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  4. 我国镍镀层及镍电沉积层标准浅析

金属功能材料, 2015, 22(4): 51-54. doi: 10.13228/j.b0yuan.issn1005-8192.2015036

我国镍镀层及镍电沉积层标准浅析

张晓宇 1, , 夏天东 2, , 徐仰涛 3, , Fe3 Al/Q235及Fe3 Al/Cr18-Ni8扩散焊界面的组织结构,研究了Cr、Ni元素对Fe3 Al/钢扩散焊界面组织结构的影响.研究表明:Cr、Ni的扩散有利于促进Fe3 Al与钢中Fe、A1元素的扩散结合,使Fe3 Al/Cr18-Ni8扩散焊界面过渡区的宽度较Fe3 Al/Q235界面过渡区大;并且Fe3 Al/Cr18-Ni8扩散焊界面过渡区新形成的Fe3 Al上弥散分布有含Cr、Ni的第二相,使Fe3A1出现了具有不同间距的位错对,甚至位错缠结现象,有利于提高Fe3 Al/钢扩散焊界面的结合强度.","authors":[{"authorName":"李亚江","id":"c0aa6382-5cbb-40eb-a4b9-d42737591eb9","originalAuthorName":"李亚江"},{"authorName":"王娟","id":"c71470b3-b7fe-4010-bf5b-1d60966cbf91","originalAuthorName":"王娟"},{"authorName":"","id":"00cf3f63-c7cc-4ec2-ba85-100283127d38","originalAuthorName":""},{"authorName":"马海军","id":"537b6ffb-058f-4d59-ac62-525360bd0be1","originalAuthorName":"马海军"}],"doi":"10.3969/j.issn.1005-0299.2007.04.007","fpage":"469","id":"7c5aff6d-a8f0-401b-b61c-329240019104","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":"07c06f57-9e6d-4e8a-89a6-19f925faa42e","keyword":"Cr、Ni元素","originalKeyword":"Cr、Ni元素"},{"id":"92b5355c-8fde-4982-b275-485a879ead03","keyword":"Fe3 Al/钢界面","originalKeyword":"Fe3 Al/钢界面"},{"id":"2a9185bc-dfdc-4a13-a2bf-38fcc0d958ff","keyword":"扩散焊","originalKeyword":"扩散焊"},{"id":"e9cae317-5814-4943-b1a9-85ca067d4d8d","keyword":"组织结构","originalKeyword":"组织结构"}],"language":"zh","publisherId":"clkxygy200704007","title":"Cr、Ni元素对Fe3 Al/钢扩散焊界面组织结构的影响","volume":"15","year":"2007"},{"abstractinfo":"以偏硅酸钠为硅源,采用沉淀法将Fe3 O4颗粒包覆在SiO2中,制备了磁性核壳型Fe3 O4@SiO2。通过单因素实验考察了反应时间、盐酸滴加时间和偏硅酸钠浓度对样品包覆率的影响,并对样品的物相和显微结构进行了分析与表征。结果表明:偏硅酸钠可作为制备磁性核壳型Fe3 O4@SiO2材料的硅源;适宜的反应条件为反应时间2h、盐酸滴加时间2h、偏硅酸钠浓度0.2mol·L-1,此时样品包覆率接近100%;SiO2对Fe3 O4形成了有效包覆,但存在团聚现象。","authors":[{"authorName":"丁冰晶","id":"84fbc3e0-60e4-48ff-9561-54c4ece55ce1","originalAuthorName":"丁冰晶"},{"authorName":"范立维","id":"210376e2-e9fd-465b-b2fb-e8c32a3e179a","originalAuthorName":"范立维"},{"authorName":"林兆宇","id":"5b8dd9bd-f445-4a74-8dc4-9d034352bb07","originalAuthorName":"林兆宇"},{"authorName":"吴正国","id":"a77bf173-85fb-4cfe-b6bf-6992cfd7877f","originalAuthorName":"吴正国"},{"authorName":"吕迪","id":"b31f90dd-ccff-4c95-be55-f8d247b1dc16","originalAuthorName":"吕迪"},{"authorName":"卢泽湘","id":"2ea0927d-e92b-4cfc-9b35-e56115c7b064","originalAuthorName":"卢泽湘"}],"doi":"","fpage":"44","id":"2a3141c4-47f2-494b-a9ea-874b8c2d5a87","issue":"4","journal":{"abbrevTitle":"HCCLLHYYY","coverImgSrc":"journal/img/cover/HCCLLHYYY.jpg","id":"42","issnPpub":"1671-5381","publisherId":"HCCLLHYYY","title":"合成材料老化与应用"},"keywords":[{"id":"b802631f-cd3d-4248-b3fb-e665b317f681","keyword":"制备","originalKeyword":"制备"},{"id":"fe2a7194-7e47-4480-bb2b-6a1547b8806c","keyword":"磁性","originalKeyword":"磁性"},{"id":"83e4a383-e866-4ab8-b1ff-a6e6a48e8b1b","keyword":"Fe3O4SiO2","originalKeyword":"Fe3O4SiO2"},{"id":"1f8c9e5e-333e-4904-83f6-da7f3043343a","keyword":"硅源","originalKeyword":"硅源"}],"language":"zh","publisherId":"hccllhyyy201504010","title":"磁性核壳型Fe3 O4@SiO2的制备及表征?","volume":"","year":"2015"},{"abstractinfo":"对落叶松植物多酚进行胺甲基化改性,将其包覆于磁性 Fe3 O4颗粒表面,制备了功能化 Fe3 O4@胺甲基改性植物多酚(Fe3 O4@A-PP),用于能源微藻-普通小球藻的收集。采用 FTIR、磁滞回线、zeta 电位的方法对Fe3 O4@A-PP磁性材料的物理化学性质进行了测定,并研究了投加方式、包覆比例对Fe3 O4@A-PP收集微藻效能的影响。FTIR显示 Fe3 O4@A-PP具有来自 A-PP 的 C—H、N—H 和—OH 等官能团。A-PP 包覆对 Fe3 O4的磁性无改变。与 A-PP的zeta电位相比,Fe3 O4@A-PP的zeta电位增大了5~10 mV。Fe3 O4@A-PP 中两者配比影响微藻的收集效率,当配比为20/200时,收集率达到最大值84.2%。采用 Fe3 O4@A-PP可以将磁絮凝收集时间从 A-PP的30 min缩短至0.5 min 以内。显微图像显示,与 A-PP 絮凝后絮体呈片状松散团聚的状态相比, Fe3 O4@A-PP收集的微藻细胞呈链状被 Fe3 O4包裹或团簇在其四周。吸附电中和在 Fe3 O4@A-PP 磁絮凝收集微藻的机理中发挥重要作用。","authors":[{"authorName":"赵远","id":"1e3e47a8-da26-402c-8db5-bf5d144561e0","originalAuthorName":"赵远"},{"authorName":"王晓宇","id":"27c71cea-8e93-43a4-b9e0-c11c016f7922","originalAuthorName":"王晓宇"},{"authorName":"刘丽君","id":"6882365f-3df5-4e31-81db-3cd32f64681f","originalAuthorName":"刘丽君"},{"authorName":"梁文艳","id":"b2cf38c8-2aa2-40b9-bf90-e6fffdd6becd","originalAuthorName":"梁文艳"}],"doi":"10.13801/j.cnki.fhclxb.20160317.003","fpage":"121","id":"c5350aa0-b314-4c9d-9e38-5ee1acf02885","issue":"1","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":"fc01349a-ebc2-4e2a-8213-64aea6dfb4c8","keyword":"植物多酚","originalKeyword":"植物多酚"},{"id":"e4ec2203-2961-4334-8b6e-e5c3d6abe420","keyword":"Fe3 O4","originalKeyword":"Fe3 O4"},{"id":"d59cebdc-48dd-4f30-8834-d34c1ff5c77e","keyword":"胺甲基化改性","originalKeyword":"胺甲基化改性"},{"id":"7dca5394-2d31-490d-92b3-c9bed1734e72","keyword":"微藻","originalKeyword":"微藻"},{"id":"503d84ff-0bd4-4d65-8b40-46518015abb1","keyword":"收集","originalKeyword":"收集"},{"id":"b64a348a-8235-49bc-b80a-9e85f1c40c53","keyword":"絮凝","originalKeyword":"絮凝"}],"language":"zh","publisherId":"fhclxb201701016","title":"Fe3 O4@胺甲基改性植物多酚磁絮凝收集能源微藻","volume":"34","year":"2017"},{"abstractinfo":"基于密度泛函理论的第一性原理,研究了铬、钼原子对 FeAl/Fe3 Al 相界面结合能及电子结构的影响。结果表明:铬、钼原子在 FeAl/Fe3 Al 相界面处均优先替代铝原子的位置,替代铝后均可提高相界面的结合能以及断裂强度;铬、钼原子的添加增加了 FeAl/Fe3 Al 相界面态密度的成键峰数量,分化了相界面处铝和铁原子的态密度形态,增加了相界面处的电荷密度。","authors":[{"authorName":"陈煜","id":"a100c543-2816-4363-8d9b-7b067a791ad7","originalAuthorName":"陈煜"},{"authorName":"姚正军","id":"93d298d5-f468-4bd6-b7fb-b37638ba8c14","originalAuthorName":"姚正军"},{"authorName":"张平则","id":"08b1822a-fee6-4945-bf77-d0b1b608219c","originalAuthorName":"张平则"},{"authorName":"罗西希","id":"6cddb67c-1a1f-4f98-8e22-ba1392491715","originalAuthorName":"罗西希"},{"authorName":"韩培德","id":"07e7e5b8-31e9-4cc8-a455-8b5cba46c50b","originalAuthorName":"韩培德"}],"doi":"10.11973/jxgccl201605019","fpage":"96","id":"3ca1df98-a507-4a9a-b04c-11b8c67702cf","issue":"5","journal":{"abbrevTitle":"JXGCCL","coverImgSrc":"journal/img/cover/JXGCCL.jpg","id":"45","issnPpub":"1000-3738","publisherId":"JXGCCL","title":"机械工程材料"},"keywords":[{"id":"48612474-2a84-4eac-9ffd-07ce940d1df5","keyword":"FeAl/Fe3Al相界面","originalKeyword":"FeAl/Fe3Al相界面"},{"id":"f194954f-4245-4c99-8ca8-ef88a98f2ca1","keyword":"合金化","originalKeyword":"合金化"},{"id":"db629a95-d586-4af2-8d5e-2d86f9dcef0f","keyword":"电子结构","originalKeyword":"电子结构"},{"id":"722ffbd9-bd42-4184-b258-6fb82158ac12","keyword":"第一性原理","originalKeyword":"第一性原理"}],"language":"zh","publisherId":"jxgccl201605019","title":"铬、钼原子对FeAl/Fe3 Al相界面结合能和电子结构的影响","volume":"40","year":"2016"},{"abstractinfo":"将胺甲基化改性植物多酚(A?PP)包覆Fe3O4后所制备的Fe3O4@A?PP,作为功能性磁絮凝剂用于能源微藻细胞的采收,研究了藻液pH值、藻细胞胞外分泌有机物、絮凝搅拌条件和磁场强度对Fe3 O4@A?PP收集微藻细胞效率的影响.结果显示,与A?PP相比,Fe3 O4@A?PP的等电点由6.5提高到8.5,收集微藻的最佳pH值由7.1增大至8.2.Fe3O4@A?PP收集微藻细胞时,不受胞外分泌有机物的影响.快速搅拌的速率在200—500 r·min-1之间时,对Fe3 O4@A?PP收集微藻的效率影响不大,在快速搅拌之后无需增加慢速搅拌.在磁场强度为0.16 T—0.28 T时,Fe3 O4@A?PP 收集率随着磁场强度升高而逐渐增大,大于0.28 T后,收集效率不再增加.","authors":[{"authorName":"赵远","id":"1944e77b-6122-4286-b6f5-9a02c8401382","originalAuthorName":"赵远"},{"authorName":"王晓宇","id":"e2bd6f92-67ed-47b0-be2a-85796e0822e1","originalAuthorName":"王晓宇"},{"authorName":"刘丽君","id":"1f4742ea-aa5f-43f2-bc15-d0471fefad1b","originalAuthorName":"刘丽君"},{"authorName":"梁文艳","id":"38d3603e-fbbc-4670-ace2-b01db56349fb","originalAuthorName":"梁文艳"}],"doi":"10.7524/j.issn.0254-6108.2016.11.2016032205","fpage":"2418","id":"4d46fec4-5fe5-48f3-b876-052ff89b29ba","issue":"11","journal":{"abbrevTitle":"HJHX","coverImgSrc":"journal/img/cover/HJHX.jpg","id":"43","issnPpub":"0254-6108","publisherId":"HJHX","title":"环境化学 "},"keywords":[{"id":"ee45e1d5-992b-4808-aef8-26da169649d6","keyword":"Fe3O4A-PP","originalKeyword":"Fe3O4A-PP"},{"id":"aaa7522d-5b13-45de-b350-852fae9491b3","keyword":"磁分离","originalKeyword":"磁分离"},{"id":"597def11-c924-457d-99a6-a2d8c72ac441","keyword":"絮凝","originalKeyword":"絮凝"},{"id":"cf28b72a-388b-4700-b14a-9e66dcc4abb7","keyword":"影响因素","originalKeyword":"影响因素"}],"language":"zh","publisherId":"hjhx201611023","title":"Fe3 O4@胺甲基植物多酚收集微藻的影响因素","volume":"35","year":"2016"},{"abstractinfo":"以Fe3 O4为核心,以IRMOF-3为壳层,采用层层包裹的方法制备了核-壳结构的磁性 Fe3 O4@IR-MOF-3材料。用 X 射线衍射(XRD)、傅里叶变换红外光谱(FT-IR )、透射电镜(TEM )、及扫描电镜(SEM)等手段对材料进行表征,并考察了材料在 Kno-evenagel缩合反应中的催化反应性能。实验结果表明,Fe3 O4@IRMOF-3材料呈现出 Fe3 O4和 IRMOF-3的双重功能,既可以磁性分离,又具有 IRMOF-3的晶体结构、孔结构和催化性能,在 Knoevenagel 缩合反应中表现出较好的催化活性、选择性和稳定性。","authors":[{"authorName":"李晓芳","id":"ba0a0c35-616c-4d87-b0f1-56009e6aef96","originalAuthorName":"李晓芳"},{"authorName":"张艳梅","id":"871a877d-31ca-4863-81e8-d134f5b97af2","originalAuthorName":"张艳梅"},{"authorName":"田苗苗","id":"b9510517-138c-4e25-a4f0-d4db567f4f36","originalAuthorName":"田苗苗"},{"authorName":"储刚","id":"45242c3d-76e6-4b18-a4d8-ec8e80861be3","originalAuthorName":"储刚"},{"authorName":"张静","id":"c9713ccc-79de-43cb-9819-2ed54c3d9e58","originalAuthorName":"张静"},{"authorName":"范圣第","id":"958cc544-7cc1-48dc-9f47-36636a84e0f6","originalAuthorName":"范圣第"},{"authorName":"王剑锋","id":"9a88619c-f127-4742-84a3-3210d5c725ec","originalAuthorName":"王剑锋"}],"doi":"10.3969/j.issn.1001-9731.2015.06.008","fpage":"6039","id":"15d056ae-52fc-40d2-beab-3b8514411a72","issue":"6","journal":{"abbrevTitle":"GNCL","coverImgSrc":"journal/img/cover/GNCL.jpg","id":"33","issnPpub":"1001-9731","publisherId":"GNCL","title":"功能材料"},"keywords":[{"id":"1e312530-d8d3-4b36-80a3-b4fe476bafde","keyword":"金属有机骨架材料","originalKeyword":"金属有机骨架材料"},{"id":"cc4c81d2-16a3-41da-93ce-1658a5d1645b","keyword":"Fe3O4","originalKeyword":"Fe3O4"},{"id":"e121f09f-d11e-4962-b187-78850c836836","keyword":"IRMOF-3","originalKeyword":"IRMOF-3"},{"id":"d633ef29-3c95-489a-ab70-c6f868b52b41","keyword":"Kno-evenagel缩合反应","originalKeyword":"Kno-evenagel缩合反应"},{"id":"e7dcfe12-2f6b-479b-bf5d-afcd7b16585c","keyword":"稳定性","originalKeyword":"稳定性"}],"language":"zh","publisherId":"gncl201506008","title":"核-壳型磁性金属有机骨架材料Fe3 O4@IRMOF-3的合成、表征及其催化反应研究?","volume":"","year":"2015"},{"abstractinfo":"本文利用热力学分析了铁尾矿中主体元素可能发生的反应并对生成的产物进行了预测.理论分析表明,尾矿中Fe3O4和FeTiO3的还原是逐级进行的,虽有中间产物的产生,但随温度的升高,最终转化为Fe3Si和Ti(C,N),这为合成制备Fe-Si-Ti多相材料提供了理论基础.在热力学分析的基础上,采用碳热还原氮化法制备了Fe3Si-Ti(C,N)多相材料,并借助XRD和SEM对烧结体的物相和显微形貌进行了表征.结果表明,1300℃以上时,产物的主晶相为Fe3Si和Ti(C,N),与热力学分析结果吻合.通过SEM分析可知,生成的Ti(C,N)相富集在Fe3Si相的周围,形成一种高硬度、耐磨、抗腐蚀的复合材料,表明这是一条从废弃尾矿制得良好的耐磨材料的绿色工艺.","authors":[{"authorName":"刘明","id":"ff477f2f-1f85-44b6-8083-8f4cb5b65132","originalAuthorName":"刘明"},{"authorName":"徐利华","id":"5d2446e7-491c-476a-a14b-6c9071b2f717","originalAuthorName":"徐利华"},{"authorName":"邸云萍","id":"6470fecc-0063-4462-8e7c-490f13ac9e59","originalAuthorName":"邸云萍"},{"authorName":"仉小猛","id":"cca342d5-1b5b-4fa0-8ed5-daab703dedaa","originalAuthorName":"仉小猛"},{"authorName":"郝洪顺","id":"5b4186f1-c8e6-41de-b0fc-b55b3d783c44","originalAuthorName":"郝洪顺"}],"doi":"","fpage":"667","id":"0d0b6b24-d3b0-4256-9993-8bbaf04fbb1e","issue":"4","journal":{"abbrevTitle":"GSYTB","coverImgSrc":"journal/img/cover/GSYTB.jpg","id":"36","issnPpub":"1001-1625","publisherId":"GSYTB","title":"硅酸盐通报 "},"keywords":[{"id":"d9c418af-b354-458d-81d9-368d9181f4f3","keyword":"铁尾矿","originalKeyword":"铁尾矿"},{"id":"75140f81-9be4-4311-b2b1-fc4afc1de20f","keyword":"Fe3Si-Ti(C,N)多相材料","originalKeyword":"Fe3Si-Ti(C,N)多相材料"},{"id":"3b8a0849-46b1-439f-9bc7-4d49c42a8c6e","keyword":"反应热力学","originalKeyword":"反应热力学"},{"id":"8f2b79f6-7582-466c-86ba-8a1c48d901b7","keyword":"碳热还原法","originalKeyword":"碳热还原法"}],"language":"zh","publisherId":"gsytb200804002","title":"合成Fe3 Si-Ti(C,N)多相材料的热力学研究","volume":"","year":"2008"},{"abstractinfo":"目的:在较为温和的条件下制备氧化铁/碳纳米复合材料。方法以纳米 Fe3 O4粉体为催化剂,水热催化纤维素碳化,并借助扫描电镜、透射电镜、X 射线光电子能谱仪和 X 射线衍射仪对碳化产物进行表征分析。结果获得了粒径约为150 nm 的枣核形氧化铁/碳纳米复合材料。结论通过相对温和的水热反应,纤维素被碳化形成了壳核结构的纳米产物, Fe3 O4催化剂在反应过程中被氧化并成为壳核结构产物的核心。","authors":[{"authorName":"江浩","id":"5193feae-43f6-4ed1-95b3-5f55d95ef051","originalAuthorName":"江浩"},{"authorName":"杨继涛","id":"1b1677e9-be90-4b86-a103-5ee3e4cb2a3c","originalAuthorName":"杨继涛"},{"authorName":"胡国新","id":"d277408c-b6ca-4f00-9c15-1cfbac9632e1","originalAuthorName":"胡国新"},{"authorName":"黄浩","id":"0c0d9a52-1e5c-4a94-9e33-b2db6cea2c39","originalAuthorName":"黄浩"}],"doi":"","fpage":"115","id":"eab1b18a-2d5d-43fb-9d52-b391fc68fb14","issue":"4","journal":{"abbrevTitle":"BMJS","coverImgSrc":"journal/img/cover/BMJS.jpg","id":"3","issnPpub":"1001-3660","publisherId":"BMJS","title":"表面技术 "},"keywords":[{"id":"54f76a87-8590-46ff-829b-33874b9ebf1b","keyword":"纤维素","originalKeyword":"纤维素"},{"id":"a4824788-c891-4646-a5c7-6dbc54b57f14","keyword":"Fe3 O4","originalKeyword":"Fe3 O4"},{"id":"bc55f581-5990-4a54-bbd8-44bbc4c2071f","keyword":"水热法","originalKeyword":"水热法"},{"id":"01a03e28-2d99-4709-b90a-0cab63c92530","keyword":"碳化","originalKeyword":"碳化"}],"language":"zh","publisherId":"bmjs201404024","title":"Fe3 O4催化纤维素水热法制备 Fe2 O3/碳纳米复合材料","volume":"","year":"2014"},{"abstractinfo":"采用化学共沉淀?超声辅助法,制备出磁性纳米材料 Fe3 O4,利用溶胶?凝胶法在 Fe3 O4表面包裹Ce/TiO2,得到磁性复合材料Ce/TiO2/Fe3 O4.用XRD、SEM、BET等对其结构和性能进行了表征,催化剂主要以催化活性较高的锐钛矿相存在,Ce/TiO2包覆在纳米Fe3 O4的表面形成多孔结构,复合材料具有Langmuir Ⅳ吸附?脱附等温线,比表面积76.68 m2·g-1,平均孔径8 nm,主要分布在4.5—15.4 nm之间.通过电助光催化降解藏红T溶液研究了Ce/TiO2/Fe3 O4的光电催化活性.在催化剂的加入量为6 g·L-1,降解时间为60 min,外加电压为5 V,50 mg·L-1的藏红T溶液的降解率可达到90%以上,COD去除率达84.7%.所制备的Ce/TiO2/Fe3 O4在重复使用5次后仍能保持较好的光电催化活性.","authors":[{"authorName":"黄驰","id":"adabde70-6eed-4816-be50-d67d70f6a762","originalAuthorName":"黄驰"},{"authorName":"顾桂山","id":"2c9807d1-0dbf-4384-9072-695c9b9fadc2","originalAuthorName":"顾桂山"},{"authorName":"王亚楠","id":"a3256ed7-daea-4b09-92f3-38e7516d4110","originalAuthorName":"王亚楠"},{"authorName":"杨山山","id":"1c96df55-7571-4fe3-b479-babf2de86c7c","originalAuthorName":"杨山山"},{"authorName":"崔荣静","id":"a1ff0ea2-a247-4d93-9ee9-64f477ff1978","originalAuthorName":"崔荣静"},{"authorName":"汪学英","id":"336052c8-7eef-4f07-8f72-8106cb99d4bf","originalAuthorName":"汪学英"}],"doi":"10.7524/j.issn.0254-6108.2015.05.2014070304","fpage":"995","id":"18f6178f-d34c-411f-aff5-0dd4b1bccae1","issue":"5","journal":{"abbrevTitle":"HJHX","coverImgSrc":"journal/img/cover/HJHX.jpg","id":"43","issnPpub":"0254-6108","publisherId":"HJHX","title":"环境化学 "},"keywords":[{"id":"220caf9a-283a-4208-93ce-6afc1590836b","keyword":"铈","originalKeyword":"铈"},{"id":"9240bccb-b417-4974-b50e-3522a3f3393c","keyword":"掺杂","originalKeyword":"掺杂"},{"id":"977f9036-04f6-461c-907e-1a89089a9b59","keyword":"二氧化钛","originalKeyword":"二氧化钛"},{"id":"922a7616-2b28-4767-9c26-cafb9000ab5a","keyword":"四氧化三铁","originalKeyword":"四氧化三铁"},{"id":"5d4d41ec-d0ed-47b7-94c9-287d1a3bea00","keyword":"粒子电极","originalKeyword":"粒子电极"},{"id":"5436b08a-40a5-4b89-885f-94fef61103ec","keyword":"光电催化","originalKeyword":"光电催化"}],"language":"zh","publisherId":"hjhx201505025","title":"Ce/TiO2/Fe3 O4粒子电极光电催化降解藏红T模拟染料废水?","volume":"","year":"2015"},{"abstractinfo":"详细解析了Fe3O4纳米颗粒的改性条件,并对表面活性剂的用量进行了理论估算,实验确定了表面活性剂的用量.研究结果表明:pH值对改性效果影响明显,酸性或强碱性环境对改性均不利;油酸和硬脂酸按一定比例混合使用,可提高改性效果;IR图谱显示了油酸的羧基发生了漂移,表明油酸与纳米Fe3O4粒子间存在化学键结合.","authors":[{"authorName":"王伟","id":"9a95490b-879d-4288-b637-b09695a67f32","originalAuthorName":"王伟"},{"authorName":"沈辉","id":"738cbf40-a16f-42ce-8c8a-6ec57918bfd4","originalAuthorName":"沈辉"}],"doi":"10.3969/j.issn.1005-0299.2001.04.024","fpage":"431","id":"b673ff90-9ec8-47d6-9323-eaddf76ffd64","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":"2f2c2221-deb7-4525-a332-a8ddb3002bfa","keyword":"纳米Fe3O4颗粒","originalKeyword":"纳米Fe3O4颗粒"},{"id":"795a5e1f-5c1a-4bd7-a1f9-51e86952fcc0","keyword":"pH值","originalKeyword":"pH值"},{"id":"c47dd779-4580-4bcb-89dc-298f267230f0","keyword":"表面活性剂","originalKeyword":"表面活性剂"},{"id":"79ac9633-7dff-4c50-8362-e765cd126e19","keyword":"TEM","originalKeyword":"TEM"},{"id":"2311e895-ac2b-425c-8046-fd5342b89801","keyword":"IR","originalKeyword":"IR"}],"language":"zh","publisherId":"clkxygy200104024","title":"纳米Fe3 O4颗粒改性详析","volume":"9","year":"2001"}],"totalpage":6922,"totalrecord":69220}