{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"Fe大块合金因其优良的性能和成本优势已引起研究者的广泛关注,但脆性极大的缺陷阻碍其走向工程应用.综述了Fe大块合金塑性研究领域的最新进展,分析了其脆性产生的机理.介绍了目前常用的对Fe大块合金进行塑性增韧的方法,即成分设计法(微合金化)和添加第二相增韧法,提出了当前研究的重点.","authors":[{"authorName":"谢春晓","id":"7bb0823c-6b37-4c00-9b4c-41c243e46bb1","originalAuthorName":"谢春晓"},{"authorName":"杨元政","id":"b54a7169-045b-4b17-9493-04ef98380bb3","originalAuthorName":"杨元政"}],"doi":"","fpage":"98","id":"fea9db81-4202-48a0-97ed-620c5334d03b","issue":"9","journal":{"abbrevTitle":"CLDB","coverImgSrc":"journal/img/cover/CLDB.jpg","id":"8","issnPpub":"1005-023X","publisherId":"CLDB","title":"材料导报"},"keywords":[{"id":"c296ddc6-0726-435d-9f69-98ca1aaad4ae","keyword":"Fe大块合金","originalKeyword":"Fe基大块非晶合金"},{"id":"8c19b29e-a26c-4276-a168-c8af5ac83389","keyword":"塑性","originalKeyword":"塑性"},{"id":"a4e5664e-b4d8-4c21-823b-bbe6f174d936","keyword":"微合金化","originalKeyword":"微合金化"},{"id":"fc8658f2-4245-4659-81d6-e64ac4c04643","keyword":"第二相","originalKeyword":"第二相"}],"language":"zh","publisherId":"cldb201209020","title":"Fe大块合金塑性的研究进展","volume":"26","year":"2012"},{"abstractinfo":"以Fe41Co7Cr15Mo14C15B6Y2合金为基体,通过掺杂Co65 Cr15 Zr10W10合金成功获得了低热导率的Fe大块合金.利用四探针电阻率测试仪和激光闪射热导率测试仪分别测量合金的室温电阻率和25~150℃下的热导率.研究Co65 Cr15Zr10W10合金掺杂对电阻率和热导率的影响以及热导率随温度的变化关系.结果表明:在25 ~150℃范围内,Fe大块合金热导率随温度升高呈线性增加.Co65 Cr15Zr10W10合金的掺杂导致Fe大块合金的热导率和电阻率降低,当掺杂含量高于10 at%后,热导率趋于稳定.掺杂主要引起常温下声子热导率的变化,对电子热导率影响很小.提出了通过化温度Tx推算Fe大块合金常温下热导率的公式,声子热导率与Tx之间的关系符合y=0.06756X-37.31568,总热导率与Tx之间的关系符合y =0.06228X-30.58814.","authors":[{"authorName":"王诚杰","id":"2b1d5b84-afbe-4743-a93c-31d1fb3bc8fc","originalAuthorName":"王诚杰"},{"authorName":"陈庆军","id":"4c375666-b667-4305-9cc9-3fab64278926","originalAuthorName":"陈庆军"},{"authorName":"夏怀效","id":"e82101ad-2ca7-4287-9710-28c7c7bfffe8","originalAuthorName":"夏怀效"}],"doi":"","fpage":"16","id":"78857c34-9fef-462a-b6bd-0b0668a4cd71","issue":"3","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":"245f9ffb-ac65-4f63-a1f1-2027ffe4fc35","keyword":"Fe大块合金","originalKeyword":"Fe基大块非晶合金"},{"id":"eef2a9c0-1a6a-4037-9ebe-d4aa8e033368","keyword":"掺杂","originalKeyword":"掺杂"},{"id":"b184f667-ea2f-4e9b-a305-0f2fd79444eb","keyword":"化温度","originalKeyword":"晶化温度"},{"id":"32a0f6a9-091b-44b5-a26e-cbceb0ade68b","keyword":"电阻率","originalKeyword":"电阻率"},{"id":"ffdd9c92-0e7b-4b7a-a17a-879747294939","keyword":"热导率","originalKeyword":"热导率"}],"language":"zh","publisherId":"jsrclxb201703003","title":"合金系掺杂对FeCoCrMoCBY合金热导率的影响","volume":"38","year":"2017"},{"abstractinfo":"近年来,随着铁大块合金尺度不断取得新的突破,无磁钢的开发和研究受到日益广泛的关注.然而,FeCrMoCB系钢的玻璃形成能力很弱,仅能形成直径为1.5mm的大块合金.采用铜模真空吸铸法,探讨Y、Pr、Gd、Tb等稀土元素对Fe48Cr15Mo14C15B6M2(M=RE)系合金玻璃形成能力的影响,实验结果表明,用2%(原子分数)的稀土元素Y、Pr、Gd、Tb分别替换Fe50Cr15Mo14C15B6中的Fe,能制备出一系列Fe48Cr15Mo14C15B6M2(M=RE)系棒.Fe48Cr15Mo14C15B6M2(M=Pr,Y,Gd,Tb)棒的最大直径依次可达3、8、12和12mm.","authors":[{"authorName":"陶平均","id":"e84cd9a4-8b6d-416e-bf7f-1b3118d9ed99","originalAuthorName":"陶平均"},{"authorName":"杨元政","id":"a515ef8f-f725-4ef5-9470-d88b46be8731","originalAuthorName":"杨元政"},{"authorName":"白晓军","id":"42f1be4d-7c3e-4b97-a391-a900dc6b0a59","originalAuthorName":"白晓军"},{"authorName":"毛杰","id":"67396bf4-3823-4765-8e9a-a3d777f226db","originalAuthorName":"毛杰"}],"doi":"","fpage":"1110","id":"262ddbda-e15b-424a-8738-1d1b6e116f23","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":"8e03a99b-28ec-4f30-ba6d-924ccbdf52e8","keyword":"Fe大块合金","originalKeyword":"Fe基大块非晶合金"},{"id":"e7c40412-5174-4616-b139-431282451a11","keyword":"玻璃形成能力","originalKeyword":"玻璃形成能力"},{"id":"658475f9-7298-404e-a054-62f6625cef01","keyword":"稀土元素","originalKeyword":"稀土元素"}],"language":"zh","publisherId":"gncl201006049","title":"稀土元素对FeCrMoCB系合金玻璃形成能力的影响","volume":"41","year":"2010"},{"abstractinfo":"采用电弧熔炼母合金、普通铜模吸铸工艺,制备出尺寸规格为20m×10mm×1mm的板状Fe-co-ZrMo-W-B系Fe-大块合金.经DTA检测,所制备的Fe-合金具有明显的玻璃转变温度和较宽的过冷液相区(Tg=884K,ATx≥60K).采用压痕试验法测定了该板状Fe-大块合金的断裂韧性,其铸态断裂韧性在1.6MPa·mi/2量级.","authors":[{"authorName":"肖华星","id":"109ab43d-a757-4e37-8141-5538ea50613b","originalAuthorName":"肖华星"},{"authorName":"陈光","id":"765dd963-e8c0-4737-95c9-97cb7bc017e4","originalAuthorName":"陈光"}],"doi":"10.3969/j.issn.1004-244X.2004.02.007","fpage":"23","id":"554efb8b-320d-4f14-b1db-ae08a5017a7d","issue":"2","journal":{"abbrevTitle":"BQCLKXYGC","coverImgSrc":"journal/img/cover/BQCLKXYGC.jpg","id":"4","issnPpub":"1004-244X","publisherId":"BQCLKXYGC","title":"兵器材料科学与工程 "},"keywords":[{"id":"2952ffba-781a-4a94-ac44-41d3aafe236d","keyword":"Fe-","originalKeyword":"Fe-基"},{"id":"84b35e30-de03-40be-a5d7-75024f93a36b","keyword":"大块合金","originalKeyword":"大块非晶合金"},{"id":"1f368222-b286-4fcf-9c5e-2fe8cf043d8f","keyword":"断裂韧性","originalKeyword":"断裂韧性"},{"id":"209b16b6-d756-4aa6-abf1-ca2c239e3437","keyword":"制备","originalKeyword":"制备"},{"id":"736f24e1-17af-400b-a76b-4a8c984766ab","keyword":"测定","originalKeyword":"测定"}],"language":"zh","publisherId":"bqclkxygc200402007","title":"板状Fe-大块合金的制备及其断裂韧性测定","volume":"27","year":"2004"},{"abstractinfo":"利用熔点、玻璃化转变温度等易获得的参数并结合准规则模型以及生成热模型,给出了一种计算多元系合金粘度的热力学方法.利用该方法计算了ZrFe大块合金系的粘度,计算结果与经验结果吻合较好.计算表明,同一温度下,多组元合金系粘度值随组元数增加而增大,粘度随着过冷度的增加而增大;Zr-Al-Ni三元合金在xZr =0.375~0.8571、xNi=0~0.357成分范围内,Zr-Al-Cu三元合金在xzr=0.375~0.8625、xcu =0~0.400成分范围内,Zr66.7Al-Ni-Cu系在xAl=0.632~0.809、xNi=0.145~0.245成分范围内粘度较高;对Fe-块体合金系,Fe-Nb-B合金系在xNb=0.325~0.9375、xB=0.0625~0.675成分范围内,Fe-Si-B合金在xSi=0~0.521、xB=0.5124~0.9375成分范围内粘度较高.","authors":[{"authorName":"李会强","id":"15f1b69e-e530-485e-a7ba-9c0cba91af4d","originalAuthorName":"李会强"},{"authorName":"刘龙飞","id":"1af8b0cf-144c-4611-82ca-6b25e77375a5","originalAuthorName":"刘龙飞"},{"authorName":"罗柏文","id":"f8ec0d0a-7354-436b-a730-6d162a0ec965","originalAuthorName":"罗柏文"}],"doi":"","fpage":"140","id":"e4d9a1e6-e211-49ce-9a42-512ec22dd39c","issue":"16","journal":{"abbrevTitle":"CLDB","coverImgSrc":"journal/img/cover/CLDB.jpg","id":"8","issnPpub":"1005-023X","publisherId":"CLDB","title":"材料导报"},"keywords":[{"id":"be5b3202-71f0-41d2-bb1b-f502ffdc09f3","keyword":"大块合金","originalKeyword":"大块非晶合金"},{"id":"10983ce4-e906-4258-aef4-869e8fd2e468","keyword":"热力学","originalKeyword":"热力学"},{"id":"6f3222bc-0577-43cc-b62b-bd43169ce542","keyword":"粘度","originalKeyword":"粘度"},{"id":"c8dda4dd-04a0-465e-ab28-0b3acf961504","keyword":"混合焙","originalKeyword":"混合焙"}],"language":"zh","publisherId":"cldb201116036","title":"Fe、Zr大块合金粘度的热力学计算","volume":"25","year":"2011"},{"abstractinfo":"综述了镁大块合金的研究现状,重点介绍了微量元素、纳米颗粒对Mg-Cu-Y大块的影响,并对现有晶形成能力的判据进行了分析.对镁合金及其复合材料的进一步研究提出了建议.","authors":[{"authorName":"李国强","id":"3891e66d-843c-488b-b952-e61146439c83","originalAuthorName":"李国强"},{"authorName":"郑立静","id":"41b97c64-0524-476c-96f1-5a63043c17d9","originalAuthorName":"郑立静"},{"authorName":"栗丽","id":"0d99646e-ce78-4e9e-b120-dfdc3b564a4c","originalAuthorName":"栗丽"},{"authorName":"李焕喜","id":"6edf12a1-584c-4418-8f38-965af518eb1b","originalAuthorName":"李焕喜"},{"authorName":"陈昌麒","id":"9e036b9e-6029-47f3-834f-bbcd3d566d98","originalAuthorName":"陈昌麒"}],"doi":"","fpage":"54","id":"2813326b-35d2-4966-a6f4-d75636439a5d","issue":"2","journal":{"abbrevTitle":"CLDB","coverImgSrc":"journal/img/cover/CLDB.jpg","id":"8","issnPpub":"1005-023X","publisherId":"CLDB","title":"材料导报"},"keywords":[{"id":"927a99a8-72a4-4f12-bb80-abb6d55da44c","keyword":"镁合金","originalKeyword":"镁基非晶合金"},{"id":"20ba402b-e147-4edd-8a95-2b54b65d4008","keyword":"微量元素","originalKeyword":"微量元素"},{"id":"9eb3e589-181e-41dc-bdf8-4ee249deaa14","keyword":"纳米颗粒","originalKeyword":"纳米颗粒"},{"id":"6d4d383f-d2a7-42cd-9207-5521f6763fc3","keyword":"晶形成机制","originalKeyword":"非晶形成机制"}],"language":"zh","publisherId":"cldb200602015","title":"镁大块合金的研究进展","volume":"20","year":"2006"},{"abstractinfo":"概述了铁大块合金优异的力学性能、磁学性能、耐蚀性能和电学性能及其在实际工程上的应用前景.介绍了铁大块合金化研究的最新成果和结晶动力学,包括化对合金性能的影响和变温结晶转变中化激活能的计算方法,并找到了一种计算变温化激活能的新方法,即Starink 法.求化激活能时,Starink方程最佳,Kissinger方程次之,Boswell方程再次之,Ozawa方程最差.","authors":[{"authorName":"魏丹丹","id":"b499b627-79cd-4642-9349-9d00d059a4e0","originalAuthorName":"魏丹丹"},{"authorName":"陈庆军","id":"e49d3c5d-f503-41cf-a2f5-cce83a8e95d4","originalAuthorName":"陈庆军"},{"authorName":"高霁雯","id":"bcb9eb39-d6dc-4569-a407-0416ef24195d","originalAuthorName":"高霁雯"},{"authorName":"周贤良","id":"0b8411be-8b84-4d42-b5bc-59270d6f643e","originalAuthorName":"周贤良"},{"authorName":"艾云龙","id":"dc75873e-1b25-47b5-a10c-ea132d5c956d","originalAuthorName":"艾云龙"}],"doi":"","fpage":"80","id":"1ae9e803-6ca3-492f-8e95-a59690567315","issue":"z1","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":"3e0ad6c8-7fce-4415-a9c7-35a899f5fe27","keyword":"铁大块合金","originalKeyword":"铁基大块非晶合金"},{"id":"a5eed793-c448-4c02-a542-ff4c5fbd0a54","keyword":"性能","originalKeyword":"性能"},{"id":"482cbe4d-de85-4f2d-b216-3eb8ed8c7b70","keyword":"应用","originalKeyword":"应用"},{"id":"3d0af53b-4d3b-401f-ac8a-14a898dd1065","keyword":"化","originalKeyword":"晶化"}],"language":"zh","publisherId":"xyjsclygc2009z1018","title":"铁大块合金的发展现状","volume":"38","year":"2009"},{"abstractinfo":"铜大块合金Cu52.5Ti30Zr11.5Ni6与Cu53.1Ti31.4Zr9.5Ni6(at%)具有高的抗压缩断裂强度(σc,f),分别为2212MPa和2184MPa:断裂伸长率(εc,f)分别为2.1%和2.2%.断口微观形貌分析表明,Cu大块合金具有3种不同类型的微观形貌,分别与断口的3个断裂扩展区域相对应.由于断裂沿着2个不同方向进行,条带型脉状网络的产生,使得Cu具有高的抗压缩断裂强度.","authors":[{"authorName":"杨英俊","id":"45315e52-5339-4e2f-9ab6-b8845a4c3878","originalAuthorName":"杨英俊"},{"authorName":"邢大伟","id":"c9a61e8c-7b93-4a5d-929d-1c41045b21b6","originalAuthorName":"邢大伟"},{"authorName":"王刚","id":"c015d222-c2cb-4478-a683-4f4bc4b38b72","originalAuthorName":"王刚"},{"authorName":"孙剑飞","id":"a3bb9bee-eefb-4ae3-95af-0572ecca8fc0","originalAuthorName":"孙剑飞"},{"authorName":"魏思东","id":"65d28885-f262-4f14-9095-8f682bb4f610","originalAuthorName":"魏思东"},{"authorName":"沈军","id":"9907998a-32e1-4bba-a3e1-8565887ca082","originalAuthorName":"沈军"}],"doi":"","fpage":"1029","id":"40cb238a-89d0-4c63-8db9-3e4637a30150","issue":"6","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":"5ea38482-8528-4d99-831e-440ad3f00dca","keyword":"铜大块合金","originalKeyword":"铜基大块非晶合金"},{"id":"dc16989a-1ed1-4602-be7a-7cf59eca16df","keyword":"压缩断裂强度","originalKeyword":"压缩断裂强度"},{"id":"390eac68-3955-434e-a3bd-fe15d0abba63","keyword":"断口微观形貌","originalKeyword":"断口微观形貌"}],"language":"zh","publisherId":"xyjsclygc200706021","title":"铜大块合金的压缩断裂行为","volume":"36","year":"2007"},{"abstractinfo":"利用等温差示扫描量热(DSC)分析方法研究了大块Zr41Ti14Cu12.5Ni2Be22.5Fe8合金中的化行为,用Kjssinger方程计算其化表观激活能.实验表明,在Zr大块合金中掺入Fe后,其玻璃转变与化行为都与加热速率有关,均具有动力学效应.同时,从化反应速率常数的角度讨论了晶形成能力.","authors":[{"authorName":"赵德乾","id":"18b7c5a0-07fc-4758-b8e5-0a12ecb69732","originalAuthorName":"赵德乾"},{"authorName":"C.H.Shek","id":"58455807-43c2-4429-9a24-bf994d810dda","originalAuthorName":"C.H.Shek"},{"authorName":"汪卫华","id":"1bf895f1-0c95-4d12-af31-00d598a15ee2","originalAuthorName":"汪卫华"}],"categoryName":"|","doi":"","fpage":"754","id":"7af750cd-de2b-44f2-8d6c-84ff35b9a0c7","issue":"7","journal":{"abbrevTitle":"JSXB","coverImgSrc":"journal/img/cover/JSXB.jpg","id":"48","issnPpub":"0412-1961","publisherId":"JSXB","title":"金属学报"},"keywords":[{"id":"339d40e8-64f8-4b97-96ce-d58549b8844d","keyword":"大块合金","originalKeyword":"大块非晶合金"},{"id":"51a8c042-6fea-462b-8e16-2def52e209fc","keyword":"null","originalKeyword":"null"},{"id":"e4eff186-f214-4d4f-9d8c-8668d39345cc","keyword":"null","originalKeyword":"null"}],"language":"zh","publisherId":"0412-1961_2001_7_21","title":"Zr-Ti-Cu-Ni-Be-Fe大块合金化动力学效应","volume":"37","year":"2001"},{"abstractinfo":"利用等温差示扫描量热(DSC)分析方法研究了大块Zr41Ti14Cu12.5Ni2Be22.5Fe8合金中的化行为,用Kjssinger方程计算其化表观激活能.实验表明,在Zr大块合金中掺入Fe后,其玻璃转变与化行为都与加热速率有关,均具有动力学效应.同时,从化反应速率常数的角度讨论了晶形成能力.","authors":[{"authorName":"赵德乾","id":"f14d2f48-318a-484a-a849-4dfd7c34bad1","originalAuthorName":"赵德乾"},{"authorName":"C.H.Shek","id":"0eb50373-d509-4ecf-9b56-d60688b829f4","originalAuthorName":"C.H.Shek"},{"authorName":"汪卫华","id":"8b46894e-77ac-4909-9b08-bf88f70a239c","originalAuthorName":"汪卫华"}],"doi":"10.3321/j.issn:0412-1961.2001.07.016","fpage":"754","id":"3ee3e947-608d-4a01-8de8-c5f47fc64585","issue":"7","journal":{"abbrevTitle":"JSXB","coverImgSrc":"journal/img/cover/JSXB.jpg","id":"48","issnPpub":"0412-1961","publisherId":"JSXB","title":"金属学报"},"keywords":[{"id":"4381e385-f737-4534-bb90-a40f1b10f52e","keyword":"大块合金","originalKeyword":"大块非晶合金"},{"id":"2427cc26-a5f5-4d12-b219-adad2b8c54d0","keyword":"化","originalKeyword":"晶化"},{"id":"a0a44bd7-a6f3-41e0-8bf7-65c19f170d7b","keyword":"动力学效应","originalKeyword":"动力学效应"}],"language":"zh","publisherId":"jsxb200107016","title":"Zr-Ti-Cu-Ni-Be-Fe大块合金化动力学效应","volume":"37","year":"2001"}],"totalpage":8024,"totalrecord":80234}