99久久国产综合精品国-亚洲一区 日韩精品 中文字幕-国产精品自拍电影-日韩亚洲二区-久久久综合九色综合-麻豆狠色伊人亚洲综合网站-少妇av无码免费久久-国产污污高清黄色视频

2022

2022

  • Record 469 of

    Title:The Earth 2.0 Space Mission for Detecting Earth-like Planets around Solar Type Stars
    Author(s):Ge, Jian(1); Zhang, Hui(1); Deng, Hongping(1); Zhang, Yongshuai(1); Li, Yan(1); Zhou, Dan(1); Tang, Zhenghong(1); Zhang, Congcong(1); Wang, Chaoyan(1); Yu, Yong(1); Yao, Xinyu(1); Zhu, Jiapeng(1); Fang, Tong(2); Chen, Wen(2); Chen, Kun(2); Han, Xingbo(2); Yang, Yingquan(2); Bi, Xingzi(2); Zhang, Kuoxiang(2); Chen, Yonghe(3); Liu, Xiaohua(3); Yin, Dayi(3); Zhang, Quan(3); Yang, Baoyu(3); Wei, Chuanxin(3); Zhu, Yuji(3); Song, Zongxi(4); Gao, Wei(4); Li, Wei(4); Wang, Fengtao(4); Cheng, Pengfei(4); Shen, Chao(4); Pan, Yue(4); Zhang, Hongfei(5); Wang, Jian(5); Wang, Hui(5); Chen, Cheng(5); Zhang, Jun(5); Wang, Zhiyue(5); Zang, Weicheng(6); Mao, Shude(6); Zhu, Wei(6); Wang, Sharon Xuesong(6); Xie, Jiwei(7); Liu, Huigen(7); Zhou, Jilin(7); Yang, Ming(7); Jiang, Chaofeng(7); Chen, Dichang(7); Tang, Wei(7); Sun, Mengfei(7); Wang, Mutian(7); Li, Yudong(8); Wen, Lin(8); Feng, Jie(8); Willis, Kevin(9); Huang, Chelsea(10); Ma, Bo(11); Wang, Yonghao(11); Shen, Rongfeng(11); Tam, Pak-Hin Thomas(11); Hu, Zhecheng(11); Yang, Yanlv(11); Feng, Fabo(11,12); Xiang, Maosheng(13,15); Yu, Jie(14); Zhang, Jinghua(15); Wu, Yaqian(15); Zong, Weikai(16); Yuan, Haibo(16); Li, Tanda(16); Zhao, Yinan(17); Zou, Yuanchuan(18); Liu, Beibei(18,19); Yang, Jun(20); Ye, Quanzhi(21); Yin, Qing-Zhu(22)
    Source: Proceedings of SPIE - The International Society for Optical Engineering  Volume: 12180  Issue:   DOI: 10.1117/12.2630656  Published: 2022  
    Abstract:A space mission called "Earth 2.0 (ET)" is being developed in China to address a few of fundamental questions in the exoplanet field: How frequently habitable Earth-like planets orbit solar type stars (Earth 2.0s)? How do terrestrial planets form and evolve? Where did floating planets come from? ET consists of six 30 cm diameter transit telescope systems with each field of view of 500 square degrees and one 35 cm diameter microlensing telescope with a field of view of 4 square degrees. The ET transit mode will monitor ~1.2M FGKM dwarfs in the original Kepler field and its neighboring fields continuously for four years while the microlensing mode monitors over 30M I ? 2022 SPIE.
    Accession Number: 20230413449797
  • Record 470 of

    Title:Coastline Recognition Algorithm Based on Multi-Feature Network Fusion of Multi-Spectral Remote Sensing Images
    Author(s):Qiu, Shi(1); Ye, Huping(2,3); Liao, Xiaohan(2,3,4)
    Source: Remote Sensing  Volume: 14  Issue: 23  DOI: 10.3390/rs14235931  Published: December 2022  
    Abstract:Remote sensing images can obtain broad geomorphic features and provide a strong basis for analysis and decision making. As 71% of the earth is covered by water, shipping has become an efficient means of international trade and transportation, and the development level of coastal cities will directly reflect the development level of a country. The coastline is the boundary line between seawater and land, so it is of great significance to accurately identify it to assist shipping traffic and docking, and this identification will also play a certain auxiliary role in environmental analysis. Currently, the main problems of coastline recognition conducted by remote sensing images include: (1) in the process of remote sensing, image transmission inevitably brings noise causing poor image quality and difficult image quality enhancement; (2) s single scale does not allow for the identification of coastlines at different scales; and (3) features are under-utilized, false detection is high and intuitive measurement is difficult. To address these issues, we used the following multispectral methods: (1) a PCA-based image enhancement algorithm was proposed to improve image quality; (2) a dual attention network and HRnet network were proposed to extract suspected coastlines from different levels; and (3) a decision set fusion approach was proposed to transform the coastline identification problem into a probabilistic problem for coastline extraction. Finally, we constructed a coastline straightening model to visualize and analyze the recognition effect. Experiments showed that the algorithm has an AOM greater than 0.88 and can achieve coastline extraction. ? 2022 by the authors.
    Accession Number: 20225013248952
  • Record 471 of

    Title:The Plastic Scintillator Detector of the HERD space mission
    Author(s):Kyratzis, D.(1,2); Alemanno, F.(1,2); Altomare, C.(3,4); Barbato, F.C.T.(1,2); Bernardini, P.(5,6); Cattaneo, P.W.(7); De Mitri, I.(1,2); de Palma, F.(5,6); Di Venere, L.(3,4); Di Santo, M.(1,2); Fusco, P.(3,4); Gargano, F.(4); Loparco, F.(3,4); Loporchio, S.(4); Marsella, G.(8); Mazziotta, M.N.(4); Pantaleo, F.R.(3,4); Parenti, A.(1,2); Pillera, R.(3,4); Rappoldi, A.(7); Raselli, G.(7); Rossella, M.(7); Serini, D.(4); Silveri, L.(1,2); Surdo, A.(6); Wu, L.(1,2); Adriani, O.(34); Aloisio, R.(35,36); Ambrosi, G.(40); An, Q.(18); Antonelli, M.(51); Azzarello, P.(43); Bai, L.(16); Bai, Y.L.(11); Bao, T.W.(9); Barbanera, M.(40); Berti, E.(34); Bertucci, B.(41); Bi, X.J.(9); Bigongiari, G.(42); Bongi, M.(34); Bonvicini, V.(51); Bordas, P.(46); Bosch-Ramon, V.(46); Bottai, S.(33); Brogi, P.(42); Cadoux, F.(43); Campana, D.(38); Cao, W.W.(11); Cao, Z.(9); Casaus, J.(45); Catanzani, E.(41); Chang, J.(17,21); Chang, Y.H.(29); Chen, G.M.(9); Chen, Y.(23); Cianetti, F.(41); Comerma, A.(46,47); Cortis, D.(37); Cui, X.H.(21); Cui, X.Z.(9); Dai, C.(13); Dai, Z.G.(23); D'Alessandro, R.(34); De Gaetano, S.(32); Di Felice, V.(56); Di Giovanni, A.(35,36); Dong, J.N.(14,15); Dong, Y.W.(9); Donvito, G.(31); Duranti, M.(40); D'Urso, D.(55); Evoli, C.(35,36); Fang, K.(9); Fari?a, L.(48); Favre, Y.(43); Feng, C.Q.(18); Feng, H.(24); Feng, H.B.(13); Feng, Z.K.(13); Finetti, N.(30); Formato, V.(56); Frieden, J.M.(50); Gao, J.R.(11); Gascon-Fora, D.(46); Gasparrini, D.(56); Giglietto, N.(32); Giovacchini, F.(45); Gomez, S.(46); Gong, K.(9); Gou, Q.B.(9); Guida, R.(52); Guo, D.Y.(9); Guo, J.H.(17); Guo, Y.Q.(9); He, H.H.(9); Hu, H.B.(9); Hu, J.Y.(9,10); Hu, P.(9,10); Hu, Y.M.(17); Huang, G.S.(18); Huang, J.(9); Huang, W.H.(14,15); Huang, X.T.(14,15); Huang, Y.B.(13); Huang, Y.F.(23); Ionica, M.(40); Jouvin, L.(48); Kotenko, A.(43); La Marra, D.(43); Li, M.J.(14,15); Li, Q.Y.(14,15); Li, R.(11); Li, S.L.(9,10); Li, T.(14,15); Li, X.(17); Li, Z.(25); Li, Z.H.(9,10); Liang, E.W.(13); Liang, M.J.(9,10); Liao, C.L.(16); Licciulli, F.(31); Lin, S.J.(9); Liu, D.(14,15); Liu, H.B.(13); Liu, H.(16); Liu, J.B.(18); Liu, S.B.(18); Liu, X.(9,10); Liu, X.W.(13); Liu, Y.Q.(9); Lu, X.(13); Lyu, J.G.(12); Lyu, L.W.(11); Maestro, P.(42); Mancini, E.(40); Manera, R.(46); Marin, J.(45); Marrocchesi, P.S.(42); Martinez, G.(45); Martinez, M.(48); Marzullo, D.(53); Mauricio, J.(46); Mocchiutti, E.(51); Morettini, G.(41); Mori, N.(33); Mussolin, L.(41); Oliva, A.(57); Orlandi, D.(37); Osteria, G.(38); Pacini, L.(33); Panico, B.(38); Papa, S.(52); Papini, P.(33); Paredes, J.M.(46); Pauluzzi, M.(41); Pearce, M.(49); Peng, W.X.(9); Perfetto, F.(38); Perrina, C.(50); Perrotta, G.(52); Pizzolotto, C.(51); Qiao, R.(9); Qin, J.J.(11)
    Source: Proceedings of Science  Volume: 395  Issue:   DOI:   Published: March 18, 2022  
    Abstract:The High Energy cosmic-Radiation (HERD) detector is one of the prominent space-borne instruments to be installed on-board the Chinese Space Station (CSS), around 2027. Primary scientific goals regarding this initiative include: precise measurements of cosmic ray (CR) energy spectra and mass composition, at energies up to the PeV range; contributions to high energy gamma-ray astronomy and transient studies; as well as indirect searches for Dark Matter (DM) particles via their possible annihilation/decay to detectable products. HERD is configured to accept incident particles from both its top and four lateral sides. Owing to its pioneering design, an order of magnitude increase in acceptance is foreseen, with respect to previous and ongoing experiments. The Plastic Scintillator Detector (PSD) constitutes an important sub-detector of HERD, particularly aimed towards anti-coincidence (discriminating incident photons from charged particles), while providing precise charge measurement of incoming cosmic-ray nuclei in a range of Z = 1-26. Main requirements concerning its design, include: high detection efficiency, broad dynamic range and good energy resolution. In order to select the optimal layout, two geometries are currently under investigation: one based on long scintillator bars and the other on square tiles, with both layouts being readout by Silicon Photomultipliers (SiPMs). Ongoing activities and future plans regarding the HERD PSD will be presented in this work. ? Copyright owned by the author(s) under the terms of the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License (CC BY-NC-ND 4.0)
    Accession Number: 20225113256982
  • Record 472 of

    Title:Pencil-beam scanning catheter for intracoronary optical coherence tomography
    Author(s):Kang, Jiqiang(1); Zhu, Rui(2,3,4); Sun, Yunxu(1); Li, Jianan(3,4); Wong, Kenneth K. Y.(5,6)
    Source: Opto-Electronic Advances  Volume: 5  Issue: 3  DOI: 10.29026/oea.2022.200050  Published: 2022  
    Abstract:Current gradient-index (GRIN) lens based proximal-driven intracoronary optical coherence tomography (ICOCT) probes consist of a spacer and a GRIN lens with large gradient constant. This design provides great flexibility to control beam profiles, but the spacer length should be well controlled to obtain desired beam profiles and thus it sets an obstacle in mass catheter fabrication. Besides, although GRIN lens with large gradient constant can provide tight focus spot, it has short depth of focus and fast-expanded beam which leads to poor lateral resolution for deep tissue. In this paper, a type of spacer-removed probe is demonstrated with a small gradient constant GRIN lens. This design simplifies the fabrication process and is suitable for mass production. The output beam of the catheter is a narrow nearly collimated light beam, referred to as pencil beam here. The full width at half maximum beam size varies from 35.1 μm to 75.3 μm in air over 3-mm range. Probe design principles are elaborated with probe/catheter fabrication and performance test. The in vivo imaging of the catheter was verified by a clinical ICOCT system. Those results prove that this novel pencil-beam scanning catheter is potentially a good choice for ICOCT systems. ? The Author(s) 2022.
    Accession Number: 20221511951912
  • Record 473 of

    Title:Gamma-ray performance study of the HERD payload
    Author(s):Adriani, O.(26); Alemanno, F.(27,28); Aloisio, R.(27,28); Altomare, C.(23); Ambrosi, G.(35); An, Q.(10); Antonelli, M.(46); Azzarello, P.(38); Bai, L.(8); Bai, Y.L.(3); Bao, T.W.(1); Barbanera, M.(35); Barbato, F.C.T.(27,28); Bernardini, P.(31); Berti, E.(26); Bertucci, B.(36); Bi, X.J.(1); Bigongiari, G.(37); Bongi, M.(26); Bonvicini, V.(46); Bordas, P.(41); Bosch-Ramon, V.(41); Bottai, S.(25); Brogi, P.(37); Cadoux, F.(38); Campana, D.(32); Cao, W.W.(3); Cao, Z.(1); Casaus, J.(40); Catanzani, E.(36); Cattaneo, P.W.(34); Chang, J.(9,13); Chang, Y.H.(21); Chen, G.M.(1); Chen, Y.(15); Cianetti, F.(36); Comerma, A.(41,42); Cortis, D.(29); Cui, X.H.(13); Cui, X.Z.(1); Dai, C.(5); Dai, Z.G.(15); D'Alessandro, R.(26); De Gaetano, S.(24); De Mitri, I.(27,28); de Palma, F.(31); Di Felice, V.(51); Di Giovanni, A.(27,28); Di Santo, M.(27,28); Di Venere, L.(24); Dong, J.N.(6,7); Dong, Y.W.(1); Donvito, G.(23); Duranti, M.(35); D'Urso, D.(50); Evoli, C.(27,28); Fang, K.(1); Fari?a, L.(43); Favre, Y.(38); Feng, C.Q.(10); Feng, H.(16); Feng, H.B.(5); Feng, Z.K.(5); Finetti, N.(22); Formato, V.(51); Frieden, J.M.(45); Fusco, P.(24); Gao, J.R.(3); Gargano, F.(23); Gascon-Fora, D.(41); Gasparrini, D.(51); Giglietto, N.(24); Giovacchini, F.(40); Gomez, S.(41); Gong, K.(1); Gou, Q.B.(1); Guida, R.(47); Guo, D.Y.(1); Guo, J.H.(9); Guo, Y.Q.(1); He, H.H.(1); Hu, H.B.(1); Hu, J.Y.(1,2); Hu, P.(1,2); Hu, Y.M.(9); Huang, G.S.(10); Huang, J.(1); Huang, W.H.(6,7); Huang, X.T.(6,7); Huang, Y.B.(5); Huang, Y.F.(15); Ionica, M.(35); Jouvin, L.(43); Kotenko, A.(38); Kyratzis, D.(27,28); La Marra, D.(38); Li, M.J.(6,7); Li, Q.Y.(6,7); Li, R.(3); Li, S.L.(1,2); Li, T.(6,7); Li, X.(9); Li, Z.(17); Li, Z.H.(1,2); Liang, E.W.(5); Liang, M.J.(1,2); Liao, C.L.(8); Licciulli, F.(23); Lin, S.J.(1); Liu, D.(6,7); Liu, H.B.(5); Liu, H.(8); Liu, J.B.(10); Liu, S.B.(10); Liu, X.(1,2); Liu, X.W.(5); Liu, Y.Q.(1); Loparco, F.(24); Loporchio, S.(23); Lu, X.(5); Lyu, J.G.(4); Lyu, L.W.(3); Maestro, P.(37); Mancini, E.(35); Manera, R.(41); Marin, J.(40); Marrocchesi, P.S.(37); Marsella, G.(54,55); Martinez, G.(40); Martinez, M.(43); Marzullo, D.(48); Mauricio, J.(41); Mocchiutti, E.(46); Morettini, G.(36); Mori, N.(25); Mussolin, L.(36); Nicola Mazziotta, M.(23); Oliva, A.(52); Orlandi, D.(29); Osteria, G.(32); Pacini, L.(25); Panico, B.(32); Pantaleo, F.R.(24); Papa, S.(47); Papini, P.(25); Paredes, J.M.(41); Parenti, A.(27,28); Pauluzzi, M.(36); Pearce, M.(44); Peng, W.X.(1); Perfetto, F.(32); Perrina, C.(45); Perrotta, G.(47); Pillera, R.(24); Pizzolotto, C.(46); Qiao, R.(1); Qin, J.J.(3); Quadrani, L.(52,53); Quan, Z.(1); Rappoldi, A.(34); Raselli, G.(34); Ren, X.X.(6,7); Renno, F.(47); Ribo, M.(41)
    Source: Proceedings of Science  Volume: 395  Issue:   DOI:   Published: March 18, 2022  
    Abstract:The High Energy cosmic-Radiation Detection (HERD) facility has been proposed as a space astronomy payload onboard the future China's Space Station. HERD is planned for operation starting around 2027 for about 10 years In addition to the unprecedented sensitivity for dark matter searches and cosmic-ray measurements up to the knee energy, it should perform gamma-ray monitoring and full sky survey from few hundred MeV up to tens of TeV. We present the first study of the HERD gamma-ray performance obtained with full simulations of the whole detector geometry. HERD will be a cubic detector composed with 5 active faces. We present a study conducted inside the HERD analysis software package, which includes a detailed description of the detector materials. In this work we present the HERD effective area, the point spread function and the resulting gamma-ray sensitivity. ? Copyright owned by the author(s) under the terms of the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License (CC BY-NC-ND 4.0)
    Accession Number: 20230113326372
  • Record 474 of

    Title:Automatic Laboratory Martian Rock and Mineral Classification Using Highly-Discriminative Representation Derived from Spectral Signatures
    Author(s):Yang, Juntao(1,2,3); Kang, Zhizhong(2,3,4); Yang, Ze(2,3,4); Xie, Juan(2,3,4); Xue, Bin(5); Yang, Jianfeng(5); Tao, Jinyou(5)
    Source: Remote Sensing  Volume: 14  Issue: 20  DOI: 10.3390/rs14205070  Published: October 2022  
    Abstract:The optical properties of rocks and minerals provide a reliable way to measure their chemical and mineralogical composition due to the specific reflection behaviors, which is also the key insight behind most automatic identification and classification approaches. However, the inter-category spectral similarity poses a great challenge to the automatic identification and classification tasks because of the diversity of rocks and minerals. Therefore, this paper develops a recognition and classification approach of rocks and minerals using the highly discriminative representation derived from their raw spectral signatures. More specifically, a transformer-based classification approach integrated with category-aware contrastive learning is constructed and trained in an end-to-end manner, which would force instances of the same category to remain close-by while pushing instances of a dissimilar category far apart in the high-dimensional feature space, in order to produce the highly discriminative feature representation of the rocks and minerals. From both qualitative and quantitative views, experiments are conducted on the laboratory sample dataset with 30 types of rocks and minerals shared from the National Mineral Rock and Fossil Specimens Resource Center, and the spectral information of the laboratory rocks and minerals is captured using a multi-spectral sensor, with a duplicated payload of the counterpart onboard the Zhurong rover. Quantitative results demonstrate that the developed approach can effectively distinguish 30 types of rocks and minerals, with a high overall accuracy of 96.92%. Furthermore, the developed approach is remarkably superior to other existing methods, with average differences of 4.75% in the overall accuracy. Furthermore, we also visualized the derived highly discriminative features of different types of rocks and minerals by projecting them onto a two-dimensional map, where the same categories tend to be modeled by nearby locations and the dissimilar categories by distant locations with high probability. It can be observed that, compared with those in the raw spectral feature space, the clusters are formed better in the derived highly discriminative feature space, which further confirms the promising representation capability. ? 2022 by the authors.
    Accession Number: 20224413049651
  • Record 475 of

    Title:Dynamics of frustrated tunneling ionization driven by inhomogeneous laser fields
    Author(s):Xu, Jingkun(1); Zhou, Yueming(1); Li, Yingbin(2); Liu, Aihua(3,7); Chen, Yongkun(1); Ma, Xiaomeng(4,5); Huang, Xiang(1); Liu, Kunlong(1); Zhang, Qingbin(1); Li, Min(1); Yu, Benhai(2); Lu, Peixiang(1,6)
    Source: New Journal of Physics  Volume: 24  Issue: 12  DOI: 10.1088/1367-2630/acadfe  Published: December 1, 2022  
    Abstract:We theoretically investigated frustrated tunneling ionization (FTI) driven by spatially inhomogeneous strong laser fields induced by surface plasmon resonance within a bow-tie metal nanostructure. The results show that the FTI probability and the principal quantum number distribution exhibit similar oscillatory behavior as a function of the pulse duration. Our analysis reveals that the periodic defocusing and refocusing of the electron spatial distribution due to the inhomogeneous laser field is responsible for the oscillatory structures. In addition, the initial tunneling coordinates and the angular momentum distributions of the FTI events and theirs pulse duration dependence are also explored. Moreover, our results show that the frequency of the oscillatory structures depends sensitively on the electron quiver amplitude and the inhomogeneity strength. Thus, the electron quiver amplitude and the size of the gap between bow-tie nanostructure are useful and efficient knobs for controlling the yield and properties of exited Rydberg states. ? 2023 The Author(s). Published by IOP Publishing Ltd on behalf of the Institute of Physics and Deutsche Physikalische Gesellschaft.
    Accession Number: 20230213381505
  • Record 476 of

    Title:The High Energy cosmic-Radiation Detector (HERD) Trigger System
    Author(s):Velasco, M.A.(1,45); Bao, T.(2); Berti, E.(3); Bonvicini, V.(4); Casaus, J.(1); Giovacchini, F.(1); Liu, X.(2); Marco, R.(1); Marín, J.(1); Martínez, G.(1); Mori, N.(3); Oliva, A.(5); Pacini, L.(3); Quan, Z.(2); Tang, Z.(2); Xu, M.(2); Zampa, G.(4); Zampa, N.(4); Adriani, O.(31); Alemanno, F.(32,33); Aloisio, R.(32,33); Altomare, C.(28); Ambrosi, G.(40); An, Q.(15); Antonelli, M.(51); Azzarello, P.(43); Bai, L.(13); Bai, Y.L.(8); Bao, T.W.(6); Barbanera, M.(40); Barbato, F.C.T.(32,33); Bernardini, P.(36); Bertucci, B.(41); Bi, X.J.(6); Bigongiari, G.(42); Bongi, M.(31); Bordas, P.(46); Bosch-Ramon, V.(46); Bottai, S.(30); Brogi, P.(42); Cadoux, F.(43); Campana, D.(37); Cao, W.W.(8); Cao, Z.(6); Catanzani, E.(41); Cattaneo, P.W.(39); Chang, J.(14,18); Chang, Y.H.(26); Chen, G.M.(6); Chen, Y.(20); Cianetti, F.(41); Comerma, A.(46,47); Cortis, D.(34); Cui, X.H.(18); Cui, X.Z.(6); Dai, C.(10); Dai, Z.G.(20); D'Alessandro, R.(31); De Gaetanoe, S.(29); De Mitri, I.(32,33); de Palma, F.(36); Di Felice, V.(56); Di Giovanni, A.(32,33); Di Santo, M.(32,33); Di Venere, L.(29); Dong, J.N.(11,12); Dong, Y.W.(6); Donvito, G.(28); Duranti, M.(40); D'Urso, D.(55); Evoli, C.(32,33); Fang, K.(6); Fari?a, L.(48); Favre, Y.(43); Feng, C.Q.(15); Feng, H.(21); Feng, H.B.(10); Feng, Z.K.(10); Finetti, N.(27); Formato, V.(56); Frieden, J.M.(50); Fusco, P.(29); Gao, J.R.(8); Gargano, F.(28); Gascon-Fora, D.(46); Gasparrini, D.(56); Giglietto, N.(29); Gomez, S.(46); Gong, K.(6); Gou, Q.B.(6); Guida, R.(52); Guo, D.Y.(6); Guo, J.H.(14); Guo, Y.Q.(6); He, H.H.(6); Hu, H.B.(6); Hu, J.Y.(6,7); Hu, P.(6,7); Hu, Y.M.(14); Huang, G.S.(15); Huang, J.(6); Huang, W.H.(11,12); Huang, X.T.(11,12); Huang, Y.B.(10); Huang, Y.F.(20); Ionica, M.(40); Jouvin, L.(48); Kotenko, A.(43); Kyratzis, D.(32,33); La Marra, D.(43); Li, M.J.(11,12); Li, Q.Y.(11,12); Li, R.(8); Li, S.L.(6,7); Li, T.(11,12); Li, X.(14); Li, Z.(22); Li, Z.H.(6,7); Liang, E.W.(10); Liang, M.J.(6,7); Liao, C.L.(13); Licciulli, F.(28); Lin, S.J.(6); Liu, D.(11,12); Liu, H.B.(10); Liu, H.(13); Liu, J.B.(15); Liu, S.B.(15); Liu, X.W.(10); Liu, Y.Q.(6); Loparco, F.(29); Loporchio, S.(28); Lu, X.(10); Lyu, J.G.(9); Lyu, L.W.(8); Maestro, P.(42); Mancini, E.(40); Manera, R.(46); Marrocchesi, P.S.(42); Marsella, G.(59,60); Martinez, M.(48); Marzullo, D.(53); Mauricio, J.(46); Mocchiutti, E.(51); Morettini, G.(41); Mussolin, L.(41); Nicola Mazziotta, M.(28); Orlandi, D.(34); Osteria, G.(37); Panico, B.(37); Pantalei, F.R.(29); Papa, S.(52); Papini, P.(30); Paredes, J.M.(46); Parenti, A.(32,33); Pauluzzi, M.(41); Pearce, M.(49); Peng, W.X.(6); Perfetto, F.(37); Perrina, C.(50); Perrotta, G.(52); Pillera, R.(29); Pizzolotto, C.(51); Qiao, R.(6)
    Source: Proceedings of Science  Volume: 395  Issue:   DOI:   Published: March 18, 2022  
    Abstract:The High Energy cosmic-Radiation Detection (HERD) facility is a next generation spaceborne detector to be installed onboard the Chinese Space Station for about 10 years. HERD will address major problems in fundamental physics and astrophysics, providing precise measurements of charged-cosmic rays up to PeV energies, performing indirect searches for dark matter in the electron spectrum up to few tens of TeV and monitoring the gamma-ray skymap for surveys and transient searches. HERD is composed of a 3D imaging calorimeter (CALO) surrounded by a scintillating fiber tracker (FIT), a plastic scintillator detector (PSD) and a silicon charge detector (SCD). In addition, a transition radiation detector (TRD) is placed on a lateral side to provide accurate energy calibration. Based on this innovative design, the effective geometric factor of HERD will be one order of magnitud larger than that of current space-based detectors. The HERD trigger strategy is designed to accomplish the scientific goals of the mission, and is based on trigger definitions that rely on the energy deposited in CALO and the PSD. The trigger performances are evaluated using a detailed Monte Carlo simulation that includes the latest HERD geometry. In addition, alternative trigger definitions based on the event topology can be established thanks to the photodiode readout of CALO crystals. The feasibility of these topological triggers is also investigated and presented. ? Copyright owned by the author(s) under the terms of the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License (CC BY-NC-ND 4.0)
    Accession Number: 20225113275758
  • Record 477 of

    Title:Families of gap solitons and their complexes in media with saturable nonlinearity and fractional diffraction
    Author(s):Zeng, Liangwei(1); Beli?, Milivoj R.(2); Mihalache, Dumitru(3); Shi, Jincheng(4); Li, Jiawei(5); Li, Siqi(5); Lu, Xiaowei(1); Cai, Yi(1); Li, Jingzhen(1)
    Source: Nonlinear Dynamics  Volume: 108  Issue: 2  DOI: 10.1007/s11071-022-07291-z  Published: April 2022  
    Abstract:We demonstrate the existence of various types of gap localized modes, including one- and two-dimensional (1D and 2D) single solitons and soliton clusters, as well as the corresponding vortex modes in optical media with saturable Kerr nonlinearity and fractional diffraction. We find that soliton clusters with different number of peaks can be stable in these media. The 1D and 2D localized modes existing at the center of the first and second band gaps are stable, whereas the ones in the peripheries are unstable. In addition, the vortex modes with different number of peaks and vorticity number m= 1 are found to be stable, while the ones with m≥ 2 are unstable. The stability of these localized modes is investigated by using the linear stability analysis and is confirmed by the numerical simulation of their dynamical propagation. The obtained results may enrich the understanding of gap solitons and their complexes in media with saturable nonlinearity and fractional diffraction, and may find potential applications in optical information processing and other related fields. ? 2022, The Author(s), under exclusive licence to Springer Nature B.V.
    Accession Number: 20220811691429
  • Record 478 of

    Title:Manipulating Nonsequential Double Ionization of Argon Atoms via Orthogonal Two-Color Field
    Author(s):Li, Yingbin(1); Qin, Lingling(1); Liu, Aihua(2,7); Zhang, Ke(1); Tang, Qingbin(1); Zhai, Chunyang(1); Xu, Jingkun(3); Chen, Shi(4); Yu, Benhai(1); Chen, Jing(5,6)
    Source: Chinese Physics Letters  Volume: 39  Issue: 9  DOI: 10.1088/0256-307X/39/9/093201  Published: August 1, 2022  
    Abstract:Using a three-dimensional classical ensemble model, we investigate the dependence of relative frequency and relative initial phase for nonsequential double ionization (NSDI) of atoms driven by orthogonal two-color (OTC) fields. Our findings reveal that the NSDI probability is clearly dependent on the relative initial phase of OTC fields at different relative frequencies. The inversion analysis results indicate that adjusting the relative frequency of OTC fields helps control returning probability and flight time of the first electron. Furthermore, manipulating the relative frequency at the same relative initial phases can vary the revisit time of the recolliding electron, leading that the emission direction of Ar2+ ions is explicitly dependent on the relative frequency. ? 2022 Chinese Physical Society and IOP Publishing Ltd.
    Accession Number: 20223412595705
  • Record 479 of

    Title:Emerging material platforms for integrated microcavity photonics
    Author(s):Liu, Jin(1); Bo, Fang(2); Chang, Lin(3); Dong, Chun-Hua(4); Ou, Xin(5); Regan, Blake(6); Shen, Xiaoqin(7); Song, Qinghai(8); Yao, Baicheng(9); Zhang, Wenfu(10); Zou, Chang-Ling(4); Xiao, Yun-Feng(11)
    Source: Science China: Physics, Mechanics and Astronomy  Volume: 65  Issue: 10  DOI: 10.1007/s11433-022-1957-3  Published: October 2022  
    Abstract:Many breakthroughs in technologies are closely associated with the deep understanding and development of new material platforms. As the main material used in microelectronics, Si also plays a leading role in the development of integrated photonics. The indirect bandgap, absence of χ(2) nonlinearity and the parasitic nonlinear absorptions at the telecom band of Si imposed technological bottlenecks for further improving the performances and expanding the functionalities of Si microcavities in which the circulating light intensity is dramatically amplified. The past two decades have witnessed the burgeoning of the novel material platforms that are compatible with the complementary metal-oxide-semiconductor (COMS) process. In particular, the unprecedented optical properties of the emerging materials in the thin film form have resulted in revolutionary progress in microcavity photonics. In this review article, we summarize the recently developed material platforms for integrated photonics with the focus on chip-scale microcavity devices. The material characteristics, fabrication processes and device applications have been thoroughly discussed for the most widely used new material platforms. We also discuss open challenges and opportunities in microcavity photonics, such as heterogeneous integrated devices, and provide an outlook for the future development of integrated microcavities. ? 2022, Science China Press and Springer-Verlag GmbH Germany, part of Springer Nature.
    Accession Number: 20223712723895
  • Record 480 of

    Title:The enhanced X-ray Timing and Polarimetry mission – eXTP: an update on its scientific cases, mission profile and development status
    Author(s):Zhang, Shuang-Nan(1); Santangelo, Andrea(2); Xu, Yupeng(1); Feroci, Marco(3,4); Hernanz, Margarita(5,6); Lu, Fangjun(1); Chen, Yong(1); Feng, Hua(7); Nandra, Kirpal(8); Jiang, Weichun(1); Svoboda, Jiri(9); Brandt, S?ren(10); Schanne, Stéphane(11); Zand, Jean(12); Michalska, Malgorzata(13); Bozzo, Enrico(14); Kalemci, Emrah(15); Agudo, Ivan(16); Ahangarianabhari, Mahdi(17); Aitink-Kroes, Gabby(12); Ambrosi, Giovanni(18); Ambrosino, Filippo(3); An, Zhenghua(1); Perez Torres, Miguel Angel(16); Antonelli, Matias(19); Argan, Andrea(3,20); Babinec, Viktor(21); Baldini, Luca(22); Barbera, Marco(23,24); van Baren, Coen(12); Baudin, David(11); Bayer, J?rg(2); Bellazzini, Ronaldo(22); Bellutti, Pierluigi(25); Bertucci, Bruna(26); Bertuccio, Giuseppe(17); Bi, Xingzi(27); Boezio, Mirko(19); Bonvicini, Valter(19); Bonvicini, Walter(19); Bordas, Pol(28); Borghese, Alice(5,6); Borghi, Giacomo(25); Bouyjou, Florent(11); Bozkurt, Ayhan(15); Brez, Alessandro(22); Brienza, Daniele(29); Cadoux, Franck(30); Campana, Riccardo(31); Cao, Jiewei(1); Cao, Xuelei(1); Casares, Jorge(32); Cavazzuti, Elisabetta(29); Ceraudo, Francesco(3); Chen, Tianxiang(1); Chen, Wen(27); Chen, Can(1); Chen, Yupeng(1); Chen, Xin(27); Chen, Yehai(27); Chenevez, Jerome(10); Cheng, Yaodong(1); Cirrincione, Daniela(19,33); Civitani, Marta(34); Cong, Min(1); Zelati, Francesco Coti(5,6); Cui, Weiwei(1); Cui, Tao(1); Cui, Wei(7); Dai, Boyu(1); Dauser, Thomas(35); De Angelis, Nicolas(30); De Marco, Barbara(36); De Rosa, Alessandra(3); Monte, Ettore Del(3,4); Cosimo, Sergio Di(3); Diebold, Sebastian(2); Dilillo, Giuseppe(3); Ding, Fei(37); Dohnal, Roman(21); Dong, Zefang(1); Donnarumma, Immacolata(29); Dovciak, Michal(9); Du, Yuanyuan(1); Ducci, Lorenzo(2); Evangelista, Yuri(3,4); Fan, Qingmei(38); Favre, Yannick(30); Ferrés, Patrícia(5,6); Fiandrini, Emanuele(26); Ficorella, Francesco(25); Fuschino, Fabio(31); Gálvez, José Luis(5,6); Gao, Na(1); Gao, Min(1); Ge, Yuqiang(37); Ge, Mingyu(1); Gevin, Olivier(11); Grassi, Marco(39); Gu, Yudong(1); Gu, Quanying(38); Guan, Ju(1); Guedel, Manuel(40); Han, Xingbo(27); Han, Dawei(1); He, Huilin(1); He, Junwang(27); Hedderman, Paul(2); den Herder, Jan-Willem(12); Hong, Bin(38); Hormaetxe, Ander(5,6); Hou, Dongjie(1); Hu, Zexun(41); Hu, Hao(1); Hu, Qingbao(1); Hu, Yu(1); Huang, Yue(1); Huang, Jiangjiang(27); Huang, Qiushi(42); Huo, Jia(1); Hynek, Richard(21); Iwasawa, Kazumi(28); Izzo, Lucca(16); Ji, Long(43); Jia, Shumei(1); Jiang, Bowen(41); Jiang, Wei(37); Jiang, Jiechen(1); Jiang, Xiaowei(1); Jiao, Yang(1); Jin, Ge(41); Jin, Fan(37); Jose, Jordi(36); Karas, Vladimir(9); Kennedy, Thomas(44); Kirsch, Christian(35); Kole, Merlin(30); Komarek, Martin(21); Kreykenbohm, Ingo(35); Kuiper, Lucien(12); Kuvvetli, Irfan(10); Labanti, Claudio(31); Latronico, Luca(45); Laubert, Phillip(12); Li, Tao(41); Li, Longhui(41); Li, Hong(7); Li, Duo(37)
    Source: Proceedings of SPIE - The International Society for Optical Engineering  Volume: 12181  Issue:   DOI: 10.1117/12.2629340  Published: 2022  
    Abstract:The enhanced X-ray Timing and Polarimetry mission (eXTP) is a flagship observatory for X-ray timing, spectroscopy and polarimetry developed by an International Consortium. Thanks to its very large collecting area, good spectral resolution and unprecedented polarimetry capabilities, eXTP will explore the properties of matter and the propagation of light in the most extreme conditions found in the Universe. eXTP will, in addition, be a powerful X-ray observatory. The mission will continuously monitor the X-ray sky, and will enable multiwavelength and multi-messenger studies. The mission is currently in phase B, which will be completed in the middle of 2022. ? 2022 SPIE. All rights reserved.
    Accession Number: 20224413019007
99九九在线视频| 色99欧洲色19| 色情婷婷| 色五月五月丁香| 日本一级一级一级一级| 婷婷八月激情| 日韩大片艹艹| 97热这里只有精品| 这里只有精品2| 色婷婷AV久久| 99爱视频| 97人人操| 九九色综合九九色| 精品99网站| 超碰操日| 韩国激情五月天综合网| 青青草轻轻操| 色五月在线观看| 丁香六月婷婷综合麻豆| 啪啪色激情五月天| 99九九玖玖| 丁香六月婷婷一区| www.91AV.com| 天天综合网在线| 人人操A| 色婷婷狠狠久久YY| 五月婷婷激情网| 第四色婷婷五月| www.久久色.com| 激情五月丁香六月综合AVXXXX| 色五月婷婷中文字幕| 成熟妇人A片免费看网站| 日韩精品无码99| 婷婷玖玖丁香| 狠狠干狠狠色| 激情综合激情五月| 99热亚洲只有色| 婷婷狠狠操| 九九黄色网| 久热无码| 国产激情在线| 99色丁香婷婷综合网| 超碰人妻公开在线| 成人免费在线电影| 欧美激情xxxXX| 五月丁香亭亭A片| 91丨九色丨熟女|新版| 操逼123网| 99色热视频| 香蕉AV777XXX色综合一区| 欧洲色| 精品久久婷婷五月天| 超碰啪啪网| 99热超碰在线| 婷婷丁香五月在线播放| 丁香婷婷人妻| 婷婷丁香www视频日本韩国| 色婷婷丁香| 色五月婷婷天天操夜夜操| 五月花激情网| 亚洲无AV在线中文字幕| 草莓视频免费观看| 玖玖在线资源视频| 99综合自拍| 亚州美女| 99亚洲精品视频| 少妇激情基地| 婷婷视频在线碰| 五月丁香激情婷婷| 国产精品蜜臀99| 在线观看av网站| 少妇性按摩无码中文A片| 天天色天天操天天射| 全网最新网黄大秀直播高清,主播国产录屏在线 | 婷婷月综合| 婷婷五月婷婷五月| 久久曰曰| 色色网91| 国产亚洲成AV人片在线观黄桃| 国产毛片精品一区二区色欲黄A片| 在线五月色播| 日韩超碰在线| 99色嘟嘟精品网站| 国产FREESEXVIDEOS性中国| 丁香婷婷综合激情五月色| 青草视频在线蜜臀| 色射影院| 激情影院69| 亚洲啪啪啪啪| 丁香五月另类小说| 99精品偷自拍| 丁香六月情| 久久综合激情五月天| 丁香五月综合激情久久潮喷| 久久97| 深爱婷婷丁香五月激情| 色欲婷婷夜夜| 99热热热国产超碰| 影音先锋五月婷婷| 丁香六月激情| 婷婷色丁香五月| 操人妻视频91| 伊人婷婷五月| 丁香五月婷婷无码AV| 激情亭亭五月| 老师高潮流白浆喷水的A片| 激情综合网五月婷婷| 玖玖资源站蜜臀| 五月激情六月| 丁香五月婷婷色情综合| 丁香五月成人社区| 五月婷婷在线视频免费观看| 婷婷爱爱蜜臀天天操| 99热个人在线| AV人人操| 五月婷婷激情久久| 五月婷婷在线免费| 亚洲婷婷六月天| 久久久WWW| 大香蕉伊然在亚洲90| 粉嫩AV久久一区二区三区| 思思热久久久在线| 亚洲无码成人性爰网| 激情综合色图| 九九视屏| 婷婷五月综合激情| 国产亚洲精品久久久久苍井松| 超碰93在线观看| 夜夜撸夜夜骑| 色久五月| 五月婷婷激情综合网| 丁香婷婷六月天| 另类A片| 婷五月天六| 丁香综合日产精品久久| 国产精产国品一二三在观看| 国产69精品久久久久999小说| 超碰人妻在线| 亚洲AV综合网| 成人五月丁香社区| 99热9| 超碰99热| 久操热线| 久久婷婷五月天懂色| 99re热在线视频观看| 99热这里只有精品免费观看| 99国产性感视频| 综合色天天| 色墦五月丁香| 激情综合九月| XX久久| 久久婷婷六月综合| 99这里有精品免费| 超碰AV在线| 国产色网站| 久久婷婷六月综合综合| 亚洲无码猫咪| 91人人人人人人人| 免费观看全黄做爰的视频| 久久久97| 丁香五月色情| 粉嫩av懂色av蜜臀av熟妇| 人妻久久久久久久久妻久久久久| 色婷婷在线视频久| 五月天自拍网| 伊人狠狠干| 亚洲国产精品成人va在线观看| 99热久只有| 亚洲精品操一操、噜一噜、摸一摸、爽 | 亚洲天堂AAA| 婷婷 激情 五月| 天天日天天舔天天摸| 97干免费视频| 九久久精品视频99| 日本三级日本三级99| 色婷婷中文在线| 91九色在线视频| 色你久久| 日本九九九九| 5月婷婷综合| 婷婷五月天亚洲色| 密乳视频| 五月天精品视频| 操操操AV| 狠狠草在线观看| 99热这里只有在线| 五月天婷婷在线播放免费| 99热777| 深爱激情av| 亭亭色色五月天| www.91久久| 97久久精品| 色婷| 俺去也五月| 99热精品在线观看| 黄急一级视频| 婷婷五月天性色| 97丨九色丨国产丨PORNY| 99综合视频| 99色综合| 伊人99久久| 无语停婷丁香网| 一级韩国产精品毛| 69精品人人人人人人| 五月天AV大香蕉| 9久热在线视频精品| 久操97| 久久久久久久久久久久63| 97碰操| 色综合久久中文| 日日撸天天干| 日本三级中国三级99| 97香蕉碰碰人妻国产欧美| 热99免费在线| 一本色综合色| av一区免费看| 久久九九思思| 五月亭亭色| 色婷婷丁香综合中文字幕| 久操人妻| 五月婷婷m| 天天爽夜夜爽天天爽夜夜爽| 激情小说五月天| 熟女网站久久| 日本不卡高字幕在线2019| 亚洲精品无人区| www.五月婷婷| 久热中文字幕| 五月花综合| 秋霞学生妹一二级| 这里只有精品9| 99∨VTV| 中文字幕在线免费观看视频| 伊人五月天| 国产日产亚系列精品版优势| 色情终和网| 拍色综合| 色综合中文| 97碰碰人人| 伊人婷婷青青cao| 安息电影在线观看完整版| 99亚洲大片精品永久在线观看 | 五月婷中文字幕| 五月天停婷基地| 成人精品在线观看| 五月综合激情啪啪啪啪啪| 色播五月婷婷| wuyuedingxiang99| 日批在线看| 日日干天天爽| 日本久久天堂| 亚洲欧美综合7777色亭亭| 人人操婷婷| 天堂色婷婷| 97激情五月天| 午夜丁香婷婷| A久久| 欧美熟女视频 色婷婷| 色婷婷综合成人| www.99热国产| 色色性爱视频| 99免费| 99久久国产综合精品五月天喷水\| 久艹伊| 六月丁香成人| 可以免费观看的AV| 久久久久久人妻| 久久密臀婷婷| 激情婷婷色色| 五月之婷婷| 五月天伊人网| 开心五月激情网| 亚州精品色情无码A片| 情情五月天色| 香蕉AV777XXX色综合一区| 狠狠色色| 20253AV| 91婷色| 久1色色| 丁香五月综合在线观看| 综合色播| AV六月丁香| 伊九九三级区| 都市激情小说婷婷| 亚洲综合无码| A短视频免费在线观看| 91九色欧美| 丁香五月日啪| 四川BBB搡BBB搡多| 91操操| 丁香六月婷婷色播| 婷婷五月电影院| www激情五月天| 五月第四色| 欧美噜一噜| 日本高清综合网五月丁香| 亚洲情欲| 草榴视频网| 99久久综合精品五月天| 99色干| 久草丁香婷婷1024| 99五月丁香丁| 婷婷丁香五月天激情| 99这里都是精品| 色涩影院六月丁香| 思思久久96热在精品国产,| 婷婷五月天情色| 天天综合天天玩夜夜玩天天玩夜夜玩| 激情小说视频图片| 99精品在线| 色五月婷婷五月天激情综合| 五月丁香色情| 五月六月丁香激情| 婷婷五月天伊人| 热99久| 激情网开心网| 久久九九热视频| 99热九九热| 久婷| 婷婷.com| 国产婷婷五月中文字幕高清| 原琪琪色影院| 国产色99| 五月婷婷乱| 操人无码| 大香蕉婷婷五月天| 99亚洲视频| 国产AV一区二区三区最新精品 | 亚洲国产另类av| 狠色狠色狠色狠色狠色网| 亚洲第一成人无码A片| 99综合成人视频在线观看| 性爱激情小说AV五月丁香花| hd五月婷婷在线| 亚洲旡码| 日本在线wwww| 五月婷婷精品无在线| 国产69久久久欧美黑人A片| 丁香五月综合网亚洲综合欧美狠狠| 五月婷婷六月激情| 操B无码视频国语| 丁香婷婷五月天色综合| 99精品一二三四视频| 啪啪日本欧美| 99热首页在线30| 97色色色色| 天天爽天天日天天舔| 五月丁香大香蕉| 丁香九色不卡aaa| 激情婷婷五月天伊人在线观看| 丁香婷婷性久久| 九九视频在线观看视频在线播放69| 玖玖精品视频99| 97色婷婷| 国产精品色婷婷久久久精品| 丁香五月狠狠综合欧美| 日韩一级网站| 四色综合网| 色婷婷亚洲婷婷| 情色五月天 网站| 久久亚洲精品成人无码网站导航| 中文字幕成人| 色~性~乱~伦~噜| 婷婷五月天AV| 色九九九综合| 五月丁香色婷婷综合| 少妇搡BBBB搡BBB搡毛茸茸 | 色婷婷小说| 五月香蕉婷婷| 激情五月婷婷丁香| 国产99久| 丁香5月啪啪| 屁股翘好撅高迎合跪趴| 天天人人综合| 婷婷深爱五月天| 九九九九综合| 一区二区成人电影| 大香蕉五月天婷婷| 第四色五月婷婷| 色色色.COM| 97caop| 青青草护士中出内射-欧美电影在线天堂新版| 久久与婷婷| 久久人人九| 中文字幕 中文字幕明步| 色色色丁香| 婷婷瑟瑟五月天| 国产高清视频91九九九久久久| 四虎婷婷五月天| 无码人妻丰满熟妇奶水区码| 色婷婷五月天激情| 九九激情网| 激情六| 开心婷婷五月| 五月天伊人av| 中文字幕无码人妻少妇免费视频 | 日本的α片xxxwww| 欧美性生交XXXXX无码小说 | 婷婷五月av| 丁香六月婷婷综合激情欧美| 亚洲综合在线伊人婷| 婷婷天天日婷婷| 精a品a视a频| 人人摸人人| 男人天堂亚洲综合| 丁香五月婷婷基地| 国产一级婬片毛片| 亚洲正能量欧美| 丁香五月在线看| 一级韩国产精品毛| 五月成人网站| 色爱99| 婷婷色片| www.超碰在线| 激情五月天小说网| 综合欧美五月婷婷| 久色资源| 色综合久久天天综合网 | 婷婷丁香五月视频| 涩五月婷婷| 欧洲激情五月天| 另类五月激情| 婷婷五月天偷拍| 手机在线视频观看9| 婷婷五月天免费视频| 91在线精品一区二区| 99乱视频| 日本色婷婷| 天天操天天操天天操天天操天天操天天操天天操天天操天天操 | 日本熟女一区二区| 大香蕉啪啪啪啪啪啪| 五月成人网站| 色吧五月婷婷| 久久新地址| 99re66热这里只有精品| 99性色| 丁香六月婷婷综合网| 亚洲人妻一区二区 | 久久五月天 91| 天插天啪天啪天啪| 91久久九九| 亚洲色激情| 九九人人自拍| 99视频精品| 五月激情开心婷婷| 久久婷婷五月综合色天| 伊人网碰碰| 丁香五月在线视频| 97人人操人人干| 女人天堂av| 天堂在线婷婷| 久热黄色| 成人婷婷色五月天| 日韩在线视频9色| 欧美婷婷综合| 色婷婷成人| 欧美成人精品A片免费一区99| 操笔无码| 久久久九九视频精品18| 婷婷激情九月| 五月天激情网址| 加勒比久热| 丁香五月激情网| 91啪啪| 婷婷.com| 五月天综合网| 五月婷婷丁香啪啪| 丁香五月天天久久综合小说| 26uuu成人网| 少妇高潮一区二区三区99欧美| 色久综合| 深爱激情丁香| 五月天日日操夜夜操 | www.色婷婷| 在线中文亚洲| 中文字幕成人| 99热在线观看| 色狠狠999综合网| 婷婷性爱| www.婷婷,com| 美日韩成人| caop视频| 成人丁香| 亚洲精品五十一区| www.激情五月天。com| 久久久WWW| 久久99jiu9| 久久激情网| WWW,五月天| www.射伊蕉婷婷| 婷婷五月激情热播| 欧美日韩一区二区三区四区| 26UUU欧美| 99er日韩| 碰碰91| 五月激情网综合| 超碰在线超碰| 久热婷婷| 99热| 色久五月| 久久精品9| 亚洲激情AV| 99久久玖玖| 色五月婷婷基地| 五月婷视频| 五月久久婷婷成人网| 狠狠综合网| 91黄色五月天视频| www.狠狠| 狠狠狠狠狠干| 激情婷婷五月天网址| 日韩久综合| 日日躁夜夜躁狠狠久久AV| 99视频精品在线| 精品人妻伦| 操操自拍| 97色碰碰公开视频| 超碰激情网| 91人人爽久久涩噜噜噜| 青草性爱视频| 五月丁香无码| 久草 tingting| 亚洲综合激情五月久久| 天天操婷婷| 五月激情综合五月| 大香蕉婷婷色| 91九色PORNY中文啦| 国产日韩欧美性爱| 在线视频激情网站| 激情五月色综合国产精品| 丁香五月婷婷激情尤物| av免费在线观看0| 五月丁香六月欧美综合网站| 五月天激情电影| 婷婷色情小说| 五月六月播婷婷| 久久日韩婷婷五月| 91919191919久久成人视频| 婷婷五月激情网| 狠狠操天天干| 五月丁香在线国产| 婷婷五月天久久久| 狠狠色噜噜色狠狠狠综合色| 99ER热精品视频| 亚洲九九视频| 日韩AV色色色| www.激情在线| 亚洲午夜电影| 婷婷九月久久| 久久婷婷国产| 日本婷婷五月天| 秋霞电影理论| 天天天操天天天爰| 婷婷色在线观看| 激情无码网| 91精品刘玥| 乱精品一区字幕二区| www.99热这里精品| 538在线精品| 91九色中文| 啪啪亚洲综合| 色。 日日日| 99婷婷| 色婷婷777狠狠| 五月深情久久| 热99玖玖99玖玖99九九| 精品一二三区久久AAA片| 日本九婷婷| www.99成人视频| 国产精品-第3页-91JQ就要激情网91JQ5.JQJQ926.XYZ | 丁香激情网| 精品一区二区三区三区| 色逼综合网| 另类少妇人与禽zOZZ0性伦| 桔色成人官方网站| 婷婷五月天av网| 国产成人+综合亚洲+天堂| 色五月激情综合| 日韩有码一区| 亚洲AV成人一区二区在线观看| 国产99久久久国产精品免费看| 久久九九99| 色色色色网| va亚洲中文在线| 免费观看的AV| 九九九午夜影院成人| 日本天天综合| 亚洲无码另类| 日美三级| 丁香五月玖玖| 香蕉久日夜| 婷婷久久网| www.久久久.com| 这里只有精品视频在线| 伍月婷丁香花全集| 深爱激情四射| www婷婷亚洲| 亚洲婷婷开心五月| 久久精品国产色| 六月婷婷久久| 婷婷五月天网址| 婷婷五月,偷窥偷拍网| 99re在线免费视频| 久久九九经典| 伊人激情综合| 婷婷五月天熟妇| 色综合久久天天综合网| xxxx久| 1024你懂的欧美曰韩| 亚洲视频在线网| 天天狠狠夜夜狠狠2023| 激情五月天之五月婷婷| 五月天合网| 99热这里都是精品| 97丁香五月| 日本九九视频| 色综合久久天天综合网| AAA久久久AAA久久久AAA| 婷婷五月丁香色综合| 999久久久国产精品| 97碰碰人人视频| 色yeye色综合| 色五月色开心开心五月| 婷婷丁香五月天操逼| 玖玖婷婷五月天毛片| 人人操人人妻| 东北熟女高潮99综合99| 天天综合网色欲香| 色99婷婷五月天| 99视频综合网| 9久热在线视频| 久久综合五月天激情小说网站| wwwss在线观看| 天堂成人A片永久免费网站| 搡BBBB搡BBB搡五十| 国产毛片精品一区二区色欲黄A片| 五月天国产| 五月婷婷激情综合| 日本久久久97| 五月天另类图片区99| 久久色天堂| 99热这里在线精品| 夜夜爽日日躁| 天天综合影院| 色爱99| 激情综合网五月婷婷| 婷婷情色开心五月天99| 国产中文字幕在线视频免费观看| 九九热在线99| 亚洲AV成人精品日韩在线播放| 免费日韩99| 色性五月天| 欧美这里只有精品| 天天射美女| 亚洲亚洲人成综合网络| 五月天丁香花婷婷| 久久停停超碰| 天天爽,天天操。| 激情五月婷婷色| 婷婷五月丁香超碰| 午夜天堂一区人妻| 91女人18毛片水多国产| 色五月婷婷操逼| 婷婷国产综合| 五月丁香色狠狠干大屄| 六月丁香五月天| 99热爱爱干干日| 男女啪啪做爰高潮无遮挡| 中文婷婷狠狠| 亚洲成人网在线观看| 天天做天天双| 99久在线精品99re8| WWW.99热| 不卡在线视频| 99精品久久久久| 亚洲色爽| 欧美xx激情视频在线观看| 色五月五月婷婷| 99在线精品观看99| 91热手机在线| 超碰99在线| 99只有这里是精品| 99热精品在线观看| 免费看欧美成人A片无码| 久热A片| 五月丁香久久久久| 欧美丁香六月激情视频| 激情六月天| 国产精产国品一二三在观看 | 四色五月婷婷在线观看| 久久人妻熟女一区二区| 强壮的公次次弄得我高潮A片日本 | 99久久精品网| 九九re精品视频在线观看| 99热在线观看| 五月久久网| 久久亚洲网| 欧美丁香婷婷五月| 五月天堂婷婷| 99re资源在线视频导航| 另类视频综合| 五月综合六月婷婷| 大香蕉五月天婷婷| 色吧网综合| 噜噜噜噜婷婷五月天| 婷婷丁香色情五月天| 超碰AV在线| 91av成人| 久久综合这里只有精品1 | 五月天怕怕| 天天操夜夜啊| 五月天精品| 91精品久久久久久综合五月天| 九九综舍久久| 丁香婷婷五色月| 国产免费AV在线| 精品人妻在线免费观看| 亚洲av综合网| 亚洲五月六月婷婷| 深爱激情六月| 成人AV在线电影| 五月丁香婷婷伊人日韩| 狠狠色婷婷7777久| 人人爽欧美婷婷久久久五月丁香| 依人大香蕉| 超碰啪啪网| 伊人五月婷婷| 婷婷丁香六月| 狠狠色噜噜狠狠亚洲A∨| 女人天堂AV| 亚洲九九婷婷| 最新精品视频99| 九九99九九99偷拍视频免费看| 婷久久高清| 久久综合丁香五月| 久热只有精品| 91无码色色| 91久久久久久久| 婷婷丁香人妻天天爽| 青草视频在线播放| 91热在线| 丁香五月天资源网| 日本欧美成人片AAAA| 九月激情网| 人人干人人看| 激情都市另类| 99热在线爱| 天天做天天爱天天爽综合网| 99热久久这里只有精品| 99视频精品| 91精品久久久久、久五月天| http://www.com久久久精品一区| 91日韩在线| 99久久网站| 婷婷狠狠干| 国产永久一二一起草| 啪色综合| 狠狠久久婷| 99精品爱| 精品亚洲国产成AV人片传媒| 最新色色五月天| 激情五月天综合| 国产在线激情视频| 五月丁欧美| 色五月激情综合| 九九美女视频| 婷婷五亚洲| 最近免费中文字幕大全高清大全1| 日本熟女二区| 成人精品视频99在线观看免费| 五月色丁香激情| 91精品久久久久久77777| 色五月中文字幕| 精品成人无码A片观看香草视频| 99日韩| 人人操 色| 婷婷夜夜夜夜| 精品人妻伦九区久久AAA片| 91大神操美女| 66色在线日韩| 日韩人人操| 天天操天天爽天天爱| 五月天精品视频| 色婷婷成人网| 丁香五月婷婷五月天| 日韩AV在线免费| 天色综合网站| 极品少妇XXXX精品少妇偷拍| 99re热精品在线视频| 丁香五月婷婷亚洲色图| 五月婷婷黄色毛片| 涩婷婷五月天| www.lchjjc.com| 婷婷综合成人五月天| 色五月天电影| 亚洲综合激情五月久久| 日本欧美国产| 26uuu偷拍亚洲欧洲综合| 人妻视频一区而且二区| 色五月综合婷婷久久综合婷婷久久综合婷婷久久综合婷婷久久 | 天天撸天天射| 天堂网色婷婷| a久久免费视频| 久久大国产香蕉| 99精品视频在线| 99网| 日本本土色网第一区| 色综合婷婷| 男人天堂99| 超碰国产在线观看| 久久91久久91色欲精品| 夜夜操天天干| txt五月激情四射网综合俺也来了 五月天婷婷丁香人人操91 | 99视频内射三四| 婷婷丁香高潮了| 中字幕视频在线永久在线观看免费| 久久久人妻不卡| 天天肏视频| 午夜色婷婷| 婷婷精品在线| 亚洲天堂爱爱| 超碰在线视屏| 国产激情综合| 五月丁香啪啪网| 色五月首页| 久久婷婷伊人| 婷婷综合另类小说| 精品人妻一区| 99热热九九| 丁香五月花| 精品无码人妻一区| 五月天社区| 激情五月网站| 97丨九色丨国产丨PORNY| 麻豆123区| 婷婷影院A成人| 丁香丝袜五月| 色色日本| 五月丁香六月婷婷,婷| 久久机热/这里只有精品| 久久九九玖玖| 久久永久视频| 婷婷五月色| 六月丁香五月天| 六月欧美综合色情| 第四色色六月色综合| 成人做爰高潮A片免费视频| 婷婷六月激情啪啪| 日韩AV无码影片| 操啊操av| 久久免费干| 五月婷婷丁香俺日污视频| 丁香五月123| 色色五月婷婷久久| AV中文在线| 亚洲五月婷婷| 五月天色导航| 91九色白丝| 激情五月天伊人av| 精品综合爱| 日本高清久| 五六月婷婷| 在线观看国产高清视频免费网站| 怡红院院久久| 婷婷酒色网| 精品人妻伦一二三区久| 久久婷婷五月天激情| 9久热在线视频精品| 丁香五月婷婷久久综合激情网| 天天射影院| 丁香六月高清视频| 亚州男人天堂婷婷五月| 天天狠狠干| 夜夜久久综合网| 欧美久久网| 丁香午月AV中文字幕| 五月色综合| 婷婷丁香五月在线播放| 久久婷视频| 超碰超碰在线| 天天草婷婷五月| 日操夜操天天操不卡| 99热这里只有精品4| 九热...av| 激情综合网激情五月天| | 久久99精品久久久| 97影院一级片| 99er6| 五月色亭丁香| 日本色久| 2050人人操免费工开爱| 久久婷婷青青| 久久人妻熟女一区二区| 国产精品久久99| 激情图片亚洲| 色综合五月| 噜噜噜噜噜久| 天天干人人奸97| 99热这里都是精品| 五月婷婷黄色| 岛国AAAV| 久9免费视频| 六月婷婷无码| 国内精品免费一区二区2009| 国产成人AV在线播放| 婷婷激情小说网| 天堂在线观看视频| 暴躁少女CSGO免费观看视频大全| 亚洲精品网站色视频| 伊人热在线大香蕉| 五月花成人网| wwW天天干| 国产综合A片| 久久精品视频99| 成人网丁香五月| 91色在线 | 日韩| 成人丁香| 激情开心五月天婷婷基地丁香社区| 狠狠人妻色综合| 无码日本精品XXXXXXXXX| 亚洲视色| 99视频精品全部免费看| 久99久视频精品| 4438激情网| 欧美黑人巨大猛烈cuckold| 婷婷色五月天色| www.婷婷五月| 这里精品| 五月丁香六月在线欧美| 九九久久9 9在线观看| 五月综合丁香婷婷| 99爱视频在线免费观看| 激情亚洲婷婷| 精品国产AV色一区二区深夜久久| 激情六月综合| 狠狠艹狠狠艹| 五月婷婷狠狠久久| 五月婷婷在线视频| 五月天激情亚洲| 日本精品在线噜噜噜| 欧美久久久中文字幕| 99热最新| 婷婷射婷婷舔| wwwss在线观看| 97色综合视频| 精品人妻一区二区三区四区不卡在| 精品A√| AV色五月婷婷| 奇米影视777在线_在线观看午夜_h小视频在线观看_岛国大片 | 久久婷婷视频| 沈娜娜av| 色色激情| 99热这里只有免费精品| 丁香色五月婷婷17C| 五月激情久久| 五月天激情视频| 这里只有精品免费| 日本美女天天日天天爽| 婷婷久久影院| 亚洲综合激情五月久久| 亚洲成人中心| 婷婷色五月情| 亚洲色婷婷| 黄页免费一级视频懂色| 99热只有| 成全二人世界免费观看完整版| 九九视频精品在线免费| 久久香蕉网| 99热这里有精品| 丁香五月婷婷AV在线| 亚洲综合丁香五月| 中文字幕,综合,91| www.玖玖九| 开心五月网| 久久亚洲精品无码Va白人极品| 玖玖资源网站最新站| 日夜操B| 久热伊人在91| 婷婷香蕉| 婷婷五月天黄色| 丁香五月在线观看| 午夜精品777| 天天激情5月天亚洲| 在线看黄色| 五月J香蕉婷婷| 亚洲激情婷婷| 超碰猛烈的性猛交| 色色哒五月婷婷六月丁香| 六月丁香婷婷拍拍| 九九大香视频| 婷婷丁香五月在线观看91| 五月色婷婷综合| 狠狠摸狠狠摸| 天堂AV在线看| 精品婷婷五月视| 五月天婷婷久久| 丁香五月婷婷欧美激情-中文天堂最新版在线观看 | 婷婷精品性视频| 九九热区一区二区三区| 天天爽爽日日做做| 久久久久网站| 激情婷婷。| 久久无码成人| 成人国产欧美大片一区| 91热在线| 丁香花网站| 五月天开心激情综合网| 欧美天天干天天草| 婷婷丁香午夜综合影视| 大香蕉婷婷| 99网址在线看| 丁香五月综合久久| 午夜激情四射影院| 免费精品99| 亚洲经典三级| 狠狠色婷婷7777久| 久久五月婷婷丁香| 色天五月天在线观看视频| 天天爽天天草| 俺去也在线官网| 天天操天天操综合| 五月天色狠狠| 五月婷婷六月丁香| 丁香五月婷婷亚洲综合精品| 99免费在线视频| 婷婷丁香五月天色色| 色99最新网址| 日韩成人精品中文字幕电影| 蜜桃五月天| www.婷婷五月| 久久99久久99久久99人受| 狠狠爱激情网| 再深点灬舒服灬太大了添A片小说| 人人摸人人搞| 久久丁香久久| 99久久久国产精品免费蜜乳tv| 丁香婷婷六月天| 久久er九九| 婷婷五月激情六月丁香| 婷婷五月天成人导航| 99精品国产热久久91色欲| 日韩av在线免费观看| 婷婷五月天大香蕉| 69精品无码一区二区三区| 超级碰碰碰久久网站视频| 性爱激情久久| 骚逼视频一区2区| 色婷婷丁香女女| 丁香五月婷婷激情四射深爱激情| 九九热视频在线观看| 99久久99久久综合| 婷婷色导航| 色五月网址| 大香蕉综合网| 天天综合精品| 97人妻超级碰碰碰碰碰| 激情久久久| 97夫妻超碰| 青青草青青草五月天| 亚洲狠狠色丁香婷婷综合久久| 99免费超碰在线| 天天色综网| 色五月婷婷在线观看第一页舔| 超碰人妻公开在线| 激情5月婷婷| www九九免费视频| 亚洲超碰中文字幕| www.婷婷五月.com| 婷婷丁香婷婷97| 第1影院之五月婷婷| 亚洲激情| 久热伊人9| www一起操| 五月婷婷熟女| 99综合视频| 久久五月视频| av在线超清中文| 人人色性网| 五月综合六月丁| 能直接看的AV网站| 99热99色| 色五月欧美| 亚洲精品在线视频| 婷婷射丁香| 人妻无码精品一区| 丁香五月激情网| 超碰在线99| 伊人九热| 超碰京东热av男人的天堂| 性爱人人网| 99 re视频一区| 婷婷导航| 亚洲精品乱码久久久久99| 五月丁香花伦理电影| 夜夜撸天天日| 五月天色影院| 婷婷玖玖五月天| a在线观看| 极品人妻VIDEOSSS人妻| 99热综合| 嫩草视频。| 久婷婷五月天影院| 激情综合无码| www.婷婷网| 五月丁香六月婷婷玖玖| 五月丁香六月婷婷综合| 国产日韩欧美性爱| 丁香五月天黄色片| 99热官网| 亚洲婷婷性爱| 伊人久久大香线蕉AV最新午夜| 婷婷色在线视频| 五月丁香狠狠爱| 色欲五月天| 天天橾夜夜爽| 国产做A爰片毛片A片美国| 婷婷99狠狠躁天天| 国产成人精品一区二三区熟女在线| 婷婷中合| 伊人久久综合| 五月婷婷激情网| 丁香婷婷激情五月| 五月婷婷欧美激情| 丁香六月天| 大香蕉综合网| 九九9久九9国产视频| 91seAV| 色噜噜狠狠色综合成人网| 婷婷激情五月吧| 中文字幕 久久9999| 涩综合婷婷| 色欲久久综合| 性爱综合网| 婷婷色基地在线看 | 色婷婷狠狠禁18久久| 丁香五月成人丝袜| www色色com| tingtingzonghewang| 五月天婷婷在线AN| 99欧州偷拍视频| 精品亚洲国产成人A片在线鸭王| 色亭亭九月| 色色色婷婷五月| 国产va在线视频| 国产成人99久久亚洲综合精品| 久超超碰| 97碰碰碰免费公开在线视频| 激情影院69| 97人人做| 丁香婷婷五月天色播| 丁香午夜天| 91精品久久久久久77777| 五月天婷婷综合网| 综合玖玖偷拍| 婷婷激情丁香五月婷婷激情丁香五月婷婷| 开心五月婷| 99丁香五月婷| 少妇水多A片太爽了| 丁香综合久久|