{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"具有高磁晶各向异性场的六角钡<span style=\"color:red\">铁氧体</span>(BaFe12O19, BaM)是毫米波器件中关键的<span style=\"color:red\">旋</span>磁材料.以片状纳米尺度六角钡<span style=\"color:red\">铁氧体</span>单畴颗粒为原料粉体,通过强磁场颗粒取向、加压成型、等静压处理以及微液相参与烧结等过程,成功制备得到了晶粒沿c轴取向度达99%的六角钡<span style=\"color:red\">铁氧体</span>准单晶材料,其磁性接近单晶铁酸钡,饱和磁化强度达到4654kA/m,矫顽场约为9.552kA/m,并对其织构化和致密化机理进行了分析与讨论.","authors":[{"authorName":"刘俊亮","id":"479ebd21-3ae5-4211-a840-d453732c4264","originalAuthorName":"刘俊亮"},{"authorName":"郭翠静","id":"08b661c9-8c64-4c13-bf52-4382b7d02c84","originalAuthorName":"郭翠静"},{"authorName":"张伟","id":"ae851a00-5420-429f-aeac-380c0c9313d0","originalAuthorName":"张伟"},{"authorName":"曾燕伟","id":"5a47ea55-b0f1-439c-8bc7-5235d5001d52","originalAuthorName":"曾燕伟"}],"doi":"10.3724/SP.J.1077.2009.00599","fpage":"599","id":"0c5f3692-7bc3-4151-97c4-84e151a4a1f2","issue":"3","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":"26be3c6b-9e6d-43f6-9f4b-c3d6e2442b43","keyword":"六角钡<span style=\"color:red\">铁氧体</span>","originalKeyword":"六角钡铁氧体"},{"id":"cf52d293-cac3-42a2-aa5a-d3e7d7708026","keyword":"<span style=\"color:red\">旋</span><span style=\"color:red\">磁铁氧体</span>","originalKeyword":"旋磁铁氧体"},{"id":"5dc302d9-a04c-445c-a7f3-98585eb56d03","keyword":"准单晶结构","originalKeyword":"准单晶结构"},{"id":"6acf09e9-cd24-4c9c-87c0-6b19b9b2f0e5","keyword":"液相参与烧结","originalKeyword":"液相参与烧结"}],"language":"zh","publisherId":"wjclxb200903037","title":"六角钡<span style=\"color:red\">铁氧体</span>准单晶块材制备及其磁性能研究","volume":"24","year":"2009"},{"abstractinfo":"采用氧化物陶瓷工艺制备了Ni0.6533-xCu0.1005 Zn0.2613+xFe1.9899O4(x=0,0.0402,0.0804,0.1206)微波<span style=\"color:red\">铁氧体</span>,研究了不同Zn含量对NiCuZn<span style=\"color:red\">铁氧体</span>的显微结构、磁性能和介电性能的影响.结果表明:ZnO具有明显的助熔作用,NiCuZn<span style=\"color:red\">铁氧体</span>的平均晶粒尺寸与饱和磁化强度随着Zn含量的增多逐渐增大,而矫顽力和居里温度则逐渐减小.样品的剩余磁感应强度随着温度的升高而不断降低,且Zn含量越多,其下降速率越大.当x=0.0804时,室温下NiCuZn<span style=\"color:red\">铁氧体</span>具有最高的剩余磁感应强度356 mT,且其温度稳定性也较好.此外,x在0～0.1206范围内,<span style=\"color:red\">铁氧体</span>的电阻率、介电常数和介电损耗角正切变化不大.","authors":[{"authorName":"陈玲珑","id":"de695561-a68c-45d3-9c48-212484e8b5f3","originalAuthorName":"陈玲珑"},{"authorName":"杨艳","id":"81126eea-5c39-4607-8425-e707baabd608","originalAuthorName":"杨艳"},{"authorName":"余忠","id":"d1190c11-552f-4701-abe8-f82cb240127c","originalAuthorName":"余忠"},{"authorName":"蒋晓娜","id":"d1a69b6f-0b07-4f3a-af77-05c76931c957","originalAuthorName":"蒋晓娜"},{"authorName":"孙科","id":"bc1d9687-3656-489d-9c9b-c7b7727dcc58","originalAuthorName":"孙科"},{"authorName":"兰中文","id":"615e8e43-0da4-491e-ba4f-df75f880b0f4","originalAuthorName":"兰中文"}],"doi":"","fpage":"2101","id":"f01bc8bc-a1af-46e2-9e94-eca1a7962e0d","issue":"8","journal":{"abbrevTitle":"RGJTXB","coverImgSrc":"journal/img/cover/RGJTXB.jpg","id":"57","issnPpub":"1000-985X","publisherId":"RGJTXB","title":"人工晶体学报"},"keywords":[{"id":"3abdaeac-4705-4e64-a762-5ae0dacfa902","keyword":"NiCuZn<span style=\"color:red\">铁氧体</span>","originalKeyword":"NiCuZn铁氧体"},{"id":"ca9bae22-f344-4fb0-9b8b-a0729794da79","keyword":"磁性能","originalKeyword":"磁性能"},{"id":"37c15b44-f108-456f-b09f-cce8d59a5258","keyword":"介电性能","originalKeyword":"介电性能"}],"language":"zh","publisherId":"rgjtxb98201508015","title":"Zn含量对NiCuZn<span style=\"color:red\">旋</span><span style=\"color:red\">磁铁氧体</span>的显微结构、磁性能和介电性能的影响","volume":"44","year":"2015"},{"abstractinfo":"叙述了软<span style=\"color:red\">磁铁氧体</span>材料工艺的现状，以及软<span style=\"color:red\">磁铁氧体</span>材料的发展趋势。","authors":[],"doi":"","fpage":"30","id":"b2b3ad72-93cb-42ef-8f04-9ee2c1a5d1f3","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":"284e351e-3900-4a25-b04b-2bf2177c6d4e","keyword":"软<span style=\"color:red\">磁铁氧体</span> 材料工艺Current Status and Future Trend of R&D on Son FerritesLiu Yuhong (Fenghua Electronic Engineering R&D Co．,Ltd,Zhaoqing 526020)","originalKeyword":"软磁铁氧体 材料工艺Current Status and Future Trend of R&D on Son FerritesLiu Yuhong (Fenghua Electronic Engineering R&D Co．,Ltd,Zhaoqing 526020)"}],"language":"zh","publisherId":"cldb200007010","title":"软<span style=\"color:red\">磁铁氧体</span>材料的现状及其发展趋势","volume":"14","year":"2000"},{"abstractinfo":"以铁粉为还原剂,在酸性条件下浸取软锰矿,浸出液通过除杂得净化液,采用碳铵共沉淀法制备锰锌软<span style=\"color:red\">磁铁氧体</span>粉体.并用XRD、SEM和震动样品磁强计对制得的<span style=\"color:red\">铁氧体</span>粉体进行表征.结果表明:在最佳浸提条件下锰的浸出率达到98.4％,通过共沉淀法制备的锰锌软<span style=\"color:red\">磁铁氧体</span>粉体颗粒呈细而均匀的球状,XRD表征结果显示为纯相,饱和磁感应强度为60.45 emu/g,与用硫酸盐制备得到的锰锌软<span style=\"color:red\">磁铁氧体</span>粉体饱和磁感应强度相当.","authors":[{"authorName":"张晓君","id":"a67d6a7b-1227-4449-91e2-f23129d8f013","originalAuthorName":"张晓君"},{"authorName":"颜文斌","id":"40299f71-83cc-4f70-80dd-1a57a02caea2","originalAuthorName":"颜文斌"},{"authorName":"高峰","id":"8c2ddf67-3817-4c5e-9ff6-9be4b09e50a1","originalAuthorName":"高峰"},{"authorName":"易静","id":"0c41f335-748d-4d71-9627-c0d7dc5119b2","originalAuthorName":"易静"},{"authorName":"胡亚莉","id":"2082c5cb-10a6-41ba-827e-5e7eca4842d4","originalAuthorName":"胡亚莉"}],"doi":"","fpage":"1085","id":"5c144433-1283-4ec1-a2f4-b0cd8fc2875a","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":"0eb5b83a-610d-47ed-9709-98ac09436272","keyword":"软锰矿","originalKeyword":"软锰矿"},{"id":"9b14f544-8495-4abb-9f9a-47979ab6c133","keyword":"还原","originalKeyword":"还原"},{"id":"84171640-2a14-46b4-89d4-8850d4e84281","keyword":"浸出","originalKeyword":"浸出"},{"id":"635d43ab-e5ac-450c-9745-df589bd9fc8b","keyword":"锰锌软<span style=\"color:red\">磁铁氧体</span>","originalKeyword":"锰锌软磁铁氧体"}],"language":"zh","publisherId":"gsytb201604017","title":"软锰矿还原浸出制备锰锌软<span style=\"color:red\">磁铁氧体</span>","volume":"35","year":"2016"},{"abstractinfo":"对La-Co替代的M型高性能永<span style=\"color:red\">磁铁氧体</span>进行了详细介绍,包括材料制备的工艺特点,成分,显微结构,材料的内禀参数,技术磁性能以及温度特性等.研究结果表明:最优化组分为Sr0.7La0.3Fe11.7Co0.3O19的M型永<span style=\"color:red\">磁铁氧体</span>的饱和磁化强度Ms(298K)比SrFe12O19永<span style=\"color:red\">磁铁氧体</span>的大1%～3%,磁晶各向异性场Ha大16.8%,磁晶各向异性常数K1大16.7%,磁性能:Br=450mT,Hcj=384kA/m,(BH)max=38.6kJ/m3.","authors":[{"authorName":"王亦工","id":"be72301d-b62c-4d6b-b89b-4cdf96332f22","originalAuthorName":"王亦工"},{"authorName":"陈华辉","id":"71884633-846d-460e-96e9-3e1f6ef124bf","originalAuthorName":"陈华辉"},{"authorName":"张婷","id":"23404678-2d81-4c15-992d-97c5416e43fe","originalAuthorName":"张婷"}],"doi":"","fpage":"758","id":"2f151ec3-23dc-43b4-b0e7-ba8f50841b89","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":"6c5feedb-71ce-4655-8ad7-9fed5ae6a42e","keyword":"M型永<span style=\"color:red\">磁铁氧体</span>","originalKeyword":"M型永磁铁氧体"},{"id":"071fe52a-eb98-49c4-9b20-aff820b2c721","keyword":"La-Co替代","originalKeyword":"La-Co替代"},{"id":"f4d2ee37-58e3-4e13-81a3-bac6c23d809b","keyword":"工艺","originalKeyword":"工艺"},{"id":"13abdac4-4ebe-43de-ae45-c3058e8f393b","keyword":"磁性能","originalKeyword":"磁性能"}],"language":"zh","publisherId":"gncl2004z1212","title":"La-Co替代的M型永<span style=\"color:red\">磁铁氧体</span>","volume":"35","year":"2004"},{"abstractinfo":"研究了Bi<SUB>2</SUB>O<SUB>3</SUB>-V<SUB>2</SUB>O<SUB>5</SUB>系复合添加剂对Ni-Cu-Zn<span style=\"color:red\">铁氧体</span>的烧结及其磁性能的影响.研究表明,Bi<SUB>2</SUB>O<SUB>3</SUB>-V<SUB>2</SUB>O<SUB>5</SUB>系复合添加剂具有促进晶粒生长的作用,随着添加量的增加,样品断面形貌显示大晶粒增多,X射线衍射分析表明,过多的添加剂引起少量的杂相析出,晶界变宽。然而,适当量的Bi<SUB>2</SUB>O<SUB>3</SUB>-V<SUB>2</SUB>O<SUB>5</SUB>系复合添加剂能使普通Ni-Cu-Zn<span style=\"color:red\">铁氧体</span>的烧结温度降至875℃以下,烧结时间缩短为30min,烧结样品的磁导率可达195(10MHz)。","authors":[{"authorName":"王依琳","id":"e646aefc-5de1-48a3-9ab6-b8501546db5a","originalAuthorName":"王依琳"},{"authorName":"吴文骏","id":"c28f6715-fa17-4dda-b6b6-15e3e3aa3277","originalAuthorName":"吴文骏"},{"authorName":"毛文东","id":"837e7678-4bb8-4e40-82d7-a6911b6825ec","originalAuthorName":"毛文东"},{"authorName":"赵梅瑜","id":"61d0cfc0-3647-4b36-abf8-19421f725615","originalAuthorName":"赵梅瑜"}],"categoryName":"|","doi":"","fpage":"601","id":"58e4f370-1704-4a03-a9f7-3f78792873c2","issue":"3","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":"42960977-e3a7-4257-ad8f-51a8ea48f24a","keyword":"低温烧结","originalKeyword":"低温烧结"},{"id":"917b3d9f-fb5c-4cd8-82e3-ecb8d36700d0","keyword":" soft ferrite","originalKeyword":" soft ferrite"},{"id":"6979071f-2609-47c5-a91a-264b7877b8fe","keyword":" sintering aids","originalKeyword":" sintering aids"}],"language":"zh","publisherId":"1000-324X_2003_3_10","title":"低温快速烧结软<span style=\"color:red\">磁铁氧体</span>材料","volume":"18","year":"2003"},{"abstractinfo":"研究了Bi2O3-V2O5系复合添加剂对Ni-Cu-Zn<span style=\"color:red\">铁氧体</span>的烧结及其磁性能的影响.研究表明,Bi2O3-V2O5系复合添加剂具有促进晶粒生长的作用,随着添加量的增加,样品断面形貌显示大晶粒增多.X射线衍射分析表明,过多的添加剂引起少量的杂相析出,晶界变宽.然而,适当量的Bi2O3-V2O5系复合添加剂能使普通Ni-Cu-Zn<span style=\"color:red\">铁氧体</span>的烧结温度降至875℃以下,烧结时间缩短为30min.烧结样品的磁导率可达195(10MHz).","authors":[{"authorName":"王依琳","id":"d159fbd1-d083-42f9-acf0-73d98407bdb3","originalAuthorName":"王依琳"},{"authorName":"吴文骏","id":"6d224ffc-17dc-4fc0-a833-b389581e7fef","originalAuthorName":"吴文骏"},{"authorName":"毛文东","id":"251296b3-5dfd-4087-bef3-ebeb67d12369","originalAuthorName":"毛文东"},{"authorName":"赵梅瑜","id":"46aa0b35-c978-44ea-8bcb-e4f20f9a9226","originalAuthorName":"赵梅瑜"}],"doi":"10.3321/j.issn:1000-324X.2003.03.015","fpage":"601","id":"0de31856-1d99-4fdf-b1b0-32d9cbf67291","issue":"3","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":"0d880935-a74e-4123-a826-04db56726ea0","keyword":"低温烧结","originalKeyword":"低温烧结"},{"id":"9e06afe4-5a8d-4374-935d-9b396c930f12","keyword":"软<span style=\"color:red\">磁铁氧体</span>","originalKeyword":"软磁铁氧体"},{"id":"f4af3f46-13bc-4025-bd05-7661164046e8","keyword":"烧结助剂","originalKeyword":"烧结助剂"}],"language":"zh","publisherId":"wjclxb200303015","title":"低温快速烧结软<span style=\"color:red\">磁铁氧体</span>材料","volume":"18","year":"2003"},{"abstractinfo":"近年来,永<span style=\"color:red\">磁铁氧体</span>材料的市场容量稳步发展,高性能永<span style=\"color:red\">磁铁氧体</span>材料技术发展十分迅速,介绍了国际上高性能永<span style=\"color:red\">磁铁氧体</span>当前发展水平,并着重介绍了近年来中钢天源公司的高性能永<span style=\"color:red\">磁铁氧体</span>材料研究开发情况,最后对中钢天源高性能产品未来市场情况和技术发展进行了展望.","authors":[{"authorName":"李小艳","id":"5c98c14e-2b60-405a-8d2b-0c988504120a","originalAuthorName":"李小艳"},{"authorName":"赵修彬","id":"5418376f-7cd1-402e-8eb6-02e58a80be59","originalAuthorName":"赵修彬"},{"authorName":"李劲松","id":"77d7bd94-8ecb-4acf-b507-f96a0e4de786","originalAuthorName":"李劲松"},{"authorName":"邱伟国","id":"01d38bac-1f64-412b-8152-8849177b7546","originalAuthorName":"邱伟国"},{"authorName":"舒云峰","id":"83bfb154-505f-49b9-bd0f-15e77ebd9e93","originalAuthorName":"舒云峰"},{"authorName":"马宝","id":"b382956e-0a97-429c-9584-2269748576d9","originalAuthorName":"马宝"}],"doi":"10.13228/j.boyuan.issn1005-8192.2015047","fpage":"53","id":"bce6dd92-d723-4c0c-82fe-df07bae0adfe","issue":"5","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":"5de2a426-dac0-44fb-8958-a9cc0c61740b","keyword":"高性能","originalKeyword":"高性能"},{"id":"86623a0d-4a62-4239-81b4-11d4981e82e1","keyword":"永<span style=\"color:red\">磁铁氧体</span>","originalKeyword":"永磁铁氧体"},{"id":"3c3cc1fc-e871-4897-8258-c56e4ee134a3","keyword":"磁性材料","originalKeyword":"磁性材料"},{"id":"3ec17f9f-750f-4532-b054-9a959cc4784e","keyword":"研发进展","originalKeyword":"研发进展"}],"language":"zh","publisherId":"jsgncl201505012","title":"中钢天源高性能永<span style=\"color:red\">磁铁氧体</span>材料研发进展","volume":"22","year":"2015"},{"abstractinfo":"本文主要阐述了Ni-Zn软<span style=\"color:red\">磁铁氧体</span>材料的发展和研究现状.介绍了主成分配方、非磁性氧化物和稀土氧化物掺杂对Ni-Zn软<span style=\"color:red\">磁铁氧体</span>磁性能的影响,有效控制微观结构和物理性能,能够得到高磁性能的<span style=\"color:red\">铁氧体</span>.根据目前的发展现状,指出了Ni-Zn软<span style=\"color:red\">磁铁氧体</span>材料将来的研究方向.","authors":[{"authorName":"范秀风","id":"88a379f8-3baf-43d8-8021-25f6b6fcc36f","originalAuthorName":"范秀风"},{"authorName":"任慧平","id":"ea4f23f2-9a20-4938-a052-cd266fc6a5da","originalAuthorName":"任慧平"},{"authorName":"张羊换","id":"fda419ca-fc4a-4b05-9808-081eb4157286","originalAuthorName":"张羊换"},{"authorName":"郭世海","id":"5497e9c3-c79c-4020-aafd-f39620cba0ad","originalAuthorName":"郭世海"},{"authorName":"王新林","id":"8bbf7a92-0d53-4997-94b5-c1183066a821","originalAuthorName":"王新林"}],"doi":"10.3969/j.issn.1005-8192.2007.02.009","fpage":"36","id":"34e1913d-8645-4c1d-8ce1-1fa91a5c76fd","issue":"2","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":"586f2586-519a-477c-a4a9-1ebecfe7b926","keyword":"Ni-Zn软<span style=\"color:red\">磁铁氧体</span>","originalKeyword":"Ni-Zn软磁铁氧体"},{"id":"9ce3b846-2415-49b8-9476-3f558a1c42d4","keyword":"磁性能","originalKeyword":"磁性能"},{"id":"f45274ae-4a9a-4027-a4d3-452d566f69f2","keyword":"非磁性氧化物","originalKeyword":"非磁性氧化物"},{"id":"d6602bb8-5c3f-46f1-9d06-d3de05b9c6f2","keyword":"稀土氧化物","originalKeyword":"稀土氧化物"}],"language":"zh","publisherId":"jsgncl200702009","title":"Ni-Zn软<span style=\"color:red\">磁铁氧体</span>材料成分配方的研究进展","volume":"14","year":"2007"},{"abstractinfo":"用陶瓷工艺制备了Ca永<span style=\"color:red\">磁铁氧体</span>,用永<span style=\"color:red\">磁铁氧体</span>测量仪、振动样品磁强计、X射线衍射仪、EDS以及扫描电子显微镜等设备仪器对Ca永<span style=\"color:red\">磁铁氧体</span>的物相、磁性能及断面形貌等进行了分析;探讨了Ca永<span style=\"color:red\">磁铁氧体</span>微观结构、主、辅配方及取向磁场等对磁性能的影响.实验表明:微量元素Ba的添加在一定程度上能够抑制晶粒生长,同时更有利于Ca永<span style=\"color:red\">磁铁氧体</span>晶粒的均匀生长及取向度f的改善,从而明显改善了产品的磁性能,矩形比(Hk/HCJ)从89％提高到96％,M*值提高2.6％,达到6200以上;对Ca0.98-xLaxBa0.02 Fe10.6-xCoxO19-δ,x=0.3时的预烧料细粉碎时,添加0.2％的H3 B03、0.4％的SiO2,研磨之后的料浆在1150 kA/m,即约3倍HCJ的磁场下成型更有利于Ca永<span style=\"color:red\">磁铁氧体</span>磁参数的改善,Ca永<span style=\"color:red\">磁铁氧体</span>产品的典型磁参数:Br为452 mT,HCJ为402 kA/m.","authors":[{"authorName":"王自敏","id":"f2c9c4c9-51da-4c82-b010-db24f4bf0edd","originalAuthorName":"王自敏"},{"authorName":"邓志刚","id":"4065dbfe-2ded-40c9-93df-2a3b386577b9","originalAuthorName":"邓志刚"}],"doi":"10.7502/j.issn.1674-3962.2016.09.10","fpage":"713","id":"75841659-ff34-4240-923e-4c11d436ca62","issue":"9","journal":{"abbrevTitle":"ZGCLJZ","coverImgSrc":"journal/img/cover/中国材料进展.jpg","id":"80","issnPpub":"1674-3962","publisherId":"ZGCLJZ","title":"中国材料进展"},"keywords":[{"id":"6251177a-45b6-401d-a97d-25f9a03d2438","keyword":"Ca系永<span style=\"color:red\">磁铁氧体</span>","originalKeyword":"Ca系永磁铁氧体"},{"id":"13a9d4b3-4677-42c1-b9a6-efcd25c757d5","keyword":"矩形比","originalKeyword":"矩形比"},{"id":"b0784e59-a520-4892-93cb-b4cffe72a885","keyword":"磁性能","originalKeyword":"磁性能"},{"id":"947bfbf1-3856-4f22-9c67-450be2dca711","keyword":"固相反应","originalKeyword":"固相反应"}],"language":"zh","publisherId":"zgcljz201609010","title":"Ca永<span style=\"color:red\">磁铁氧体</span>的组成及微观结构与磁性研究","volume":"35","year":"2016"}],"totalpage":209,"totalrecord":2086}