{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":2,"startPagecode":1},"records":[{"abstractinfo":"","authors":[],"doi":"","fpage":"41","id":"1b12b792-73eb-4b67-ac9e-62dba99957f2","issue":"4","journal":{"abbrevTitle":"JSGNCL","coverImgSrc":"journal/img/cover/JSGNCL.jpg","id":"46","issnPpub":"1005-8192","publisherId":"JSGNCL","title":"金属功能材料"},"keywords":[{"id":"1d4c7f80-a9d1-421d-9a28-0c74f921a879","keyword":"","originalKeyword":""}],"language":"zh","publisherId":"jsgncl200104011","title":"Fe3B7Nd2<span style=\"color:red\">Fei</span>4B纳米复合磁体的组织细化","volume":"8","year":"2001"},{"abstractinfo":"A novel method was reported to measure the remnant magnetic field in Lorentz mode in a <span style=\"color:red\">FEI</span> Tecnai F20 transmission electron microscope equipped with a Lorentz lens. The movement of the circle Bloch line of the cross-tie wall in Permalloy is used to measure the remnant magnetic field by tilting the specimen and adjusting the objective lens current. The remnant magnetic field is estimated to be about 17 Oe, in a direction opposite to that of the objective lens magnetic field. The remnant magnetic field can be compensated by adjusting the value of the objective lens current.","authors":[{"authorName":"Haihua LIU","id":"d1087523-96b3-4a5e-bea7-24c9b01b9f90","originalAuthorName":"Haihua LIU"}],"categoryName":"|","doi":"10.1016/S1006-7191(08)60120-9","fpage":"435","id":"7c829e06-3b93-4bea-bf8e-259309e7bfd1","issue":"6","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":"a1ab2bdb-61de-4818-9e7a-1252bae965e2","keyword":"Lorentz electron microscopy","originalKeyword":"Lorentz electron microscopy"},{"id":"718f7a5d-991a-45b1-bd20-9995907c422e","keyword":"Lorentz lens","originalKeyword":"Lorentz lens"},{"id":"8d7e669d-9f2a-43c1-9f1c-50f9beff68c7","keyword":"remnant magnetic field","originalKeyword":"remnant magnetic field"},{"id":"8c4a22fc-b102-48ea-8755-096c37812c72","keyword":"Permalloy","originalKeyword":"Permalloy"},{"id":"01550cab-85bb-4a2c-b0c0-0d32d1a111e3","keyword":"cross-tie walls","originalKeyword":"cross-tie walls"}],"language":"en","publisherId":"1006-7191_2009_6_8","title":"Measurement of the remnant magnetic-field in Lorentz mode using permalloy","volume":"22","year":"2009"},{"abstractinfo":"采用电沉积方法从硫酸盐体系镀液中沉积得到Fe18Ni82合金薄膜.运用扫描电子显微镜(SEM),原子力显微镜(AFM),透射电子显微镜(TEM)和X射线衍射分析(XRD)以及磁测量设备分别对薄膜的表面形貌、显微结构和磁性能进行表征和测量.同时利用万能材料试验机和显微硬度计测量了薄膜的力学性能.结果表明:电沉积制备的Fe18Ni82合金薄膜成分均匀,表面平整、光亮、致密,晶粒大小为40～50 nm.薄膜是以Ni为溶剂原子,Fe为溶质原子的置换型固溶体,只存在单一的fcc相,<span style=\"color:red\">Fei</span>8Ni82合金薄膜沿(111)面有较强的择优取向.镀态<span style=\"color:red\">Fei</span>8Ni82合金薄膜在50 Hz交流磁场下,测得其饱和磁感应强度为1.08 T,最低矫顽力为20 A/m.19 μm厚的纳米晶薄膜的断裂应力达到785MPa,显微硬度达到605Hv.","authors":[{"authorName":"刘天成","id":"4b732885-0afe-4644-983a-e9f05bd83a10","originalAuthorName":"刘天成"},{"authorName":"卢志超","id":"146a516b-a741-41ff-a152-824f55c1fabb","originalAuthorName":"卢志超"},{"authorName":"李德仁","id":"d3b07e2e-7f80-4d1e-ad3d-e82fdbd0b43d","originalAuthorName":"李德仁"},{"authorName":"孙克","id":"76fb92e5-2db4-4aa4-9030-1c605f845b0e","originalAuthorName":"孙克"},{"authorName":"周少雄","id":"f1a4d467-13b2-49f3-9bc8-b2f546953b96","originalAuthorName":"周少雄"},{"authorName":"卢燕平","id":"9e4abe5d-8d06-4efb-a4fc-719c60202b10","originalAuthorName":"卢燕平"}],"doi":"","fpage":"138","id":"9b780687-ba50-4a77-bbfd-02f05d27c343","issue":"1","journal":{"abbrevTitle":"GNCL","coverImgSrc":"journal/img/cover/GNCL.jpg","id":"33","issnPpub":"1001-9731","publisherId":"GNCL","title":"功能材料"},"keywords":[{"id":"0b6fc2e5-d168-42a3-b209-e38aa499aa68","keyword":"铁镍合金","originalKeyword":"铁镍合金"},{"id":"aec1ef9c-0f20-4683-a8c7-4c3af5744d54","keyword":"薄膜","originalKeyword":"薄膜"},{"id":"68efd93f-bd89-4e79-8c1b-568a5fcd2b01","keyword":"电沉积","originalKeyword":"电沉积"},{"id":"66497d74-4c03-4b80-95c6-13afdf77fce6","keyword":"纳米结构","originalKeyword":"纳米结构"},{"id":"b0201513-847b-4feb-94b5-620814fc6a96","keyword":"性能","originalKeyword":"性能"}],"language":"zh","publisherId":"gncl200701041","title":"电沉积铁镍纳米合金薄膜的结构和性能研究","volume":"38","year":"2007"},{"abstractinfo":"利用ZnFeO4铁氧体材料居里温度对Zn含量敏感的特点,将其作为主成分,通过Cu、Ti离子掺杂技术调整居里温度并提高材料的温度稳定性.采用传统氧化物工艺制备CuTiZn尖晶石铁氧体材料;采用测量起始磁导率的温变曲线间接测量居里温度的方法,获得了CuTiZn磁热铁氧体材料的居里温度.结果表明,Zn含量增加将使居里温度快速下降;材料成分为Cu.0.45Zn0.55Ti0.03<span style=\"color:red\">Fei</span>.97O4时居里温度为44.9℃,起始磁导率达852.5,且居里温度点磁导率的变化率达50.3/℃,该组分的CuZnTi铁氧体具有良好的自控温灵敏度,可以用作温热疗法磁热材料.","authors":[{"authorName":"邓联文","id":"29515183-915b-4f76-bcd8-f83f120b1ce0","originalAuthorName":"邓联文"},{"authorName":"周亮","id":"3232dd91-fcd3-4c73-9ad0-854e6531ef28","originalAuthorName":"周亮"},{"authorName":"李慧敏","id":"cd5b11dd-4b23-4daf-bed6-042a20607d4b","originalAuthorName":"李慧敏"},{"authorName":"黄生祥","id":"31d2dfa5-3144-43c1-9c1f-8ecd78c193ae","originalAuthorName":"黄生祥"},{"authorName":"丁丽","id":"9a9c02d5-1ab9-42bb-bc83-d36ee3988566","originalAuthorName":"丁丽"},{"authorName":"周克省","id":"2963fa99-608d-4461-b7a5-dea6d4e29408","originalAuthorName":"周克省"}],"doi":"","fpage":"7","id":"0ae5dbf1-9754-425c-aff6-fb7011fff5dc","issue":"12","journal":{"abbrevTitle":"CLDB","coverImgSrc":"journal/img/cover/CLDB.jpg","id":"8","issnPpub":"1005-023X","publisherId":"CLDB","title":"材料导报"},"keywords":[{"id":"ea0375be-23f4-4802-b06e-6ebc1e71c6f8","keyword":"CuTiZn铁氧体","originalKeyword":"CuTiZn铁氧体"},{"id":"8b579522-6812-48bb-bce5-7fec056e25a4","keyword":"居里温度","originalKeyword":"居里温度"},{"id":"da27d6de-2a00-4867-9937-35f4d17da16f","keyword":"磁热效应","originalKeyword":"磁热效应"},{"id":"95176163-4628-497e-8fbe-a10e141f6921","keyword":"温热疗法","originalKeyword":"温热疗法"}],"language":"zh","publisherId":"cldb201112003","title":"低居里温度CuZnTi磁热铁氧体材料的研制","volume":"25","year":"2011"},{"abstractinfo":"本文研究了Sm含量,凝固速度及Nb和Zr元素的添加对Sm-Fe合金微观组织及氮化后Sm2<span style=\"color:red\">Fei</span>7Nx合金磁性能的影响.研究结果表明:采用真空感应炉熔炼Sm-Fe合金,当Sm的补偿量大于10wt%时,合金铸锭组织中出现大量的富Sm相,这将导致氮化后磁体磁性能的恶化;提高铸锭的冷却速度及添加Nb和Zr等元素可以有效地细化铸锭中α-Fe相的晶粒,减少均匀化退火后α-Fe相的数量,提高磁性能.","authors":[{"authorName":"马建勋","id":"bd74e4ea-844f-4fcb-8e80-c7236f31c64f","originalAuthorName":"马建勋"},{"authorName":"严密","id":"367caaaf-d9d8-4e8a-9240-f3c0da8847b8","originalAuthorName":"严密"},{"authorName":"赵传礼","id":"d4414e66-f0c8-4f8e-acdf-6156bb52fdb8","originalAuthorName":"赵传礼"},{"authorName":"肖洪博","id":"207ea7ac-0fe0-4434-9b5c-1d8b9669f954","originalAuthorName":"肖洪博"},{"authorName":"文玉华","id":"b9480f60-5771-4a61-9b79-b6af68e68dda","originalAuthorName":"文玉华"},{"authorName":"杨德仁","id":"e1537de6-f53f-4641-b558-b8f7c53e13b3","originalAuthorName":"杨德仁"}],"doi":"10.3969/j.issn.1673-2812.2005.02.023","fpage":"244","id":"5e188b79-a3e6-4a38-bc06-3fa2c83e5241","issue":"2","journal":{"abbrevTitle":"CLKXYGCXB","coverImgSrc":"journal/img/cover/CLKXYGCXB.jpg","id":"13","issnPpub":"1673-2812","publisherId":"CLKXYGCXB","title":"材料科学与工程学报"},"keywords":[{"id":"138f6e7e-827f-4e3d-8ab9-cabcb2879d29","keyword":"微观组织","originalKeyword":"微观组织"},{"id":"e81111ed-44b2-4e27-8bfe-146907dc538d","keyword":"Sm2<span style=\"color:red\">Fei</span>7Nx","originalKeyword":"Sm2Fei7Nx"},{"id":"2688edb9-9fb7-4a23-af16-0b2f57e044fd","keyword":"磁性能","originalKeyword":"磁性能"}],"language":"zh","publisherId":"clkxygc200502023","title":"氮化前显微组织对SmFeN合金磁性能的影响","volume":"23","year":"2005"},{"abstractinfo":"采用X射线衍射分析(XRD)技术,研究了NdprFeCoB熔体快淬所制备的α-Fee/Nd2Fe14B纳米晶的织构形成过程.结果表明,Nd2Fe14B纳米晶具有较强的(001)织构,而α-Fe纳米晶具有(110)织构,这些织构垂直于薄带表面,且从自由面到激冷面逐渐减弱.从自由面到激冷面,Nd2Fe14B相在(001)晶面法线方向的尺寸和α-Fe相在(220)晶面法线方向的尺寸逐渐减小.在激冷面各晶面法线方向的尺寸相近,表明纳米晶的形状近似于等轴晶.α-Fe/Nd2<span style=\"color:red\">Fei</span>4B纳米晶织构的形成和生长受合金薄带在凝固过程中热流梯度的控制.","authors":[{"authorName":"李晓红","id":"e73b3272-e0da-44b9-905a-7bb25a9c321a","originalAuthorName":"李晓红"},{"authorName":"关颖","id":"d6eca433-83d3-4caa-9678-ab5ab2c3e57d","originalAuthorName":"关颖"},{"authorName":"李伟","id":"0a1f1d04-a435-43e4-9de8-5625612e2b42","originalAuthorName":"李伟"},{"authorName":"张静武","id":"c9732262-7339-4998-a697-d7425968f16e","originalAuthorName":"张静武"},{"authorName":"张湘义","id":"c66aa407-1284-407f-ac23-6ec9b5487e3d","originalAuthorName":"张湘义"}],"doi":"","fpage":"558","id":"01119a37-dbc5-433e-8b79-86fbf5bd35ab","issue":"z1","journal":{"abbrevTitle":"GNCL","coverImgSrc":"journal/img/cover/GNCL.jpg","id":"33","issnPpub":"1001-9731","publisherId":"GNCL","title":"功能材料"},"keywords":[{"id":"5e8c0ca8-4e13-4b04-918d-10a0b2436735","keyword":"复合纳米永磁体","originalKeyword":"复合纳米永磁体"},{"id":"c1d1639c-3597-4f7a-aac9-faa4a0a2f101","keyword":"晶体织构","originalKeyword":"晶体织构"},{"id":"3f44e5e5-1c42-48ab-9360-5e0677bd083e","keyword":"控制","originalKeyword":"控制"},{"id":"15002c31-709a-4b2e-a41d-5df6c89f7df4","keyword":"凝固","originalKeyword":"凝固"}],"language":"zh","publisherId":"gncl2004z1147","title":"α-Fe/Nd2Fe14B复合纳米晶的织构形成研究","volume":"35","year":"2004"},{"abstractinfo":"采用真空氩弧熔炼加铜模吸铸的方法成功制备了3种ZrAlNiCu全非晶材料.通过Instron-3369力学性能试验机测试了3种金属玻璃的压缩力学性能,并采用<span style=\"color:red\">FEI</span> Nano230型场发射扫描电镜(SEM)研究了压缩断口特征.研究表明,增加Ni含量和降低Cu含量将降低ZrAlNiCu金属玻璃的断裂强度和弹性模量,并使得ZrAINiCu金属玻璃的断口由扩展良好的“脉络状”花纹转变为完全脆性特征.Ni含量的增加以及Cu含量的降低减少了ZrAlNiCu金属玻璃中自由体积的密度,降低了合金的变形能力,增加了合金的变形局域化程度,从而降低了ZrAlNiCu金属玻璃的断裂强度、塑性和弹性模量.","authors":[{"authorName":"宋旼","id":"97033cf6-1762-41bd-ba46-089692a20800","originalAuthorName":"宋旼"},{"authorName":"李杳奇","id":"5dc95ecf-c51b-4222-ad37-b9384f36f5f2","originalAuthorName":"李杳奇"},{"authorName":"贺跃辉","id":"93a00bc6-1e91-4475-87b6-324a7b1b3080","originalAuthorName":"贺跃辉"}],"doi":"","fpage":"1836","id":"420cf6e1-bf12-4f30-8aaa-9b511838b267","issue":"10","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":"c003773a-de6d-4c5c-9d2d-bbf9e22e7568","keyword":"ZrAlNiCu金属玻璃","originalKeyword":"ZrAlNiCu金属玻璃"},{"id":"4838673a-c319-4518-9509-c50aef87fa35","keyword":"力学性能","originalKeyword":"力学性能"},{"id":"133fe7c0-6281-4826-91a4-a5ec185e76d1","keyword":"自由体积","originalKeyword":"自由体积"}],"language":"zh","publisherId":"xyjsclygc201110031","title":"三种ZrAlNiCu大块金属玻璃的力学性能","volume":"40","year":"2011"},{"abstractinfo":"为了探讨1,4-丁炔二醇对纳米晶镍镀层硬度和耐蚀性的影响,采用直流电沉积法在黄铜表面制备了纳米晶镍镀层.利用X7000 X射线衍射仪、<span style=\"color:red\">FEI</span> Quanta600 FE-SEM扫描电镜、DUH-211S动态超显微微米压痕仪、动电位极化曲线及阻抗谱,研究了不同浓度1,4-丁炔二醇对镍镀层结构、硬度及耐蚀性的影响规律.结果表明:随着镀液中1,4-丁炔二醇浓度的增加,镍镀层晶面的择优取向由(200)织构向(111)转变,晶粒尺寸减小;镍镀层硬度增加,在1,4丁炔二醇浓度为0.5 g/L时达到654 HV;在3.5％NaCl(质量分数)溶液中当1,4-丁炔二醇浓度为0.1 g/L时,镍镀层的耐腐蚀性最好.","authors":[{"authorName":"朴楠","id":"54537e43-9d6e-4012-a4f4-2cc803bec4f9","originalAuthorName":"朴楠"},{"authorName":"陈吉","id":"03ef006d-07e4-41c8-a20f-25fe20c1746f","originalAuthorName":"陈吉"},{"authorName":"孙彦伟","id":"f0a9f847-41b1-4c7f-a65b-354f248f4044","originalAuthorName":"孙彦伟"},{"authorName":"许志显","id":"7404f5bd-aabe-4dc8-8872-e79331d5a7cb","originalAuthorName":"许志显"},{"authorName":"陈晓明","id":"d0f7765d-41bb-4ba0-860c-6829619bf1f9","originalAuthorName":"陈晓明"},{"authorName":"韩啸","id":"20cea98d-b1f3-4bdd-8620-c5c911e9ab68","originalAuthorName":"韩啸"}],"doi":"","fpage":"5","id":"8ce28b1f-8787-441a-b5dc-102c170bb3d4","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":"d420935d-9bbf-4619-af3e-116b7669092a","keyword":"直流电沉积","originalKeyword":"直流电沉积"},{"id":"aa4e02c1-c788-4c1b-a0b5-e8b31ee99d0c","keyword":"纳米晶镍","originalKeyword":"纳米晶镍"},{"id":"c02fbb8e-a58b-4bb7-a4fc-195d7e86195b","keyword":"1,4-丁炔二醇","originalKeyword":"1,4-丁炔二醇"},{"id":"2ba9697c-538f-473e-a4bb-1e8c73eb099d","keyword":"镀层结构","originalKeyword":"镀层结构"},{"id":"59382766-5184-4a70-b1ce-911a29bd45a8","keyword":"硬度","originalKeyword":"硬度"},{"id":"bc104d1d-2959-4c4b-b2fd-f946e6535e3c","keyword":"耐蚀性","originalKeyword":"耐蚀性"}],"language":"zh","publisherId":"clbh201502002","title":"1,4-丁炔二醇对纳米晶镍镀层结构及性能的影响","volume":"48","year":"2015"},{"abstractinfo":"为了掌握含Re的高温叶片用钢11Cr10Co2W2MoReVNbNB的最佳热处理工艺和组织性能,对钢进行了热处理工艺试验和组织性能分析.采用Gleeble3800型热/力模拟试验机测定了钢的相变点,采用IN-STRON-5582型电子拉力试验机、HVS-1000型维氏硬度计测定了钢的力学性能,采用Olympus-PMG3型光学显微镜、SUPRA55型扫描电镜、<span style=\"color:red\">FEI</span> Tecnai G2 F30型透射电镜分析了钢的组织性能.实验结果表明:钢在1 100～1 140℃内淬火、在660～ 700℃内回火时,淬火温度和回火温度对材料性能基本没有影响；与其他高温用12％ Cr钢相比,11 Cr10Co2W2MoReVNbNB钢具有良好的韧性,室温V型冲击性能高达40 J以上；钢的组织为回火索氏体,组织均匀、晶粒细小.钢的最佳热处理工艺为(1 120±10)℃油冷+(690±10)℃空冷,钢的主要强化相为M23 C6,Re主要存在于基体中,起固溶强化作用.","authors":[{"authorName":"彭建强","id":"b87e66da-5760-45c9-8180-7bb692e797b0","originalAuthorName":"彭建强"},{"authorName":"闫红博","id":"86e1d03b-8beb-4181-a1cb-1928cd4d6606","originalAuthorName":"闫红博"},{"authorName":"孙福民","id":"4194591e-2122-4bd2-80ab-4b44a684570e","originalAuthorName":"孙福民"},{"authorName":"宗影影","id":"8bbab835-037c-413d-abf0-7f75e2398edd","originalAuthorName":"宗影影"},{"authorName":"单德彬","id":"cc6924bf-7045-4d94-b69a-b46b8c285a5b","originalAuthorName":"单德彬"}],"doi":"","fpage":"44","id":"6e9d337d-4e87-4626-a8c9-2cd21726bc32","issue":"4","journal":{"abbrevTitle":"CLKXYGY","coverImgSrc":"journal/img/cover/CLKXYGY.jpg","id":"14","issnPpub":"1005-0299","publisherId":"CLKXYGY","title":"材料科学与工艺"},"keywords":[{"id":"c2edc15b-3484-425f-bb4c-947f40d2d54b","keyword":"含Re叶片钢","originalKeyword":"含Re叶片钢"},{"id":"845766da-e326-4838-abe5-9ee38161a869","keyword":"汽轮机","originalKeyword":"汽轮机"},{"id":"e436b5f2-214c-41f3-8c73-5ee1cb074556","keyword":"热处理工艺","originalKeyword":"热处理工艺"},{"id":"5d0a2df2-4a68-4975-8a85-b90314c72738","keyword":"高温","originalKeyword":"高温"},{"id":"9fb4a86e-d493-49dd-bb57-5a032d671450","keyword":"组织","originalKeyword":"组织"}],"language":"zh","publisherId":"clkxygy201304008","title":"一种含Re叶片钢的热处理工艺和组织性能研究","volume":"21","year":"2013"},{"abstractinfo":"铈盐转化膜耐蚀性能不足.采用由氟硅酸盐、氟钛酸铵双组分封闭液对镀锌钢铈盐转化膜进行了封闭处理,优选了封闭液的最佳含量及封闭工艺条件.分别采用BM-4XC金相显微镜、<span style=\"color:red\">FEI</span>-Quanta600环境扫描电镜、INCA能谱仪分析了铈盐转化膜封闭前后的形貌、结构与成分;依据ASTM1B17标准进行了中性盐雾腐蚀,采用PARSTAT227电化学工作站,测试了其在3.5％NaCl溶液中的极化曲线和腐蚀形貌.结果表明:镀锌钢铈盐转化膜封闭后成分从5.80％P,1.96％Fe,64.84％Zn,2.94％Ce和24.46％O变为7.34％P,55.26％Zn,3.67％Ce,33.07％O,0.19％Si和0.47％ Ti;腐蚀电位负移30 mV,腐蚀电流密度降低了11.4％;封闭前中性盐雾时间为10 h,封闭后为72 h,耐蚀性能大大提高.","authors":[{"authorName":"张震","id":"7b5de376-5ccc-4b79-bdf6-776f4df3d46a","originalAuthorName":"张震"},{"authorName":"郭瑞光","id":"af993969-0ef7-4125-b043-baf0e89f6de6","originalAuthorName":"郭瑞光"}],"doi":"","fpage":"17","id":"9e1ce42d-df6f-4906-86f8-ffeeaae4e098","issue":"6","journal":{"abbrevTitle":"CLBH","coverImgSrc":"journal/img/cover/CLBH.jpg","id":"7","issnPpub":"1001-1560","publisherId":"CLBH","title":"材料保护"},"keywords":[{"id":"d04cce02-95d6-4f76-9b96-53165d081b59","keyword":"封闭处理","originalKeyword":"封闭处理"},{"id":"c3a51e3a-e90c-4e9b-b8b6-cfec689ce755","keyword":"氟硅酸盐","originalKeyword":"氟硅酸盐"},{"id":"8ecd13b2-4016-4d08-b42f-bbdd12484ba9","keyword":"氟钛酸铵","originalKeyword":"氟钛酸铵"},{"id":"e6979bb1-4233-45dc-8f0c-204ad1e0bb8a","keyword":"铈盐转化膜","originalKeyword":"铈盐转化膜"},{"id":"ef1a8a64-d9f8-44a1-bf23-d22e68388dc3","keyword":"镀锌钢","originalKeyword":"镀锌钢"}],"language":"zh","publisherId":"clbh201406005","title":"氟硅酸盐/氟钛酸铵封闭铈盐转化膜的耐蚀性能","volume":"47","year":"2014"}],"totalpage":2,"totalrecord":14}