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  4. Design of cascading two stages of high gain harmonic generation scheme based on Shanghai deep ultraviolet free electron laser

中国物理C, 2008, 32(3): 236-242.

1, , 2,

1.Shanghai Institute of Applied Physics, CAS, Shanghai 201800, China;Graduate University of Chinese Academy of Sciences,Beijing 100049,china

C涂层对界面行为的影响.结果表明,C涂层可以明显改善纤维和基体之间的界面结合状况;SiC/C/Ti-6Al-4V复合材料的界面反应产物是主要为TiC,而无C涂层SiC/Ti-6Al-4V的界面反应产物为TiC,Ti5Si3和Ti3SiC2界面反应层生长受扩散控制,其厚度增长满足抛物线生长规律,SiC/C/Ti-6Al-4V由于C涂层消耗完毕前后的不同情况,其界面反应层生长并不完全符合这一规律,C涂层的存在可以有效的抑制界面反应的进行.","authors":[{"authorName":"罗恒军","id":"a831a13e-0c4a-4a2d-9099-bdaaf8995924","originalAuthorName":"罗恒军"},{"authorName":"杨延清","id":"254b5975-c7e4-4644-9fb5-27df0c7fe2ee","originalAuthorName":"杨延清"},{"authorName":"黄斌","id":"5121c937-0b7e-49a2-bce3-e484a6a16800","originalAuthorName":"黄斌"},{"authorName":"罗贤","id":"0cbd1826-5097-4433-88f0-4903a9d11c07","originalAuthorName":"罗贤"},{"authorName":"原梅妮","id":"19142aa3-52c2-41dc-a7c0-d8206234f909","originalAuthorName":"原梅妮"}],"doi":"10.3969/j.issn.1001-4381.2009.03.004","fpage":"13","id":"3039e0e8-1962-431e-9f11-83dcc21a240e","issue":"3","journal":{"abbrevTitle":"CLGC","coverImgSrc":"journal/img/cover/CLGC.jpg","id":"9","issnPpub":"1001-4381","publisherId":"CLGC","title":"材料工程"},"keywords":[{"id":"338fac78-ae46-42fc-982a-61100d538ec0","keyword":"复合材料","originalKeyword":"复合材料"},{"id":"9f250753-1c2c-45d8-b2ac-b4ec013681b9","keyword":"SiC纤维","originalKeyword":"SiC纤维"},{"id":"11775ef6-eb5b-46f2-a3f5-a3b527073cc2","keyword":"C涂层","originalKeyword":"C涂层"},{"id":"b23775b1-dc01-4ade-9cb8-45beaa5dcafb","keyword":"界面","originalKeyword":"界面"}],"language":"zh","publisherId":"clgc200903004","title":"C涂层对SiC纤维增强Ti基复合材料界面的影响","volume":"","year":"2009"},{"abstractinfo":"采用化学气相沉积(CVD)法,在SiC纤维表面沉积了100nm厚的C涂层,研究了制备温度对C涂层微观结构、单丝纤维体电导率及纤维编制体介电性能的影响.采用SEM和RAM显微技术(Raman microscopy)对C涂层的表面形貌和微观结构进行分析.结果表明:保持C涂层厚度一致,当沉积温度由800℃升到900℃后,C涂层的石墨化程度提高,晶粒变大,SiC纤维单丝体电导率由0.745Ω~(-1)·cm~(-1)升到6.289Ω~(-1)·cm~(-1);SiC纤维编制体的复介电常数实部由90升到132,介电损耗由0.95升到1.14,其中虚部由87升到150.实部增大与载流子浓度增大有关,虚部增大与材料漏导电有关.认为这是SiC纤维表面沉积的C层使纤维电导率增大所致.直流电导损耗足其主要损耗机制.","authors":[{"authorName":"郑文景","id":"90cdd581-07bf-4e60-95ae-3d68b545c93e","originalAuthorName":"郑文景"},{"authorName":"周万城","id":"210084cf-b935-4de4-963b-2a62bdb40828","originalAuthorName":"周万城"},{"authorName":"罗发","id":"e98fa394-7837-4b60-8c69-1e9728b8119c","originalAuthorName":"罗发"},{"authorName":"于新民","id":"a3ddce70-176d-4b93-88f4-46784ff75faf","originalAuthorName":"于新民"}],"doi":"10.3969/j.issn.1001-4381.2009.11.009","fpage":"36","id":"fa80d6a5-a4a0-443a-bd7e-53a8cc7a16a5","issue":"11","journal":{"abbrevTitle":"CLGC","coverImgSrc":"journal/img/cover/CLGC.jpg","id":"9","issnPpub":"1001-4381","publisherId":"CLGC","title":"材料工程"},"keywords":[{"id":"5c4841cb-be92-4ae1-bf09-ea0afd0b9a3a","keyword":"化学气相沉积(CVD)","originalKeyword":"化学气相沉积(CVD)"},{"id":"cec38bf9-7456-4db1-8a74-dbef6acfafc2","keyword":"SiC纤维","originalKeyword":"SiC纤维"},{"id":"dfa95917-ddc5-4bb8-b613-e2da129e4482","keyword":"C涂层","originalKeyword":"C涂层"},{"id":"1b1c1470-9d09-4174-9de1-1d1b2ba3829b","keyword":"体电导率","originalKeyword":"体电导率"},{"id":"b0d37259-448b-448f-a220-36267bcdd35f","keyword":"拉曼光谱","originalKeyword":"拉曼光谱"},{"id":"fba36306-2012-4ed7-b3ed-e3d14974e269","keyword":"介电性能","originalKeyword":"介电性能"}],"language":"zh","publisherId":"clgc200911009","title":"SiC纤维表面C涂层的制备及介电性能研究","volume":"","year":"2009"},{"abstractinfo":"采用双辉等离子技术分别在抛光、氧化和高温热处理的C/C复合材料表面制备贵金属铱涂层.C/C复合材料和铱涂层的表面微观结构通过扫描电镜观测.结果表明:在抛光的C/C复合材料表面获得沉积较好、覆盖良好的铱涂层,但铱涂层表面出现微裂纹.微裂纹出现是由于较高沉积温度下涂层与基体之间的热膨胀系数不匹配导致的.氧化和高温热处理的C/C复合材料基体表面出现较大间隙和缺陷,铱涂层没能完全覆盖其表面,需多次沉积填满这些缺陷.","authors":[{"authorName":"吴王平","id":"94014718-e4dd-480f-a424-4f1a61610f3b","originalAuthorName":"吴王平"},{"authorName":"陈照峰","id":"d404d6c8-7f1b-4321-bd65-503e9d792475","originalAuthorName":"陈照峰"},{"authorName":"丛湘娜","id":"15bfd770-0343-4db2-a801-d8237214cd34","originalAuthorName":"丛湘娜"}],"doi":"","fpage":"10","id":"97985a8d-3f77-45aa-a832-873b8ae8446e","issue":"3","journal":{"abbrevTitle":"GJS","coverImgSrc":"journal/img/cover/GJS.jpg","id":"38","issnPpub":"1004-0676","publisherId":"GJS","title":"贵金属"},"keywords":[{"id":"99a53eae-524d-41dd-953d-1fc042531aa5","keyword":"复合材料","originalKeyword":"复合材料"},{"id":"2fafb5d6-5d30-418a-bd68-94a3ddc022d0","keyword":"C/C复合材料","originalKeyword":"C/C复合材料"},{"id":"a3876662-4328-4eeb-9a70-4fcda67b9731","keyword":"铱","originalKeyword":"铱"},{"id":"6157b5a3-f76d-4620-bc08-c80ae133b487","keyword":"涂层","originalKeyword":"涂层"},{"id":"a3dbaa91-6538-4111-94de-fd9e8f04e548","keyword":"微观结构","originalKeyword":"微观结构"}],"language":"zh","publisherId":"gjs201203003","title":"C/C复合材料表面铱涂层的研究","volume":"33","year":"2012"},{"abstractinfo":"研制了一种以磷酸、磷酸盐、硼化物等为原材料的磷酸盐涂料,在不同温度下烧结处理后,对其抗氧化性能及表面微观形貌进行研究.结果表明:650℃烧结的涂层氧化防护性能明显优于900℃烧结的;在700℃氧化30 h后,最小氧化失重率仅为1.76%,氧化后涂层仍然保持完整致密;经过900℃、3 min<=>室温、2min循环30次和l 100℃、3 min<=>室温、2 min循环10次的连续热震后,失重率为1.97%,涂层C/C基体结合良好,涂层的热性能稳定.","authors":[{"authorName":"薛宁娟","id":"f945a589-559c-43db-9e0b-8c4e62a07cb3","originalAuthorName":"薛宁娟"},{"authorName":"肖志超","id":"c702384e-a65c-407e-b27d-b8896d23b6e8","originalAuthorName":"肖志超"},{"authorName":"苏君明","id":"54062f39-5304-4db0-b158-5d1af39fbd2a","originalAuthorName":"苏君明"},{"authorName":"孟凡才","id":"b8ba974f-b2b2-4825-b87c-4a1982915c1b","originalAuthorName":"孟凡才"},{"authorName":"彭志刚","id":"e855fddf-a5b7-4405-8c94-b6668ef284a4","originalAuthorName":"彭志刚"}],"doi":"10.3969/j.issn.1007-2330.2009.01.015","fpage":"49","id":"cb1cdbdc-a4a7-40e3-9c89-c96dc5ce709e","issue":"1","journal":{"abbrevTitle":"YHCLGY","coverImgSrc":"journal/img/cover/YHCLGY.jpg","id":"77","issnPpub":"1007-2330","publisherId":"YHCLGY","title":"宇航材料工艺 "},"keywords":[{"id":"0b902e67-314e-481a-9515-60300185602e","keyword":"C/C刹车材料","originalKeyword":"C/C刹车材料"},{"id":"83122214-1741-42d0-9f02-f63b475a1c64","keyword":"抗氧化性能","originalKeyword":"抗氧化性能"},{"id":"16560f0e-f313-44f9-a045-9a2532862974","keyword":"磷酸盐涂层","originalKeyword":"磷酸盐涂层"},{"id":"1bb64184-a3e2-4fbf-bef4-95826dcdc133","keyword":"氧化失重率","originalKeyword":"氧化失重率"}],"language":"zh","publisherId":"yhclgy200901015","title":"C/C刹车材料用抗氧化涂层性能","volume":"39","year":"2009"},{"abstractinfo":"以氯化锌、磷酸、磷酸盐等为原料研制一种新型改性磷酸盐涂料,利用扫描电镜观察涂层C/C复合材料试样氧化前后微观结构形貌的变化,并对比研究改性前后磷酸盐涂料及以硅、硼为主的多组分陶瓷涂料涂层试样的静态防氧化性能、热震性能.结果表明:在500℃氧化100h,这三种涂层均具有良好的氧化防护性能,涂层试样最大失重率仅为1.25%;在700℃氧化30h,以及经过\"900℃、3min<=>室温、2min 30次\"→\"1100℃、3min<=>室温、2min 10次\"的连续热震实验,改性磷酸盐涂层试样的氧化失重率均最小,分别为1.76%和1.98%,远优于另外两种试样.改性磷酸盐涂料具有优异的防氧化性能和抗热震性能.","authors":[{"authorName":"肖志超","id":"43037ed9-8682-482d-957f-33e3139ea7a3","originalAuthorName":"肖志超"},{"authorName":"薛宁娟","id":"fa706c04-264a-4449-81b2-bf252290e5a9","originalAuthorName":"薛宁娟"},{"authorName":"苏君明","id":"dec6bdcb-077e-49bc-bcc6-a5bda2c9e139","originalAuthorName":"苏君明"},{"authorName":"彭志刚","id":"0955db99-f037-4a3f-9e54-bf02983edc94","originalAuthorName":"彭志刚"},{"authorName":"金志浩","id":"bc0878df-8481-4bc0-9d27-4853a0cb11ed","originalAuthorName":"金志浩"},{"authorName":"郝志彪","id":"a736e84e-248b-442a-80d1-14d6acb937b3","originalAuthorName":"郝志彪"}],"doi":"","fpage":"156","id":"18d99380-f885-4d3c-a5e0-772bf3b0ed23","issue":"2","journal":{"abbrevTitle":"XXTCL","coverImgSrc":"journal/img/cover/XXTCL.jpg","id":"70","issnPpub":"1007-8827","publisherId":"XXTCL","title":"新型炭材料"},"keywords":[{"id":"4e78433f-9056-4448-a860-f35f8cd2ed1a","keyword":"C/C复合材料","originalKeyword":"C/C复合材料"},{"id":"a06610ff-37e3-4af1-a103-3c332cb567f2","keyword":"防氧化涂层","originalKeyword":"防氧化涂层"},{"id":"304fc868-f26f-4504-8673-143e513f8d65","keyword":"磷酸盐","originalKeyword":"磷酸盐"}],"language":"zh","publisherId":"xxtcl201002014","title":"C/C复合刹车材料防氧化涂层的性能","volume":"25","year":"2010"},{"abstractinfo":"C/C复合材料在高温下的氧化严重制约了该材料在航空航天领域的推广应用,涂层技术是目前解决该材料高温易氧化的最佳手段.本文综述了C/C复合材料高温抗氧化技术在玻璃涂层、金属涂层、陶瓷涂层和复合涂层等体系方面的研究现状,总结了C/C复合材料高温抗氧化涂层在传统制备工艺的改善以及新方法的开发等方面取得的研究成果,并提出了C/C复合材料高温抗氧化涂层当前研究中存在的问题和今后潜在的发展方向.","authors":[{"authorName":"李贺军","id":"def18e8b-7d30-4038-a338-995678696e19","originalAuthorName":"李贺军"},{"authorName":"薛晖","id":"c7ed9503-7fd7-41de-85e5-6ffa2bb946dd","originalAuthorName":"薛晖"},{"authorName":"付前刚","id":"37266488-ee46-49c0-945a-e6557908ad73","originalAuthorName":"付前刚"},{"authorName":"张雨雷","id":"cb1d4147-b876-41f9-b017-893fa10c7446","originalAuthorName":"张雨雷"},{"authorName":"史小红","id":"5532ebb1-2be5-439d-a86b-efbbe65451f6","originalAuthorName":"史小红"},{"authorName":"李克智","id":"f618f9e3-98d8-4bf6-9517-87af41089ec5","originalAuthorName":"李克智"}],"categoryName":"|","doi":"10.3724/SP.J.1077.2010.00337","fpage":"337","id":"dd932852-6014-4560-822a-279cc96c46af","issue":"4","journal":{"abbrevTitle":"WJCLXB","coverImgSrc":"journal/img/cover/WJCLXB.jpg","id":"62","issnPpub":"1000-324X","publisherId":"WJCLXB","title":"无机材料学报"},"keywords":[{"id":"046731d6-df00-4302-a46b-5cf4fb66a25d","keyword":"C/C复合材料","originalKeyword":"C/C复合材料"},{"id":"609225b4-6058-4ef7-8247-d8fdde05c598","keyword":" coating","originalKeyword":" coating"},{"id":"f7faebbe-4026-47e3-9fe2-6d11522d22e3","keyword":" oxidation","originalKeyword":" oxidation"}],"language":"zh","publisherId":"1000-324X_2010_4_5","title":"C/C复合材料高温抗氧化涂层的研究现状与展望","volume":"25","year":"2010"},{"abstractinfo":"C/C复合材料在高温下的氧化严重制约了该材料在航空航天领域的推广应用,涂层技术是目前解决该材料高温易氧化的最佳手段.本文综述了C/C复合材料高温抗氧化技术在玻璃涂层、金属涂层、陶瓷涂层和复合涂层等体系方面的研究现状,总结了C/C复合材料高温抗氧化涂层在传统制备工艺的改善以及新方法的开发等方面取得的研究成果,并提出了C/C复合材料高温抗氧化涂层当前研究中存在的问题和今后潜在的发展方向.","authors":[{"authorName":"李贺军","id":"5e3966f3-66ee-4a88-9c03-500eeda4d00a","originalAuthorName":"李贺军"},{"authorName":"薛晖","id":"eba8fb97-d610-4552-add4-6a1dcb77aba7","originalAuthorName":"薛晖"},{"authorName":"付前刚","id":"de33bd5d-545f-48ab-858a-837011b6d886","originalAuthorName":"付前刚"},{"authorName":"张雨雷","id":"fc209128-62b0-4050-8a78-47a15d236c34","originalAuthorName":"张雨雷"},{"authorName":"史小红","id":"7d84fee5-104b-4e42-a4a1-405f111e54ac","originalAuthorName":"史小红"},{"authorName":"李克智","id":"19a40626-277a-4a35-8056-a46d838601f5","originalAuthorName":"李克智"}],"doi":"10.3724/SP.J.1077.2010.00337","fpage":"337","id":"fcafe53b-eedd-498e-9648-4a09feb1bfda","issue":"4","journal":{"abbrevTitle":"WJCLXB","coverImgSrc":"journal/img/cover/WJCLXB.jpg","id":"62","issnPpub":"1000-324X","publisherId":"WJCLXB","title":"无机材料学报"},"keywords":[{"id":"37aee2c7-a7f2-4cae-95f2-8123857d6da4","keyword":"C/C复合材料","originalKeyword":"C/C复合材料"},{"id":"edcebcaa-42c7-4c59-9a19-ff6e36a9ca50","keyword":"涂层","originalKeyword":"涂层"},{"id":"d74f9030-de84-4a57-8646-d155306b17cf","keyword":"氧化","originalKeyword":"氧化"}],"language":"zh","publisherId":"wjclxb201004001","title":"C/C复合材料高温抗氧化涂层的研究现状与展望","volume":"25","year":"2010"},{"abstractinfo":"C/C复合材料在高温燃气高速冲刷环境中的严重氧化烧蚀限制了其在航空航天等领域的广泛应用,采用抗烧蚀涂层技术是目前提高该材料高温抗烧蚀性能的有效方法.综述了近年来国内外C/C复合材料高温抗烧蚀涂层在玻璃涂层、金属涂层、陶瓷涂层等体系方面的研究进展,总结并评价了C/C复合材料抗烧蚀涂层的抗烧蚀性能测试技术及其研究成果,提出了C/C复合材料高温抗烧蚀涂层在未来研究中潜在的重点发展方向.","authors":[{"authorName":"韩伟","id":"39846bdb-8238-45c9-96a9-fac02943ce16","originalAuthorName":"韩伟"},{"authorName":"刘敏","id":"9cf9d224-bcfb-4413-9ea7-2c5478080107","originalAuthorName":"刘敏"},{"authorName":"邓春明","id":"7096a4e4-41c5-4002-ab77-be7e804595a8","originalAuthorName":"邓春明"},{"authorName":"毛杰","id":"bab4a8b5-2f65-4b4a-8070-5f8b38634fa5","originalAuthorName":"毛杰"},{"authorName":"曾德长","id":"bbd67603-bde4-438f-8261-a541f98c312e","originalAuthorName":"曾德长"}],"doi":"10.11973/fsyfh-201703001","fpage":"163","id":"6d4a9ed6-d236-4058-9e6d-25146b8810b6","issue":"3","journal":{"abbrevTitle":"FSYFH","coverImgSrc":"journal/img/cover/FSYFH.jpg","id":"25","issnPpub":"1005-748X","publisherId":"FSYFH","title":"腐蚀与防护"},"keywords":[{"id":"a195d2b5-4958-4b83-8c18-fa1f5f29e831","keyword":"C/C复合材料","originalKeyword":"C/C复合材料"},{"id":"546f5779-c43b-4163-a942-7021d47533e1","keyword":"抗烧蚀性能","originalKeyword":"抗烧蚀性能"},{"id":"819f383e-9b1c-4af4-b87f-a546f5b5c1b1","keyword":"涂层","originalKeyword":"涂层"}],"language":"zh","publisherId":"fsyfh201703001","title":"C/C复合材料高温抗烧蚀涂层的研究进展","volume":"38","year":"2017"},{"abstractinfo":"由于涂层C/C复合材料之间热膨胀系数不匹配,当冷却至室温时在高温下制备的抗氧化涂层会产生裂纹,为分析涂层裂纹的组态,通过在碳毡和真空穿刺两种C/C复合材料基体上制备单层、双层SiC涂层来研究涂层裂纹的形貌及分布.利用金相显微镜和扫描电镜观察两种涂层裂纹的形貌和分布,解释了裂纹与涂层所受热应力及基体原有缺陷的关系,利用XRD分析了单层和双层涂层的成分,说明了不同类型SiC结构与涂层裂纹之间的联系.结果表明涂层裂纹分布及裂纹宽度与基体纤维方向有关;随着涂层厚度增大,微裂纹数量减少;基体原有缺陷会导致涂层产生穿透性裂纹.","authors":[{"authorName":"祝俊良","id":"20ebea9d-7b10-452d-9ed3-98dbab8b004c","originalAuthorName":"祝俊良"},{"authorName":"史小红","id":"8c62b927-25fd-48d1-8e76-ba7e5b609a77","originalAuthorName":"史小红"},{"authorName":"陈梓山","id":"ac61611b-9a05-4680-a1c1-885bae988709","originalAuthorName":"陈梓山"},{"authorName":"李贺军","id":"dee49cf4-e764-4373-bee0-8b4a3a615da2","originalAuthorName":"李贺军"}],"doi":"10.3969/j.issn.0258-7076.2012.03.017","fpage":"423","id":"aa976f28-2548-4a49-afa4-df4274792ea1","issue":"3","journal":{"abbrevTitle":"XYJS","coverImgSrc":"journal/img/cover/XYJS.jpg","id":"67","issnPpub":"0258-7076","publisherId":"XYJS","title":"稀有金属"},"keywords":[{"id":"1eefe58b-4d42-48a2-839b-8ed28e07fd05","keyword":"C/C复合材料","originalKeyword":"C/C复合材料"},{"id":"bbf95afe-db66-40b4-aa5c-be7cb5ff972d","keyword":"SiC涂层","originalKeyword":"SiC涂层"},{"id":"a6956bdf-b6e7-4c21-a6d7-fbfbb6c287ad","keyword":"裂纹","originalKeyword":"裂纹"}],"language":"zh","publisherId":"xyjs201203017","title":"C/C复合材料SiC涂层裂纹形貌及分布的研究","volume":"36","year":"2012"},{"abstractinfo":"采用低压化学气相沉积法在碳纤维增强碳基(C/C)复合材料表面制备了碳化硅(SiC)涂层,借助XRD与SEM对SiC涂层的微观结构进行了分析,采用划痕仪测试了SiC涂层的结合力,研究了涂覆涂层后的C/C复合材料在强冲蚀条件下的烧蚀性能,分析了SiC涂层在强冲蚀条件下的失效机理.结果表明:LPCVD法制备的SiC涂层结构完整,无裂纹,无缺陷;涂层的结合力较弱,为5N;C/C复合材料烧蚀600s后涂层大部分区域保持完好,冲刷最强位置涂层遭到破坏;机械剥蚀是在强冲蚀条件下SiC涂层失效的主要原因.","authors":[{"authorName":"姚栋嘉","id":"1fb32869-fcf9-48e7-a600-bc3ea53662c7","originalAuthorName":"姚栋嘉"},{"authorName":"李贺军","id":"b0baaf36-9eb3-4f94-88a5-28e1a31a86a2","originalAuthorName":"李贺军"},{"authorName":"张守阳","id":"cd0ceeef-a05f-4721-a2ea-e79ddc13c786","originalAuthorName":"张守阳"},{"authorName":"李克智","id":"673e3bcc-237b-43b8-80c7-f3bfb5c401eb","originalAuthorName":"李克智"},{"authorName":"王永杰","id":"d906bbb3-1d6c-4312-946a-c54dc661f9e7","originalAuthorName":"王永杰"}],"doi":"10.7502/j.issn.1674-3962.2015.07.17","fpage":"610","id":"bd58af06-cdd2-4f1f-bf6c-9ea60e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