{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"在金属陶瓷领域中,三元硼化物的研究已经取得了一系列的成果,但是对Mo2NiB2基金属陶瓷涂层的研究还比较少.主要论述了Mo2 NiB2晶体结构、显微组织、Mo2NiB2基金属陶瓷的性能、Mo2 NiB2基金属陶瓷的合金化、Mo2NiB2基金属陶瓷涂层研究进展,并且对Mo2NiB2基金属陶瓷的研究进行了展望.","authors":[{"authorName":"罗致","id":"d41dc80e-52ef-4615-be77-2c64ff154dbc","originalAuthorName":"罗致"},{"authorName":"李小波","id":"2977e284-2fcd-4217-a165-75ae705a5b3d","originalAuthorName":"李小波"},{"authorName":"谢浪","id":"eb66f373-6ecf-4255-9516-f7f0451405a0","originalAuthorName":"谢浪"},{"authorName":"陈琛","id":"5952567c-1422-4f40-afbb-53a32efd9de4","originalAuthorName":"陈琛"}],"doi":"10.11896/j.issn.1005-023X.2016.07.015","fpage":"86","id":"e64dd7fa-e674-4143-aa8a-3006ba9829c9","issue":"7","journal":{"abbrevTitle":"CLDB","coverImgSrc":"journal/img/cover/CLDB.jpg","id":"8","issnPpub":"1005-023X","publisherId":"CLDB","title":"材料导报"},"keywords":[{"id":"e79b42b2-45ed-4eaf-8516-8d66a4f88cf6","keyword":"Mo2NiB2","originalKeyword":"Mo2NiB2"},{"id":"14baae0d-1e02-4be5-9784-40ab7361e165","keyword":"金属陶瓷","originalKeyword":"金属陶瓷"},{"id":"eee59ac6-a30e-42c8-9e68-6080db1c26a4","keyword":"研究进展","originalKeyword":"研究进展"}],"language":"zh","publisherId":"cldb201607015","title":"Mo2NiB2基金属陶瓷的研究进展","volume":"30","year":"2016"},{"abstractinfo":"计算了Mo-Ni-B三元系生成化合物和氧化反应产物的吉布斯自由能.结果表明反应过程中氧的存在对合成Mo2NiB2有很大的危害.从能量守恒的角度分析了材料吸收能量与激光输出能量的关系.利用ANSYS模拟了激光熔覆原位合成法的温度场.结果表明该制备法与烧结法反应机制不同.大功率激光辐照下温度迅速升至材料熔点,纯物质Mo、Ni、B在液相下发生反应形成Mo2NiB2.在激光功率为2500W,扫描速度为1 mm/s的工艺条件下,获得了良好的Mo2NiB2金属基陶瓷涂层.","authors":[{"authorName":"胡肇炜","id":"ef7a94d7-11df-46ca-8876-0e099a5a7ac6","originalAuthorName":"胡肇炜"},{"authorName":"李文戈","id":"89999868-fdef-4519-bdc4-d48d1ad75e3b","originalAuthorName":"李文戈"},{"authorName":"吴钱林","id":"70c9ac21-eae3-47b5-8a63-ea3934bb1c6b","originalAuthorName":"吴钱林"}],"doi":"10.13289/j.issn.1009-6264.2016-X134","fpage":"166","id":"2fe710fb-bbb1-495d-a236-c411c1aa9071","issue":"5","journal":{"abbrevTitle":"CLRCLXB","coverImgSrc":"journal/img/cover/CLRCLXB.jpg","id":"15","issnPpub":"1009-6264","publisherId":"CLRCLXB","title":"材料热处理学报"},"keywords":[{"id":"9ebb87fd-e917-451f-872c-2f8dcab9010b","keyword":"硼化物陶瓷","originalKeyword":"硼化物陶瓷"},{"id":"13024e4c-a11c-48da-afa3-695d13bb9947","keyword":"激光熔覆","originalKeyword":"激光熔覆"},{"id":"2140cd84-0bcf-4213-88c1-e8c10b2a7ceb","keyword":"原位合成","originalKeyword":"原位合成"},{"id":"abc83ad1-f387-47af-97c8-cab1bd2589b2","keyword":"热力学分析","originalKeyword":"热力学分析"},{"id":"f064d401-5216-42f3-ad9f-03769eb8468a","keyword":"数值模拟","originalKeyword":"数值模拟"}],"language":"zh","publisherId":"jsrclxb201705028","title":"激光熔覆原位合成Mo2NiB2的热力学分析及数值模拟","volume":"38","year":"2017"},{"abstractinfo":"采用激光熔覆技术在Q235钢表面原位合成了Mo2NiB2陶瓷涂层。利用扫描电镜和静态浸泡法、电化学方法研究了涂层的显微组织及耐腐蚀性能。结果表明,涂层与基材形成了良好的冶金结合,组织致密,增强相分布较为均匀且无明显的裂纹和孔洞。在3.5%NaCl溶液中,涂层的腐蚀电位明显比基材正移,腐蚀电流密度约为基材的1/4,说明Mo2NiB2陶瓷涂层显著提高了基材的耐腐蚀性能。","authors":[{"authorName":"代宽宽","id":"fc16fc2b-3f88-4f26-a6d9-cf84ff27c0c8","originalAuthorName":"代宽宽"},{"authorName":"宋光明","id":"f4a53877-a659-4cdf-90f5-9051a1cfa924","originalAuthorName":"宋光明"},{"authorName":"吴钱林","id":"ed5a405e-6aef-461f-aab8-b529c72f9f24","originalAuthorName":"吴钱林"},{"authorName":"李文戈","id":"5e02183c-1118-4082-b5ac-eaa3ec482a63","originalAuthorName":"李文戈"}],"doi":"","fpage":"375","id":"59cc81e8-78d4-4f9b-85b0-41b69707932d","issue":"5","journal":{"abbrevTitle":"FSYFH","coverImgSrc":"journal/img/cover/FSYFH.jpg","id":"25","issnPpub":"1005-748X","publisherId":"FSYFH","title":"腐蚀与防护"},"keywords":[{"id":"ff7c3cdc-57a0-4d10-9bb1-ae1e29321421","keyword":"激光熔覆","originalKeyword":"激光熔覆"},{"id":"032a3e34-d9aa-44a2-95bf-e5fa8509cb41","keyword":"Mo-Ni-B三元硼化物","originalKeyword":"Mo-Ni-B三元硼化物"},{"id":"35902134-0d2e-4b69-a11c-ab5ada7d4440","keyword":"原位合成","originalKeyword":"原位合成"},{"id":"eadd8107-340f-482c-a31d-451077908c3f","keyword":"腐蚀","originalKeyword":"腐蚀"}],"language":"zh","publisherId":"fsyfh201205005","title":"Mo-Ni-B系三元硼化物陶瓷涂层激光熔覆制备及其腐蚀性能","volume":"33","year":"2012"},{"abstractinfo":"采用诱导沉积法及粉末化学镀法分别制备了纯态NiB及负载型NiB/TiO2非晶态合金催化剂. 用XRD,ICP,SEM,TEM和DSC等手段对催化剂的物性及TiO2载体与NiB非晶态合金之间的相互作用进行了表征,考察了非晶态合金的结构、组成、形貌和热稳定性,并将其用于环丁烯砜加氢反应中. 结果表明,相对于NiB而言,NiB/TiO2催化剂具有优良的热稳定性和催化活性,这缘于NiB和TiO2载体之间的相互作用及载体的分散作用. ","authors":[{"authorName":"王来军","id":"6dfc5090-d347-4524-9a08-4456fed43993","originalAuthorName":"王来军"},{"authorName":"李伟","id":"2acc99f9-60e2-4a01-9cb3-137ef0e09ecb","originalAuthorName":"李伟"},{"authorName":"张明慧","id":"2f5e42ad-2b5b-4a22-9f1b-94c31ccaa816","originalAuthorName":"张明慧"},{"authorName":"陶克毅","id":"fb5b39fe-4ec5-4cb9-8ab5-4f0fc203af4b","originalAuthorName":"陶克毅"}],"doi":"","fpage":"816","id":"b815a6ae-b2b9-401c-8be2-bd1a097a7dc4","issue":"11","journal":{"abbrevTitle":"CHXB","coverImgSrc":"journal/img/cover/CHXB.jpg","id":"18","issnPpub":"0253-9837","publisherId":"CHXB","title":"催化学报 "},"keywords":[{"id":"b866ba7b-386a-405f-962a-cbbeedf48a6a","keyword":"非晶态合金","originalKeyword":"非晶态合金"},{"id":"d4c4551c-da5f-4541-9ab3-cdf4f60b48d9","keyword":"镍","originalKeyword":"镍"},{"id":"cd36458e-97f6-404e-806d-2e9065a96920","keyword":"硼","originalKeyword":"硼"},{"id":"a9348606-c4f6-4c67-9d60-e7eb54d6d3dc","keyword":"氧化钛","originalKeyword":"氧化钛"},{"id":"764b3f1a-bef3-4092-aa7b-e6f4d10f4175","keyword":"负载型催化剂","originalKeyword":"负载型催化剂"},{"id":"95ac3fcb-80c5-46f6-afb5-46cc71bb9fd2","keyword":"诱导化学沉积法","originalKeyword":"诱导化学沉积法"},{"id":"117f1ffa-527e-420f-b3f1-31ce9baccd6d","keyword":"粉末化学镀法","originalKeyword":"粉末化学镀法"},{"id":"80b1ddd5-78b1-4902-982c-1d76187ee559","keyword":"环丁烯砜","originalKeyword":"环丁烯砜"},{"id":"5716a23b-f76f-4a59-bd8f-bf0978330348","keyword":"加氢","originalKeyword":"加氢"},{"id":"a66eae05-afdb-4ac3-a446-2bb4140105ce","keyword":"环丁砜","originalKeyword":"环丁砜"}],"language":"zh","publisherId":"cuihuaxb200311005","title":"粉末化学镀法制备的NiB/TiO2非晶态合金催化剂对环丁烯砜加氢反应的催化性能","volume":"24","year":"2003"},{"abstractinfo":"本文采用脉冲技术研究了稀土氧化物对负载型非晶态NiB/Al2O3合金催化剂苯加氢活性和抗硫性能的影响.用XRD鉴定了非晶态结构,用TPR、TPD表征了催化剂的表面性质,用CO化学吸附法测定了活性镍表面积.实验结果表明,非晶态合金催化剂上至少有两种吸附中心,稀土氧化物能明显地提高催化剂的苯加氢活性和抗硫性能,其原因是稀土氧化物有助于氧化镍的还原,从而在反应温度下有更多的活性镍物种被还原,稀土氧化物还能使镍物种颗粒细化,提高了活性镍面积.","authors":[{"authorName":"李凤仪","id":"8fbe655b-8fa0-4077-8ad9-b449c12c1453","originalAuthorName":"李凤仪"},{"authorName":"张荣斌","id":"3e7806fa-fc85-4976-80cb-537fc5aebbe1","originalAuthorName":"张荣斌"},{"authorName":"石秋杰","id":"11e7f632-c995-4135-9e5c-96e37ac384cf","originalAuthorName":"石秋杰"},{"authorName":"罗来涛","id":"b56584aa-531d-4102-a3e6-0ccf3cae2922","originalAuthorName":"罗来涛"}],"doi":"10.3969/j.issn.1004-0277.2000.04.010","fpage":"38","id":"b604247c-1d21-43de-962e-ddb62091c38b","issue":"4","journal":{"abbrevTitle":"XT","coverImgSrc":"journal/img/cover/XT.jpg","id":"65","issnPpub":"1004-0277","publisherId":"XT","title":"稀土"},"keywords":[{"id":"168ddee5-c3cf-497f-86dc-ca7476c0ab7e","keyword":"负载型催化剂","originalKeyword":"负载型催化剂"},{"id":"5356e58b-38d0-44c4-bce2-4e324686906a","keyword":"非晶态NiB合金","originalKeyword":"非晶态NiB合金"},{"id":"8449080b-78d9-4d10-8316-fe3c064d41cd","keyword":"苯加氢","originalKeyword":"苯加氢"},{"id":"aff36a25-fc65-4fa6-9c7d-272d19e73fd3","keyword":"抗硫性","originalKeyword":"抗硫性"},{"id":"adbd0370-1bd7-445f-a046-18541991ecc1","keyword":"稀土氧化物","originalKeyword":"稀土氧化物"}],"language":"zh","publisherId":"xitu200004010","title":"稀土在负载型非晶态NiB/Al2O3合金上作用研究","volume":"21","year":"2000"},{"abstractinfo":"用化学还原法制备出平均粒径20nm的NiB非晶态合金和NiCuB合金粉,以及负载型NiB/Al2O3和NiB/SiO2催化剂.DTA结果表明:NiB和NiCuB合金粉可以显著降低AP的高温分解温度,表现了对AP高温分解反应良好的催化效果.负载型NiB/Al2O3和NiB/SiO2对AP热分解的催化效果,与NiB相比没有明显增强.随NiB非晶态合金增加对AP热分解的催化效果变化不明显.","authors":[{"authorName":"刘磊力","id":"d6b37081-8f80-4359-a231-50660ee94864","originalAuthorName":"刘磊力"},{"authorName":"李凤生","id":"9a2890c9-2d7d-444a-95e7-e7fb4b48ee9e","originalAuthorName":"李凤生"},{"authorName":"谈玲华","id":"4fc96f2e-ae25-4143-a2be-75792e035ef5","originalAuthorName":"谈玲华"},{"authorName":"李敏","id":"402edd0e-e82d-4a01-be3d-9cf44ee754df","originalAuthorName":"李敏"},{"authorName":"杨毅","id":"57d5f2a5-391c-48c3-8568-7013182a7d23","originalAuthorName":"杨毅"}],"doi":"10.3969/j.issn.1007-2330.2004.03.009","fpage":"39","id":"2ebd4038-089b-426e-9739-ea59d52630df","issue":"3","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":"fcd22dbe-9d73-4916-9ba2-0d372fbfc7e8","keyword":"纳米","originalKeyword":"纳米"},{"id":"a4dcede4-a3de-4dba-a996-34b4ba73c2e4","keyword":"NiB非晶合金","originalKeyword":"NiB非晶合金"},{"id":"b2199433-d8c6-4f79-9bdd-9f34edc1d1d9","keyword":"催化剂","originalKeyword":"催化剂"},{"id":"24305cdf-dab8-42fc-9736-1cc6bf7a62b5","keyword":"AP","originalKeyword":"AP"},{"id":"f2885ba6-2f0d-4093-b168-b50fa1b586a3","keyword":"热分解","originalKeyword":"热分解"}],"language":"zh","publisherId":"yhclgy200403009","title":"纳米NiB非晶合金对AP热分解性能的影响","volume":"34","year":"2004"},{"abstractinfo":"将Ag2O/MgO分别加入到NiSO4-NH3和NiSO4-乙二胺两种不同的镀液体系中,通过粉末化学镀法制备了NiB/MgO负载型非晶态合金催化剂,并与化学还原法制备的纯态NiB催化剂进行对比. 用XRD,ICP和TEM对催化剂进行了表征,并将它们用于环丁烯砜加氢反应. TEM结果表明,纯态NiB为团聚严重的纳米颗粒,而NiB/MgO催化剂上纳米NiB得到了很好的分散. 环丁烯砜加氢反应结果表明,NiB/MgO的催化活性远高于纯态NiB,尤其是用NiSO4-乙二胺体系制备的NiB/MgO-2的活性高于环丁烯砜加氢工业用Raney Ni催化剂,因而NiB/MgO具有良好的工业应用前景. ","authors":[{"authorName":"王来军","id":"a2be2070-1372-4f76-b98e-82660f809f0b","originalAuthorName":"王来军"},{"authorName":"张明慧","id":"53e7a8e0-8820-485a-866f-92035bada17a","originalAuthorName":"张明慧"},{"authorName":"李伟","id":"2e2387f5-6d81-4e68-ba70-7561213f68da","originalAuthorName":"李伟"},{"authorName":"陶克毅","id":"9d2e3a83-1fb8-4ae8-be60-8a719b7091b2","originalAuthorName":"陶克毅"}],"doi":"","fpage":"91","id":"108a1fc2-e69b-41a6-ad35-b84e6a038dac","issue":"2","journal":{"abbrevTitle":"CHXB","coverImgSrc":"journal/img/cover/CHXB.jpg","id":"18","issnPpub":"0253-9837","publisherId":"CHXB","title":"催化学报 "},"keywords":[{"id":"8f22924d-90dc-4175-88e8-226260f2c582","keyword":"非晶态合金","originalKeyword":"非晶态合金"},{"id":"53053b94-1d9d-4fdf-9b75-d881017dc3bb","keyword":"粉末化学镀法","originalKeyword":"粉末化学镀法"},{"id":"ba9e82b1-2307-4154-8576-5cedc20f571b","keyword":"镍","originalKeyword":"镍"},{"id":"2d8419db-f6d1-4d17-94e1-c7949275d849","keyword":"硼","originalKeyword":"硼"},{"id":"baa3db0d-a34c-4028-a14b-b9be3c08b2b4","keyword":"环丁烯砜","originalKeyword":"环丁烯砜"},{"id":"a0e710d6-f997-4606-89de-994b4bfdb6ce","keyword":"加氢","originalKeyword":"加氢"}],"language":"zh","publisherId":"cuihuaxb200502001","title":"粉末化学镀法制备负载型NiB非晶态合金催化剂","volume":"26","year":"2005"},{"abstractinfo":"The structural and magnetic properties of RFe(10)Mo(2) and RFe(10)Mo(2)N have been studied by x-ray diffraction and high-field magnetization measurements on free-powder or magnetically aligned samples. The lattice of RFe(10)Mo(2) expands anisotropically upon nitrogenation and the volume of the unit cell increases by 2.9-4.0%. The rare-earth element dependence of lattice expansion is found to be just opposite to that of the Curie temperature. The saturation magnetization of RFe(10)Mo(2) increases after the introduction of nitrogen. The abnormally large values of magnetization for some heavy-rare-earth compounds imply that a non-collinear moment configuration in the absence of an external field may exist in these compounds.","authors":[],"categoryName":"|","doi":"","fpage":"8923","id":"74cf5d8d-dceb-4063-a595-84354e6f1bf3","issue":"45","journal":{"abbrevTitle":"JOPM","id":"f0e359df-48a6-4a7f-b16d-2389d3e793ee","issnPpub":"0953-8984","publisherId":"JOPM","title":"Journal of Physics-Condensed Matter"},"keywords":[{"id":"0c7e61bf-c710-45d2-a65f-1e1a25fd6734","keyword":"spin reorientation;ndfe10mo2n0.5;yfe12-xmox;field;nd;ho;mo","originalKeyword":"spin reorientation;ndfe10mo2n0.5;yfe12-xmox;field;nd;ho;mo"}],"language":"en","publisherId":"0953-8984_1996_45_1","title":"Structural and magnetic properties of RFe(10)Mo(2) and RFe(10)Mo(2)N","volume":"8","year":"1996"},{"abstractinfo":"Effect of Mo and Mo2C on the microstructure\nand properties of Ti(C,N)-based cermets was investigated in this\narticle. The results have indicated that the weight percentage of Mo\nfrom 5 to 10 can reduce Ti(C,N) grain diameter and thickness of the\nrim, and Ti(C,N) grain can be wetted by Ni-Cu-Mo liquid so as to get\nsmall contiguity of Ti(C,N) grain. In that way, the transverse\nrupture strength of Ti(C,N)-based cermets has reached\n1800—1900 MPa; the fracture toughness has been due to\n16—18 MPa m1/2. But 15wt pct Mo was not more effective\non Ti(C,N)-based cermets, because the thickness of the rim becomes\nlarger. In the circumstance of Mo 2 C, 5 wt pct Mo 2 C was\ngood for microstructure and properties of Ti(C,N)-based cermets, but\n11 wt pct Mo 2 C has resulted in larger contiguity of Ti(C,N)\ngrain and big Ti(C,N) grain diameter so as to reduce transverse\nrupture strength and fracture toughness. So that, the effect of Mo\non Ti(C,N)-based cermets is better than Mo 2 C.","authors":[{"authorName":"S.Q. Zhou","id":"2bf4c2bf-f086-47ab-b248-3bf85df34f25","originalAuthorName":"S.Q. Zhou"},{"authorName":" W. Zhao","id":"a15f8ad9-42ff-4852-b7fc-660eccc7f6d6","originalAuthorName":" W. Zhao"},{"authorName":" W.H. Xiong","id":"a7f17c0a-ad9a-461a-8fc5-d77d47902fb4","originalAuthorName":" W.H. Xiong"},{"authorName":" Y.N. Zhou","id":"2ee96280-dc5f-46f9-90de-99ecc6b551a3","originalAuthorName":" Y.N. Zhou"},{"authorName":"null","id":"f9faa2dd-df9d-49b9-a7b5-46da1302dd0d","originalAuthorName":"null"},{"authorName":"null","id":"cacd0105-ac8e-4782-a88f-d7d9472b7eec","originalAuthorName":"null"},{"authorName":"null","id":"7b8612c1-0167-4c47-aca5-135df0b23a2b","originalAuthorName":"null"},{"authorName":"null","id":"1ab3b611-7541-43c3-81d6-e6f51d8700cf","originalAuthorName":"null"}],"categoryName":"|","doi":"","fpage":"211","id":"aef5cf62-ef73-4178-acdf-77af4a27583d","issue":"3","journal":{"abbrevTitle":"JSXBYWB","coverImgSrc":"journal/img/cover/amse.jpg","id":"49","issnPpub":"1006-7191","publisherId":"JSXBYWB","title":"金属学报(英文版)"},"keywords":[{"id":"b262a04e-9d5c-4034-8c0e-633a37150e5e","keyword":"Transverse rupture strength (TRS)","originalKeyword":"Transverse rupture strength (TRS)"},{"id":"4c7738eb-4280-4099-a338-6da8c8bde8bc","keyword":"null","originalKeyword":"null"},{"id":"67d1762e-090d-4698-bac3-3ccd55986409","keyword":"null","originalKeyword":"null"}],"language":"en","publisherId":"1006-7191_2008_3_3","title":"Effect Of Mo And Mo2c On Themicrostructure And Properties Of The Cermets Based On Ti(C,N)","volume":"21","year":"2008"},{"abstractinfo":"利用Al-Si混合粉末包覆金属Mo,并在Ar气氛围中,900℃进行高温扩散反应,在金属Mo表面制备Mo(Si,Al)2化合物层.在空气中12 00℃的条件下进行的高温氧化试验表明,化合物Mo(Si,Al)2具有优异的抗氧化性,样品外表面生成了致密的氧化铝层,从而阻止样品内部被进一步氧化.另外,氧化试验后在基体Mo和Mo (Si,Al)2层界面处还观察到Mo5(Si,Al)3层和Mo3 Al8层.","authors":[{"authorName":"李雪","id":"2ae7c318-02bb-4fc5-b44c-37653c7bfbde","originalAuthorName":"李雪"},{"authorName":"卢公昊","id":"2d64be91-0db0-4747-a4b3-21eb8aa7a65a","originalAuthorName":"卢公昊"},{"authorName":"王淼","id":"8a3e47ef-7a3f-40ac-b33a-913c3dea7a5a","originalAuthorName":"王淼"},{"authorName":"高田润","id":"0189495f-baa7-4ede-aade-d70372181253","originalAuthorName":"高田润"}],"doi":"10.14186/j.cnki.1671-6620.2015.02.011","fpage":"131","id":"508bd254-09c7-4e95-9168-146624ae464b","issue":"2","journal":{"abbrevTitle":"CLYYJXB","coverImgSrc":"journal/img/cover/CLYYJXB.jpg","id":"17","issnPpub":"1671-6620","publisherId":"CLYYJXB","title":"材料与冶金学报"},"keywords":[{"id":"1af9ad61-cf96-40aa-846d-de1b08efc04d","keyword":"金属Mo","originalKeyword":"金属Mo"},{"id":"ca385b1d-c49b-4b2f-a3fa-ec99988b6c30","keyword":"Mo(Si,Al)2","originalKeyword":"Mo(Si,Al)2"},{"id":"d0f7f347-2b8b-4bb5-b463-2347ca9fcd0e","keyword":"粉末包覆法","originalKeyword":"粉末包覆法"},{"id":"a8726b78-d972-4337-bc05-8e1560998725","keyword":"高温抗氧化性","originalKeyword":"高温抗氧化性"}],"language":"zh","publisherId":"clyyjxb201502011","title":"Mo表面Mo(Si,Al)2层的制备及抗高温氧化性能","volume":"14","year":"2015"}],"totalpage":8206,"totalrecord":82052}