亚洲欧美日韩在线播,亚洲激情网久久久久,中文字幕乱码二区免费,91精一区二区三区,亚洲自国产拍揄拍综合1区,久久这里就有国产熟女精品,日本中文字幕a在线,少妇被大黑捧猛烈进出,丰满大白屁股bbwbbw

2024

2024

  • Record 49 of

    Title:Evaporation characteristics of Er3+-doped silica fiber and its application in the preparation of whispering gallery mode lasers
    Author Full Names:Li, Angzhen(1); Ward, Jonathan M.(2); Tian, Ke(3,4); Yu, Jibo(5); She, Shengfei(6); Hou, Chaoqi(6); Guo, Haitao(6); Chormaic, Síle Nic(4,7); Wang, Pengfei(3)
    Source Title:Optics Express
    Language:English
    Document Type:Journal article (JA)
    Abstract:In this work, the concentration of rare-earth ions in doped silica whispering gallery lasers (WGLs) is controlled by evaporation. The fabrication of WGLs is used to experimentally evaluate the evaporation rate (mol/μm) and ratio (mol/mol) of erbium and silica lost from a doped fiber during heating. Fixed lengths of doped silica fiber are spliced to different lengths of undoped fiber and then evaporated by feeding into the focus of a CO2 laser. During evaporation, erbium ions are precipitated in the doped silica fiber to control the erbium concentration in the remaining SiO2, which is melted into a microsphere. By increasing the length of the undoped section, a critical point is reached where effectively no ions remain in the glass microsphere. The critical point is found using the spectra of the whispering gallery modes in microspheres with equal sizes. From the critical point, it is estimated that, for a given CO2 laser power, 6.36 × 10?21 mol of Er3+ is lost during the evaporation process for every cubic micron of silica fiber. This is equivalent to 1.74 × 10?7 mol of Er3+ lost per mol of SiO2 evaporated. This result facilitates the control of the doping concentration in WGLs and provides insight into the kinetics of laser-induced evaporation of doped silica. ? 2024 Optica Publishing Group under the terms of the Optica Open Access Publishing Agreement.
    Affiliations:(1) Tianjin Key Laboratory of Quantum Optics and Intelligent Photonics, School of Science, Tianjin University of Technology, Tianjin; 300384, China; (2) Physics Department, University College Cork, Cork, Ireland; (3) Key Laboratory of In-Fiber Integrated Optics of Ministry of Education, College of Science, Harbin Engineering University, Harbin; 150001, China; (4) Light-Matter Interactions for Quantum Technologies Unit, Okinawa Institute of Science and Technology Graduate University, Okinawa, Onna; 904-0495, Japan; (5) Xi’an Institute of Applied Optics, Xi’an; 710065, China; (6) State Key Laboratory of Transient Optics and Photonics, Xi’an Institute of Optics and Precision Mechanics, Chinese Academy of Sciences, Xi’an; 710119, China; (7) Institute of Physics, Technische Universit?t Chemnitz, Chemnitz; D-09107, Germany
    Publication Year:2024
    Volume:32
    Issue:3
    Start Page:3912-3921
    DOI Link:10.1364/OE.509662
    數(shù)據(jù)庫ID(收錄號):20240615502598
  • Record 50 of

    Title:Switchable Pancharatnam–Berry Phases in Heterogeneously Integrated THz Metasurfaces
    Author Full Names:Dong, Bowen(1,2); Zhu, Shuangqi(1); Guo, Guanxuan(3); Wu, Tong(3); Lu, Xueguang(4); Huang, Wanxia(4); Ma, Hua(5); Xu, Quan(3); Han, Jiaguang(3,6); Zhang, Shuang(7); Wang, Yongtian(1); Zhang, Xueqian(3); Huang, Lingling(1)
    Source Title:Advanced Materials
    Language:English
    Document Type:Article in Press
    Abstract:The Pancharatnam–Berry (PB) phase has revolutionized the design of metasurfaces, offering a straightforward and robust method for controlling wavefronts of electromagnetic waves. However, traditional metasurfaces have fixed PB phases determined by the orientation of their individual elements. In this study, an innovative structural design and integration scheme is proposed that utilizes vanadium dioxide, a phase-change material, to achieve thermally controlled dynamic PB phase control within the metasurface. By leveraging the material's properties, this can dynamically alter the optical orientation of individual elements of the metasurface and achieve temperature-dependent local phase modulation based on the geometric phase principle. This approach, combined with advanced fabrication processing technology, paves the way for next-generation dynamic devices with customizable functions. ? 2024 Wiley-VCH GmbH.
    Affiliations:(1) School of Optics and Photonics, Beijing Engineering Research Center of Mixed Reality and Advanced Display, Beijing Institute of Technology, Beijing; 100081, China; (2) National Innovation Institute of Defense Technology, Academy of Military Sciences, Beijing; 100071, China; (3) Center for Terahertz waves and College of Precision Instrument and Optoelectronics Engineering, Tianjin University and the Key Laboratory of Optoelectronics Information and Technology (Ministry of Education), Tianjin; 300072, China; (4) College of Materials Science and Engineering, Sichuan University, Chengdu; 610065, China; (5) Department of Basic Sciences, Air Force Engineering University, Xian; 710038, China; (6) Guangxi Key Laboratory of Optoelectronic Information Processing, School of Optoelectronic Engineering, Guilin University of Electronic Technology, Guilin; 541004, China; (7) New Cornerstone Science Laboratory, Department of Physics, University of Hong Kong, 999077, Hong Kong
    Publication Year:2024
    DOI Link:10.1002/adma.202417183
    數(shù)據(jù)庫ID(收錄號):20245117545544
  • Record 51 of

    Title:Scalable parallel ultrafast optical random bit generation based on a single chaotic microcomb
    Author Full Names:Li, Pu(1,2,3); Li, Qizhi(4); Tang, Wenye(4); Wang, Weiqiang(5); Zhang, Wenfu(5); Little, Brent E.(5); Chu, Sai Tek(6); Shore, K. Alan(7); Qin, Yuwen(1,2,3); Wang, Yuncai(1,2,3)
    Source Title:Light: Science and Applications
    Language:English
    Document Type:Journal article (JA)
    Abstract:Random bit generators are critical for information security, cryptography, stochastic modeling, and simulations. Speed and scalability are key challenges faced by current physical random bit generation. Herein, we propose a massively parallel scheme for ultrafast random bit generation towards rates of order 100 terabit per second based on a single micro-ring resonator. A modulation-instability-driven chaotic comb in a micro-ring resonator enables the simultaneous generation of hundreds of independent and unbiased random bit streams. A proof-of-concept experiment demonstrates that using our method, random bit streams beyond 2 terabit per second can be successfully generated with only 7 comb lines. This bit rate can be easily enhanced by further increasing the number of comb lines used. Our approach provides a chip-scale solution to random bit generation for secure communication and high-performance computation, and offers superhigh speed and large scalability. ? The Author(s) 2024.
    Affiliations:(1) Institute of Advanced Photonics Technology, School of Information Engineering, Guangdong University of Technology, Guangzhou; 51006, China; (2) Key Laboratory of Photonic Technology for Integrated Sensing and Communication, Ministry of Education of China, Guangdong University of Technology, Guangzhou; 51006, China; (3) Guangdong Provincial Key Laboratory of Information Photonics Technology, Guangdong University of Technology, Guangzhou; 51006, China; (4) Key Laboratory of Advanced Transducers and Intelligent Control System, Ministry of Education, Taiyuan University of Technology, Taiyuan; 030024, China; (5) State Key Laboratory of Transient Optics and Photonics, Xi’an Institute of Optics and Precision Mechanics, Chinese Academy of Sciences, Xi’an; 710119, China; (6) Department of Physics and Materials Science, City University of Hong Kong, Hong Kong; (7) School of Electronic Engineering, Bangor University, Wales, Bangor; LL57 1UT, United Kingdom
    Publication Year:2024
    Volume:13
    Issue:1
    Article Number:66
    DOI Link:10.1038/s41377-024-01411-7
    數(shù)據(jù)庫ID(收錄號):20241015704601
  • Record 52 of

    Title:Polarization-Based Enhancement for Oceanic Constituents and Inherent Optical Properties (Iops) Retrieval from Multi-Angular Polarimetric Measurements Over Global Oceans
    Author Full Names:Liu, Jia(1,2,3,4); Li, Chunxia(5); He, Xianqiang(3); Chen, Tieqiao(2); Jia, Xinyin(2); Bai, Yan(3); Liu, Dong(6); Liu, Yupeng(1); Yang, Wentao(7); Wang, Yihao(2); Zhang, Geng(2); Li, Siyuan(2); Hu, Bingliang(2); Pan, Delu(3)
    Source Title:SSRN
    Language:English
    Document Type:Preprint (PP)
    Abstract:Multi-angle polarization characteristics of water-leaving radiation, which contain rich information on oceanic constituents and inherent optical properties (IOPs), have often been neglected. In this study, global radiative transfer (RT) simulations for the polarization characteristics of water-leaving radiance (Lw) were performed using the vector radiative transfer model for a coupled ocean-atmosphere system (PCOART). And, a global polarization-based algorithm for retrieving oceanic constituents and inherent optical properties (IOPs) was developed, employing the Fully Connected U-Net (FCUN). The retrieval performance of the algorithm was then analyzed using in-situ measurements collected during the Qiandao Lake field campaign. Results indicated that the low degrees of polarization (DOP) at short blue bands at solar zenith angle of 0° predominantly occurred in the tropical and subtropical oceans, with the lowest DOP value of 0.0176 observed in the extra oligotrophic subtropical gyres. The global mean absolute percentage error (MAPE) of the FCUN predictions compared to RT simulations for oceanic constituents (Chla, ag(443), NAP) and IOPs (a, b, aph, bph, aNAP, bNAP, bb, bbph, bbNAP) at 443 nm were 6.24%, 3.90%, 10.65%, 2.85%, 3.15%, 3.79%, 4.42%, 3.90%, 3.90%, 3.13%, 4.44%, and 3.90%, respectively, with mean global MAPE values of 4.52%. Additionally, the FCUN model’s predictions were consistent with RT simulation inputs under various random instrument noise conditions, with mean global MAPE values of 6.74% and 8.84% for those 12 retrieved parameters, respectively. Moreover, the retrieval performance analysis of FCUN on the in-situ measurements was performed with MAPE for Chla, a, aph, bb at 443 nm of 31.80%, 29.65%, 34.87%, and 43.04%, respectively. The importance of multi-angles polarization observations of Lw for ocean constituents and IOPs retrieval were also examined with the global mean MAPE decreasing from 16.91% to 1.48% as the observation angles increasing. Overall, the global polarization-based inversion model exhibited substantial potential for the oceanic constituents and IOPs retrieval of using multi-angle polarimetry. ? 2024, The Authors. All rights reserved.
    Affiliations:(1) State Key Laboratory of Tropical Oceanography, South China Sea Institute of Oceanology, Chinese Academy of Sciences, Guangzhou; 510301, China; (2) Key Laboratory of Spectral Imaging Technology of CAS, Xi’an Institute of Optics and Precision Mechanics, Chinese Academy of Sciences, Xi’an; 710119, China; (3) State Key Laboratory of Satellite Ocean Environment Dynamics, Second Institute of Oceanography, Ministry of Natural Resources, Hangzhou; 310012, China; (4) University of Chinese Academy of Sciences, Beijing; 100049, China; (5) School of Human Settlements and Civil Engineering, Xi’an Jiaotong University, Xi’an; 710049, China; (6) Key Laboratory of Watershed Geographic Sciences, Nanjing Institute of Geography and Limnology, Chinese Academy of Sciences, Nanjing; 210008, China; (7) National-local Joint Engineering Laboratory of Geospatial Information Technology, Hunan University of Science and Technology, Xiangtan; 411201, China
    Publication Year:2024
    DOI Link:10.2139/ssrn.4803997
    數(shù)據(jù)庫ID(收錄號):20240169237
  • Record 53 of

    Title:Dark gap soliton families in coupled nonlinear Schr?dinger equations with linear lattices
    Author Full Names:Chen, Junbo(1); Mihalache, Dumitru(2); Beli?, Milivoj R.(3); Qin, Wenqiang(4,5,6); Zhu, Danfeng(1); Zhu, Xing(7); Zeng, Liangwei(7)
    Source Title:Nonlinear Dynamics
    Language:English
    Document Type:Article in Press
    Abstract:We demonstrate that two types of dark gap soliton families, the fundamental dark solitons and the dark soliton clusters, can be stabilized in coupled nonlinear Schr?dinger equations (NLSEs) with linear lattices. Two types of coupled NLSEs are investigated, those with identical lattices and those with different lattices. In the latter case, one component features a monochromatic linear lattice, while the other features a bichromatic linear lattice. For coupled NLSEs with the same lattices, the soliton profiles are nearly identical, with both components exhibiting monochromatic backgrounds. In contrast, for coupled NLSEs with different lattices, the profiles differ significantly: one component has a monochromatic background, while the other has a bichromatic background. The stability domains of these dark soliton families are determined by the method of linear stability analysis, and also confirmed by direct numerical simulations. ? The Author(s), under exclusive licence to Springer Nature B.V. 2024.
    Affiliations:(1) School of Physics and Electronic Engineering, Jiaying University, Meizhou; 514015, China; (2) Horia Hulubei National Institute of Physics and Nuclear Engineering, Magurele, Bucharest; 077125, Romania; (3) College of Sciences and Engineering, Hamad Bin Khalifa University, Doha; 23874, Qatar; (4) Key Laboratory for Physical Electronics and Devices of the Ministry of Education, Shaanxi Key Lab of Information Photonic Technique, School of Electronic Science and Engineering, Xi’an Jiaotong University, Xi’an; 710049, China; (5) Key Laboratory of Ultra-fast Photoelectric Diagnostics Technology of CAS, Xi’an Institute of Optics and Precision Mechanics of Chinese Academy of Sciences, Xi’an; 710119, China; (6) University of Chinese Academy of Sciences, Beijing; 100049, China; (7) School of Arts and Sciences, Guangzhou Maritime University, Guangzhou; 510725, China
    Publication Year:2024
    Article Number:213001
    DOI Link:10.1007/s11071-024-10788-4
    數(shù)據(jù)庫ID(收錄號):20245217571754
  • Record 54 of

    Title:Enhancing the spatial resolution of time-of-flight based non-line-of-sight imaging via instrument response function deconvolution
    Author Full Names:Wang, Dingjie(1,2); Hao, Wei(1,3,4); Tian, Yuyuan(1,2); Xu, Weihao(1,2); Tian, Yuan(1,2); Cheng, Haihao(2,5); Chen, Songmao(1,3,4); Zhang, Ning(6); Zhu, Wen Hua(7); Su, Xiuqin(1,3,4)
    Source Title:Optics Express
    Language:English
    Document Type:Journal article (JA)
    Abstract:Non-line-of-sight (NLOS) imaging retrieves the hidden scenes by utilizing the signals indirectly reflected by the relay wall. Benefiting from the picosecond-level timing accuracy, time-correlated single photon counting (TCSPC) based NLOS imaging can achieve theoretical spatial resolutions up to millimeter level. However, in practical applications, the total temporal resolution (also known as total time jitter, TTJ) of most current TCSPC systems exceeds hundreds of picoseconds due to the combined effects of multiple electronic devices, which restricts the underlying spatial resolution of NLOS imaging. In this paper, an instrument response function deconvolution (IRF-DC) method is proposed to overcome the constraints of a TCSPC system s TTJ on the spatial resolution of NLOS imaging. Specifically, we model the transient measurements as Poisson convolution process with the normalized IRF as convolution kernel, and solve the inverse problem with iterative deconvolution algorithm, which significantly improves the spatial resolution of NLOS imaging after reconstruction. Numerical simulations show that the IRF-DC facilitates light-cone transform and frequency-wavenumber migration solver to achieve successful reconstruction even when the system s TTJ reaches 1200 ps, which is equivalent to what was previously possible when TTJ was about 200 ps. In addition, the IRF-DC produces satisfactory reconstruction outcomes when the signal-To-noise ratio (SNR) is low. Furthermore, the effectiveness of the proposed method has also been experimentally verified. The proposed IRF-DC method is highly applicable and efficient, which may promote the development of high-resolution NLOS imaging. ? 2024 Optica Publishing Group (formerly OSA). All rights reserved.
    Affiliations:(1) Key Laboratory of Space Precision Measurement Technology, Xi an Institute of Optics and Precision Mechanics, Chinese Academy of Sciences, Xi an; 710719, China; (2) University of Chinese Academy of Science, Beijing; 100049, China; (3) Center for Shared Technologies and Facilities, Xi an Institute of Optics and Precision Mechanics, Chinese Academy of Sciences, Xi an; 710119, China; (4) Pilot National Laboratory for Marine Science and Technology (Qingdao), Qingdao; 266237, China; (5) State Key Laboratory of Transient Optics and Photonics, Xi an Institute of Optics and Precision Mechanics, Chinese Academy of Sciences, Xi an; 710119, China; (6) Key Laboratory of Spectral Imaging Technology, Xi an Institute of Optics and Precision Mechanics, Chinese Academy of Sciences, Xi an; 710119, China; (7) School of Electronic and Information Engineering, Jiujiang University, Jiujiang; 332005, China
    Publication Year:2024
    Volume:32
    Issue:7
    Start Page:12303-12317
    DOI Link:10.1364/OE.518767
    數(shù)據(jù)庫ID(收錄號):20241415837517
  • Record 55 of

    Title:200 mm optical synthetic aperture imaging over 120 meters distance via macroscopic Fourier ptychography
    Author Full Names:Zhang, Qi(1,2,3); Lu, Yuran(4); Guo, Yinghui(1,2,3,5,6); Shang, Yingjie(1,2,3,5); Pu, Mingbo(1,2,3,5); Fan, Yulong(1,2,3); Zhou, Rui(4); Li, Xiaoyin(1,2,3); Pan, An(7); Zhang, Fei(1,2,3); Xu, Mingfeng(1,2,3); Luo, Xiangang(1,2,3,5)
    Source Title:Optics Express
    Language:English
    Document Type:Journal article (JA)
    Abstract:Fourier ptychography (FP) imaging, drawing on the idea of synthetic aperture, has been demonstrated as a potential approach for remote sub-diffraction-limited imaging. Nevertheless, the farthest imaging distance is still limited to around 10 m, even though there has been a significant improvement in macroscopic FP. The most severe issue in increasing the imaging distance is the field of view (FoV) limitation caused by far-field conditions for diffraction. Here, we propose to modify the Fourier far-field condition for rough reflective objects, aiming to overcome the small FoV limitation by using a divergent beam to illuminate objects. A joint optimization of pupil function and target image is utilized to attain the aberration-free image while estimating the pupil function simultaneously. Benefiting from the optimized reconstruction algorithm, which effectively expands the camera’s effective aperture, we experimentally implement several FP systems suited for imaging distances of 12 m, 65 m, and 120 m with the maximum synthetic aperture of 200 mm. The maximum synthetic aperture is thus improved by more than one order of magnitude of the state-of-the-art works from the furthest distance, with an over fourfold improvement in the resolution compared to a single aperture. Our findings demonstrate significant potential for advancing the field of macroscopic FP, propelling it into a new stage of development. ? 2024 Optica Publishing Group under the terms of the Optica Open Access Publishing Agreement.
    Affiliations:(1) National Key Laboratory of Optical Field Manipulation Science and Technology, Institute of Optics and Electronics, Chinese Academy of Sciences, Chengdu; 610209, China; (2) State Key Laboratory of Optical Technologies on Nano-Fabrication and Micro-Engineering, Institute of Optics and Electronics, Chinese Academy of Sciences, Chengdu; 610209, China; (3) Research Center on Vector Optical Fields, Institute of Optics and Electronics, Chinese Academy of Sciences, Chengdu; 610209, China; (4) Tianfu Xinglong Lake Laboratory, Chengdu; 610299, China; (5) College of Materials Sciences and Opto-Electronic Technology, University of Chinese Academy of Sciences, Beijing; 100049, China; (6) Sichuan Provincial Engineering Research Center of Digital Materials, Chengdu; 610299, China; (7) State Key Laboratory of Transient Optics and Photonics, Xi’an Institute of Optics and Precision Mechanics, Chinese Academy of Sciences, Xi’an; 710119, China
    Publication Year:2024
    Volume:32
    Issue:25
    Start Page:44252-44264
    DOI Link:10.1364/OE.533063
    數(shù)據(jù)庫ID(收錄號):20244917491979
  • Record 56 of

    Title:PneumoLLM: Harnessing the power of large language model for pneumoconiosis diagnosis
    Author Full Names:Song, Meiyue(1,2); Wang, Jiarui(3); Yu, Zhihua(4); Wang, Jiaxin(5); Yang, Le(6); Lu, Yuting(3); Li, Baicun(7); Wang, Xue(8,9); Wang, Xiaoxu(3); Huang, Qinghua(10); Li, Zhijun(11,12); Kanellakis, Nikolaos I.(13,14,15); Liu, Jiangfeng(1,16,17); Wang, Jing(1,2); Wang, Binglu(3); Yang, Juntao(1,16,17)
    Source Title:Medical Image Analysis
    Language:English
    Document Type:Journal article (JA)
    Abstract:The conventional pretraining-and-finetuning paradigm, while effective for common diseases with ample data, faces challenges in diagnosing data-scarce occupational diseases like pneumoconiosis. Recently, large language models (LLMs) have exhibits unprecedented ability when conducting multiple tasks in dialogue, bringing opportunities to diagnosis. A common strategy might involve using adapter layers for vision–language alignment and diagnosis in a dialogic manner. Yet, this approach often requires optimization of extensive learnable parameters in the text branch and the dialogue head, potentially diminishing the LLMs’ efficacy, especially with limited training data. In our work, we innovate by eliminating the text branch and substituting the dialogue head with a classification head. This approach presents a more effective method for harnessing LLMs in diagnosis with fewer learnable parameters. Furthermore, to balance the retention of detailed image information with progression towards accurate diagnosis, we introduce the contextual multi-token engine. This engine is specialized in adaptively generating diagnostic tokens. Additionally, we propose the information emitter module, which unidirectionally emits information from image tokens to diagnosis tokens. Comprehensive experiments validate the superiority of our methods. ? 2024 Elsevier B.V.
    Affiliations:(1) Institute of Basic Medical Sciences Chinese Academy of Medical Sciences, School of Basic Medicine Peking Union Medical College, Beijing; 100005, China; (2) State Key Laboratory of Respiratory Health and Multimorbidity, Beijing; 100005, China; (3) School of Automation, Northwestern Polytechnical University, Shaanxi, Xi'an; 710072, China; (4) Jinneng Holding Coal Industry Group Co. Ltd Occupational Disease Precaution Clinic, Shanxi; 037001, China; (5) School of Medicine, Tsinghua University, Beijing; 100084, China; (6) School of Electronics and Control Engineering, Chang'an University, Shaanxi, Xi'an; 710064, China; (7) Center of Respiratory Medicine, China-Japan Friendship Hospital, National Center for Respiratory Medicine, Institute of Respiratory Medicine, Chinese Academy of Medical Sciences, National Clinical Research Center for Respiratory Diseases, Beijing; 100020, China; (8) Department of Respiratory, the Second Affiliated Hospital of Harbin Medical University, Harbin, Heilongjiang; 150086, China; (9) Internal Medicine, Harbin Medical University, Harbin, Heilongjiang; 150081, China; (10) School of Artificial Intelligence, OPtics and ElectroNics (iOPEN), Northwestern Polytechnical University, Xi'an; 710072, China; (11) Translational Research Center, Shanghai YangZhi Rehabilitation Hospital (Shanghai Sunshine Rehabilitation Center), Shanghai; 201619, China; (12) School of Mechanical Engineering, Tongji University, Shanghai; 201804, China; (13) Laboratory of Pleural and Lung Cancer Translational Research, CAMS Oxford Institute, Nuffield Department of Medicine, University of Oxford, Oxford, United Kingdom; (14) Oxford Centre for Respiratory Medicine, Churchill Hospital, Oxford University Hospitals NHS Foundation Trust, Oxford, United Kingdom; (15) National Institute for Health Research Oxford Biomedical Research Centre, University of Oxford, Oxford, United Kingdom; (16) Plastic Surgery Hospital, Chinese Academy of Medical Sciences and Peking Union Medical College, Beijing; 100144, China; (17) State Key Laboratory of Common Mechanism Research for Major Diseases, Beijing; 100005, China
    Publication Year:2024
    Volume:97
    Article Number:103248
    DOI Link:10.1016/j.media.2024.103248
    數(shù)據(jù)庫ID(收錄號):20242616508439
  • Record 57 of

    Title:On-chip generation and processing of ultrafast time-entangled photonic qudits for quantum communications
    Author Full Names:Sciara, Stefania(1); Yu, Hao(1,2); Chemnitz, Mario(1,3); Montaut, Nicola(1); Fischer, Bennet(1,3); Helsten, Robin(1); Crockett, Benjamin(1); Wetzel, Benjamin(4); Goebel, Thorsten A.(5); Kr?mer, Ria G.(5); Little, Brent E.(6); Chu, Sai T.(7); Nolte, Stefan(5,8); Munro, William J.(9); Moss, David J.(10); Aza?a, José(1); Wang, Zhiming(2); Morandotti, Roberto(1,2)
    Source Title:2024 Conference on Lasers and Electro-Optics, CLEO 2024
    Language:English
    Document Type:Conference article (CA)
    Conference Title:2024 Conference on Lasers and Electro-Optics, CLEO 2024
    Conference Date:May 7, 2024 - May 10, 2024
    Conference Location:Charlotte, NC, United states
    Conference Sponsor:American Elements; American Physical Society, Division of Laser Science; et al.; IEEE Photonics Society; IPG Photonics; LIGENTEC
    Abstract:We present a photonic platform for the generation and processing of picosecond-spaced time entangled qudits, based on on-chip interferometers and a spiral waveguide. We utilize these qudits to implement quantum communications over standard optical fibers. ? Optica Publishing Group 2024 ? 2024 The Author (s)
    Affiliations:(1) Institut national de la recherche scientifique - Centre énergie, Matériaux et Télécommunications (INRS-EMT), Varennes; J3X 1S2, Canada; (2) Institute of Fundamental and Frontier Sciences, University of Science and Technology of China, Chendu; 610054, China; (3) Leibniz Institute of Photonic Technology, Albert-Einstein Strasse 9, Jena; 07745, Germany; (4) XLIM Research Institute, CNRS, UMR 7252, Université de Limoges, Limoges; 87060, France; (5) Friedrich Schiller University Jena, Abbe Center of Photonics, Institute of Applied Physics, Albert-Einstein-Strasse 15, Jena; 07745, Germany; (6) QXP Technology Inc., Xi'an, China; (7) Department of Physics, City University of Hong Kong, Hong Kong, Hong Kong; (8) Fraunhofer Institute for Applied Optics and Precision Engineering IOF, Center of Excellence in Photonics, Albert-Einstein-Strasse 7, Jena; 07745, Germany; (9) Okinawa Institute of Science and Technology Graduate University, Okinawa, Onna-son; 904-0495, Japan; (10) Optical Sciences Centre, Swinburne University of Technology, Hawthorn; VIC; 3122, Australia
    Publication Year:2024
    DOI Link:10.1364/cleo_fs.2024.ftu4f.6
    數(shù)據(jù)庫ID(收錄號):20244917467986
  • Record 58 of

    Title:On-chip generation and processing of ultrafast time-entangled photonic qudits for quantum communications
    Author Full Names:Sciara, Stefania(1); Yu, Hao(1,2); Chemnitz, Mario(1,3); Montaut, Nicola(1); Fischer, Bennet(1,3); Helsten, Robin(1); Crockett, Benjamin(1); Wetzel, Benjamin(4); Goebel, Thorsten A.(5); Kr?mer, Ria G.(5); Little, Brent E.(6); Chu, Sai T.(7); Nolte, Stefan(5,8); Munro, William J.(9); Moss, David J.(10); Aza?a, José(1); Wang, Zhiming(2); Morandotti, Roberto(1,2)
    Source Title:CLEO: Fundamental Science, CLEO:FS 2024 in Proceedings CLEO 2024 - Part of Conference on Lasers and Electro-Optics
    Language:English
    Document Type:Conference article (CA)
    Conference Title:CLEO: Fundamental Science, CLEO:FS 2024 - Part of Conference on Lasers and Electro-Optics, CLEO 2024
    Conference Date:May 5, 2024 - May 10, 2024
    Conference Location:Charlotte, NC, United states
    Abstract:We present a photonic platform for the generation and processing of picosecond-spaced time entangled qudits, based on on-chip interferometers and a spiral waveguide. We utilize these qudits to implement quantum communications over standard optical fibers. ? Optica Publishing Group 2024 ? 2024 The Author(s)
    Affiliations:(1) Institut National de la Recherche Scientifique - Centre énergie, Matériaux et Télécommunications (INRS-EMT), Varennes; J3X 1S2, Canada; (2) Institute of Fundamental and Frontier Sciences, University of Science and Technology of China, Chendu; 610054, China; (3) Leibniz Institute of Photonic Technology, Albert-Einstein Strasse 9, Jena; 07745, Germany; (4) XLIM Research Institute, CNRS, UMR 7252, Université de Limoges, Limoges; 87060, France; (5) Friedrich Schiller University Jena, Abbe Center of Photonics, Institute of Applied Physics, Albert-Einstein-Strasse 15, Jena; 07745, Germany; (6) QXP Technology Inc., Xi'an, China; (7) Department of Physics, City University of HongKong, Hong Kong, Hong Kong; (8) Fraunhofer Institute for Applied Optics and Precision Engineering IOF, Center of Excellence in Photonics, Albert-Einstein-Strasse 7, Jena; 07745, Germany; (9) Okinawa Institute of Science and Technology, Graduate University, Okinawa, Onna-son; 904-0495, Japan; (10) Optical Sciences Centre, Swinburne University of Technology, Hawthorn; VIC; 3122, Australia
    Publication Year:2024
    DOI Link:10.1364/cleo_fs.2024.ftu4f.6
    數(shù)據(jù)庫ID(收錄號):20244217221602
  • Record 59 of

    Title:New Upper Limit on the Axion-Photon Coupling with an Extended CAST Run with a Xe-Based Micromegas Detector
    Author Full Names:Altenmüller, K.(1); Anastassopoulos, V.(2); Arguedas-Cuendis, S.(3); Aune, S.(4); Baier, J.(5); Barth, K.(3); Br?uninger, H.(6); Cantatore, G.(7); Caspers, F.(3,8); Castel, J.F.(1); ?etin, S.A.(9); Christensen, F.(10); Cogollos, C.(1,11); Dafni, T.(1); Davenport, M.(3); Decker, T.A.(12); Desch, K.(13); Díez-Ibá?ez, D.(1); D?brich, B.(3); Ferrer-Ribas, E.(4); Fischer, H.(5); Funk, W.(3); Galán, J.(1); García, J.A.(1); Gardikiotis, A.(14); Giomataris, I.(4); Golm, J.(3,15); Hailey, C.H.(16); Hasinoff, M.D.(17); Hoffmann, D.H.H.(18); Irastorza, I.G.(1); Jacoby, J.(5); Jakobsen, A.C.(10); Jakov?i?, K.(19); Kaminski, J.(13); Karuza, M.(20,21); Kostoglou, S.(3); Krieger, C.(22); Laki?, B.(19); Laurent, J.M.(3); Luzón, G.(1); Malbrunot, C.(3); Margalejo, C.(1); Maroudas, M.(23); Miceli, L.(24); Mirallas, H.(1); Navarro, P.(25); Obis, L.(1); ?zbey, A.(9,26); ?zbozduman, K.(9,27); Papaevangelou, T.(4); Pérez, O.(1); Pivovaroff, M.J.(12); Rosu, M.(28); Ruiz-Chóliz, E.(1); Ruz, J.(1,12); Schmidt, S.(13); Schumann, M.(5); Semertzidis, Y.K.(24,29); Solanki, S.K.(30); Stewart, L.(3); Vafeiadis, T.(3); Vogel, J.K.(1,12); Zioutas, K.(2,3)
    Source Title:Physical Review Letters
    Language:English
    Document Type:Journal article (JA)
    Abstract:Hypothetical axions provide a compelling explanation for dark matter and could be emitted from the hot solar interior. The CERN Axion Solar Telescope has been searching for solar axions via their back conversion to x-ray photons in a 9-T 10-m long magnet directed toward the Sun. We report on an extended run with the International Axion Observatory pathfinder detector, doubling the previous exposure time. The detector was operated with a xenon-based gas mixture for part of the new run, providing technical insights for future configurations. No counts were detected in the 95% signal-encircling region during the new run, while 0.75 were expected. The new data improve the axion-photon coupling limit to 5.8×10-11 GeV-1 at 95% CL (for ma0.02 eV), the most restrictive experimental limit to date. ? 2024 authors. Published by the American Physical Society.
    Affiliations:(1) Centro de Astropartículas y Física de Altas Energías (CAPA), Departamento de Física Teórica, University de Zaragoza, Zaragoza; 50009, Spain; (2) Physics Department, University of Patras, Patras, Greece; (3) European Organization for Nuclear Research (CERN), Geneva 23; 1211, Switzerland; (4) IRFU, CEA, Université Paris-Saclay, Gif-sur-Yvette; 91191, France; (5) Physikalisches Institut, Albert-Ludwigs-Universit?t Freiburg, Freiburg; 79104, Germany; (6) Max-Planck-Institut für Extraterrestrische Physik, Garching, Germany; (7) University of Trieste and Instituto Nazionale di Fisica Nucleare (INFN), Sezione di Trieste, Trieste, Italy; (8) European Scientific Institute, Archamps, France; (9) Istinye University, Institute of Sciences, Sariyer, Istanbul; 34396, Turkey; (10) DTU Space, National Space Institute, Technical University of Denmark, Lyngby; 2800, Denmark; (11) Institut de Ciències Del Cosmos, Universitat de Barcelona (UB-IEEC), Catalonia, Barcelona, Spain; (12) Lawrence Livermore National Laboratory, Livermore; CA; 94550, United States; (13) Physikalisches Institut, University of Bonn, Bonn; 53115, Germany; (14) Istituto Nazionale di Fisica Nucleare (INFN), Sezione di Padova, Padova; 35131, Italy; (15) Institute for Optics and Quantum Electronics, Friedrich Schiller University Jena, Jena, Germany; (16) Physics Department and Columbia Astrophysics Laboratory, Columbia University, New York; NY; 10027, United States; (17) Department of Physics and Astronomy, University of British Columbia, Vancouver; BC, Canada; (18) Xi'An Jiaotong University, School of Science, Xi'An; 710049, China; (19) Rudjer Bo?kovi? Institute, Zagreb, Croatia; (20) Istituto Nazionale di Fisica Nucleare (INFN), Sezione di Trieste, Trieste, Italy; (21) Faculty of Physics, Center for Micro and Nano Sciences and Technologies, University of Rijeka, Rijeka; 51000, Croatia; (22) Universit?t Hamburg, Hamburg, Germany; (23) Institute of Experimental Physics, University of Hamburg, Hamburg; 22761, Germany; (24) Center for Axion and Precision Physics Research, Institute for Basic Science (IBS), Daejeon; 34141, Korea, Republic of; (25) Department of Information and Communications Technologies, Technical University of Cartagena, Murcia; 30203, Spain; (26) Istanbul University-Cerrahpasa, Department of Mechanical Engineering, Avcilar, Istanbul, Turkey; (27) Bo?azi?i University, Physics Department, Bebek, Istanbul, Turkey; (28) Extreme Light Infrastructure - Nuclear Physics (ELI-NP), Magurele; 077125, Romania; (29) Department of Physics, Korea Advanced Institute of Science and Technology (KAIST), Daejeon; 34141, Korea, Republic of; (30) Max-Planck-Institut für Sonnensystemforschung, G?ttingen; 37077, Germany
    Publication Year:2024
    Volume:133
    Issue:22
    Article Number:221005
    DOI Link:10.1103/PhysRevLett.133.221005
    數(shù)據(jù)庫ID(收錄號):20244817454689
  • Record 60 of

    Title:The scintillating-fiber tracker (FIT) of the HERD space mission from design to performance
    Author Full Names:Adriani, O.(1,2); Alemanno, F.(3,4); Altomare, C.(5); Ambrosi, G.(6); Antonelli, M.(7); Bai, X.H.(9); Bai, Y.L.(9); Bao, T.W.(10); Barbanera, M.(6); Barbato, F.C.T.(3,4); Bernard, F.(11); Bernardini, P.(12,13); Berti, E.(2); Bertucci, B.(6,14); Betti, P.(1,2); Bi, X.J.(10,15); Bigongiari, G.(16,17); Blanch, O.(18); Boix, J.(18); Bongi, M.(1,2); Bonvicini, V.(7); Bottai, S.(2); Brogi, P.(16,17); Brugnoni, C.(6,14); Cadoux, F.(8); Cagnoli, I.(3,4); Cai, H.Y.(10,15); Campana, D.(19); Cao, W.W.(9); Cardiel-Sas, L.(18); Casaus, J.(20); Casilli, E.(12,13); Catala, R.(21); Catanzani, E.(6,14); Cattaneo, P.W.(22); Cerasole, D.(5,23); Chang, L.(24); Chen, H.(10,15); Chen, K.(25); Chen, L.(26); Chen, M.L.(10); Chen, P.D.(27); Chen, R.(25); Cheng, Y.D.(10,15); Cianetti, F.(6,14); Comerma, A.(28); Cong, X.Q.(29); Coppin, P.(8); Cui, X.Z.(10); D'Alessandro, R.(1,2); D'Urso, D.(6,30); Díaz, C.(20); Dai, C.(31); De Mitri, I.(3,4); de Palma, F.(12,13); De Vecchi, C.(22); Di Felice, V.(32); Di Giovanni, A.(3,4); Di Santo, M.(3,4); Di Venere, L.(5); Dong, Y.W.(10); Donvito, G.(5); Du, Y.J.(33); Duranti, M.(6); Espinya, A.(21); Fang, K.(10); Fari?a, L.(18); Favre, Y.(8); Feng, H.B.(31); Fernandez Alonso, M.(3,4); Finetti, N.(2,34); Fontanella, G.(3,4); Formato, V.(32); Frieden, J.M.(11); Fu, Y.(33); Fusco, P.(5,23); Gao, J.R.(9); Gargano, F.(5); Gascón, D.(21,35); Gasparrini, D.(32); Ghose, E.(12,13,48); Giovacchini, F.(20); Gómez, S.(21,28); Gong, K.(10); Gu, M.H.(10); Guberman, D.(21); Guerrisi, C.(5,23); Guida, R.(36); Guo, D.Y.(10); Guo, J.H.(37); He, H.L.(10,15); Hu, H.(10); Hu, H.J.(31); Hu, Y.M.(37); Hu, Z.X.(29); Huang, G.S.(27); Huang, W.H.(38); Huang, X.T.(38); Huang, Y.G.(33); Ionica, M.(6); Jia, F.(31); Jia, J.S.(33); Jiang, F.(31); Jiang, X.W.(10); Jiang, Y.(6,14); Jiao, P.(33); Kotenko, A.(8); Kyratzis, D.(3,4); La Marra, D.(8); Lathika, K.R.(18); Li, L.(10); Li, M.J.(38); Li, M.X.(25); Li, Q.Y.(39); Li, Q.Y.(40); Li, R.(9); Li, S.L.(10,15); Li, T.(29); Li, T.(38); Li, X.Q.(10); Li, X.Q.(41); Li, Y.Y.(39); Li, Z.H.(10,15); Liang, M.J.(10,15); Liang, X.Z.(9); Liao, C.L.(10,15); Licciulli, F.(5); Lin, Y.J.(29); Liu, B.H.(24); Liu, D.(38); Liu, H.(26); Liu, H.B.(31); Liu, H.W.(10); Liu, X.(10,15); Liu, X.J.(10); Liu, X.W.(31); Liu, Y.Q.(10); Loparco, F.(5,23); Loporchio, S.(5,23); Lorusso, L.(5,23); Lu, B.(10); Lu, R.S.(10,15); Lu, Y.P.(10); Lucchetta, G.(18); Lv, J.G.(10); Lv, L.W.(9); Maestro, P.(16,17); Mancini, E.(6); Manera, R.(21); Marin, J.(20); Marrocchesi, P.S.(16,17); Marsella, G.(42,43); Martinez, G.(20); Martinez, M.(18); Mauricio, J.(21); Mazziotta, M.N.(5); Morettini, G.(6,14); Mori, N.(2); Mussolin, L.(6,14); Nicotri, S.(5); Niu, Y.(38); Oliva, A.(44); Orlandi, D.(4); Orta, M.(21,35)
    Source Title:Proceedings of Science
    Language:English
    Document Type:Conference article (CA)
    Conference Title:38th International Cosmic Ray Conference, ICRC 2023
    Conference Date:July 26, 2023 - August 3, 2023
    Conference Location:Nagoya, Japan
    Conference Sponsor:et al.; Institute for Cosmic Ray Research (ICRR) Univeristy of Tokyo; International Union of Pure and Applied Physics (IUPAP); JPS; Nagoya Convention and Visitors Bureau; Nagoya University
    Abstract:The High Energy cosmic-Radiation Detection facility (HERD) will be a calorimetric experiment on board the China Space Station. Starting from 2027, HERD will perform the first direct measurement of cosmic rays in the PeV region and the gamma-ray full-sky survey from 100 MeV. The detector will be equipped with a scintillating-fiber tracker (FIT) read out with silicon photomultipliers. A miniature of a FIT sector, called MiniFIT, was designed, built and tested with particle beams at CERN. The FIT design, together with the design and physics performance of MiniFIT will be presented in this contribution. ? Copyright owned by the author(s) under the terms of the Creative Commons.
    Affiliations:(1) Department of Physics, University of Florence, Via Sansone 1, Sesto Fiorentino, Firenze; I-50019, Italy; (2) Istituto Nazionale di Fisica Nucleare, Sezione di Firenze, Sesto Fiorentino, Via Sansone 1, Firenze; I-50019, Italy; (3) Gran Sasso Science Institute (GSSI), Viale Crispi 7, L'Aquila; I-67100, Italy; (4) Istituto Nazionale di Fisica Nucleare, Laboratori Nazionali del Gran Sasso, Via Acitelli 22, Assergi, L'Aquila; I-67100, Italy; (5) Istituto Nazionale di Fisica Nucleare, Sezione di Bari, via Orabona 4, Bari; I-70126, Italy; (6) Istituto Nazionale di Fisica Nucleare, Sezione di Perugia, Via Alessandro Pascoli 23c, Perugia; I-06123, Italy; (7) Istituto Nazionale di Fisica Nucleare, Sezione di Trieste, via A. Valerio 2, Trieste; I-34127, Italy; (8) Département de Physique Nucléaire et Corpusculaire (DPNC), Université de Genève, 24 quai Ernest-Ansermet, 4, Genève; CH-1211, Switzerland; (9) Xi'an Institute of Optics and Precision Mechanics, CAS, No.17 Xinxi Road, New Industrial Park, Xi'an Hi-Tech Industrial Development Zone, Xi'an; 710019, China; (10) Institute of High Energy Physics, Chinese Academy of Sciences, 19B Yuquan Road, Shijingshan District, Beijing; 100049, China; (11) Institute of Physics, Ecole Polytechnique Fédérale de Lausanne (EPFL), Batiment PH, Station 3, Lausanne; CH-1015, Switzerland; (12) Dipartimento di Matematica e Fisica 'E. De Giorgi', Università del Salento, Lecce; I-73100, Italy; (13) Istituto Nazionale di Fisica Nucleare, Sezione di Lecce, Via per Arnesano, Lecce; I-73100, Italy; (14) Università degli Studi di Perugia, Piazza Università 1, Perugia; I-06123, Italy; (15) University of Chinese Academy of Sciences, No.1 Yanqihu East Rd, Huairou District, Beijing; 101408, China; (16) Department of Physical Sciences, Earth and Environment, University of Siena, via Roma 56, Siena; I-53100, Italy; (17) Istituto Nazionale di Fisica Nucleare, Sezione di Pisa, Largo B. Pontecorvo 3, Pisa; I-56127, Italy; (18) Institut de Física d'Altes Energies (IFAE), The Barcelona Institute of Science and Technology (BIST), Bellaterra, Barcelona; E-08193, Spain; (19) Istituto Nazionale di Fisica Nucleare, Sezione di Napoli, Via Cintia, Napoli; I-80126, Italy; (20) Centro de Investigaciones Energéticas, Medioambientales y Tecnológicas (CIEMAT), Madrid; E-28040, Spain; (21) Departament de Física Quàntica i Astrofísica (FQA), Institut de Ciències del Cosmos (ICCUB), Universitat de Barcelona (UB), Barcelona; E-08028, Spain; (22) Istituto Nazionale di Fisica Nucleare, Sezione di Pavia, Via Bassi 6, Pavia; I-27100, Italy; (23) Dipartimento di Fisica, 'M. Merlin' dell'Università e del Politecnico di Bari, via Amendola 173, Bari; I-70126, Italy; (24) North Night Vision Technology Co., Ltd., Hongwai Road 5, Kunming; 650217, China; (25) PLAC, Key Laboratory of Quark & Lepton Physics (MOE), Central China Normal University, Wuhan; 430079, China; (26) School of Physical Science and Technology, Southwest Jiaotong University, No.999, Xi'an Road, Chengdu; 611756, China; (27) Department of Modern Physics, University of Science and Technology of China, Hefei; 230026, China; (28) Polytechnic University of Catalonia (UPC), Electronics Department, Barcelona; E-08019, Spain; (29) North Night Vision Science & Technology (Nanjing) Research Institute Co., Ltd, Kangping Street 2, Nanjing; 211100, China; (30) Università degli Studi di Sassari, Piazza Università 21, Sassari; I-07100, Italy; (31) Guangxi Key Laboratory for Relativistic Astrophysics, Guangxi University, Daxue East Road 100, Nanning; 530004, China; (32) Istituto Nazionale di Fisica Nucleare, Sezione di Roma Tor Vergata, via della Ricerca Scientifica 1, Roma; I-00133, Italy; (33) Institute of Special Glass Fiber & Optoelectronic Functional Materials, China Building Materials Academy, Guanzhuang Dongli 1, Chaoyang district, Beijing; 100024, China; (34) Department of Physical and Chemical Sciences, University of L'Aquila, Via Vetoio, Coppito, L'Aquila; I-67100, Italy; (35) Institut d'Estudis Espacials de Catalunya (IEEC), Barcelona; E-08034, Spain; (36) Dipartimento di Ingegneria Industriale, Università degli Studi di Napoli Federico II, P.le Tecchio 80, Napoli; I-80125, Italy; (37) Purple Mountain Observatory, CAS, No.10 Yuanhua Road, Qixia District, Nanjing; 210023, China; (38) Shandong University (SDU), 72 Binhai Road, Qingdao, Jimo; 266237, China; (39) Shandong University (SDU), 27 Shanda Nanlu, Shandong, Jinan; 250100, China; (40) Shandong Institute of Advanced Technology (SDIAT), 1501, Panlong Road, Shandong, Jinan; 250100, China; (41) Institute of Modern Physics, CAS, 509 Nanchang Rd., Lanzhou; 730000, China; (42) Dipartimento di Fisica e Chimica, 'E. Segrè', Università degli Studi di Palermo, via delle Scienze, Palermo; I-90128, Italy; (43) Istituto Nazionale di Fisica Nucleare, Sezione di Catania, Via Santa Sofia 64, Catania; I-95123, Italy; (44) Istituto Nazionale di Fisica Nucleare, Sezione di Bologna, Viale C. Berti Pichat 6/2, Bologna; I-40127, Italy; (45) Università di Napoli Federico II, Dipartimento di Fisica 'Ettore Pancini', Via Cintia, Napoli; I-80126, Italy; (46) Agenzia Spaziale Italiana, via del Politecnico s.n.c., Roma; I-00133, Italy; (47) Département d'Astronomie, Université de Genève, Chemin d'Ecogia 16, Versoix; CH-1290, Switzerland; (48) Dipartimento di Fisica, Università di Trento, via Sommarive 14, Trento; I-38123, Italy
    Publication Year:2024
    Volume:444
    Article Number:147
    數(shù)據(jù)庫ID(收錄號):20245117556256
婷婷丁香红五月91C| 98热精品| 97香蕉人人在线观看| 中美月韩免费A片| 色五月婷婷天天干| 日韩精品二三区| 丁香五月开心亚洲| 色婷婷基地 | 国产91在线视频| 96精品久久久久久久久| 99国产这里只有精品| 精品久久久999| 国产精品一区在线观看你懂的| 婷婷五月天久草在线| 天天肏天天肏天天肏| 思思99精品视频在线观看| 99re最新地址| 亚洲精品午夜国产va久久成人| 九九婷| 丁香五月大香蕉AV| 深爱网深爱综合网| 欧美又粗又大AAA片| 开心婷婷五月| 欧美啪啪五月天| 操操操操操操婷婷五月天| 婷婷五月久久| 五月激情婷婷在线| 91欧美日韩| 欧美日本VA| 色亭亭五月天丁香综合AV - 百度 - 百度 | 色色日本| 色约约视频一区二区三区四区五区 | 99re最新地址| 久久只有18视频| 强奸幻女毛片| 亚洲色色爱| 久久婷婷五月天蜜桃| 亚洲天天| www激情网站| 99小精品| 91五月天| 丁香五月天激情四射网| 好好日激情五月天| 五月丁香大相交| 激情综合网激情五月俺也去| 色综合色色| 丁香婷婷色五月天| 99久热这里只有精品| 9 1大香蕉| 99亚洲综合| 丁香五月天之婷婷影院| 色五月婷婷久久| 丁香婷婷色九月| 久噜久噜| 热99在线| 久久久婷婷五月亚洲97号色| 精品一区二区三区木瓜| 97干在线视频| 伦99热| 色狠狠六月| 99久在线精品| 欧美碰碰碰| 国内婷婷丁香社区在线播放| 婷婷五月综合网| 大香人妻| 99人人操人人摸| 欧美日朝成人| 97黑人精品区| 久久婷婷五月天综合| 99热官网| 色婷婷九月| 99热这里有精力| AA片在线观看视频在线播放 | 五月婷婷狠狠干| 超碰久热| 熟女激情网| 久久99热这里只有精品| 婷婷丁香综合网| 激情5月舔| 高清无码网址| 国产综合A片| 丁香月五月天婷婷久久| 97久久久| 丁香五月性| 天天撸天天射| 91亚洲免费片| 狠狠色综合五月| 五月丁香啪啪| av在线超清中文| 91九色精品女同系列| 青996青| 99热在线免费| 99视频在线9| 婷婷天天插天天爱| 这里只有精品免费| 久久久久久欧美精品se一二三四| 最近中文字幕2018| 久久五月婷婷丁香| 五月天开心网| 亚洲小电影在线观看黄999| 婷婷五月丁香综合激情| 色综合色综合色综合| 婷婷五月综合激情小说| 乱精品一区字幕二区| 久久久久久久五月婷婷六月丁香综合,开心激情综合网 | 国产日产亚系列精品版优势| 九月婷婷综合八月丁香在线观看| 丁香五月天啪啪| 激情九月婷婷| 婷婷婷婷婷婷婷五月丁香| 91色在线| 99九色视频在线观看| 五月婷婷婷| 亚洲婷婷免费| 五月婷久草| 性色99| 激情九月婷婷九月| 婷婷免费无视频| 九九日伊人| 婷婷五月天深爱| 色噜噜狠狠色综无码久久合欧美| 婷婷五月在线综合| 狠狠综合| 一本大道熟女人妻中文字幕在线| 欧美精品在线观看| 99热这里只有99| 99热啪啪| 99色婷婷视频| 亚州色色色| 色婷婷小说| 伊人久久艹| 97久久久| 日韩无码色色| 丁香五月婷婷成人色区| 五月婷婷综合天天操| 日本操逼九九九九58日本操逼| 国产毛片操B| 99热这里只有精品1998| 亚洲人成网站999久久久综合| 激情五月天婷婷丁香 | 99热国产这里只有| 中文中文在线| 成年人看Va免费视频| 五月丁香A∨在线| 五月婷婷啪| 99热国产婷婷| 噜噜操操| 五月丁香六月婷婷综合在线| 日本欧美成人片AAAA| 色天天久婷婷| 超碰免费观看| 婷婷五月天综合在线| WWW.久久久久久久久久久久久| 亚洲这里只有精品| 91操在线视频| 开心五月色婷婷综合开心网| 九九爱激情| 99久久.www| 激情亭亭五月| 亚洲精99| 超碰妻人人| 色婷婷亚洲六月婷婷中文字幕| 成人在线视频男人的天堂4399| 五月天婷婷基地| 99操视频| 99热在线观看| 五月天另类图片| 久久人五月| 五月天综合激情网| 日日操夜夜操狠狠操| wwwav大香蕉| 丁香婷婷视频在线| 91操操| 欧美久热| 夜夜骑夜夜操| 就是色婷婷五月亚洲色| 色综合综合综合| 天天干天天操天天拍| 婷婷色五月激情强奸四射| 五月丁香综合啪啪| 色婷婷六月丁香综合欲精品| 玖玖在线视| 开心五月深爱五月| 色偷偷狠狠| 99热亚洲精品| 成人无码髙潮喷水A片| 天天做天天爱天天玩夜夜爽| 五月婷婷色播| 丰满老熟妇BBBBB搡BBB| 97色色综合| 成人电影一区| H亚洲| 开心五月四房播播| 久久在这里有精品| 涩婷婷视频快播人妻| 99久久婷婷五月综合| 可以免费看av网站| 玖玖综合玖玖| 久久ab| 激情五月婷婷色| 97在线视频人妻九色| 日日躁夜夜躁狠狠久久AV| 噜噜色com| 成人五月天丁香| 99自拍视频| 天天做天天爱| 成人婷婷色五月天| 美女91一起草| 欧美激情综合色综合啪啪五月| 思思精品热在线| 99啪| 九九色网专区| 99激情网| 婷婷五月综合激情免费| Av狠狠色丁香婷| 青青色com久久| 九九热最新地址| 九九无码视屏| 激情五月综合色| 国产综合A片| 综合网天天| 婷婷射丁香| 成人五月天在线观看| 日本欧美999久久久三级片| 婷婷五月天激情网| 色婷婷六月| 激情欧美婷五月| 六月色激情| 激情综合亚洲| 超碰日日操| 色噜综| 五月丁香综合| 丁香五月婷婷欧美成人色图| 久久久GOGO无码啪啪艺术| 五月网| 99热精国产这里只有精品| 成人短视频在线| 婷婷激情97| 国精产品一区一区三区免费视频| 亚洲色图五月丁香| 狠色色狠网| 激情综合4月| 亚洲色图81p| AA片在线观看视频在线播放| 色六月婷婷| 久播影院免费观看电视剧大全最新网| 狠狠看狠狠| 国产精品日日躁夜夜躁| 久草x色在线观看99| 99热这里是精品| 亚洲激情五月| 五月丁香无码| 婷婷五月丁香色情| 亚洲激情高潮| 婷婷五月丁香综合亚洲 | 婷婷九月丁香久久| 久久婷婷丁香五月一二三| 99九九视频| 婷婷成人av| 精品一二三区久久AAA片| 91偷拍视频| 五月激情六月综合| 欧美天天干天天草| 激情综合五月.....| 狠狠做五月| 色欧美影院| 丁香五月熟女| 七月丁香五月婷婷在线| 做爰丰满少妇1313| 五月香婷婷| 五月天天天天天天天天天天天天天天天婷婷婷| 激情五月天婷婷视频| 亚洲99激情| 超碰人人在线| 色碰碰| 丁香五月天婷婷91| 偷偷操九九| 婷婷在线五月综合| 亚洲乱码日产精品BD| 色五月首页| www.maotanji.com| 婷婷五月天在线视频网站| 日日狠狠久久偷偷四色综合免费 | 一逼色综合| 色色色区| 嫩草视频观看| 色色色色色色五月婷婷| av一区二区电影免费在线观看| 亚洲精品久久久无码| 天天狠狠夜夜狠狠2023| 97操视频| 丁香六月在线| 天天干天天拍| 狠狠综合网| 婷婷激情六月| 另类激情综合| 色99在线观看| 色偷偷综合| 婷婷五月天久久久| 99自拍网| a在线观看| 婷婷午夜激情| 狠狠操综合| 久久9精品| 亚洲欧洲另类| 可以免费观看的AV| 五月婷婷丁香| 免费视频WWW在线观看网站| 综合久久99| 久久久久久人妻| 能看的av网站| 一本大道熟女人妻中文字幕在线| 国产亚洲精品AAAAAAA片| 天天插天天爽| 色色婷婷五月| Blackedraw视频一区二区| 99精品久久| 久久婷婷综合五月| 丁香五月停停av| 五月 婷 久| 亚洲中文AV网站| 婷婷五月天首页激情| 久草嫩草在线观看| 超碰国产av| 99在线免费视频| 欧美日本国产欧美日本韩国99| 强伦轩人妻一区二区电影| 综合激情在线| 久久久激情| 99久久99视频只有精品| 丁香五月天婷婷久久| 色五月天成人在线| 色欲天天综合| 疯狂做受XXXX高潮A片| 老美AA片| 久久久久激情| 五月天偷拍| 99热在线观看| 97碰精品| 91天堂网综合| 亚洲国产成人在线| 色很很96| 99热这里只有精品热| 九色色| 天天日本夜夜谢| 啪啪色区| 五月开心激情| 五月天开心色色网| 99热高清在线| 色综合久| 激情校园 亚洲| 日韩欧美一级大黄网站| 亚洲色无码A片中文字幕| 成人 视频免费观看网站| 六月丁香啪啪啪| 五月婷婷六月天| www.久操| 97在线碰| 久久五月丁香综合17C| 97婷婷五月天| 97资源欧美日韩大香蕉超碰一区| 六月天婷婷| 色色色com| 国产亚洲色婷婷久久99精品91 www.riverspirits.org www.hnnun.com www.changh | 97操操| 五月夜丁香| 激情五月天小说| 干一干xxxx| 天堂成人A片永久免费网站| 日本操B视频| 久久香蕉婷婷| 五月综合视频在线| 日韩99精品| 婷婷午夜综合| 8090在线影视少妇| 色欧美日| 丁香六月天婷婷在线| 欧美激情-区二区三区| 99九九视频| 丰满少妇猛烈A片免费看观看| 大香蕉视频99| 91偷拍视频| 最新五月天婷婷影| 99ER热精品视频| 五月婷婷色播| 91视频久久久| 天天舔夜夜操www com| 天天看夜夜看| 中文字幕在线不卡| 97爱艹婷婷开心丁香激情综合| 特级操b片| 久婷婷五月激情| 99这里只有精品|v| 激情五月天色播| 亭亭丁香97| 亚洲综人色综网| 欧美激情凹凸丁香网| 人人干99| 婷婷五月天淫荡| 国产av影片| 啪啪五月天啪啪| 激情六月天| 中文成人在线| 99热丁香| 欧美婷| 亚洲无线视频| 欧美日韩成人h| 婷婷久久大香蕉| 亚洲综合婷婷六月丁香五月| 久色网| 婷婷五月欧美| 99爱欧美| 免费观看欧美成人AA片爱我多深 | 成人做爰黄A片免费看直播室男男| 熟妇国产| 综合激情啪啪| 天天舔天天爽| 99燥99日| 99热这里在线精品| 色综合天天综合成人网| 五月天大香蕉| 精品婷婷| 婷婷六月综合激情| 五月天色色色| 五夜婷婷| 五月丁香色六月激情干大屄| 色五月激情五月| 久久久久亚洲AV成人无码电影| 中文字幕性爱丰满| 天天爽夜夜操| 九九热99视频在线| 婷婷六月激情综合| 婷婷综合网| 五月丁香综合激情| 色五月五月天色婷婷色五月| 天天日天天肏天天奸| 91狠狠综合久久久久久| 天天草天天爽| 蜜臀av 粉嫩av 懂色av| 丁香五月婷婷成人色区| 99精品久久久久久久婷婷| 91综合在线观看| 六月丁香五月亭亭| 婷婷婷婷婷婷婷五月丁香| 丁香五月天婷婷91| www.亭亭五月天| 欧美日本韩国亚洲| 99视频这里只有免费精品| 天天干天天拍| 欧美三级大片AA在线看| 五月婷婷丁香大陆免费| 久久丁香| 婷婷五月激情欧美| 婷婷五月天亚洲五码| 99欧美精品99日本精品| 狠狠婷婷爱| 激情婷婷色色| 99爽视频| 色婷婷亚洲婷婷| 97亚洲精品| 六月婷婷私欲| 极品人妻VIDEOSSS人妻| 无码se| 国产色网站| 久九九热| 欧洲亚洲精品| 丁香五月综合激情久久潮喷| 欧美va欧美va差| 亚洲三A| 26uuu淫色| 操91| 、激情六月天| av九九| 9久精品视频| 国产精品视频| 99精品人人| 99热8| 丁香婷婷综合喷| 五月婷婷六月婷| 亚洲成人在线在线| 久久婷婷操| 日韩丰满少妇无码内射| 操笔无码| 亚洲情综合五月天| 丁香香五月激情免费视频| 啪啪啪大香蕉| 99久热在线精品| 91日本在线观看| 婷婷五月天综合网| 久草天堂| 色五月xxx| 色情五月综合婷婷| 做爱夜夜干天天操| 五月天婷婷影院| www.天天干.com| 天天爱天天做天天操| 久久婷婷五月天激情新地址| 五月婷婷六月丁香| 婷婷色色狠狠| 国产精产国品一二三在观看| 人色五月天婷婷| www.99色| 色婷婷六月天在线| 亚洲成人AV一区在线观看| 亚洲色模骚货| 日本人妻操| 天天爱天天操| 久久99网址| 色色色婷| 久久久这里都是精品| 丁香五月天色婷婷| 97丁香五月天| 九九九激情综合| 天天热夜夜操| 激情婷婷22月间| 婷婷六月天激情| 五月天天综合| 99热爱爱干干日| 2015好吊操| 欧美成人AAA片一区国产精品| 丁香久色| 97超级碰人人| 操骚货在线| 五月婷婷激情久久| 色欲一区二区三区精品A片| 九九精品这里只有| 久久se 综合网 | 亚洲日韩成人三级av| 激情综合网 激情五月天| 久久日婷婷| 亚洲欧美丁香五月天亚洲欧美| 狼人婷婷综合| 色色激情五月天| 狠狠夜夜五月丁香| 婷婷丁香综合网| www.99视频| 午夜九九九九九九九九九九九九九| 91丨九色丨熟女| 亚洲午夜精品久久久久久人妖| 国产亚洲精品久久久久久郑州| 婷婷五月色丁香在线看| 9999热在线观看| 超碰超碰在线| 天天综合干| 亚洲欧美日韩另类| 99热碰碰| 插插插丁香五月婷婷| 色青青电影色五月| 五月天另类激情在线| 99日韩| 少妇性按摩无码中文A片| 丁香五月第四色88| 国产97色在线 | 日韩| 思思热精品在线| 99福利视频| 草榴视频网| 狠狠草狠狠草| 色五月亚洲开心网| 9久久婷婷国产综合精品性色| A久久| 狠狠五月激情婷婷直播片| 亚洲国产网站| 爱射综合| 五月六月激情| 亚洲第一成人无码A片| 免费看欧美成人A片无码| 久热网在线视频| 996热re视频精品视频| 无码人妻少妇色欲AV一区二区| AV天堂婷婷五月天| 久久激情五月婷婷| 五月天激情小说| 亚洲婷婷五月天| 丁香五月 综合| 在线一起草av| 国产 码在线成人网站| 婷婷激情啪啪| 香蕉综合在线| 五月婷婷亚洲天堂97色婷婷| 婷婷五月,偷窥偷拍网| 日本婷婷网| 日韩精品电影| 99国产精品久久久久久久久久久| 欧美五月丁香| 天堂婷婷五月在线| 日本人妻操| 51国精产品自偷自偷综合| 五月花激情| 国产亚洲精品人人| 精品动漫 无码av| 深爱五月激情| 五月丁香成人视频| 欧美在线骚货| 操日本三片99| 九九激情网| 高潮A片揉搓乳尖乱颤视频| 天天肏天天插| 欧美色久| 久久9情免费| 成人在线网| 国产色99| 99热成人精品| 精品99在线| 色五月婷婷7777| 婷婷五月天黄色| 久久精品亚洲一级牲爱综合| 激情五月天噢美| 男人的天堂97| 成人.在线日韩| 97人人操人人| 亚洲AV色婷婷人禽五月天| 婷婷,五月天,丁香,第一| 久久日韩婷婷五月| 97色婷婷| 精品婷婷| 性色五月天| 九九成人精品| www.日本久久videos| 九九热91| 99久久精品免费精品国产_国产精品久久久久久_国产在线|日韩_久久国产精品电影 | 五月丁香六月情| 丁香婷婷情色五月天| 色 五月俺去也| 婷婷色色网| 婷婷久久图片| www.丁香黄色五月天人与| 婷婷丁香五月亚洲| 亚洲va999成人A片在线观看| 99热传媒| 99人人操人人操人人精| 天天久综合网永久入口18| 欧美婷婷| 丁香久月| 五月天精品视频| 伊人狠狠狠综合| 欧美色图45678| 色九九七七| 久久久久久久91| 国产精品国产成人国产三级| 婷婷色九月| www.色婷婷.com| 人人人va亚洲视频在线| 深夜婷婷五月丁香| www.久久| 超碰com| 岛国午夜视频| 淫视馆av三区| 九九无码| 一本道在线电影| 色五月丁香五月| 91肏| 五月天婷婷综合网| 无码人妻一区| 99色 色| 狠狠色婷婷丁香六月| www.粉嫩av.com| 狠狠色狠狠| 婷婷成人AV| 久人人操| 日韩欧美婷婷丁| 久久看九九90| 色色色香蕉五月婷| 色www久视频| 风流少妇A片一区二区蜜桃| 婷婷婷婷婷婷婷五月丁香| 日本美女上人| 大香蕉婷婷五月| 婷婷五月影院| 中文AV网| 色综合色色色| 国产无套精品一区二区| 婷婷精品性性性性性性性| 99re这里有精品手机在线| 久久久久综合激动五月天| 怕怕視頻| 欧美欧盟性爱网| 天天久久66xxx| 91色久| 久九色| 亚洲区视频| 超碰在线免费| 欧美va视频| 婷婷五月电影院| 激情九月综合| 欧美性爱五月天| 97在线精品| 草草视频91| 丁香五月婷婷狠狠色| 欧美日韩999| 日本一级一级一级一级| 五月天无码| 欧美丁香婷婷天天操| 亚洲va日| 综合久色五月| 69婷婷丁香午夜| 色色婷婷综合网| 午夜激情五月| 婷婷激情社区| 六九色综合婷婷五月天| 99色在线| 狠狠爱婷婷爱| 97热视频| 久久这里只有精品99| 亚洲精品一区中文字幕乱码| 福利视频在线播放| 成人网在线观看视频| 伊人久久婷婷五月综合97色| 黄色激情网站在线观看| 国产三级在线播放| 好色婷婷| 亚洲成人av在线| 色色五月丁香| www.91.com处女在线直播| 婷婷五月永远18免费久久久| 男女久久婷婷五月天| 狠狠色噜噜狠狠| 天天插天天爽| 99九九在线视频| 狠狠综合网| 99ER热精品视频| 婷婷色影音天| 久9热在线免费观看| 99 福利 导航| 日本三级中文字幕| 人人干人人干骚美女| 天天激情视频| 欧美狠狠地| 这里只有精品视频在线| 久久五月激情| 婷婷五月婷婷| 久久婷婷青青草| 热婷婷在线视频| 激情综合国产| 亚洲五月丁香综合网| 麻豆123区| 色99网| 色五月超碰| 涩涩五月天| 久久九九99视频| 久久久久激情网| 五月天色色激情综合| 色婷婷丁香五月天在线视频| 99热只有精| 蜜桃精品AV无码喷奶水小说| 中文字幕在线日亚州9| 熟女人妻一区二区三区免费看| www.ywav| 欧美日本黄色| 激情综合网五月天天| 26uuuuuuuu国产| 91大屁股精品| 777精品久无码人妻蜜桃| 丰滿爆乳一区二区三区| 波多野结衣AV无码Porn| 狠狠做六月爱婷婷综合aⅴ| 天天添天天摸天天天天做| 九九色综合九九色| 日本久久婷| 九九99九九精品免费| 艹天天射| 婷婷久久欧美| 婷婷五月天综合小说网| 婷婷五月AV| wwwss在线观看| 99人人操| 五月婷婷五月丁香综合| 免费观看欧美成人AA片爱我多深| 玖玖婷婷综合| 九色PORNY9l原创自拍| 99热99| 五月婷婷六月丁香激情深爱| 久久欧洲综合网| 亚洲AV中文在线| 热91久| 99视频在线播放大全| 婷婷丁香五月天在线视频| 天天日天天干天天爽| 亚洲a色| 五月婷久久综合| 午夜婷婷| 人草人人| 五月婷婷之综合激情| 欧美日韩国产一二区| 久久婷婷亚洲| av网站中文| 婷婷久久亚洲| 色婷婷yy久| 99re6热在线精品视频播放速度 | 三级三久久线久久99久目本WW| 99精品视频免费观看,| 五月网| 伊人91| 99热主页日本| 米奇影视五月天| 日本久久高清| 久久久久久婷| 九九热这里有精品视频| 五月天激情婷婷久久| 亚洲六月婷婷| 99热热热国产超碰| 开心婷婷五月天电影院| 免费无码又爽又刺激A片涩涩直播| 国产精品久久久久久喷浆| 无码A片一区二区免费| 密臀久久| 香蕉婷婷色五月| 亚洲AV久久久久久久久久久久久久久久 | 色婷婷很很十八禁| 久久XX| 亚洲最大视频| 婷婷综合网| www.99久久久| 亚洲激情网站| 丰满少妇乱A片无码| 超碰av天堂| 精品少妇蜜臀91| 激情综合五月| 操操精品| 日日操日日射| 日韩无码色色| 九九精品热播| 夜夜做夜夜愛| 五月综合激情| 丁香五月婷婷AV| 五月丁香婷婷激情视频| 亚洲精品久久久久久久久久飞鱼| 婷婷情色五月天| 五月婷婷九月婷婷九月婷婷| 丁香五月天激情视频| 色欲久久久久久综合网综合网| 天天操天天日天天爽| 91精品91久久久中77777| 在线看黄色| 99热的无码| 国产精品人成A片一区二区| 国产精品成人AV在线| 开心激情播播五月天| 亚洲乱码精品久久久久..| 色久九| 天天干电影| 日韩野外 无套| 天天噜天天爱| 99久久99久久综合| 91九色精品| 四色五月婷婷在线观看| AV片一区在线观看| 激情文学天天| 另类图片色五月| 色色九九五月天 | 五月天社区狠狠| 国产AV一区二区三区日韩| 婷婷五月天成人网| 久热亚洲| 婷婷 丁香 久久| 天天综合网亚洲网站| 色色婷婷五月| 色五月婷婷五月丁香五月激情五月视频| 99热在线看片| 无码九九九九| 婷婷精品综合| 丁香五月婷婷国产av| tingting五月天亚洲| 色色射| 亚洲精品成人| 婷婷丁香社区| 东北黄色一级| 五月天六月婷| 大香焦A∨| 天天干天天操天天上| 日本精品人妻无码77777| 亭亭玉立国色天香| 在线中文av| 丁香婷婷六月天| 青草青草视频2免费观看| 国产精品成人网站| 九九性视频| 亚洲中文字幕在线电影| 婷婷五月AV| 精品二区| 五月婷婷综合色拍| 国产精品久久久久9999小说| 琪琪理论片| 思思热视频在线| 俺也去在线久久精品23欧美综合视频网站,丰满人妻一区二区三区在线视频53,丰满 | 狠狠色婷婷六月激情网| 九八Av| 午夜青草资源| 伊人综合网站| 噜色精品| 99在线精品观看99| 五月婷婷亚洲综合网| 欧美顶级少妇做爰HD| 亚洲天堂亚洲色色色| 丰满少妇猛烈A片免费看观看| 五月综合亚洲色| 日日操日日撸| 综合激情开心五月| 激情99| 丁香婷婷免费| www.色五月| 九九爱看亚洲| 亚洲日韩成人三级av| 色色色色色色色色色999| www,婷婷,com| 婷婷五月天激情AV影院| 久久九九激情五月天 | A片试看120分钟做受视频红杏| 狠狠香婷婷五月| 久久思思热| 婷婷久久五月天亚洲欧美国产日韩在线观看 | 玖玖爱资源站| 热99这里只是精品| 色婷婷久久综合中文久久一本 | www.色综合.com| 国产精品成人AV在线| 激情综合久久| 99久在线精品99re8| 第二色AⅤ| 99久久99久久综合| 久久这里只有精品16| 67194中文在线| 深爱激情六月天| 色香久久| www.久久久久久久| 亚洲激情亚洲激情 | 精国产品一区二区三区A片| 国产va在线视频| 天天草女人| 婷婷五月天激情丁香| 大香蕉伊在| 91精品国产99久久久久久天美| 另类图片天天影视在线观看| 五月丁香婷婷综合| 26uuuu精品一区二区| 国产乱轮一区二区三区| 日韩aaa| 91色涩| 激情五月天影院| 五月丁香六月婷婷免费视频| 色色999三级片| 五月丁香婷婷欧美| 色婷婷久久久| 激情五月婷婷| 激情综合色| 色婷婷五月影院| 色情五月综合婷婷| 婷婷热婷婷色| 高清免费在线视频| 国产熟人AV一二三区| 依人大香蕉| AV中文在线| 久久一热| 99热在线精品播放| 亚洲va成人va成人va在线观看| 美女激情婷婷| 国产99久9在线| 色999五月色| 五月天色官网| 伊人丁香五月婷婷潮吹| 综合久久高清| 亚洲激情 久久| 九九综合网| 国产精品色婷婷99久久精品| 麻豆科斗777| 婷婷激情六月中文| 91九色欧美| 亚洲成人色五月婷婷综合| 影音先锋男人AV资源站| 五月网| 五月激情六月| 大香蕉伊然在亚洲90| 9久久久久久久久久久| 激情五月婷婷欧美极品| www狠狠爱com| 丁香六月久久| 天天拍久久| 91色吧网| 亚洲V国产V欧美V久久久久久| 亚洲无码九九| 人妻精品在线| 无码色| 天天操天天插| 韩国情人在线电视剧免费观看高清版全集| 婷婷色色欧美综合网| 五月丁香婷婷婷激情爱爱| 亚洲成色综合网站免费观看| 亚洲婷婷综合视频| 婷婷丁香六月| 激情综合色婷婷啪啪六月天| 99九九在线观看免费| 中文字幕成人| 老妇槡BBBB槡BBBB槡| 丁香五月天天日| 五月综合丁| 高清一区二区三区日本久| 婷婷色基地| 99国产小视频2013| 五月婷婷 自拍| 99热精品在线| 五月天婷婷丁香社区| 成人短视频在线观看| 91黄色五月天视频| 丁香六月婷婷开心| 午夜婷婷六月天| 色色婷| 久热精品9999| 五月婷婷六月丁香| 婷婷六月久久综合导航| 五月丁香A片| www,久久久人人| 九九热在线视频| 色五月天电影| 婷婷久久免费看| 六月婷婷色色色| 狠狠狠狠狠| 综合网啪啪| 五月婷婷六月婷| 99 热国产在| 极品少妇婷婷五月| www.婷婷六月天| 日本欧美成人片AAAA| 色五月aV| 99 re视频一区| 67久久| 99热在线只有精品| 天天艹夜夜艹| 《》【无码】想被搞到爽AV应募而来的超M素人 西纯子 10musume-011723-01 | 91久久久久久久久18| 亚洲美女裸体被操在线观看| 99自拍视频在线| 99爱视频免费| 伊人五月久久| 五月婷婷丁香| 日韩成人影片在线观看| 高清一区二区三区日本久| 丁香花在线电影小说观看| 9这里只有精品| 婷婷六月丁香激情| 人人爽欧美婷婷久久久五月丁香| 最近中文字幕大全免费版在线| 99久久www| 狠狠干综合网| 成人色五月天| 国产激情视频在线观看| 婷婷丁香先锋资源网站| 亚洲色久| 97自拍视频在线| 五月激情综合网| 99热这里只有精品 搜| 婷婷久久午夜网| 亚欧州精品视频| 影音先锋AV男人站| 亚洲丁香花色| 九九色精品| 99热| www色婷婷com| 天天干天天日日| 久久五月婷| 99九九视频| 婷婷天天五月天| 成人综合网站| 大香蕉九九| 综合 夜夜| 婷婷欧美激情| 狠狠操.COM| www.国产亚洲69ty.久久久久久久久久久久| 五月天久久www| 大香蕉啪啪啪啪啪啪| 97啪在线观看视频| 夜精品无码A片一区二区蜜桃| 久久伊人婷婷| 在线天堂新版最新版在线8| 成人五月天视频播放| yazhouzonghesese| WWW色综合| 色狠狠色| 99精品人人| 色五月中文字幕| 人人操婷婷| 婷色天堂| 国产肥白大熟妇BBBB视频| 99热最新网址| 啪啪婷婷五月天激情| 天天色天天操天天射| 亚洲激情97五月天| 人人干Av| 插插插色综合网| 色婷婷久久综合久色| 九月丁香| 99热大香蕉| 骚五月婷婷| 91九色超碰正在播放| 丁香五月天日韩无码| 欧美十二区| 国产性av| 丁香六月婷婷久久综合| 99国产精品白浆在线观看免费| 97色碰| 亚洲中文字幕AV| 97狠狠色| 丁香婷婷五月色成人网站| 天堂五月婷婷| 女人与拘的交酡过程| 激情五月婷婷视频一区二区三区| 五月天激情AV| 丁香六月激情综合啪啪| 久久丁香五月婷婷| 欧美婷婷五月天综合| 丁香激情六月天婷婷| 2023天天日夜夜爽| 亚洲爱爱无码婷婷色五月| 大波美女VA网站| 五月色情婷婷开心五月色情| 色五月婷婷少妇人妻| 五月婷婷中字在线| 婷婷五月色花丁香社区| 久久无码激情视频| 久热这里只有精品3| 99这里有精品视频3| 婷婷六月丁香激情| 99色区| xxxx五月| 99热国产国产| WWW五月天| 婷婷丁香五月激情中文字幕版| 五月天堂婷婷| 激情五月丁香在线观看直播| 九九热区一区二区三区| 六月婷婷影院| 99热久草| 五月天综合在线观看| 天天干天天日天天操| 俺去也婷婷| 99啪啪网| 九九精品99| 天天插综合| 大地9中文在线观看免费高清| 午夜天堂一区人妻| 五月丁香啪啪| 日本44久久在线| av电影在线播放| 在线看av| 日本久久爽| 五月丁香香蕉| 第四色色六月色综合| 婷婷激情综合色五月久久,色婷婷丁香花,丁香婷婷五月情天,久久婷婷五月综合色 | 99热狠狠操| 中文字幕在线免费| 婷婷五月天AV网| 九月婷婷综合八月丁香在线观看| 狠狠干五月丁香| 99热这里只有的精品视| 日韩九九| 亚洲爆乳无码精品AAA片蜜桃| 伊人婷婷综合| 五月丁香啪啪网| 丁香五月AV| 99精品综合在线| 91久久久久久久91| 99视频自拍|