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3,158 results on '"Shao, Lei"'

1. Nonadiabatic evolution and thermodynamics for a boundary-driven system with a weak intrasubsystem interaction

Author

Jiang, Chao and Shao, Lei

Subjects
Quantum Physics
Abstract

We derive a time-dependent master equation for an externally driven system whose subsystems weakly interact with each other and locally connect to the thermal reservoirs. The nonadiabatic equation obtained here can be viewed as a generalization of the local master equation, which has already been extensively used in describing the dynamics of a boundary-driven system. In addition, we investigate the fundamental reason underlying the thermodynamic inconsistency generated by the local and nonadiabatic master equations. We fnd that these two equations are consistent with the second law of thermodynamics when the system is far away from the steady state, while they give rise to the contradiction at the steady state. Finally, we numerically confrm our results by considering a toy model consisting of two qubits and two local heat baths.

Published
2024

2. Spin squeezing generated by anisotropic central spin model

Author

Shao, Lei and Fu, Libin

Subjects
Quantum Physics
Abstract

Spin squeezing, as a crucial quantum resource, plays a pivotal role in quantum metrology, enabling us to achieve high-precision parameter estimation schemes. Here we investigate the spin squeezing and the quantum phase transition in anisotropic central spin systems. We find that this kind of central spin systems can be mapped to the anisotropic Lipkin-Meshkov-Glick model in the limit where the ratio of transition frequencies between the central spin and the spin bath tends towards infinity. This property can induce a one-axis twisting interaction and provides a new possibility for generating spin squeezing. We consider generating spin-squeezed states via the ground state and the dynamic evolution of the central spin model. The results show that the spin squeezing parameter improves as the anisotropy parameter decreases, and its value scales with system size as $N^{-2/3}$. Furthermore, we obtain the critical exponent of the quantum Fisher information around the critical point by numerical simulation, and find this value tends to $4/3$ as the frequency ratio and the system size approach infinity. This work offers a promising scheme for generating spin-squeezed state and paves the way for potential advancements in quantum sensing., Comment: 10 pages, 4 figures

Published
2023

7. Microscaling Data Formats for Deep Learning

Author

Rouhani, Bita Darvish, Zhao, Ritchie, More, Ankit, Hall, Mathew, Khodamoradi, Alireza, Deng, Summer, Choudhary, Dhruv, Cornea, Marius, Dellinger, Eric, Denolf, Kristof, Dusan, Stosic, Elango, Venmugil, Golub, Maximilian, Heinecke, Alexander, James-Roxby, Phil, Jani, Dharmesh, Kolhe, Gaurav, Langhammer, Martin, Li, Ada, Melnick, Levi, Mesmakhosroshahi, Maral, Rodriguez, Andres, Schulte, Michael, Shafipour, Rasoul, Shao, Lei, Siu, Michael, Dubey, Pradeep, Micikevicius, Paulius, Naumov, Maxim, Verrilli, Colin, Wittig, Ralph, Burger, Doug, and Chung, Eric

Subjects
Computer Science - Machine Learning, Computer Science - Artificial Intelligence
Abstract

Narrow bit-width data formats are key to reducing the computational and storage costs of modern deep learning applications. This paper evaluates Microscaling (MX) data formats that combine a per-block scaling factor with narrow floating-point and integer types for individual elements. MX formats balance the competing needs of hardware efficiency, model accuracy, and user friction. Empirical results on over two dozen benchmarks demonstrate practicality of MX data formats as a drop-in replacement for baseline FP32 for AI inference and training with low user friction. We also show the first instance of training generative language models at sub-8-bit weights, activations, and gradients with minimal accuracy loss and no modifications to the training recipe.

Published
2023

10. Mechanical transistors for logic-with-memory computing

Author

Chen, Huyue, Song, Chao, Wu, Jiahao, Zou, Bihui, Zhang, Zhihan, Zou, An, Cho, Yuljae, Wang, Zhaoguang, Zhang, Wenming, Shao, Lei, and Ju, Jaehyung

Subjects
Physics - Applied Physics
Abstract

As a potential revolutionary topic in future information processing, mechanical computing has gained tremendous attention for replacing or supplementing conventional electronics vulnerable to power outages, security attacks, and harsh environments. Despite its potential for constructing intelligent matter towards nonclassical computing systems beyond the von Neumann architecture, most works on mechanical computing demonstrated that the ad hoc design of simple logic gates cannot fully realize a universal mechanical processing framework involving interconnected arithmetic logic components and memory. However, such a logic-with-memory computing architecture is critical for complex and persistent state-dependent computations such as sequential logic. Here we propose a mechanical transistor (M-Transistor), abstracting omnipresent temperatures as the input-output mechanical bits, which consists of a metamaterial thermal channel as the gate terminal driving a nonlinear bistable soft actuator to selectively connect the output terminal to two other variable thermal sources. This M-Transistor is an elementary unit to modularly form various combinational and sequential circuits, such as complex logic gates, registers (volatile memory), and long-term memories (non-volatile memory) with much fewer units than the electronic counterparts. Moreover, they can establish a universal processing core comprising an arithmetic circuit and a register in a compact, reprogrammable network involving periodic read, write, memory, and logic operations of the mechanical bits. Our work contributes to realizing a non-electric universal mechanical computing architecture that combines multidisciplinary engineering with structural mechanics, materials science, thermal engineering, physical intelligence, and computational science., Comment: 25 pages, 4 figures, Article

Published
2023

12. Quantum metrology, criticality, and classical brachistochrone problem

Author

Zhang, Rui, Zhang, Zhucheng, Shao, Lei, Zhang, Yuyu, and Wang, Xiaoguang

Subjects
Quantum Physics
Abstract

There has always been an ambiguous connection between quantum metrology and criticality. We clarify this relationship in a unitary parametrization process with a Hamiltonian governed by su(1,1) Lie algebra. Based on this type of Hamiltonian, we investigate the quantum Cram\'{e}r-Rao bound of the coupling strength in the quantum Rabi model close to the phase transition point. We show that the generator $\mathcal{H}$ in the unitary parametrization process can be treated as an extended brachistochrone problem on the $x-y$ plane and a linear function of time in the $z$ direction. In addition, we find that the value of quantum Fisher information is proportional to the sixth power of the evolution time when the system is close to the phase transition point., Comment: 5 pages, 3 figures

Published
2023

13. With Shared Microexponents, A Little Shifting Goes a Long Way

Author

Rouhani, Bita, Zhao, Ritchie, Elango, Venmugil, Shafipour, Rasoul, Hall, Mathew, Mesmakhosroshahi, Maral, More, Ankit, Melnick, Levi, Golub, Maximilian, Varatkar, Girish, Shao, Lei, Kolhe, Gaurav, Melts, Dimitry, Klar, Jasmine, L'Heureux, Renee, Perry, Matt, Burger, Doug, Chung, Eric, Deng, Zhaoxia, Naghshineh, Sam, Park, Jongsoo, and Naumov, Maxim

Subjects
Computer Science - Machine Learning, Computer Science - Artificial Intelligence, Computer Science - Hardware Architecture
Abstract

This paper introduces Block Data Representations (BDR), a framework for exploring and evaluating a wide spectrum of narrow-precision formats for deep learning. It enables comparison of popular quantization standards, and through BDR, new formats based on shared microexponents (MX) are identified, which outperform other state-of-the-art quantization approaches, including narrow-precision floating-point and block floating-point. MX utilizes multiple levels of quantization scaling with ultra-fine scaling factors based on shared microexponents in the hardware. The effectiveness of MX is demonstrated on real-world models including large-scale generative pretraining and inferencing, and production-scale recommendation systems.

Published
2023

14. Advantage of quantum coherence in postselected metrology

Author

Xiong, Shao-Jie, Wei, Peng-Fei, Wang, Huang-Qiu-Chen, Shao, Lei, Sun, Yong-Nan, Liu, Jing, Sun, Zhe, and Wang, Xiao-Guang

Subjects
Quantum Physics
Abstract

In conventional measurement, to reach the greatest accuracy of parameter estimation, all samples must be measured since each independent sample contains the same quantum Fisher information. In postselected metrology, postselection can concentrate the quantum Fisher information of the initial samples into a tiny post-selected sub-ensemble. It has been proven that this quantum advantage can not be realized in any classically commuting theory. In this work, we present that the advantage of postselection in weak value amplification (WVA) can not be achieved without quantum coherence. The quantum coherence of the initial system is closely related to the preparation costs and measurement costs in parameter estimation. With the increase of initial quantum coherence, the joint values of preparation costs and measurement costs can be optimized to smaller. Moreover, we derive an analytical tradeoff relation between the preparation, measurement and the quantum coherence. We further experimentally test the tradeoff relation in a linear optical setup. The experimental and theoretical results are in good agreement and show that the quantum coherence plays a key role in bounding the resource costs in the postselected metrology process.

Published
2022

15. A novel model for evaluating the strain-controlled fracture behavior in strip martensite steel

Author

L.O.N.G. Shao-lei, Y.I. Yan-liang, W.U. Shan, L.U.O. Xiang-lan, Z.H.A.N.G. Hao-dong, L.I.N.G. Min, L.O.N.G. Xiao, and L.I.A.N.G. Yi-long

Subjects
Strip martensite steel, Multi-level structures, Hall-petch relationship, Composite parameter model (CPM), Critical cavity ratio model, Fracture behavior, Mining engineering. Metallurgy, TN1-997
Abstract

To address the challenges posed by the limitations of the Hall-Petch equation for strip martensite steel and the complex relationship between its macro-plasticity/toughness (MATP) and micro-plasticity/toughness (MITP), a composite parameter model (CPM) was developed, factoring in strain-controlled fracture (Di=di/nδC). The fracture behavior of strip martensite steel and fracture characteristics were investigated in detail. The fracture morphology results showed that the effective grain of plasticity/toughness from the lath martensite steel involved in the ductile fracture was martensite lath, while the brittle fracture was martensite packet. It was found that the Hall-Petch equation was not applicable due to different fracture modes of the same material under different heat treatment processes, as well as the equivalent size and the small angle orientation of martensite laths. However, the CPM effectively determined the effective grains of MATP and MITP as laths in the strain-controlled fracture, and the Di of MATP and MITP less than 1, revealing the consistent relationship between MATP and MITP. In addition, although Di was infinite in the stress-controlled fracture, which rendered CPM practically insignificant, it effectively revealed the relationship between MATP and MITP. When the effective grains of MATP and MITP were different, the Di value of MATP was greater than 1, and that of MITP was less than 1, reflecting the mixed fracture mode. The MATP and MITP showed an inverse relationship with the coarse grain size. When the Di values of MATP and MITP approached infinity, and the effective grains were the same, they demonstrated martensite packet sizes, showing stress-controlled fracture. MATP and MITP showed the same variation with grain coarsening and decreased in size simultaneously. Moreover, the relationship between CPM and the critical cavity expansion ratio revealed the microscopic characteristics of the macroscopic change during ductile fractures, providing a fresh perspective for studying the coupling relationship of mechanical properties.

Published
2024
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16. Twisted Lattice Nanocavity Based on Mode Locking in Momentum Space

Author

Ma, Ren-Min, Luan, Hong-Yi, Zhao, Zi-Wei, Mao, Wen-Zhi, Wang, Shao-Lei, Ouyang, Yun-Hao, and Shao, Zeng-Kai

Subjects
Physics - Optics
Abstract

Simultaneous localization of light to extreme spatial and spectral scales is of high importance for testing fundamental physics and various applications. However, there is a long-standing trade-off between localizing light field in space and in frequency. Here we discover a new class of twisted lattice nanocavities based on mode locking in momentum space. The twisted lattice nanocavity hosts a strongly localized light field in a 0.048 lambda^3 mode volume with a quality factor exceeding 2.9*10^11 (~250 us photon lifetime), which presents a record high figure of merit of light localization among all reported optical cavities. Based on the discovery, we have demonstrated silicon based twisted lattice nanocavities with quality factor over 1 million. Our result provides a powerful platform to study light-matter interaction in extreme condition for tests of fundamental physics and applications in nanolasing, ultrasensing, nonlinear optics, optomechanics and quantum-optical devices.

Published
2022

17. Instantaneous indirect measurement principle in quantum mechanics

Author

Lu, Wangjun, Zhang, Xingyu, Shao, Lei, Zhang, Zhucheng, Chen, Jie, Zhang, Rui, Xiong, Shaojie, Zhan, Liyao, and Wang, Xiaoguang

Subjects
Quantum Physics
Abstract

In quantum systems, the measurement of operators and the measurement of the quantum states of the system are very challenging tasks. In this Letter, we propose a method to obtain the average value of one operator in a certain state by measuring the instantaneous change of the average value of another operator with the assistance of a known reference state. We refer to this measurement method as the instantaneous indirect measurement method. By studying the application of this method to some typical models, we find that this measurement can be applied to the measurement of an arbitrary state of a quantum system. Furthermore, for the system to be measured, we find that such measurement neither significantly affects the wave function of the system nor causes wave function collapse of the system. Also, our study shows that when two independent systems are coupled, the information mapping between them is done instantaneously. Finally, we discuss applying this measurement method to the measurement of quantum Fisher information, which quantizes the limited accuracy of estimating a parameter from a quantum state., Comment: 19pages, 5figures

Published
2022

18. Quantum phase transition in XXZ central spin model

Author

Shao, Lei, Zhang, Rui, Lu, Wangjun, Zhang, Zhucheng, and Wang, Xiaoguang

Subjects
Quantum Physics
Abstract

We investigate the quantum phase transition (QPT) in the XXZ central spin model, which can be described as a spin-1/2 particle coupled to N bath spins. In general, the QPT is supposed to occur only in the thermodynamical limit. In contrast, we present that the central spin model exhibits a normal-to-superradiant phase transition in the limit where the ratio of the transition frequency of the central spin to that of the bath spins and the number of the bath spins tend to infinity. We give the low-energy effective Hamiltonian analytically in the normal phase and the superradiant phase, and we find that the longitudinal interaction can significantly influence the excitation number and the coherence of the ground state. These two quantities are remarkably enhanced for the negative longitudinal interaction while suppressed for the positive longitudinal interaction. We also use the quantum Fisher information (QFI) to characterize the QPT and illustrate a measurement scheme that can be applied in practice. This work builds a novel connection between the qubit-spin systems and the qubit-field systems, which provides a possibility for the realization of criticality-enhanced quantum sensing in central spin systems., Comment: 10 pages, 5 figures

Published
2022
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19. All-optical generation of deterministic squeezed Schr\'odinger-cat states

Author

Zhang, Zhucheng, Shao, Lei, Lu, Wangjun, and Wang, Xiaoguang

Subjects
Quantum Physics
Abstract

Quantum states are important resources and their preparations are essential prerequisites to all quantum technologies. However, they are extremely fragile due to the inevitable dissipations. Here, an all-optical generation of a deterministic squeezed Schr$\ddot{\mathrm{o}}$dinger-cat state based on dissipation is proposed. Our system is based on the Fredkin-type interaction between three optical modes, one of which is subject to coherent two-photon driving and the rest are coherent driving. We show that an effective degenerate three-wave mixing process can be engineered in our system, which can cause the simultaneous loss of two photons, resulting in the generation of a deterministic squeezed Schr$\ddot{\mathrm{o}}$dinger-cat state. More importantly, by controlling the driving fields in our system, the two-photon loss can be adjustable, which can accelerate the generation of squeezed Schr$\ddot{\mathrm{o}}$dinger-cat states. Besides, we exploit the squeezed Schr$\ddot{\mathrm{o}}$dinger-cat states to estimate the phase in the optical interferometer, and show that the quantum Fisher information about the phase can reach the Heisenberg limit in the limit of a large photon number. Meanwhile, it can have an order of magnitude factor improvement over the Heisenberg limit in the low-photon-number regime, which is very valuable for fragile systems that cannot withstand large photon fluxes. This work proposes an all-optical scheme to deterministically prepare the squeezed Schr$\ddot{\mathrm{o}}$dinger-cat state with high speed and can also be generalized to other physical platforms., Comment: 12 pages, 6 figures

Published
2022
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22. Verification of colorable hypergraph states with stabilizer test

Author

Tao, Hong, Zhang, Xiaoqian, Shao, Lei, and Tan, Xiaoqing

Subjects
Quantum Physics
Abstract

Many-body quantum states, as a matter of fact, are extremely essential to solve certain mathematical problems or simulate quantum systems in measurement-based quantum computation. However, how to verify large scale quantum states, such as hypergraph states, is an exceedingly hard task for multi-body quantum systems. Here, we propose a novel fault-tolerant solution for verification of colorable hypergraph states by using stabilizer test. Compared with the adaptive stabilizer test, our protocol is dramatically facilitating by making only Pauli-X and Pauli-Z measurement. As to appliance, it will be also applied to blind quantum computing., Comment: Verification, colorable hypergraph states, stabilizer test

Published
2022

26. Bardeen black hole in magnetically charged four-dimensional Einstein-Gauss-Bonnet gravity

Author

Zhang, Shu-Jun, Zhang, He-Xu, Shao, Lei, Deng, Jian-Bo, and Hu, Xian-Ru

Subjects
General Relativity and Quantum Cosmology
Abstract

In this paper, we investigate the shadow radius and quasinormal modes of a four-dimensional magnetically charged Einstein-Gauss-Bonnet Bardeen black hole and point out a simple connection between them in the eikonal limit. By studying a massless scalar field perturbation in this spacetime background and using the sixth-order Wentzel-Kramers-Brillouin(WKB) approximation, we get the quasinormal modes(QNMs) and perform a detailed analysis. It shows that the quasinormal modes are depend on the Gauss-Bonnet coupling constant and the magnetic charge. We also give a formula of the QNMs and shadow radius in the eikonal limit and check it numerically for the real and imaginary part of it, respectively., Comment: 21 pages

Published
2021

27. Plasmon Coupling Induced Photon Scattering Torque

Author

Li, Yang, Wang, Jing, Lin, Hai-Qing, and Shao, Lei

Subjects
Physics - Optics
Abstract

Bio-compatible Au nanoparticles exhibit great advantages in the application of biomedical researches, such as bio-sensing, medical diagnosis, and cancer therapy. Bio-molecules can even be manipulated by laser tweezers with the optically trapped Au nanoparticles as handles. In this Letter, optical scattering torque arising from the coupled Au nanoparticles driven by circularly polarized light is theoretically presented. The coupled plasmon resonance modes boost the angular momentum transfer from photons to the Au nanoparticle dimers and trimers through light scattering, which does not bring any optical-heating side effect. The generated optical torques on the nanostructures highly depend on the plasmon coupling in the structures. The angular momentum transfer efficiencies from scattered photons to nanostructures can reach around 200\%. The results suggest that coupled plasmonic nanoparticle oligomers are promising candidates to construct optically driven rotary nanomotors that can be applied in biomedical applications.

Published
2021
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28. Anapole-Mediated Emission Enhancement in Gallium Nitride Nanocavities

Author

Wang, Hao, Wang, Jing, Li, Shasha, Li, Kwai Hei, Lin, Hai-Qing, and Shao, Lei

Subjects
Physics - Optics
Abstract

Benefiting from their low-loss light manipulation at subwavelength scales, optically resonant dielectric nanostructures have emerged as one of the most promising nanophotonic building blocks. Here, we theoretically conceive a dielectric nanocavity made of moderate-refractive-index gallium nitride and investigate the strong electromagnetic field confinement inside the nanocavity. We demonstrate that gallium nitride nanodisks can support anapole states, which result from interference between electric dipole and toroidal dipole modes and are tunable by changing sizes of the nanodisks. The highly confined electromagnetic field of the anapole states can promote the emission efficiency of a single quantum emitter inside the nanocavity. Moreover, the emission polarization can be tuned by placing the quantum emitter off the nanodisk center. Our findings provide a promising candidate for the construction of ultra-compact, super-radiative integrated quantum light sources.

Published
2021

38. A low-loss molybdenum plasmonic waveguide: perfect single-crystal preparation and subwavelength grating optimization

Author

Cui Tao, Shen Yan, Cheng Ao, Zhan Runze, Zheng Zebo, Tian Bo, Shi Jia, Ke Yanlin, Shao Lei, Chen Huanjun, and Deng Shaozhi

Subjects
plasmonic waveguide, near-infrared, low-loss propagation, molybdenum single-crystal, subwavelength grating, Physics, QC1-999
Abstract

Plasmonic waveguides have attracted tremendous interest due to efficiently confining photons on the subwavelength spatial scale to be beating the propagation diffraction limit. Transition metal molybdenum (Mo) exhibits outstanding properties in light trapping and electromagnetic field confining, making it potentially valuable in 1.55 μm plasmonic waveguide applications. However, the reliable fabrication of high-quality Mo plasmonic waveguides is a significant challenge. A real-space micro-imaging study of the surface plasmon on Mo structures is still absent. In this study, we successfully prepared a single-crystalline Mo microrod waveguide structure and fabricated subwavelength gratings on it. The diffraction gratings were designed, optimized, and etched to excite the surface plasmon polariton behaviour of Mo for the first time. The grating-optimized Mo microrod single-crystal reveals highly efficient waveguide performance around near-infrared spectroscopy, exhibiting a long propagation length of 32 μm and a low transmission loss of 0.067 dB μm−1. The results provide an alternative to advanced materials research and optical device applications of plasmonic waveguide systems.

Published
2023
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39. Extreme expected values and their applications in quantum information processing

Author

Lu, Wangjun, Shao, Lei, Zhang, Xingyu, Zhang, Zhucheng, Chen, Jie, Tao, Hong, and Wang, Xiaoguang

Subjects
Quantum Physics
Abstract

We consider the probability distribution when the monotonic function $F(X)$ of the independent variable $X$ takes the maximum or minimum expected value under the two constraints of a certain probability and a certain expected value of the independent variable $X$. We proposed an equal probability and equal expected value splitting method. With this method, we proved four inequalities, and two of them can be reduced to Jensen's inequalities. Subsequently, we find that after dividing the non-monotone function $H(X)$ into multiple monotone intervals, the problem of solving the maximum and minimum expected values of $H(X)$ can be transformed into the problem of solving the extreme value of a multiple-variable function. Finally, we apply the proved theory to solve three problems in quantum information processing. When studying the quantum parameter estimation in Mach-Zehnder interferometer, for an equal total input photon number, we find an optimal path-symmetric input state that makes the quantum Fisher information take the maximum value, and we prove that the NOON state is the path-symmetric state that makes the quantum Fisher information takes the minimum value. When studying the quantum parameter estimation in Landau-Zener-Jaynes-Cummings model, we find the optimal initial state of the cavity field that makes the system obtain the maximum quantum Fisher information. Finally, for an equal initial average photon number, we find the optimal initial state of the cavity field that makes the Tavis-Cummings quantum battery have the maximum stored energy and the maximum average charging power., Comment: 13 pages, 4 figures

Published
2021
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40. Single-photon-triggered spin squeezing with decoherence reduction in optomechanics via phase matching

Author

Zhang, Zhucheng, Shao, Lei, Lu, Wangjun, Su, Yuguo, Wang, Yi-Ping, Liu, Jing, and Wang, Xiaoguang

Subjects
Quantum Physics
Abstract

Quantum spin squeezing is an important resource for quantum information processing, but its squeezing degree is not easy to preserve in an open system with decoherence. Here, we propose a scheme to implement single-photon-triggered spin squeezing with decoherence reduction in an open system. In our system, a Dicke model (DM) is introduced into the quadratic optomechanics, which can be equivalent to an effective DM manipulated by the photon number. Besides, the phonon mode of the optomechanical system is coupled to a squeezed vacuum reservoir with a phase matching, resulting in that the thermal noise caused by the environment can be suppressed completely. We show that squeezing of the phonon mode triggered by a single photon can be transferred to the spin ensemble totally, and pairwise entanglement of the spin ensemble can be realized if and only if there is spin squeezing. Importantly, when considering the impact of the environment, our system can obtain a better squeezing degree than the optimal squeezing that can be achieved in the traditional DM. Meanwhile, the spin squeezing generated in our system is immune to the thermal noise. This work offers an effective way to generate spin squeezing with a single photon and to reduce decoherence in an open system, which will have promising applications in quantum information processing., Comment: 10 pages, 5 figures

Published
2021
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