2 CrO 2 .

Published

2020

15. Narrow-line Cooling and Determination of the Magic Wavelength of Cd.

Author

Yamaguchi A, Safronova MS, Gibble K, and Katori H

Abstract

We experimentally and theoretically determine the magic wavelength of the (5s^{2})^{1}S_{0}-(5s5p)^{3}P_{0} clock transition of ^{111}Cd to be 419.88(14) and 420.1(7) nm. To perform Lamb-Dicke spectroscopy of the clock transition, we use narrow-line laser cooling on the ^{1}S_{0}-^{3}P_{1} transition to cool the atoms to 6  μK and load them into an optical lattice. Cadmium is an attractive candidate for optical lattice clocks because it has a small sensitivity to blackbody radiation and its efficient narrow-line cooling mitigates higher order light shifts. We calculate the blackbody shift, including the dynamic correction, to be fractionally 2.83(8)×10^{-16} at 300 K, an order of magnitude smaller than that of Sr and Yb. We also report calculations of the Cd ^{1}P_{1} lifetime and the ground state C_{6} coefficient.

Published

2019

16. Repeaterless quantum key distribution with efficient finite-key analysis overcoming the rate-distance limit.

Author

Maeda K, Sasaki T, and Koashi M

Abstract

Quantum key distribution (QKD) over a point-to-point link enables us to benefit from a genuine quantum effect even with conventional optics tools such as lasers and photon detectors, but its capacity is limited to a linear scaling of the repeaterless bound. Recently, twin-field (TF) QKD was conjectured to beat the limit by using an untrusted central station conducting a single-photon interference detection. So far, the effort to prove the conjecture was confined to the infinite key limit which neglected the time and cost for monitoring an adversary's act. Here we propose a variant of TF-type QKD protocol equipped with a simple methodology of monitoring to reduce its cost and provide an information-theoretic security proof applicable to finite communication time. We simulate the key rate to show that the protocol beats the linear bound in a reasonable running time of sending 10 12 pulses, which positively solves the conjecture.

Published

2019

17. Operational Magic Intensity for Sr Optical Lattice Clocks.

Author

Ushijima I, Takamoto M, and Katori H

Abstract

We experimentally investigate the lattice-induced light shift by the electric-quadrupole (E2) and magnetic-dipole (M1) polarizabilities and the hyperpolarizability in Sr optical lattice clocks. Precise control of the axial as well as the radial motion of atoms in a one-dimensional lattice allows observing the E2-M1 polarizability difference. Measured polarizabilities determine an operational lattice depth to be 72(2)E_{R}, where the total light shift cancels to the 10^{-19} level, over a lattice-intensity variation of about 30%. This operational trap depth and its allowable intensity range conveniently coincide with experimentally feasible operating conditions for Sr optical lattice clocks.

Published

2018

18. Efficient Simulation of Quantum Error Correction Under Coherent Error Based on the Nonunitary Free-Fermionic Formalism.

Author

Suzuki Y, Fujii K, and Koashi M

Abstract

In order to realize fault-tolerant quantum computation, a tight evaluation of the error threshold under practical noise models is essential. While non-Clifford noise is ubiquitous in experiments, the error threshold under non-Clifford noise cannot be efficiently treated with known approaches. We construct an efficient scheme for estimating the error threshold of the one-dimensional quantum repetition code under non-Clifford noise. To this end, we employ the nonunitary free-fermionic formalism for efficient simulation of the one-dimensional repetition code under coherent noise. This allows us to evaluate the effect of coherence in noise on the error threshold without any approximation. The result shows that the error threshold becomes one-third when the noise is fully coherent. Our scheme is also applicable to the surface code undergoing a specific coherent noise model. The dependence of the error threshold on noise coherence can be explained with a leading-order analysis with respect to coherence terms in the noise map. We expect that this analysis is also valid for the surface code since it is a two-dimensional extension of the one-dimensional repetition code. Moreover, since the obtained threshold is accurate, our results can be used as a benchmark for the approximation or heuristic schemes for non-Clifford noise.

Published

2017

19. Enhanced robustness of evolving open systems by the bidirectionality of interactions between elements.

Author

Ogushi F, Kertész J, Kaski K, and Shimada T

Abstract

Living organisms, ecosystems, and social systems are examples of complex systems in which robustness against inclusion of new elements is an essential feature. A recently proposed simple model has revealed a general mechanism by which such systems can become robust against inclusion of elements with totally random interactions when the elements have a moderate number of links. The interaction is, however, in many systems often intrinsically bidirectional like for mutual symbiosis and competition in ecology. This study reports the strong reinforcement effect of the bidirectionality of the interactions on the robustness of evolving systems. We show that the system with purely bidirectional interactions can grow with twofold average degree, in comparison with the purely unidirectional system. This drastic shift of the transition point comes from the reinforcement of each node, not from a change in structure of the emergent system. For systems with partially bidirectional interactions we find that the regime of the growing phase gets expanded. In the dense interaction regime, there exists an optimum proportion of bidirectional interactions for the growth rate at around 1/3. In the sparsely connected systems, small but finite fraction of bidirectional links can change the system's behaviour from non-growing to growing.

Published

2017

20. Splash detail due to a single grain incident on a granular bed.

Author

Tanabe T, Shimada T, Ito N, and Nishimori H

Abstract

Using the discrete element method, we study the splash processes induced by the impact of a grain on a randomly packed bed. Good correspondence is obtained between our numerical results and the findings of previous experiments for the movement of ejected grains. Furthermore, the distributions of the ejection angle and ejection speed for individual grains vary depending on the relative timing at which the grains are ejected after the initial impact. Obvious differences are observed between the distributions of grains ejected during the earlier and later splash periods: the form of the vertical ejection-speed distribution varies from a power-law form to a lognormal form with time; this difference may determine grain trajectory after ejection.

Published

2017

21. Primary Phenomenon in the Network Formation of Endothelial Cells: Effect of Charge.

Author

Arai S

Subjects

Computer Simulation, Humans, Hydrodynamics, Ions metabolism, Models, Biological, Neovascularization, Physiologic, Static Electricity, Cell Communication, Endothelial Cells cytology, Endothelial Cells metabolism, Vascular Endothelial Growth Factor A metabolism

Abstract

Blood vessels are essential organs that are involved in the supply of nutrients and oxygen and play an important role in regulating the body's internal environment, including pH, body temperature, and water homeostasis. Many studies have examined the formation of networks of endothelial cells. The results of these studies have revealed that vascular endothelial growth factor (VEGF) affects the interactions of these cells and modulates the network structure. Though almost all previous simulation studies have assumed that the chemoattractant VEGF is present before network formation, vascular endothelial cells secrete VEGF only after the cells bind to the substrate. This suggests VEGF is not essential for vasculogenesis especially at the early stage. Using a simple experiment, we find chain-like structures which last quite longer than it is expected, unless the energetically stable cluster should be compact. Using a purely physical model and simulation, we find that the hydrodynamic interaction retard the compaction of clusters and that the chains are stabilized through the effects of charge. The charge at the surface of the cells affect the interparticle potential, and the resulting repulsive forces prevent the chains from folding. The ions surrounding the cells may also be involved in this process.

Published

2015

22. Frequency Ratio of (199)Hg and (87)Sr Optical Lattice Clocks beyond the SI Limit.

Author

Yamanaka K, Ohmae N, Ushijima I, Takamoto M, and Katori H

Abstract

We report on a frequency ratio measurement of a (199)Hg-based optical lattice clock referencing a (87)Sr-based clock. Evaluations of lattice light shift, including atomic-motion-dependent shift, enable us to achieve a total systematic uncertainty of 7.2×10(-17) for the Hg clock. The frequency ratio is measured to be νHg/νSr=2.629 314 209 898 909 60(22) with a fractional uncertainty of 8.4×10(-17), which is smaller than the uncertainty of the realization of the International System of Units (SI) second, i.e., the SI limit.

Published

2015

23. Kinetic Monte Carlo algorithm for thermally induced breakdown of fiber bundles.

Author

Yoshioka N, Kun F, and Ito N

Abstract

Fiber bundle models are one of the most fundamental modeling approaches for the investigation of the fracture of heterogeneous materials being able to capture a broad spectrum of damage mechanisms, loading conditions, and types of load sharing. In the framework of the fiber bundle model we introduce a kinetic Monte Carlo algorithm to investigate the thermally induced creep rupture of materials occurring under a constant external load. We demonstrate that the method overcomes several limitations of previous techniques and provides an efficient numerical framework at any load and temperature values. We show for both equal and localized load sharing that the computational time does not depend on the temperature; it is solely determined by the external load and the system size. In the limit of low load where the lifetime of the system diverges, the computational time saturates to a constant value. The method takes into account the secondary failures induced by subsequent load redistributions after breaking events, with the additional advantage that breaking avalanches always start from a single broken fiber.

Published

2015

24. Lamb-Dicke spectroscopy of atoms in a hollow-core photonic crystal fibre.

Author

Okaba S, Takano T, Benabid F, Bradley T, Vincetti L, Maizelis Z, Yampol'skii V, Nori F, and Katori H

Abstract

Unlike photons, which are conveniently handled by mirrors and optical fibres without loss of coherence, atoms lose their coherence via atom-atom and atom-wall interactions. This decoherence of atoms deteriorates the performance of atomic clocks and magnetometers, and also hinders their miniaturization. Here we report a novel platform for precision spectroscopy. Ultracold strontium atoms inside a kagome-lattice hollow-core photonic crystal fibre are transversely confined by an optical lattice to prevent atoms from interacting with the fibre wall. By confining at most one atom in each lattice site, to avoid atom-atom interactions and Doppler effect, a 7.8-kHz-wide spectrum is observed for the (1)S0-(3)P1(m=0) transition. Atoms singly trapped in a magic lattice in hollow-core photonic crystal fibres improve the optical depth while preserving atomic coherence time.

Published

2014

25. Iterated crowdsourcing dilemma game.

Author

Oishi K, Cebrian M, Abeliuk A, and Masuda N

Abstract

The Internet has enabled the emergence of collective problem solving, also known as crowdsourcing, as a viable option for solving complex tasks. However, the openness of crowdsourcing presents a challenge because solutions obtained by it can be sabotaged, stolen, and manipulated at a low cost for the attacker. We extend a previously proposed crowdsourcing dilemma game to an iterated game to address this question. We enumerate pure evolutionarily stable strategies within the class of so-called reactive strategies, i.e., those depending on the last action of the opponent. Among the 4096 possible reactive strategies, we find 16 strategies each of which is stable in some parameter regions. Repeated encounters of the players can improve social welfare when the damage inflicted by an attack and the cost of attack are both small. Under the current framework, repeated interactions do not really ameliorate the crowdsourcing dilemma in a majority of the parameter space.

Published

2014

26. A universal transition in the robustness of evolving open systems.

Author

Shimada T

Abstract

Can the structure of a system that consists of many elements interacting with each other grow in complexity when new elements are added to it? This is an essential question for understanding various real, open, complex systems, such as living organisms, ecosystems, and social systems. Using a very simple model, this study demonstrates that such systems can grow only when the elements have a moderate number of interactions on average. This behaviour comes from a balance between two opposing effects: although an increase in the number of interactions makes each individual element more robust against disturbances, it also increases the net impact of the loss of any element on the system.

Published

2014

27. Conductive optical-fiber STM probe for local excitation and collection of cathodoluminescence at semiconductor surfaces.

Author

Watanabe K, Nakamura Y, and Ichikawa M

Abstract

Luminescence imaging of semiconductor surfaces in nanometric resolution is a key to novel optoelectronic nano-devices, which requires local carrier excitation and local luminescence collection within the nanometric areas at the surfaces. However, there have not been a practical nanospectroscopies applicable to wide range of specimens. STM-cathodoluminescence (STM-CL) nanospectroscopy offers both high spatial resolution (of the order of 10 nm) and novel high carrier excitation power (up to ~1 mW), which enables local luminescence imaging of less-luminescent nano-structures. In this study, we advanced STM-CL technique by introducing a novel optical fiber probe with Cr thin film coating (Cr-FP), which was found to work as a STM probe, as an electron field-emitter for local carrier excitation, and as an alignment-free efficient local STM-CL collector which blinds luminescence after the minority carrier diffusion.

Published

2013

28. Long-range interacting many-body systems with alkaline-earth-metal atoms.

Author

Olmos B, Yu D, Singh Y, Schreck F, Bongs K, and Lesanovsky I

Abstract

Alkaline-earth-metal atoms can exhibit long-range dipolar interactions, which are generated via the coherent exchange of photons on the (3)P(0) - (3)D(1) transition of the triplet manifold. In the case of bosonic strontium, which we discuss here, this transition has a wavelength of 2.6 μm and a dipole moment of 4.03 D, and there exists a magic wavelength permitting the creation of optical lattices that are identical for the states (3)P(0) and (3)D(1). This interaction enables the realization and study of mixtures of hard-core lattice bosons featuring long-range hopping, with tunable disorder and anisotropy. We derive the many-body master equation, investigate the dynamics of excitation transport, and analyze spectroscopic signatures stemming from coherent long-range interactions and collective dissipation. Our results show that lattice gases of alkaline-earth-metal atoms permit the creation of long-lived collective atomic states and constitute a simple and versatile platform for the exploration of many-body systems with long-range interactions. As such, they represent an alternative to current related efforts employing Rydberg gases, atoms with large magnetic moment, or polar molecules.

Published

2013

29. Nanoprobe fourier-transform photoabsorption spectroscopy using a supercontinuum light source.

Author

Ishibe K, Nakada S, Mera Y, and Maeda K

Abstract

A scheme of photoabsorption spectroscopy based on scanning tunneling microscopy (STM) has been developed by using a supercontinuum light as the wideband light source of a Fourier transform interferometer for spectroscopic measurements. The performance was demonstrated for a sample of GaAs. The proof-of-concept test showed that the use of the supercontinuum light instead of halogen lamps greatly enhances the signal-to-noise ratio due to the high brilliance of the supercontinuum light emitted from a small core of the photonic crystal fiber that enables tight focusing of the spectroscopy light onto the sample beneath the STM tip.

Published

2012

30. Formation of a multiscale aggregate structure through spontaneous blebbing of an interface.

Author

Sumino Y, Kitahata H, Shinohara Y, Yamada NL, and Seto H

Subjects

Nanostructures, Surface Properties, Surface-Active Agents, Oils chemistry, Water chemistry

Abstract

The motion of an oil-water interface that mimics biological motility was investigated in a Hele-Shaw-like cell where elastic surfactant aggregates were formed at the oil-water interface. With the interfacial motion, millimeter-scale pillar structures composed of the aggregates were formed. The pillars grew downward in the aqueous phase, and the separations between pillars were roughly equal. Small-angle X-ray scattering using a microbeam X-ray revealed that these aggregates had nanometer-scale lamellar structures whose orientation correlated well with their location in the pillar structure. It is suggested that these hierarchical spatial structures are tailored by the spontaneous interfacial motion.

Published

2012

31. Magic wavelength to make optical lattice clocks insensitive to atomic motion.

Author

Katori H, Hashiguchi K, Il'inova EY, and Ovsiannikov VD

Abstract

In a standing wave of light, a difference in spatial distributions of multipolar atom-field interactions may introduce atomic-motion dependent clock uncertainties in optical lattice clocks. We show that the magic wavelength can be defined so as to eliminate the spatial mismatch in electric dipole, magnetic dipole, and electric quadrupole interactions for specific combinations of standing waves by allowing a spatially constant light shift arising from the latter two interactions. Experimental prospects of such lattices used with a blue magic wavelength are discussed.

Published

2009

32. Swimming in granular media.

Author

Shimada T, Kadau D, Shinbrot T, and Herrmann HJ

Abstract

A class of reptiles known as sand swimmers adapts to hot environments by submerging beneath desert sands during the day and so provide a unique probe into the dynamics of intruders in granular beds. To understand the mechanism for swimming in an otherwise solid bed, we study a simple model of periodic contraction and extension of large intruders in a granular bed. Using an event-driven simulation, we find optimal conditions that idealized swimmers must use to critically fluidize a sand bed so that it is rigid enough to support a load when needed, but fluid enough to permit motion with minimal resistance. Swimmers-or other intruders-that agitate the bed too rapidly produce large voids that prevent traction from being achieved, while swimmers that move too slowly cannot travel before the bed resolidifies around them, i.e., the swimmers locally probe the fundamental time scale in a granular packing.

Published

2009

33. Prospects for optical clocks with a blue-detuned lattice.

Author

Takamoto M, Katori H, Marmo SI, Ovsiannikov VD, and Pal'chikov VG

Abstract

We investigated the properties of optical lattice clocks operated with a repulsive light-shift potential. The magic wavelength, where light-shift perturbation for the clock transition cancels, was experimentally determined to be 389.889(9) nm for 87Sr. The hyperpolarizability effects on the clock transition were investigated theoretically. With minimal trapping field perturbation provided by the blue-detuned lattice, the fractional uncertainty due to the hyperpolarizability effects was found to be 2x10;{-19} in the relevant clock transition.

Published

2009

34. Size scaling and bursting activity in thermally activated breakdown of fiber bundles.

Author

Yoshioka N, Kun F, and Ito N

Subjects

Hot Temperature, Materials Testing, Stress, Mechanical, Temperature, Models, Chemical

Abstract

We study subcritical fracture driven by thermally activated damage accumulation in the framework of fiber bundle models. We show that in the presence of stress inhomogeneities, thermally activated cracking results in an anomalous size effect; i.e., the average lifetime t{f} decreases as a power law of the system size t{f} approximately L{-z}, where the exponent z depends on the external load sigma and on the temperature T in the form z approximately f(sigma/T{3/2}). We propose a modified form of the Arrhenius law which provides a comprehensive description of thermally activated breakdown. Thermal fluctuations trigger bursts of breakings which have a power law size distribution.

Published

2008

35. Trapping of neutral mercury atoms and prospects for optical lattice clocks.

Author

Hachisu H, Miyagishi K, Porsev SG, Derevianko A, Ovsiannikov VD, Pal'chikov VG, Takamoto M, and Katori H

Abstract

We report vapor-cell magneto-optical trapping of Hg isotopes on the (1)S(0)-(3)P(1) intercombination transition. Six abundant isotopes, including four bosons and two fermions, were trapped. Hg is the heaviest nonradioactive atom trapped so far, which enables sensitive atomic searches for "new physics" beyond the standard model. We propose an accurate optical lattice clock based on Hg and evaluate its systematic accuracy to be better than 10;{-18}. Highly accurate and stable Hg-based clocks will provide a new avenue for the research of optical lattice clocks and the time variation of the fine-structure constant.

Published

2008

36. Unpredictability induced by unfocused games in evolutionary game dynamics.

Author

Hashimoto K

Subjects

Animals, Ecosystem, Models, Biological, Reward, Biological Evolution, Game Theory

Abstract

Evolutionary game theory is a basis of replicator systems and has applications ranging from animal behavior and human language to ecosystems and other hierarchical network systems. Most studies in evolutionary game dynamics have focused on a single game, but, in many situations, we see that many games are played simultaneously. We construct a replicator equation with plural games by assuming that a reward of a player is a simple summation of the reward of each game. Even if the numbers of the strategies of the games are different, its dynamics can be described in one replicator equation. We here show that when players play several games at the same time, the fate of a single game cannot be determined without knowing the structures of the whole other games. The most absorbing fact is that even if a single game has a ESS (evolutionary stable strategy), the relative frequencies of strategies in the game does not always converge to the ESS point when other games are played simultaneously.

Published

2006

37. Nanoscale imaging of electronic surface transport probed by atom movements induced by scanning tunneling microscope current.

Author

Nakamura Y, Mera Y, and Maeda K

Abstract

The hopping movements of Cl atoms on a Si(111)-(7 x 7) surface that are enhanced by an electron injection from tips of a scanning tunneling microscope (STM) exhibit a spatial spread from the electron injection point with an anisotropic distribution. The enhanced hopping effect becomes greatest at a sample bias voltage being resonant with the Si-Cl antibonding states and also exhibits an oscillatory decay with the distance from the injection point characterized by the wavelength depending on the bias voltage. All of these facts can be interpreted in terms of the coherent expansion of the electron wave packets locally formed at the STM tip.

Published

2002