{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"采用燃烧反应合成方法,在球墨铸铁表面制备<span style=\"color:red\">Ni-Al-SiC</span>金属间化合物复合涂层,通过加入<span style=\"color:red\">SiC</span>粒子来改善<span style=\"color:red\">Ni-Al</span>系金属间化合物的摩擦磨损性能.试验结果表明:随着载荷的提高,磨损量增加,摩擦因数减小;随着<span style=\"color:red\">SiC</span>粒子含量的增加,硬度增加,磨损量降低;在燃烧反应的过程中,随着烧结压强的增加,硬度有明显提高.由此得出结论:<span style=\"color:red\">SiC</span>粒子的加入,明显改善了<span style=\"color:red\">Ni-Al</span>系金属间化合物的摩擦磨损性能,并且提高了材料的硬度.","authors":[{"authorName":"王宙","id":"9e48304e-63b1-4432-a5c1-0ce189a58339","originalAuthorName":"王宙"},{"authorName":"李昊涵","id":"0fcc23a2-ccd7-4d6a-a217-95336b22eebd","originalAuthorName":"李昊涵"},{"authorName":"室谷贵之","id":"45c667d7-b6d3-4c6d-964a-1eb21a29d19f","originalAuthorName":"室谷贵之"},{"authorName":"赵明华","id":"b49d7dc2-b8f8-44d4-b602-9c39d09faeed","originalAuthorName":"赵明华"},{"authorName":"付传起","id":"c6418faa-e7e7-4059-8d51-43c5b4f14a3a","originalAuthorName":"付传起"}],"doi":"10.3969/j.issn.1001-3660.2009.01.017","fpage":"45","id":"2e80bfbf-b102-418b-b550-b7743e64db68","issue":"1","journal":{"abbrevTitle":"BMJS","coverImgSrc":"journal/img/cover/BMJS.jpg","id":"3","issnPpub":"1001-3660","publisherId":"BMJS","title":"表面技术   "},"keywords":[{"id":"be495fdf-61b1-414c-a74e-1bc89c17f784","keyword":"燃烧反应合成","originalKeyword":"燃烧反应合成"},{"id":"3ba5be77-7775-4d77-84b8-274af7695780","keyword":"<span style=\"color:red\">Ni-Al-SiC</span>","originalKeyword":"Ni-Al-SiC"},{"id":"c828c050-b06a-4837-833c-95b6976109c1","keyword":"复合涂层","originalKeyword":"复合涂层"},{"id":"40b267dd-c07e-4df5-b7c1-2a1f2a66f429","keyword":"摩擦因数","originalKeyword":"摩擦因数"},{"id":"502afabc-7355-4ec2-a778-a2653727e6a8","keyword":"磨损量","originalKeyword":"磨损量"},{"id":"95f95672-5465-4750-8916-a824314eaf0e","keyword":"金属间化合物","originalKeyword":"金属间化合物"}],"language":"zh","publisherId":"bmjs200901017","title":"燃烧反应合成<span style=\"color:red\">Ni-Al-SiC</span>摩擦磨损性能研究","volume":"38","year":"2009"},{"abstractinfo":"针对<span style=\"color:red\">Al</span>2O3/<span style=\"color:red\">Al</span>复合材料中金属相<span style=\"color:red\">Al</span>对其高温性能的不利影响,本试验在高温下将铝合金熔体氧化渗透到注浆成型的<span style=\"color:red\">SiC</span>/<span style=\"color:red\">Ni</span>多孔预制体中, 制备了<span style=\"color:red\">Al</span>2O3/<span style=\"color:red\">SiC</span>/<span style=\"color:red\">Ni</span>/<span style=\"color:red\">Al</span>-Si多相陶瓷基复合材料.借助光学显微镜、电子显微镜(SEM)、X射线衍射仪(XRD)、波谱仪(EDS)等手段分析了预制体和复合材料的相组成、微观结构及界面特征.结果表明,复合材料的主晶相为<span style=\"color:red\">Al</span>2O3与<span style=\"color:red\">SiC</span>,相间存在<span style=\"color:red\">Al</span>(Si)复合氧化物、NiAl2O4及<span style=\"color:red\">Ni</span>与<span style=\"color:red\">Al</span>-Si合金相,各相界面处成分呈连续过渡变化趋势,构筑了具有模糊界面特征的多相复合材料.","authors":[{"authorName":"赵敬忠","id":"b9974672-cf50-4c04-a8da-1cc9361b9b18","originalAuthorName":"赵敬忠"},{"authorName":"成守权","id":"5e7240c5-8a28-4770-abd9-e2bada4ea83d","originalAuthorName":"成守权"},{"authorName":"谷臣清","id":"53c076d1-fa48-4036-a436-e8682d6b38f9","originalAuthorName":"谷臣清"},{"authorName":"高积强","id":"9aa5b0f5-dd78-4f8e-94d3-875b2cf9012b","originalAuthorName":"高积强"},{"authorName":"金志浩","id":"5ec04b05-006a-48e6-85e1-007658228b04","originalAuthorName":"金志浩"}],"doi":"10.3321/j.issn:1000-3851.2005.02.018","fpage":"91","id":"b32373da-81f5-4b92-9d34-f60344db6424","issue":"2","journal":{"abbrevTitle":"FHCLXB","coverImgSrc":"journal/img/cover/FHCLXB.jpg","id":"26","issnPpub":"1000-3851","publisherId":"FHCLXB","title":"复合材料学报"},"keywords":[{"id":"1ed569da-f235-4b82-a4a6-b1645af034c7","keyword":"复合材料","originalKeyword":"复合材料"},{"id":"d7f79a4d-c54b-49ba-9dc6-eb6fd1641164","keyword":"模糊界面","originalKeyword":"模糊界面"},{"id":"8451a39f-1697-49c3-9514-bd28e3814f15","keyword":"熔体氧化","originalKeyword":"熔体氧化"},{"id":"fd44a01b-e9fb-4b7d-9c93-4e792a20ed5b","keyword":"<span style=\"color:red\">SiC</span>","originalKeyword":"SiC"}],"language":"zh","publisherId":"fhclxb200502018","title":"铝合金熔体氧化制备<span style=\"color:red\">Al</span>2O3/<span style=\"color:red\">SiC</span>/<span style=\"color:red\">Ni</span>/<span style=\"color:red\">Al</span>-Si多相模糊界面陶瓷基复合材料","volume":"22","year":"2005"},{"abstractinfo":"采用高放热反应且摩尔比为1∶1的镍-铝二元系作为焊料,利用微波引燃的方法使体系以内部加热的方式迅速升温到燃烧温度并发生自蔓延高温合成反应,最终实现化学气相沉积碳化硅陶瓷(CVD <span style=\"color:red\">SiC</span>)的连接,研究不同反应产物对连接强度的影响规律.研究表明:反应层平均厚度约300 μm,反应产物与碳化硅基体之间的界面结合良好,但接头内存在着大量气孔,致密度较低.母材与中间层产物的热错配应力问题使接头界面处存在大量微裂纹.由于自蔓延连接的复杂性与高度不平衡性使反应产物较难控制,接头断面的XRD结果表明不同接头中生成了不同相的镍-铝系金属间化合物以及氧化物,但均未检测到残余单质<span style=\"color:red\">Ni</span>或<span style=\"color:red\">Al</span>.氧化物的出现会极大影响接头的剪切强度,导致试样接头强度的数值偏差较大.","authors":[{"authorName":"韩绍华","id":"5cd6e6ff-b068-42c5-b69e-dbb3b923f98b","originalAuthorName":"韩绍华"}],"doi":"","fpage":"1752","id":"ce2220a6-cc62-499d-9ccf-ae7c46296007","issue":"7","journal":{"abbrevTitle":"GSYTB","coverImgSrc":"journal/img/cover/GSYTB.jpg","id":"36","issnPpub":"1001-1625","publisherId":"GSYTB","title":"硅酸盐通报   "},"keywords":[{"id":"6cb654fa-4516-42ad-90a6-e719b41b934c","keyword":"镍-铝系焊料","originalKeyword":"镍-铝系焊料"},{"id":"7410a491-898b-46bb-b2b7-9da794e477e2","keyword":"CVD碳化硅","originalKeyword":"CVD碳化硅"},{"id":"6e387a10-4cfb-4036-8d3a-9cb4b7e851a2","keyword":"微波助燃自蔓延连接","originalKeyword":"微波助燃自蔓延连接"},{"id":"cc5f0bd4-8182-45f9-ab06-c70da2cfacad","keyword":"微观结构","originalKeyword":"微观结构"},{"id":"4c4c10f8-a089-40b1-acdb-04ef9d544a7f","keyword":"连接强度","originalKeyword":"连接强度"}],"language":"zh","publisherId":"gsytb201407035","title":"微波助燃<span style=\"color:red\">Ni-Al</span>高温自蔓延连接CVD <span style=\"color:red\">SiC</span>","volume":"33","year":"2014"},{"abstractinfo":"研究了不同工艺条件下具有<span style=\"color:red\">SiC-Ni</span> 双涂层的碳纤维增强<span style=\"color:red\">Al</span> 基复合材料的界面反应、界面结构及其对复合材料力学性能的影响,分析了不同界面条件下复合材料的典型破坏过程。实验表明:以<span style=\"color:red\">SiC</span> 涂层作为界面反应阻挡层,可有效地阻止纤维与基体的反应,保证C/<span style=\"color:red\">Al</span> 复合材料在界面反应很严重的情况下仍能保持较高的强度水平。初步提出了这种复合材料保持较高强度的原因和断裂机制。","authors":[{"authorName":"夏振海","id":"9e1110c8-312f-45e1-bfc4-fc405c1b1c9b","originalAuthorName":"夏振海"},{"authorName":"周尧和","id":"a44f62ed-578f-497d-af71-5b99f063ed72","originalAuthorName":"周尧和"},{"authorName":"毛志英","id":"2629649e-401b-43d5-bb03-b576b7a4b8f0","originalAuthorName":"毛志英"}],"categoryName":"|","doi":"","fpage":"443","id":"eb811c83-fc8e-43e7-b305-a14d15e79278","issue":"5","journal":{"abbrevTitle":"CLYJXB","coverImgSrc":"journal/img/cover/CLYJXB.jpg","id":"16","issnPpub":"1005-3093","publisherId":"CLYJXB","title":"材料研究学报"},"keywords":[{"id":"a04f77a8-7b5a-4ece-af90-f6deb78fef8b","keyword":"<span style=\"color:red\">Al</span> 基复合材料","originalKeyword":"Al 基复合材料"},{"id":"ed061b32-53a3-44ae-a994-fd89a12f718d","keyword":"coating","originalKeyword":"coating"},{"id":"2828d13b-f976-4bcf-ac43-0913859edb84","keyword":"interface reaction","originalKeyword":"interface reaction"},{"id":"e0864113-87d3-4dd0-8d17-97f1124fb322","keyword":"mechanical property","originalKeyword":"mechanical property"}],"language":"zh","publisherId":"1005-3093_1991_5_6","title":"<span style=\"color:red\">SiC-Ni</span> 双涂层的界面反应对 C/<span style=\"color:red\">Al</span> 复合材料力学性能的影响","volume":"5","year":"1991"},{"abstractinfo":"应用新型化学涂层工艺(置换法),成功地制备出结合紧密、光滑的<span style=\"color:red\">Ni</span>涂<span style=\"color:red\">SiC</span>粉末;分析对比了2种不同涂层工艺原理及涂层效果;分析了不同<span style=\"color:red\">SiC</span>增强<span style=\"color:red\">Al</span>-Fe-V-Si(0812)复合材料物理和力学性能,结果表明:由于涂覆<span style=\"color:red\">SiC</span>与基体的结合更加牢固,较软的基体合金与过渡层<span style=\"color:red\">Ni</span>的结合而降低了增强体与基体合金之间的孔隙率,从而使10%<span style=\"color:red\">SiC</span>(<span style=\"color:red\">Ni</span>)/<span style=\"color:red\">Al</span>-Fe-V-Si(0812)(质量分数,下同)复合材料在室温的断裂强度分别比基体和10%SiCp/<span style=\"color:red\">Al</span>-Fe-V-Si(0812)复合材料增加了62.15%和2.82%,在400℃时分别增加了55.3%,28.6%.","authors":[{"authorName":"李云平","id":"0253ee89-37e1-47e6-9a2b-78953671929d","originalAuthorName":"李云平"},{"authorName":"李溪滨","id":"a2ab172a-34c7-474a-a1a6-ff1ae1831f66","originalAuthorName":"李溪滨"}],"doi":"","fpage":"183","id":"4bd0818d-f654-43b5-94eb-850c5e5221af","issue":"3","journal":{"abbrevTitle":"XYJSCLYGC","coverImgSrc":"journal/img/cover/XYJSCLYGC.jpg","id":"69","issnPpub":"1002-185X","publisherId":"XYJSCLYGC","title":"稀有金属材料与工程"},"keywords":[{"id":"29f12b9d-58a8-4145-b61f-0ec4b27965ea","keyword":"化学涂层","originalKeyword":"化学涂层"},{"id":"a8ff27f0-f010-4912-b35a-1694df1747e2","keyword":"置换法","originalKeyword":"置换法"},{"id":"7d23c018-b860-4b44-a656-17cdcbb4776f","keyword":"热挤压","originalKeyword":"热挤压"},{"id":"34ebd135-6529-47a9-85fc-e7407a9b5461","keyword":"耐热铝基复合材料","originalKeyword":"耐热铝基复合材料"}],"language":"zh","publisherId":"xyjsclygc200203006","title":"涂覆颗粒增强耐热铝基复合材料<span style=\"color:red\">SiC</span>(<span style=\"color:red\">Ni</span>)/<span style=\"color:red\">Al</span>-Fe-V-Si力学性能研究","volume":"31","year":"2002"},{"abstractinfo":"The microstructure of <span style=\"color:red\">SiC</span> whisker reinforced aluminium alloy (<span style=\"color:red\">SiC</span>_w/<span style=\"color:red\">Al</span>) composite is reviewed,and the <span style=\"color:red\">SiC-Al</span> interface in <span style=\"color:red\">SiC</span>_w/<span style=\"color:red\">Al</span> composite is especially discussed,The main contents are morphology of the aluminium matrix in <span style=\"color:red\">SiC</span>_w/<span style=\"color:red\">Al</span> composite;microstructures and defects of <span style=\"color:red\">SiC</span> whiskers in <span style=\"color:red\">SiC</span>_w/<span style=\"color:red\">Al</span> composite and bonding mechanisms of the <span style=\"color:red\">SiC-Al</span> interface in <span style=\"color:red\">SiC</span>_w/<span style=\"color:red\">Al</span> com- posite.","authors":[{"authorName":"Lin GENG Congkai YAO Dept.of Metals and Technology","id":"89272f68-02b9-48ab-93c5-af9029e09ed1","originalAuthorName":"Lin GENG Congkai YAO Dept.of Metals and Technology"},{"authorName":"Harbin Institute of Technology (HIT)","id":"4d229b5f-36cc-4e03-b615-4a340e4da09c","originalAuthorName":"Harbin Institute of Technology (HIT)"},{"authorName":"Harbin","id":"ab78ccce-0c02-4758-9857-3e2b6561a50d","originalAuthorName":"Harbin"},{"authorName":"150006","id":"87b8086d-87ee-498f-9336-99758b147b29","originalAuthorName":"150006"},{"authorName":"China","id":"64f6fc25-fa62-44fc-95ab-b769fa337519","originalAuthorName":"China"}],"categoryName":"|","doi":"","fpage":"431","id":"7a572399-7e7c-4c09-b8a8-8fc7edf8ba2e","issue":"6","journal":{"abbrevTitle":"CLKXJSY","coverImgSrc":"journal/img/cover/JMST.jpg","id":"11","issnPpub":"1005-0302 ","publisherId":"CLKXJSY","title":"材料科学技术（英文）"},"keywords":[{"id":"1b4dfc27-6f92-47c8-aed9-4ce36008da0e","keyword":"silicon carbide","originalKeyword":"silicon carbide"},{"id":"0c904305-8376-4ea4-a43f-20fb4bf0cee0","keyword":"null","originalKeyword":"null"},{"id":"de1fa4c9-822e-4146-8603-bc910b42d051","keyword":"null","originalKeyword":"null"},{"id":"57f10c55-52ad-4852-967e-3ef685838b8c","keyword":"null","originalKeyword":"null"},{"id":"65f34ab4-5b78-43c5-9a8f-04177e2f0718","keyword":"null","originalKeyword":"null"}],"language":"en","publisherId":"1005-0302_1993_6_2","title":"Development of Some Fundamental Research of <span style=\"color:red\">SiC</span>_W/<span style=\"color:red\">Al</span> Composites in HIT PartⅠ Microstructure and <span style=\"color:red\">SiC</span>/<span style=\"color:red\">Al</span> Interface of <span style=\"color:red\">SiC</span>_W/<span style=\"color:red\">Al</span> Composites","volume":"9","year":"1993"},{"abstractinfo":"采用铜模铸造方法成功制备了体积分数高达27%的<span style=\"color:red\">SiC</span>/ Zr55<span style=\"color:red\">Al10Ni</span>5Cu30块体非晶复合材料. 光学显微镜、X射线衍射和透射电镜分析表明, 非晶基体上均匀分布<span style=\"color:red\">SiC</span>颗粒，<span style=\"color:red\">SiC</span>颗粒与基体间形成了厚度为10 nm的反应层. DSC分析表明, 块体非晶复合材料的玻璃转变温度、晶化温度和过冷液相区随<span style=\"color:red\">SiC</span>体积分数的增加而提高. 电子探针分析和计算结果表明, Si原子和部分C原子通过扩散进入基体合金中, 从而提高了非晶合金的形成能力和热稳定性.","authors":[{"authorName":"武晓峰","id":"2f550857-dd26-452d-8613-97c7bd8d5254","originalAuthorName":"武晓峰"},{"authorName":"邱克强","id":"9d7776ff-e8b6-4396-8839-df4cced0b8a8","originalAuthorName":"邱克强"},{"authorName":"张海峰","id":"b8205775-173b-49ae-8bd9-735ece72fad5","originalAuthorName":"张海峰"},{"authorName":"王爱民","id":"bd2fce98-86e5-4626-91f4-adc8e2c0e27e","originalAuthorName":"王爱民"},{"authorName":"杨洪才","id":"7f0e6506-bf4b-4110-a35f-26686beee8d3","originalAuthorName":"杨洪才"},{"authorName":"胡壮麒","id":"ad615a9b-f68b-45a3-8e54-e7ae960d70a7","originalAuthorName":"胡壮麒"}],"categoryName":"|","doi":"","fpage":"414","id":"fca55591-3e37-4d0c-8be7-909ba0298163","issue":"4","journal":{"abbrevTitle":"JSXB","coverImgSrc":"journal/img/cover/JSXB.jpg","id":"48","issnPpub":"0412-1961","publisherId":"JSXB","title":"金属学报"},"keywords":[{"id":"89795759-1871-48c0-950e-c9f33ae9c8ea","keyword":"<span style=\"color:red\">SiC</span>/","originalKeyword":"SiC/"},{"id":"7e31d839-68b5-4824-8d5d-3b3738462acf","keyword":"null","originalKeyword":"null"},{"id":"93c3f721-7679-47ec-bcf9-4285fb132232","keyword":"null","originalKeyword":"null"}],"language":"zh","publisherId":"0412-1961_2003_4_13","title":"<span style=\"color:red\">SiC</span>颗粒对Zr55<span style=\"color:red\">Al10Ni</span>5Cu30非晶形成能力和热稳定性的影响","volume":"39","year":"2003"},{"abstractinfo":"采用铜模铸造方法成功制备了体积分数高达27%的<span style=\"color:red\">SiC</span>/Zr55<span style=\"color:red\">Al10Ni</span>5Cu30块体非晶复合材料.光学显微镜、X射线衍射和透射电镜分析表明,非晶基体上均匀分布<span style=\"color:red\">SiC</span>颗粒,<span style=\"color:red\">SiC</span>颗粒与基体间形成了厚度为10 nm的反应层DSC分析表明,块体非晶复合材料的玻璃转变温度、晶化温度和过冷液相区随<span style=\"color:red\">SiC</span>体积分数的增加而提高.电子探针分析和计算结果表明,Si原子和部分C原子通过扩散进入基体合金中,从而提高了非晶合金的形成能力和热稳定性.","authors":[{"authorName":"武晓峰","id":"11185f4c-39fd-4333-94f0-2d6fac3a4da6","originalAuthorName":"武晓峰"},{"authorName":"邱克强","id":"f334019a-a141-4da8-9b72-0503a1d54d3a","originalAuthorName":"邱克强"},{"authorName":"张海峰","id":"4bcb6dbd-3acc-44a4-8c07-9757e0ded095","originalAuthorName":"张海峰"},{"authorName":"王爱民","id":"dedc5044-4c99-4e73-b574-efb9b5fcfa88","originalAuthorName":"王爱民"},{"authorName":"杨洪才","id":"e545d53e-4bf4-460f-a801-b4ce538fa430","originalAuthorName":"杨洪才"},{"authorName":"胡壮麒","id":"961f66ab-759d-4717-ac12-913d15cc3e7e","originalAuthorName":"胡壮麒"}],"doi":"10.3321/j.issn:0412-1961.2003.04.016","fpage":"414","id":"7b8f3c6c-c072-483f-8af7-e37be35d5308","issue":"4","journal":{"abbrevTitle":"JSXB","coverImgSrc":"journal/img/cover/JSXB.jpg","id":"48","issnPpub":"0412-1961","publisherId":"JSXB","title":"金属学报"},"keywords":[{"id":"0bdbfb88-d256-444c-8684-b6f904c172b0","keyword":"<span style=\"color:red\">SiC</span>/Zr55<span style=\"color:red\">Al10Ni</span>5Cu30,块体非晶复合材料,非晶形成能力、热稳定性","originalKeyword":"SiC/Zr55Al10Ni5Cu30,块体非晶复合材料,非晶形成能力、热稳定性"}],"language":"zh","publisherId":"jsxb200304016","title":"<span style=\"color:red\">SiC</span>颗粒对Zr55<span style=\"color:red\">Al10Ni</span>5Cu30非晶形成能力和热稳定性的影响","volume":"39","year":"2003"},{"abstractinfo":"The point of zero charge(PZC) of <span style=\"color:red\">SiC</span> nanoparticles was determined by means of standard potentiometric titration method, while the influences of the main technological parameters on the microstructure of electrodeposited <span style=\"color:red\">Ni-SiC</span> composite film were studied and optimized. The results show that high bath pH value favors <span style=\"color:red\">SiC</span> nanoparticles negatively charged and high bath temperature promotes them positively charged. Under the experimental conditions, sodium dodecyl-glycol is proven to be an effective surface modification anionic surfactant for <span style=\"color:red\">SiC</span> nanoparticles. The results also show that the optimized <span style=\"color:red\">Ni-SiC</span> composite film is composed of the nanoparticles with the average grain size in the nanometer range (100 nm), and <span style=\"color:red\">SiC</span> nanoparticles disperse into the nickel matrix uniformly.","authors":[],"categoryName":"|","doi":"","fpage":"41167","id":"02a0eba7-bc40-4b31-81cc-35e2910f6e7f","issue":"1","journal":{"abbrevTitle":"TONMSOC","id":"9449c409-0c62-400e-a51e-429b454dce51","issnPpub":"1003-6326","publisherId":"TONMSOC","title":"Transactions of Nonferrous Metals Society of China"},"keywords":[{"id":"a882a413-253d-4bf8-850b-35f804094223","keyword":"<span style=\"color:red\">Ni-SiC</span> nanocomposite film-;point of zero charge;potentiometric;titration;electroplating;nickel;coatings;codeposition;particles;oxides;silica","originalKeyword":"Ni-SiC nanocomposite film-;point of zero charge;potentiometric;titration;electroplating;nickel;coatings;codeposition;particles;oxides;silica"}],"language":"en","publisherId":"1003-6326_2007_1_1","title":"Electrodeposition of <span style=\"color:red\">Ni-SiC</span> nanocomposite film","volume":"17","year":"2007"},{"abstractinfo":"研究了<span style=\"color:red\">Ni</span>/<span style=\"color:red\">SiC</span>复合镀层在3.5%NaCl溶液中的腐蚀行为.测定了<span style=\"color:red\">Ni</span>/<span style=\"color:red\">SiC</span>镀层在NaCl溶液中的失重曲线,利用solartron恒电位仪测定其极化曲线,借助扫描电镜对镀层表面形貌进行了观察.结果表明,随着腐蚀时间的延长,腐蚀失重逐渐增加,但腐蚀速率逐渐降低;<span style=\"color:red\">Ni</span>/<span style=\"color:red\">SiC</span>复合镀层与纯<span style=\"color:red\">Ni</span>镀层耐盐水腐蚀能力基本相当;<span style=\"color:red\">Ni</span>/<span style=\"color:red\">SiC</span>复合镀层在3.5%NaCl溶液中的开路电位要高于纯<span style=\"color:red\">Ni</span>镀层的开路电位;在3.5%NaCl+H2O2溶液中,两种镀层的开路电位均明显正移,且<span style=\"color:red\">Ni</span>/<span style=\"color:red\">SiC</span>复合镀层自腐蚀电流降低,说明复合镀层耐盐水腐蚀能力有所提高.镀<span style=\"color:red\">Ni</span>层中引入<span style=\"color:red\">SiC</span>颗粒能使其组织细化,并促进复合镀层在3.5%NaCl溶液中发生钝化,可能是<span style=\"color:red\">Ni</span>/<span style=\"color:red\">SiC</span>镀层在盐水中耐蚀性能提高的主要原因.","authors":[{"authorName":"郑学斌","id":"c2191b1e-0513-4d1d-ab5e-bdb2a972778c","originalAuthorName":"郑学斌"},{"authorName":"谭澄宇","id":"58f5989c-e7c2-4e7a-98f4-d20505c3dd92","originalAuthorName":"谭澄宇"},{"authorName":"赵旭山","id":"227ded09-f0ba-4b97-b5a3-5673222695d1","originalAuthorName":"赵旭山"},{"authorName":"刘宇","id":"32620040-463b-4efa-b749-9209997456a2","originalAuthorName":"刘宇"}],"doi":"","fpage":"17","id":"fc8853bb-c549-4a9f-a501-af3fb0001ad2","issue":"2","journal":{"abbrevTitle":"CLBH","coverImgSrc":"journal/img/cover/CLBH.jpg","id":"7","issnPpub":"1001-1560","publisherId":"CLBH","title":"材料保护"},"keywords":[{"id":"bd2f1371-df16-4d30-9ef5-1b4d60d45369","keyword":"<span style=\"color:red\">Ni</span>/<span style=\"color:red\">SiC</span>复合镀层","originalKeyword":"Ni/SiC复合镀层"},{"id":"432ba750-e0e5-4b8e-b25d-004cf58765c2","keyword":"极化曲线","originalKeyword":"极化曲线"},{"id":"44423749-85bb-4d7c-b826-20e328228cee","keyword":"NaCl溶液","originalKeyword":"NaCl溶液"},{"id":"7effe9b3-0a9f-4cab-ba1e-69f18da4d713","keyword":"腐蚀行为","originalKeyword":"腐蚀行为"}],"language":"zh","publisherId":"clbh200802006","title":"<span style=\"color:red\">Ni</span>/<span style=\"color:red\">SiC</span>复合镀层腐蚀行为研究","volume":"41","year":"2008"}],"totalpage":3640,"totalrecord":36398}