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Articoli di riviste sul tema "Zhao sheng zhi du"
1
Ishii, Shudo. "On the Biography of Zhao-qing-sheng-teng in the Quan-zhou-kai-yuan-si-zhi". JOURNAL OF INDIAN AND BUDDHIST STUDIES (INDOGAKU BUKKYOGAKU KENKYU) 34, n. 1 (1985): 270–77. http://dx.doi.org/10.4259/ibk.34.270.
Testo completo
2
Cronin, Stephen B. "(Invited) In Situ spectroscopy of Electrochemical and Photoelectrochemical Interfaces". ECS Meeting Abstracts MA2022-02, n. 48 (9 ottobre 2022): 1823. http://dx.doi.org/10.1149/ma2022-02481823mtgabs.
Testo completoAbstract (sommario):
We explore various aspects of electrochemistry and photoelectrochemistry using in situ spectroscopy of electrode (metal) and photoelectrode (semiconductor) interfaces under electrochemical working conditions. Using sum frequency generation (SFG) spectroscopy, we measure the voltage dependence of the orientation of D2O molecules at a graphene electrode surface, which enables us to extract the free energy orienting potential of interfacial water.1 In particular, we measure the “free OD” feature in the spectra, which corresponds to the topmost water molecule that is rotated up out of the bulk water solution and is, therefore, not hydrogen bonded. Using transient absorption spectroscopy (TAS), we measure the lifetime of hot electrons photoexcited in plasmon resonant nanostructures.5 In a similar study, we use transient reflectance spectroscopy (TRS) to measure the photoexcited carrier dynamics in a GaP/TiO2 photoelectrode, as well as the electrostatic field dynamics at this semiconductor-liquid interface in situ under various electrochemical potentials.2 Here, the electrostatic fields at the surface of the semiconductor are measured via Franz−Keldysh oscillations (FKO). These spectra reveal that the nanoscale TiO2 protection layer enhances the built-in field and charge separation performance of GaP photoelectrodes. Using surface enhanced Raman scattering (SERS) spectroscopy, we monitor local electric fields via Stark-shifts of nitrile-functionalized silicon photoelectrodes.6 By monitoring Stark shifts in graphene-enhanced Raman spectroscopy (GERS), we measure local electric fields and local charge densities at monolayer graphene electrode surfaces.3 Lastly, we measure the stacking dependence of monolayer WSe2/MoSe2 heterostructures and observe resonant excitation of interlayer excitons for photocatalytic energy conversion.4 Montenegro, A., C. Dutta, M. Mammetkuliev, H.T. Shi, B.Y. Hou, D. Bhattacharyya, B.F. Zhao, S.B. Cronin and A.V. Benderskii, Asymmetric response of interfacial water to applied electric fields. Nature, 594, 62 (2021). Xu, Z.H., B.Y. Hou, F.Y. Zhao, Z. Cai, H.T. Shi, Y.W. Liu, C.L. Hill, D.G. Musaev, M. Mecklenburg, S.B. Cronin and T.Q. Lian, Nanoscale TiO2 Protection Layer Enhances the Built-In Field and Charge Separation Performance of GaP Photoelectrodes. Nano Letters, 21, 8017-8024 (2021). Shi, H.T., B.F. Zhao, J. Ma, M.J. Bronson, Z. Cai, J.H. Chen, Y. Wang, M. Cronin, L. Jensen and S.B. Cronin, Measuring Local Electric Fields and Local Charge Densities at Electrode Surfaces Using Graphene-Enhanced Raman Spectroscopy (GERS)-Based Stark-Shifts. ACS Applied Materials & Interfaces, 11, 36252-36258 (2019). Chen, J., C.S. Bailey, D. Cui, Y. Wang, B. Wang, H. Shi, Z. Cai, E. Pop, C. Zhou and S.B. Cronin, Stacking Independence and Resonant Interlayer Excitation of Monolayer WSe2/MoSe2 Heterostructures for Photocatalytic Energy Conversion. ACS Applied Nano Materials, DOI:10.1021/acsanm.9b01898 (2020). Yu Wang, Yi Wang, Indu Aravind, Zhi Cai, Lang Shen, Boxin Zhang, Bo Wang, Jihan Chen, Bofan Zhao, Haotian Shi, Jahan M. Dawlaty, and Stephen B. Cronin. In Situ Investigation of Ultrafast Dynamics of Hot Electron-Driven Photocatalysis in Plasmon-Resonant Grating Structures. Journal of the American Chemical Society. DOI: 10.1021/jacs.1c12069 (2022). Haotian Shi, Ryan T. Pekarek, Ran Chen, Boxin Zhang, Yu Wang, Indu Aravind, Zhi Cai, Lasse Jensen, Nathan R. Neale, and Stephen B. Cronin. Monitoring Local Electric Fields using Stark Shifts on Napthyl Nitrile-Functionalized Silicon Photoelectrodes. The Journal of Physical Chemistry C, 124, 17000-17005 (2020).
3
Cronin, Stephen B. "(Invited) In Situ Spectroscopy of Electrocatalytic and Photocatalytic Interfaces". ECS Meeting Abstracts MA2023-01, n. 46 (28 agosto 2023): 2505. http://dx.doi.org/10.1149/ma2023-01462505mtgabs.
Testo completoAbstract (sommario):
We report various aspects of electrochemistry and photoelectrochemistry using in situ spectroscopy of electrode (metal) and photoelectrode (semiconductor) interfaces in situ under electrochemical working conditions. These spectroscopies include sum frequency generation (SFG), transient reflectance/absorption spectroscopy (TAS/TRS), and surface enhanced Raman spectroscopy (SERS). Using surface enhanced Raman scattering (SERS) spectroscopy, we monitor local electric fields using Stark-shifts of nitrile-functionalized silicon photoelectrodes.6 Using Graphene-enhanced Raman spectroscopy (GERS)-based Stark-shifts, we measure local electric fields and local charge densities at monolayer graphene electrode surfaces.1 We also measured the stacking dependence and Resonant interlayer excitation of monolayer WSe2/MoSe2 heterostructures for photocatalytic energy conversion.2 Using sum frequency generation (SFG) spectroscopy, we measure the voltage dependence of the orientation of D2O molecules at a graphene electrode surface, which is related back to the “stiffness of the ensemble”.3 In particular, we measured the “free OD” feature in the spectra, which corresponds to the topmost water molecule that is rotated up out of the bulk water solution and is, therefore, not hydrogen bonded. Using transient absorption spectroscopy (TAS), we measure the lifetime of hot electrons photoexcited in plasmon resonant nanostructures.5 Using transient reflectance spectroscopy (TRS), we measure the photoexcited carrier dynamics in a GaP/TiO2 photoelectrode, as well as the electrostatic field dynamics at this semiconductor-liquid interfaces in situ under various electrochemical potentials.4 Here, the electrostatic fields at the surface of the semiconductor are measured via Franz−Keldysh oscillations (FKO). These spectra reveal that the nanoscale TiO2 protection layer enhances the built-in field and charge separation performance of GaP photoelectrodes. Shi, H.T., B.F. Zhao, J. Ma, M.J. Bronson, Z. Cai, J.H. Chen, Y. Wang, M. Cronin, L. Jensen and S.B. Cronin, Measuring Local Electric Fields and Local Charge Densities at Electrode Surfaces Using Graphene-Enhanced Raman Spectroscopy (GERS)-Based Stark-Shifts. ACS Applied Materials & Interfaces, 11, 36252-36258 (2019). Chen, J., C.S. Bailey, D. Cui, Y. Wang, B. Wang, H. Shi, Z. Cai, E. Pop, C. Zhou and S.B. Cronin, Stacking Independence and Resonant Interlayer Excitation of Monolayer WSe2/MoSe2 Heterostructures for Photocatalytic Energy Conversion. ACS Applied Nano Materials, DOI:10.1021/acsanm.9b01898 (2020). Montenegro, A., C. Dutta, M. Mammetkuliev, H.T. Shi, B.Y. Hou, D. Bhattacharyya, B.F. Zhao, S.B. Cronin and A.V. Benderskii, Asymmetric response of interfacial water to applied electric fields. Nature, 594, 62 (2021). Xu, Z.H., B.Y. Hou, F.Y. Zhao, Z. Cai, H.T. Shi, Y.W. Liu, C.L. Hill, D.G. Musaev, M. Mecklenburg, S.B. Cronin and T.Q. Lian, Nanoscale TiO2 Protection Layer Enhances the Built-In Field and Charge Separation Performance of GaP Photoelectrodes. Nano Letters, 21, 8017-8024 (2021). Yu Wang, Yi Wang, Indu Aravind, Zhi Cai, Lang Shen, Boxin Zhang, Bo Wang, Jihan Chen, Bofan Zhao, Haotian Shi, Jahan M. Dawlaty, and Stephen B. Cronin. In Situ Investigation of Ultrafast Dynamics of Hot Electron-Driven Photocatalysis in Plasmon-Resonant Grating Structures. Journal of the American Chemical Society. DOI: 10.1021/jacs.1c12069 (2022). Haotian Shi, Ryan T. Pekarek, Ran Chen, Boxin Zhang, Yu Wang, Indu Aravind, Zhi Cai, Lasse Jensen, Nathan R. Neale, and Stephen B. Cronin. Monitoring Local Electric Fields using Stark Shifts on Napthyl Nitrile-Functionalized Silicon Photoelectrodes. The Journal of Physical Chemistry C, 124, 17000-17005 (2020).
4
Sheng, Michael, Qiang Zhai e Deborah Kaple. "Perspectives on Sergey Radchenko's Two Suns in the Heavens". Journal of Cold War Studies 14, n. 1 (gennaio 2012): 96–106. http://dx.doi.org/10.1162/jcws_a_00196.
Testo completoAbstract (sommario):
In this forum, three leading experts on Sino-Soviet relations and Mao Zedong's policy toward the Soviet Union offer their appraisals of Sergey Radchenko's Two Suns in the Heavens, The Sino-Soviet Struggle for Supremacy, 1962–1967, published by the Woodrow Wilson Center Press. The commentators praise many aspects of Radchenko's book, but Michael Sheng and to a lesser extent Qiang Zhai and Deborah Kaple wonder whether Radchenko has gone too far in downplaying the role of ideology in Mao's foreign policy. Unlike Lorenz Lüthi, who gives decisive weight to ideology in his own book about the Sino-Soviet split, Radchenko argues that a classical realist approach is the best framework for understanding Chinese foreign policy and the rift between China and the Soviet Union. Sheng and Zhai also raise questions about some of the sources used by Radchenko. Replying to the commentaries, Radchenko defends his conception of Mao's foreign policy, arguing that it is a more nuanced view than Sheng and Zhai imply. Radchenko also stresses the inherent shortcomings of the source base scholars are forced to use when analyzing Chinese foreign policy.
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Radchenko, Sergey. "Reply to the Commentaries". Journal of Cold War Studies 14, n. 1 (gennaio 2012): 107–10. http://dx.doi.org/10.1162/jcws_a_00197.
Testo completoAbstract (sommario):
In this forum, three leading experts on Sino-Soviet relations and Mao Zedong's policy toward the Soviet Union offer their appraisals of Sergey Radchenko's Two Suns in the Heavens, The Sino-Soviet Struggle for Supremacy, 1962–1967, published by the Woodrow Wilson Center Press. The commentators praise many aspects of Radchenko's book, but Michael Sheng and to a lesser extent Qiang Zhai and Deborah Kaple wonder whether Radchenko has gone too far in downplaying the role of ideology in Mao's foreign policy. Unlike Lorenz Lüthi, who gives decisive weight to ideology in his own book about the Sino-Soviet split, Radchenko argues that a classical realist approach is the best framework for understanding Chinese foreign policy and the rift between China and the Soviet Union. Sheng and Zhai also raise questions about some of the sources used by Radchenko. Replying to the commentaries, Radchenko defends his conception of Mao's foreign policy, arguing that it is a more nuanced view than Sheng and Zhai imply. Radchenko also stresses the inherent shortcomings of the source base scholars are forced to use when analyzing Chinese foreign policy.
6
Chen, Li, Yi-Zhou Jiang, Songyang Wu, Jiong Wu, Genhong Di, Guangyu Liu, Keda Yu et al. "Abstract P2-14-04: Updated data from FUTURE-C-PLUS: Combination of famitinib with camrelizumab plus nab-paclitaxel as first-line treatment for advanced, immunomodulatory triple-negative breast cancer, an open-label, single-arm, phase 2 trial". Cancer Research 82, n. 4_Supplement (15 febbraio 2022): P2–14–04—P2–14–04. http://dx.doi.org/10.1158/1538-7445.sabcs21-p2-14-04.
Testo completoAbstract (sommario):
Abstract Background Camrelizumab and nab-paclitaxel demonstrated promising anti-tumour activity in refractory metastatic immunomodulatory triple-negative breast cancer (TNBC) in FUTURE trial. Anti-angiogenic agents have been reported to facilitate immune infiltration. Famitinib is a tyrosine kinase inhibitor targeting VEGFR-2, PDGFR and c-kit. The FUTURE-C-PLUS trial (NCT04129996) which added famitinib to camrelizumab and nab-paclitaxel is a single-arm, phase 2 trial evaluating this novel triplet combinatorial strategy in patients with advanced immunomodulatory TNBC. Study design and the primary endpoint ORR has been reported previously (Zhi-ming Shao, et al. ASCO 2021, Abstract 1007). Here, we reported the updated results of this trial. Method Briefly, this study enrolled women aged 18-70 years, with previously untreated, histologically confirmed, unresectable, locally advanced, recurrent or metastatic immunomodulatory TNBC. Immunomodulatory TNBC was defined as CD8 expression on at least 10% of cells using immunohistochemistry analysis. Eligible patients received the triple therapy. Study design has been reported previously in ASCO 2021. Results Between Oct 2019 and Oct 2020, 48 patients were enrolled and treated. 39 (81.3%, 95% CI 70.2-92.3) patients had a confirmed objective response which has been reported in ASCO 2021. At this updating data cutoff (June 30, 2021), the median progression-free survival was 11.9 months (95% CI, 7.3-16.5) with the median follow-up was 14.0 months. While overall survival data were not mature yet, a promising overall survival rate was observed at 12 months (84•2%, 95% CI 73.4-95.0) and 18 months (73.6%, 95% CI 52.0-95.2). In the 39 responders, median duration of response was also not mature. The disease control rate was 95.8% (46/48). The most common treatment-related grade 3 or 4 adverse events were neutropenia (16 [33.3%]), anemia (5 [10.4%]), febrile neutropenia (5 [10.4%]), and thrombocytopenia (4 [8.3%]). No treatment-related deaths were reported. Conclusions These data, combined with those from our previous reports, provide further evidence for the triplet combination of famitinib, camrelizumab and nab-paclitaxel as an active therapy in advanced Immunomodulatory TNBC. To our knowledge, this is the best objective response rate reached in first-line treatment of advanced TNBC. A randomized controlled FUTURE-Super trial (NCT04395989) is keeping recruiting patients to further validate those findings. Citation Format: Li Chen, Yi-Zhou Jiang, Songyang Wu, Jiong Wu, Genhong Di, Guangyu Liu, Keda Yu, Lei Fan, Junjie Li, Yifeng Hou, Zhen Hu, Canming Chen, Xiaoyan Huang, Ayong Cao, Xin Hu, Shen Zhao, Xiaoyan Ma, Xiaoyu Zhu, Jianjun Zou, Wentao Yang, Zhonghua Wang, Zhi-ming Shao. Updated data from FUTURE-C-PLUS: Combination of famitinib with camrelizumab plus nab-paclitaxel as first-line treatment for advanced, immunomodulatory triple-negative breast cancer, an open-label, single-arm, phase 2 trial [abstract]. In: Proceedings of the 2021 San Antonio Breast Cancer Symposium; 2021 Dec 7-10; San Antonio, TX. Philadelphia (PA): AACR; Cancer Res 2022;82(4 Suppl):Abstract nr P2-14-04.
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Wang, Xu, e Peter Schiavone. "Comment: “Thermal mechanical coupling analysis of two-dimensional decagonal quasicrystals with elastic elliptical inclusion” (Yuan-Yuan Ma, Xue-Fen Zhao, Ting Zhai, Sheng-Hu Ding. Mathematics and Mechanics of Solids (Online First) First Published Online: August 16 2021)". Mathematics and Mechanics of Solids 26, n. 11 (novembre 2021): 1732–34. http://dx.doi.org/10.1177/10812865211054337.
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Li, Ziming, Xiaomin Dang, Dingzhi Huang, Shi Jin, Weiwei Li, Jianhua Shi, Xicheng Wang et al. "Abstract CT246: Open-label, single-arm, multicenter, phase 2 trial of garsorasib in KRAS G12C-mutated non-small-cell lung cancer". Cancer Research 84, n. 7_Supplement (5 aprile 2024): CT246. http://dx.doi.org/10.1158/1538-7445.am2024-ct246.
Testo completoAbstract (sommario):
Abstract Background: Garsorasib (D-1553), a potent KRAS G12C inhibitor, has previously demonstrated promising anti-tumor activity in KRAS G12C-mutated non-small-cell lung cancer (NSCLC) in a phase 1 study. Here we present the efficacy and safety of garsorasib in a pivotal phase 2 study. Methods: In this open-label, multicenter, single-arm phase 2 study, patients received garsorasib 600 mg twice daily in 21-day cycles. Eligible criteria included patients with locally advanced or metastatic NSCLC harboring KRAS G12C mutation, who had disease progression after prior anti-PD-(L)1 therapy and platinum-based chemotherapy or intolerance to the above regimens due to toxicity, and had measurable tumor lesions according to the RECIST, v1.1. The primary end point was objective response rate (ORR) evaluated by independent review committee (IRC) per RECIST v1.1. The secondary end points included duration of response (DOR), disease control rate (DCR), time to response (TTR), progression-free survival (PFS), overall survival (OS), and safety. Results: As of November 17, 2023, 123 patients (108 [87.8%] male, median age 64 [range: 33-80], and 11.4%/88.6% ECOG PS 0/1) were enrolled and treated, with a median follow-up of 7.92 months (range, 0.7, 16.5) and a median duration of treatment of 6.24 months (range, 0.7, 15.9). At data cutoff date, 82 patients (66.7%) discontinued treatment, with disease progression (46 patients [37.4%]) being the most common reason. Among 123 patients, IRC confirmed-ORR was 49.6% (61/123, 95% CI, 40.5 to 58.8) and DCR was 88.6% (109/123, 95% CI, 81.6 to 93.6). The median TTR was 1.38 months (range, 1.12 to 5.55). The median DOR was 12.78 months (95% CI, 6.21 to NE). The median PFS was 7.56 months (95% CI, 5.55 to 9.69), and the median OS was not reached. A total of 117 (95.1%) patients reported treatment-related adverse events (TRAEs) with 61 (49.6%) patients experiencing grade 3 or higher events. The most commonly reported (≥25%) TRAEs (any grade) were increased AST, ALT and γ-GGT, anemia, increased blood bilirubin, and increased blood ALP. No new safety signals were identified, and most of the adverse events were well managed. No TRAE resulted in permanent discontinuation of garsorasib. Conclusions: Garsorasib has shown a high tumor response rate and long response duration in patients with KRAS G12C mutated NSCLC that have progressed after prior anti-PD-(L)1 therapy and platinum-based chemotherapy. Its safety profile was also shown to be well-tolerated and manageable. Garsorasib could be considered as a promising treatment option for KRAS G12C-mutant NSCLC patients with a high unmet medical need. Citation Format: Ziming Li, Xiaomin Dang, Dingzhi Huang, Shi Jin, Weiwei Li, Jianhua Shi, Xicheng Wang, Yiping Zhang, Zhengbo Song, Junping Zhang, Wu Zhuang, Xuewen Liu, Liyan Jiang, Xiangjiao Meng, Mingfang Zhao, Jianying Zhou, Liangming Zhang, Pingli Wang, Hui Luo, Junquan Yang, Shundong Cang, Xiang Wang, Jing Wang, Jiuwei Cui, Yan Yu, Zhihong Zhang, Junguo Lu, Weihua Yang, Gaofeng Li, Jifeng Feng, Dongqing Lv, Lin Wu, Yong Fang, Yan Wang, Yanqiu Zhao, Baoshan Cao, Wei Zhu, Zhixiang Zhuang, Qingshan Li, Mingxi Wang, Huan Zhou, Xiaorong Dong, Sheng Hu, Jian Fang, Yihong Zhang, Wenjia Wang, Ziyong Xiang, Zhe Shi, Ling Zhang, Shun Lu. Open-label, single-arm, multicenter, phase 2 trial of garsorasib in KRAS G12C-mutated non-small-cell lung cancer [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 2 (Late-Breaking, Clinical Trial, and Invited Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(7_Suppl):Abstract nr CT246.
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Su, Guan-Hua, Yi Xiao, Chao You, Ren-Cheng Zheng, Shen Zhao, He Wang, Yi-Zhou Jiang, Ya-Jia Gu e Zhi-Ming Shao. "Abstract PO1-07-11: Radiogenomic-based imaging intratumor heterogeneity model predicts breast cancer prognosis and unveils therapeutic targets". Cancer Research 84, n. 9_Supplement (2 maggio 2024): PO1–07–11—PO1–07–11. http://dx.doi.org/10.1158/1538-7445.sabcs23-po1-07-11.
Testo completoAbstract (sommario):
Abstract Background: Intratumor heterogeneity (ITH) refers to variations observed among cancer cells within a single tumor, posing significant challenges in clinical practice due to its contribution to treatment resistance and unfavorable outcome. However, the inconvenience of multi-region biopsy and limitations of genomic sequencing based on limited tissue impede the practical detection of ITH. Consequently, there is an urgent need for a non-invasive method that comprehensively captures ITH from a holistic perspective of the entire tumor. Methods: We utilized a large multicenter dataset comprising dynamic contrast-enhanced magnetic resonance images from breast cancer patients (n = 1423) along with matched multiomics data (n = 468) to develop a non-invasive machine learning approach for measuring ITH. We extracted quantitative radiomic features from both the entire tumor and peritumor regions, with a specific focus on features associated with imaging heterogeneity. Using these radiomic features, we established an imaging ITH (IITH) model. The robustness of IITH evaluation was determined by assessing its correlation with genomic ITH (employing the mutant-allele tumor heterogeneity [MATH] algorithm) and pathological cellular ITH (analyzing variation in quantitative nuclear features extracted through digital pathology). Prognostic power was evaluated using Kaplan-Meier and multivariate Cox proportional hazards analyses. Integrated multiomics analyses were performed to investigate the molecular basis of different IITH subgroups. Results: We developed a non-invasive radiomic signature to quantify imaging ITH (IITH) in the FUSCC cohort. Breast cancer patients were retrospectively categorized into high and low IITH groups. Multivariate Cox analysis identified high IITH as an independent predictor of poor prognosis in breast cancer patients, even after adjusting for clinical risk factors such as tumor size, positive lymph nodes, clinical subtype and lymphovascular invasion status. These findings were further validated in the DUKE cohort, confirming the prognostic value of IITH. Moreover, we substantiated the robustness of IITH by demonstrating its association with genomic and pathological ITH. Multiomics analysis revealed the activation of oncogenic pathways and metabolic dysregulation in high-IITH tumors. Intriguingly, our investigation also highlighted ferroptosis as a vulnerability and potential therapeutic target in high-IITH tumors, which was further supported by evidence from the TCGA cohort. Conclusion: Radiomic-based assessment of ITH provides a non-invasive approach to comprehensively capture ITH and predict the prognosis of breast cancer patients. Targeting ferroptosis may hold promise as a treatment strategy for patients with high IITH. Citation Format: Guan-Hua Su, Yi Xiao, Chao You, Ren-Cheng Zheng, Shen Zhao, He Wang, Yi-Zhou Jiang, Ya-Jia Gu, Zhi-Ming Shao. Radiogenomic-based imaging intratumor heterogeneity model predicts breast cancer prognosis and unveils therapeutic targets [abstract]. In: Proceedings of the 2023 San Antonio Breast Cancer Symposium; 2023 Dec 5-9; San Antonio, TX. Philadelphia (PA): AACR; Cancer Res 2024;84(9 Suppl):Abstract nr PO1-07-11.
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Ma, Shanshan, Shicong Geng, Guofeng Wang, Shuo Yang e Yu Gao. "Study on pollution of different tributaries of Bai Ta Pu river based on principal component analysis". E3S Web of Conferences 143 (2020): 02010. http://dx.doi.org/10.1051/e3sconf/202014302010.
Testo completoAbstract (sommario):
On the basis of understanding the indexes of different tributaries of Bai Ta Pu river and according to the contribution rate of each principal component, the comprehensive score of different tributaries was calculated through principal component analysis. Each tributary was ranked according to the score, and the evaluation results were analyzed. It is pointed out that the tributary with the highest comprehensive index of Bai Ta Pu river is in Shi Jia Zhai bridge and the tributary with the lowest comprehensive index is in De Sheng Tun bridge.
Tesi sul tema "Zhao sheng zhi du"
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Steacy, David. "Zhengyi Tianshi gao Zhao Sheng kouje The Celestial Masters of Orthodox unity gives Zhao Sheng oral instruction: a translation and analysis". Thesis, McGill University, 2012. http://digitool.Library.McGill.CA:80/R/?func=dbin-jump-full&object_id=110656.
Testo completoAbstract (sommario):
This study translates and examines an early Daoist text called "The Celestial Master of Orthodox Unity Gives Zhao Sheng Oral Instructions," likely written in the late 4th century C.E. It attempts to understand what the writing of this particular text reveals about its political and religious circumstances, including tentative attitudes among clergy, instability for members, and general political uncertainty, all of which are viewed in light of the two Chinese theocracies to have existed. It is necessary to first establish an acceptable date of authorship in order to relate the text to the circumstances of influence. Specific attention is given to the themes most prominently developed in the text, such as Celestial Master Daoism; millenarian traditions; eremitism, and talismans and registers. Following is an original annotated translation of the text. Analysis compares this work with other Celestial Master Daoist texts, some earlier and some later than the central piece, all with similar themes, yet employing different tactics to convey their meaning.It is the hypothesis of this study that there is an implicit connection between political action and early Celestial Master Daoism that is borne out in a variety of ways, this text being one of them.La présente étude porte sur la traduction et l'examen d'un ancien texte taoïste intitulé « Le maître céleste de l'unité orthodoxe donne ses instructions orales à Zhao Sheng », lequel fut vraisemblablement rédigé vers la fin du quatrième siècle de notre ère. À plus forte raison, elle permet de mieux appréhender ce que le texte lui-même révèle à propos des circonstances politiques et religieuses ayant conduit à sa rédaction. Notamment, y sont abordées les attitudes au sein du clergé, l'instabilité de ses membres ainsi que le contexte d'incertitude politique, lesquels sont autant d'aspects interprétés à la lumière des deux régimes théocratiques chinois jadis instaurés. Afin d'établir la liaison entre ledit texte et ses influences circonstancielles, il est dans un premier temps indispensable d'établir la date et la paternité de l'œuvre. Une attention particulière sera ainsi prêtée aux principaux thèmes abordés dans le texte, à savoir la tradition taoïste des Maîtres célestes, le millénarisme, l'hermétisme, les talismans ainsi que les registres. Par la suite, le lecteur trouvera une traduction annotée inédite du texte. Le volet analytique de la traduction consiste notamment en une comparaison entre cette œuvre et les autres textes hérités des Maîtres célestes, qu'ils fussent antérieurs ou postérieurs, lesquels, bien que discutant de thèmes similaires, emploient différents moyens pour transmettre leur sens profond.L'hypothèse de cette étude est donc qu'il y avait une relation implicite entre l'action politique et la tradition taoïste des Maîtres célestes à ses débuts, une relation qui se manifestait de diverses manières, entre autres par le biais du texte au cœur de la présente enquête.
2
Yiu, Kai-bun. "The thought of Seng Zhao (384-414) as seen in Zhao Lun Cong "Zhao lun" kan Sengzhao zhi si xiang /". Click to view the E-thesis via HKUTO, 1989. http://sunzi.lib.hku.hk/hkuto/record/B31949757.
Testo completo
3
Liu, Zhi Zhao [Verfasser]. "Renal vascular function and contrast media induced acute kidney injury / Zhi Zhao Liu". Berlin : Medizinische Fakultät Charité - Universitätsmedizin Berlin, 2013. http://d-nb.info/1042657602/34.
Testo completo
4
Yuen, Sin-ying, e 阮善盈. "Development of school for children with physical disability in Hong Kong = Xianggang zhi ti shang can xue xiao jiao yu de fa zhan". Thesis, The University of Hong Kong (Pokfulam, Hong Kong), 2013. http://hdl.handle.net/10722/193006.
Testo completoAbstract (sommario):
This study aims at the development of School for Children with Physical Disability in Hong Kong. From the first hospital school established by Hong Kong Red Cross those children studied in a ward, to seven well-equipped Special Schools for Children with Physical Disability that many of children with Physical Disability have been benefited. However, there are no structured literatures that could illustrate the history.
This study try to find out the major stakeholders, Sponsoring Bodies and Hong Kong Government, their roles and interaction between them in the sixty years history of the development of School for Children with Physical Disability in Hong Kong. The history has divided into five periods, which presented in Chapter Four. In Chapter Five, based on the history presented in Chapter Four, these historical, social and economical factors affecting the decision making of Sponsoring Bodies and Hong Kong Government would be examined. It is found that the influence of Sponsoring Bodies has being weakened during those sixty years, while the influence of Hong Kong Government has been strengthening. However, the changing damage the relationship between them, it might not lead a better future for the development of School for Children with Physical Disability in Hong Kong.published_or_final_version
Chinese Historical Studies
Master
Master of Arts
5
Cheng, Wing Kin. "Mou Zongsan xian sheng li jie Laozi zhe xue de ping xi : dui "zhi de zhi jue" he "zong guan" liang gai nian zhi tan tao /". View abstract or full-text, 2009. http://library.ust.hk/cgi/db/thesis.pl?HUMA%202009%20CHENG.
Testo completo
6
Ye, Guohua. "Shen jing gen xing jing zhui bing sheng huo zhi su tiao cha ji qi shou fa zhi liao yan jiu /". click here to view the abstract and table of contents, 2006. http://net3.hkbu.edu.hk/~libres/cgi-bin/thesisab.pl?pdf=b20009549a.pdf.
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Chen, Kwan-ho. "Lu Shiyi (1611-1672) : his life and ideas of statecraft = Lu shi yi zhi sheng ping ji qi zhi guo si xiang /". Hong Kong : University of Hong Kong, 1999. http://sunzi.lib.hku.hk/hkuto/record.jsp?B24702122.
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Mak, Yan Yan. "Cong xiao shuo dao dian ying : lun "Qing cheng zhi lian" yu "Ban sheng yuan" /". View Abstract or Full-Text, 2002. http://library.ust.hk/cgi/db/thesis.pl?HUMA%202002%20MAK.
Testo completoAbstract (sommario):
Thesis (M.Phil.)--Hong Kong University of Science and Technology, 2002.Includes bibliographical references (leaves 276-289). Also available in electronic version. Access restricted to campus users.
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Chen, Yongshen. "Zhang zhe xi gu guan jie yan dui sheng huo zhi su de ying xiang ji xiang guan Zhong yi zhi liao yan jiu /". click here to view the abstract and table of contents, 2006. http://net3.hkbu.edu.hk/~libres/cgi-bin/thesisab.pl?pdf=b20009355a.pdf.
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Tse, Chun-yip. "The political career of Yang Yiqing (1454-1530) Yang Yiqing zheng zhi sheng ya yan jiu /". Click to view the E-thesis via HKUTO, 2009. http://sunzi.lib.hku.hk/hkuto/record/B41634044.
Testo completoLibri sul tema "Zhao sheng zhi du"
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Zuo, Tian. Ma jiang shi zhan zhi sheng bai zhao. 8a ed. Beijing: Ren min ti yu chu ban she, 1999.
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tian, Wang yi. San hu bi sheng 100 zhao. Guang zhou: Guang dong jing ji chu ban she, 2001.
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Yang, Yiqing. Zhe shang zhi zhao. Hangzhou: Zhejiang ren min chu ban she, 2003.
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yan, Yang, e Mai ke bu lai de. 20 zhao guan li zhi sheng. Bei jing: Jing ji ri bao chu ban she, 2002.
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Yaodong, Lu. zhi sheng xia dan zhao fan. 8a ed. Taibei Shi: Yuan shen chu ban she, 1987.
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Gong gong ying yang shi jiao yan zu, a cura di. Zai sheng zhe li: Xian ni lei de, xun zhao sheng ming zhi yuan de yang sheng zhi dao. Beijing: Beijing yi shu yu ke xue dian zi chu ban she, 2006.
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Cheng, Leqing. Zhang shou yang sheng xiao miao zhao. Qing dao: Qing dao chu ban she, 2017.
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Sunzi, active 6th century B.C. e Zhuo Kunfeng 1962-, a cura di. Sunzi shang zhan bing fa 13 zhao: Zhi hui xing shang ye zhan zheng de zhi sheng li qi. 6a ed. Taibei Shi: Wang wen she gu fen you xian gong si, 1992.
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Sunzi, 6th cent. B.C. e Zhuo Kunfeng 1962-, a cura di. Sunzi shang zhan bing fa 13 zhao: Zhi hui xing shang ye zhan zheng de zhi sheng li qi. 6a ed. Taibei Shi: Wang wen she gu fen you xian gong si, 1992.
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Wang, Chong. Zhi sheng qi zhao sun zi bing fa. Taiwan: Sitak, 2002.
Cerca il testo completoCapitoli di libri sul tema "Zhao sheng zhi du"
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"Industrial restructuring and urban spatial transformation in Xi’an: Huaiting Yin, Xiaoping Shen and Zhe Zhao". In Restructuring the Chinese City, 155–71. Routledge, 2004. http://dx.doi.org/10.4324/9780203414460-16.
Testo completo
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Taber, Douglass F. "Organocatalyzed C–C Ring Construction: The Bradshaw/Bonjoch Synthesis of (−)-Cermizine B". In Organic Synthesis. Oxford University Press, 2017. http://dx.doi.org/10.1093/oso/9780190646165.003.0071.
Testo completoAbstract (sommario):
In a continuation of his studies (OHL20141229, OHL20140811) of organocatalyzed 2+2 photocycloaddition, Thorsten Bach of the Technische Universität München assembled (Angew. Chem. Int. Ed. 2014, 53, 7661) 3 by adding 2 to 1. Li-Xin Wang of the Chengdu Institute of Organic Chemistry also used (Org. Lett. 2014, 16, 6436) an organocatalyst to effect the addition of 5 to 4 to give 6. Shuichi Nakamura of the Nagoya Institute of Technology devised (Org. Lett. 2014, 16, 4452) an organocatalyst that mediated the enantioselective opening of the aziridine 7 to 8. Zhi Li of the National University of Singapore cloned (Chem. Commun. 2014, 50, 9729) an enzyme from Acinetobacter sp. RS1 that reduced 9 to 10. Gregory C. Fu of Caltech developed (Angew. Chem. Int. Ed. 2014, 53, 13183) a phosphine catalyst that directed the addition of 12 to 11 to give 13. Armido Studer of the Westfälische Wilhelms-Universität Münster showed (Angew. Chem. Int. Ed. 2014, 53, 9622) that 15 could be added to 14 to give 16 in high ee. Akkattu T. Biju of CSIR-National Chemical Laboratory described (Chem. Commun. 2014, 50, 14539) related results. The photostimulated enantioselective ketone alkylation developed (Chem. Sci. 2014, 5, 2438) by Paolo Melchiorre of ICIQ was powerful enough to enable the alkylation of 17 with 18 to give 19, overcoming the stereoelectronic preference for axial bond formation. David W. Lupton of Monash University established (J. Am. Chem. Soc. 2014, 136, 14397) the organocatalyzed transformation of the dienyl ester 20 to 21. James McNulty of McMaster University added (Angew. Chem. Int. Ed. 2014, 53, 8450) azido acetone 23 to 22 to give 24 in high ee. There are sixteen enantiomerically-pure diastereomers of the product 27. John C.-G. Zhao of the University of Texas at San Antonio showed (Angew. Chem. Int. Ed. 2014, 53, 7619) that with the proper choice of organocatalyst, with or without subsequent epimerization, it was possible to selectively prepare any one of eight of those diastereomers by the addition of 26 to 25. William P. Malachowski of Bryn Mawr College showed (Tetrahedron Lett. 2014, 55, 4616) that 28, readily prepared by a Birch reduction protocol, was converted by heating followed by exposure to catalytic Me3P to the angularly-substituted octalone 29.
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Taber, Douglass F. "Organocatalyzed C–C Ring Construction: The Mihovilovic Synthesis of Piperenol B". In Organic Synthesis. Oxford University Press, 2017. http://dx.doi.org/10.1093/oso/9780190646165.003.0072.
Testo completoAbstract (sommario):
M. Kevin Brown of Indiana University prepared (J. Am. Chem. Soc. 2015, 137, 3482) the cyclobutane 3 by the organocatalyzed addition of 2 to the alkene 1. Karl Anker Jørgensen of Aarhus University assembled (J. Am. Chem. Soc. 2015, 137, 1685) the complex cyclobutane 7 by the addition of 5 to the acceptor 4, followed by condensation with the phosphorane 6. Zhi Li of the National University of Singapore balanced (ACS Catal. 2015, 5, 51) three enzymes to effect enantioselective opening of the epoxide 8 followed by air oxidation to 9. Gang Zhao of the Shanghai Institute of Organic Chemistry and Zhong Li of the East China University of Science and Technology added (Org. Lett. 2015, 17, 688) 10 to 11 to give 12 in high ee. Akkattu T. Biju of the National Chemical Laboratory combined (Chem. Commun. 2015, 51, 9559) 13 with 14 to give the β-lactone 15. Paul Ha-Yeon Cheong of Oregon State University and Karl A. Scheidt of Northwestern University reported (Chem. Commun. 2015, 51, 2690) related results. Dieter Enders of RWTH Aachen University constructed (Chem. Eur. J. 2015, 21, 1004) the complex cyclopentane 20 by the controlled combination of 16, 17, and 18, followed by addition of the phosphorane 19. Derek R. Boyd and Paul J. Stevenson of Queen’s University Belfast showed (J. Org. Chem. 2015, 80, 3429) that the product from the microbial oxidation of 21 could be protected as the acetonide 22. Ignacio Carrera of the Universidad de la República described (Org. Lett. 2015, 17, 684) the related oxidation of benzyl azide (not illustrated). Manfred T. Reetz of the Max-Planck-Institut für Kohlenforschung and the Philipps-Universität Marburg found (Angew. Chem. Int. Ed. 2014, 53, 8659) that cytochrome P450 could oxidize the cyclohexane 23 to the cyclohexanol 24. F. Dean Toste of the University of California, Berkeley aminated (J. Am. Chem. Soc. 2015, 137, 3205) the ketone 25 with 26 to give 27. Benjamin List, also of the Max-Planck-Institut für Kohlenforschung, reported (Synlett 2015, 26, 1413) a parallel investigation. Philip Kraft of Givaudan Schweiz AG and Professor List added (Angew. Chem. Int. Ed. 2015, 54, 1960) 28 to 29 to give 30 in high ee.
Atti di convegni sul tema "Zhao sheng zhi du"
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"Awarding Rules for "Guan Zhao-Zhi Award"". In 2007 Chinese Control Conference. IEEE, 2006. http://dx.doi.org/10.1109/chicc.2006.4347635.
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"Awarding Rules for "Guan Zhao-Zhi Award"". In 2006 Chinese Control Conference. IEEE, 2006. http://dx.doi.org/10.1109/chicc.2006.280552.
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"Awarding rules for #x201C;Guan Zhao-Zhi Award#x201D;". In 2008 27th Chinese Control Conference. IEEE, 2008. http://dx.doi.org/10.1109/chicc.2008.4605904.
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Xiaozhi Wang and Neil Pegg, ISSC 2022 Editors. "Proceedings of the 21st International Ship and Offshore Structures Congress VOLUME 1 Technical Committee Reports". In 21st International Ship and Offshore Structures Congress, Volume 1. SNAME, 2022. http://dx.doi.org/10.5957/issc-2022-committee-vol-1.
Testo completoAbstract (sommario):
Preface The first volume contains the eight Technical Committee reports, and the second volume contains the reports of the eight Specialist Committees, presented and discussed at the 21st International Ship and Offshore Structures Congress (ISSC 2022) in Vancouver (Canada), on September 11–15, 2022. The Official Discussers’ reports and all floor discussions, including the replies by the committees, will be published after the Congress in electronic form. Table of Contents Preface .............................................................................................................iii Committee I.1: Environment .........................................................................1 Alexander Babanin (Chair); Mariana Bernardino; Franz von Bock und Polach; Ricardo Campos,; Jun Ding; Sanne van Essen; Tomaso Gaggero; Maryam Haroutunian; Vanessa Katsardi; Alexander Nilva; Arttu Polojarvi; Erik Vanem; Jungyong Wang; Huidong Zhang; Tingyao Zhu Committee I.2: Loads ................................................................................125 Ole Andreas Hermundstad (Chair); Shuhong Chai; Guillaume de Hauteclocque; Sheng Dong; Chih-Chung Fang; Thomas B. Johannessen; Celso Morooka; Masayoshi Oka; Jasna Prpić-Oršić; Alessandro Sacchet; Mahmud Sazidy; Bahadir Ugurlu; Roberto Vettor; Peter Wellens Committee II-1: Quasi-Static Response ....................................................227 James Underwood (Chair); Erick Alley; Jerolim Andrić; Dario Boote; Zhen Gao; Ad Van Hoeve; Jasmin Jelovica; Yasumi Kawamura; Yooil Kim; Jianhu Liu; Sime Malenica; Heikki Remes; Asokendu Samanta; Krzysztof Woloszyk; Deqing Yang Committee II.2: Dynamic Response .........................................................301 Gaute Storhaug (Chair); Daniele Dessi; Sharad Dhavalikar; Ingo Drummen; Michael Holtmann; Young-Cheol Huh; Lorenzo Moro; Andre Paiva; Svein Sævik; Rong-Juin Shyu; Shan Wang; Sue Wang; WenWei Wu; Yasuhira Yamada; Guiyong Zhang Committee III.1: Ultimate Strength ...........................................................395 Paul E. Hess (Chair); Chen An; Lars Brubak; Xiao Chen; Jinn Tong Chiu; Jurek Czujko; Ionel Darie; Guoqing Feng; Marco Gaiotti; Beom Seon Jang; Adnan Kefal; Sukron Makmun; Jonas Ringsberg; Jani Romanoff; Saad Saad-Eldeen; Ingrid Schipperen; Kristjan Tabri; Yikun Wang; Daisuke Yanagihara Committee III.2: Fatigue and Fracture ......................................................501 Yordan Garbatov (Chair); Sigmund K Ås; Henk Den Besten; Philipp Haselbach; Adrian Kahl; Dale Karr; Myung Hyun Kim; Junjie Liu; Marcelo Igor Lourenço de Souza; Wengang Mao; Eeva Mikkola; Naoki Osawa; Fredhi Agung Prasetyo; Mauro Sicchiero; Suhas Vhanmane; Marta Vicente del Amo; Jingxia Yue Committee IV.1: Design Principles and Criteria .......................................643 Matthew Collette (Chair); Piero Caridis; Petar Georgiev; Torfinn Hørte; Han Koo Jeong; Rafet emek Kurt; Igor Ilnytskiy; Tetsuo Okada; Charles Randall; Zbigniew Sekulski; Matteo Sidari; Zhihu Zhan; Ling Zhu Committee IV.2: Design Methods .............................................................745 Andrea Ivaldi (Chair); Abbas Bayatfar; Jean-David Caprace; Gennadiy Egorov; Svein Erling Heggelund; Shinichi Hirakawa; Jung Min Kwon; Dan Mcgreer; Pero Prebeg; Robert Sielski; Mark Slagmolen; Adam Sobey; Wenyong Tang; Jiameng Wu Subject Index .............................................................................................815 Author Index ...............................................................................................817
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Xiaozhi Wang and Neil Pegg, ISSC 2022 Editors. "Proceedings of the 21st International Ship and Offshore Structures Congress VOLUME 3 Discussions". In 21st International Ship and Offshore Structures Congress Volume 3 Discussions. SNAME, 2022. http://dx.doi.org/10.5957/issc-2022-discussion-vol-3.
Testo completoAbstract (sommario):
Committee I.1: Environment Alexander Babanin (Chair); Mariana Bernardino; Franz von Bock und Polach; Ricardo Campos,; Jun Ding; Sanne van Essen; Tomaso Gaggero; Maryam Haroutunian; Vanessa Katsardi; Alexander Nilva; Arttu Polojarvi; Erik Vanem; Jungyong Wang; Huidong Zhang; Tingyao Zhu Floor Discussers: Florian Sprenger; Carlos Guedes Soares; Henk den Besten Committee I.2: Loads Ole Andreas Hermundstad (Chair); Shuhong Chai; Guillaume de Hauteclocque; Sheng Dong; Chih-Chung Fang; Thomas B. Johannessen; Celso Morooka; Masayoshi Oka; Jasna Prpić-Oršić; Alessandro Sacchet; Mahmud Sazidy; Bahadir Ugurlu; Roberto Vettor; Peter Wellens Official Discusser: Hayden Marcollo Committee II-1: Quasi-Static Response James Underwood (Chair); Erick Alley; Jerolim Andrić Dario Boote; Zhen Gao; Ad Van Hoeve; Jasmin Jelovica; Yasumi Kawamura; Yooil Kim; Jian Hu Liu; Sime Malenica; Heikki Remes; Asokendu Samanta; Krzysztof Woloszyk; Deqing Yang Official Discusser: Prof. T. Yoshikwa Committee II.2: Dynamic Response Gaute Storhaug (Chair); Daniele Dessi; Sharad Dhavalikar; Ingo Drummen; Michael Holtmann; Young-Cheol Huh; Lorenzo Moro; Andre Paiva; Svein Sævik; Rong-Juin Shyu; Shan Wang; Sue Wang; WenWei Wu; Yasuhira Yamada; Guiyong Zhang Floor Discussers: Ling Zhu; Tomoki Takami; Anriette (Annie) Bekker; Bruce Quinton; Robert Sielski Committee III.1: Ultimate Strength Paul E. Hess (Chair); Chen An; Lars Brubak; Xiao Chen; Jinn Tong Chiu; Jurek Czujko; Ionel Darie; Guoqing Feng; Marco Gaiotti; Beom Seon Jang; Adnan Kefal; Sukron Makmun; Jonas Ringsberg; Jani Romanoff; Saad Saad-Eldeen; Ingrid Schipperen; Kristjan Tabri; Yikun Wang; Daisuke Yanagihara Official Discusser: Jørgen Amdahl Committee III.2: Fatigue and Fracture Yordan Garbatov (Chair); Sigmund K Ås; Henk Den Besten; Philipp Haselbach; Adrian Kahl; Dale Karr; Myung Hyun Kim; Junjie Liu; Marcelo Igor Lourenço de Souza; Wengang Mao; Eeva Mikkola; Naoki Osawa; Fredhi Agung Prasetyo; Mauro Sicchiero; Suhas Vhanmane; Marta Vicente del Amo; Jingxia Yue Official Discusser Weicheng Cui Floor Discussers: Robert Sielski; Sören Ehlers; Stephane Paboeuf; Teresa Magoga Committee IV.1: Design Principles and Criteria Matthew Collette (Chair); Piero Caridis; Petar Georgiev; Torfinn Hørte; Han Koo Jeong; Rafet emek Kurt; Igor Ilnytskiy; Tetsuo Okada; Charles Randall; Zbigniew Sekulski; Matteo Sidari; Zhihu Zhan; Ling Zhu Official Discusser: Enrico Rizzuto Committee IV.2: Design Methods Andrea Ivaldi (Chair); Abbas Bayatfar; Jean-David Caprace; Gennadiy Egorov; Svein Erling Heggelund; Shinichi Hirakawa; Jung Min Kwon; Dan Mcgreer; Pero Prebeg; Robert Sielski; Mark Slagmolen; Adam Sobey; Wenyong Tang; Jiameng Wu Official Discusser: Mario Dogliani Committee V.1: Accidental Limit States Bruce Quinton; Gaetano De Luca; Topan Firmandha; Mihkel Körgesaar; Hervé Le Sourne; Ken Nahshon; Gabriele Notaro; Kourosh Parsa; Smiljko Rudan; Katsuyuki Suzuki; Osiris Valdez Banda; CareyWalters; Deyu Wang; Zhaolong Yu Official Discusser: Manolis Samuelides Committee V.2: Experimental Methods Sören Ehlers (Chair); Nagi Abdussamie; Kim Branner; ShiXiao Fu; Martijn Hoogeland; Kari Kolari; Paul Lara; Constantine Michailides; Hideaki Murayama; Cesare Rizzo; Jung Kwan Seo; Patrick Kaeding Official Discusser: Giles Thomas Committee V.3: Materials and Fabrication Technology Lennart Josefson (Chair); Konstantinos Anyfantis; Bianca de Carvalho Pinheiro; Bai-Qiao Chen; Pingsha Dong; Nicole Ferrari; Koji Gotoh; James Huang; Matthias Krause; Kun Liu; Stephane Paboeuf; Stephen van Duin; Fang Wang; Albert Zamarin Official Discusser: Frank Roland Floor Discussers Alessandro Caleo; Agnes Marie Horn; Krzysztof Woloszyk; Robert Sielski Committee V.4: Offshore Renewable Energy Atanasios Kolios (Chair); Kyong-Hwan Kim; Chen Hsing Cheng; Elif Oguz; Pablo Morato; Freeman Ralph; Chuang Fang; Chunyan Ji; Marc Le Boulluec; Thomas Choisnet; Luca Greco; Tomoaki Utsunomiya; Kourosh Rezanejad; Charles Rawson; Jose Miguel Rodrigues Official Discusser: Amy Robertson Committee V.5: Special Vessels Darren Truelock (Chair); Jason Lavroff; Dustin Pearson; Zbigniew (Jan) Czaban; Hanbing Luo; Fuhua Wang; Ivan Catipovic; Ermina Begovic; Yukichi Takaoka; Claudia Loureiro; Chang Yong Song; Esther Garcia; Alexander Egorov; Jean-Baptiste Souppez; Pradeep Sensharma; Rachel Nicholls-Lee Official Discusser: Jaye Falls Floor Discussers: Jasmin Jelovica; Stephane Paboeuf; Sören Ehlers Committee V.6: Ocean Space Utilization Sebastian Schreier (Chair); Felice Arena; Harry Bingham; Nuno Fonseca; Zhiqiang Hu; Debabrata Karmakar; Ekaterina Kim; Hui Li; Pengfei Liu; Motohiko Murai; Spiro J Pahos; Chao Tian; George Wang Official Discusser: Hideyuki Suzuki Floor Discussers: Robert Sielski; Sue Wang; Sarat Mohapatra; Gaute Storhaug; Henk den Besten Committee V.7: Structural Longevity Iraklis Lazakis (Chair); Bernt Leira; Nianzhong Chen; Geovana Drumond; Chi-Fang Lee; Paul Jurisic; Bin Liu; Alysson Mondoro; Pooria Pahlavan; Xinghua Shi; Ha Cheol Song; Tadashi Sugimura; Christian Jochum; Tommaso Coppola Official Discusser: Timo de Beer Floor Discusser: Krzysztof Woloszyk Committee V.8: Subsea Technology Agnes Marie Horn (Chair); Tauhid Rahman; Ilson Pasqualino; Menglan Duan; Zhuang Kang; Michael Rye Andersen; Yoshihiro Konno; Chunsik Shim; Angelo Teixeira; Selda Oterkus; Blair Thornton; Brajendra Mishra Official Discusser: Segen F. Estefen