{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":1,"startPagecode":1},"records":[{"abstractinfo":"Adsorption and desorption of gold on the magnetic activated carbon (MAC) were investigated The adsorption rate of gold is higher than that of conventional coconut carbon in cyanide leach solution The loading gold can be easily desorbed as coconut carbon. Crushed fine magnetic carbon can be selected by a magnetic separator, It is suggested that the MAC can be used in carbon-in-pulp (CIP)process for increasing the recovery rate of gold","authors":[{"authorName":"Chonglin WANG","id":"43077431-a566-4945-88ec-7b9837b496a7","originalAuthorName":"Chonglin WANG"},{"authorName":" Qingcai LIU","id":"f19a0cef-315a-4ebe-9807-4d8c2d2a4694","originalAuthorName":" Qingcai LIU"},{"authorName":" Xiaozhen CHENG and Zuhong SHEN (Institute of Metal Research","id":"b880ece8-650d-49c9-85ba-1767e36ee098","originalAuthorName":" Xiaozhen CHENG and Zuhong SHEN (Institute of Metal Research"},{"authorName":" Academia Sinica","id":"824127cc-b26d-4638-84ea-2bf84a9e2383","originalAuthorName":" Academia Sinica"},{"authorName":" Shenyang","id":"3325d03d-2822-4d98-994c-e7c4e751df81","originalAuthorName":" Shenyang"},{"authorName":" 110015","id":"b4dbacc8-679a-45eb-963e-7298120c198a","originalAuthorName":" 110015"},{"authorName":" China)(To whom correspondence should be addressed)","id":"c1a8f7bf-1e1d-412e-9e42-27d1ee3afe16","originalAuthorName":" China)(To whom correspondence should be addressed)"}],"categoryName":"|","doi":"","fpage":"151","id":"a9446dcd-37c1-43ac-a16a-bb853ecacf1a","issue":"2","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":[],"language":"en","publisherId":"1005-0302_1994_2_9","title":"Adsorption and Desorption of Gold on the Magnetic Activated Carbon","volume":"10","year":"1994"},{"abstractinfo":"Electromagnetic separation of non-metallic inclusions from Al-Si melt is studied by theoretical analysis and experiments on self-designed electromagnetic separation apparatus. Metallographs and LECO Image Analysis System were used to analyze the content of alumina in aluminum alloy before and after electromagnetic separation. It is seen that removal effciency increases with the increase of electromagnetic force (EMF) and diameter of inclusion particles while decreases with the increase of melt velocity and height of separator. All alumina particles with diamete of 14μm have been removed successfully from the melt.","authors":[{"authorName":"T.X. Li","id":"8c75fbcb-0726-4d36-9845-2528c69641dc","originalAuthorName":"T.X. Li"},{"authorName":" Z.M. Xu","id":"b2ab6665-f1e6-4b8c-99d0-e486e6f3e170","originalAuthorName":" Z.M. Xu"},{"authorName":" B.D. Sun","id":"776f3129-6500-4240-b5d8-1d64ad267cd6","originalAuthorName":" B.D. Sun"},{"authorName":" D. Shu and Y.H. Zhou (School of Materials Science and Engineering","id":"e14a98cf-3f5e-45be-89b2-ab66a2c622c5","originalAuthorName":" D. Shu and Y.H. Zhou (School of Materials Science and Engineering"},{"authorName":" Shanghai Jiao Tong University","id":"00adf8a9-a743-44ef-b274-312d0f279386","originalAuthorName":" Shanghai Jiao Tong University"},{"authorName":" Shanghai 200030","id":"866da39b-b56d-44fa-961f-2785e6e2453b","originalAuthorName":" Shanghai 200030"},{"authorName":" China)","id":"d08bd49c-9daf-4519-8c4c-570621ad8184","originalAuthorName":" China)"}],"categoryName":"|","doi":"","fpage":"1068","id":"31207e8b-1468-46dd-8a6f-1e3f53fccedf","issue":"5","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":"a7e5e9ee-3bba-454e-a24f-b9eed79982f0","keyword":"aluminum melt","originalKeyword":"aluminum melt"},{"id":"5216d97f-3f28-48a0-b493-9a2636120d6d","keyword":"null","originalKeyword":"null"},{"id":"09f04540-67ac-4ad2-8ee0-46dc06004f7e","keyword":"null","originalKeyword":"null"},{"id":"6641a61f-485c-4ae7-a48a-a2e1d46fe59e","keyword":"null","originalKeyword":"null"}],"language":"en","publisherId":"1006-7191_2000_5_5","title":"ELECTROMAGNETIC FIELD REMOVE INCLUSIONS FROM ALUMINUM MELT IN ELECTROMAGNETIC FIELD","volume":"13","year":"2000"},{"abstractinfo":"Electrochemical capacitors (ECs) store energy in eletric double-layers formed along the interface of electrode material and electrolyte, this produces an extremely large capacitance compared with the traditional capacitors. The fundamental principles of electrochemical capacitors are briefly introduced, and the key materials used like electrode materials, electrolytes, separator and current collector materials are summarized. Electrochemical capacitors with pseudocapacitance, such as metal oxides, polymers and hybrid capacitors, are also discussed. The characteristics, possible application fields, the development state, the future R&D prospects for electrochemical capacitors are highlighted.","authors":[],"categoryName":"|","doi":"","fpage":"71","id":"c3b44752-670f-4e3b-82ea-3b76487d9522","issue":"1","journal":{"abbrevTitle":"XXTCL","coverImgSrc":"journal/img/cover/XXTCL.jpg","id":"70","issnPpub":"1007-8827","publisherId":"XXTCL","title":"新型炭材料"},"keywords":[{"id":"0777b84b-1686-4bdd-84b4-fccff57315fe","keyword":"electrochemical capacitors;supercapacitors;storage of electric energy;principles","originalKeyword":"electrochemical capacitors;supercapacitors;storage of electric energy;principles"}],"language":"en","publisherId":"1007-8827_2002_1_1","title":"Research and development of carbon materials for electrochemical capacitors I. Electrochemical capacitors","volume":"17","year":"2002"},{"abstractinfo":"The method for the recycling of copper from copper chloride solution was developed. This process consists of extraction of copper, purification and particle size reduction. In the first step, reductive metal scraps were added to acidic copper chloride waste enchants produced in the PCB industry to obtain copper powder. Composition analysis showed that this powder contained impurities such as Fe, Ni, and water. So, drying and purification were carried out by using microwave and a centrifugal separator. Thereby the copper powder had a purity of higher than 99% and spherical form in morphology. The copper powder size was decreased by ball milling.","authors":[{"authorName":"H.S.Hong","id":"4fc01421-5c0d-4576-966a-76d30c82510e","originalAuthorName":"H.S.Hong"},{"authorName":" M.S.Kong","id":"27a44a19-8a74-4f99-b1de-c5c9b196e491","originalAuthorName":" M.S.Kong"},{"authorName":" J.K.Ghu","id":"a77680cc-f45e-4c27-82cc-19edffc1ba37","originalAuthorName":" J.K.Ghu"},{"authorName":" J.K.Lee","id":"5dbe1584-58be-42c8-914b-829297796173","originalAuthorName":" J.K.Lee"},{"authorName":" H.G.Suk","id":"379cff84-de53-4d16-bef3-e9878e7bdcf3","originalAuthorName":" H.G.Suk"}],"categoryName":"|","doi":"","fpage":"141","id":"cbd510b9-0f7d-4073-968d-dd378b1aee4a","issue":"1","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":"883674ba-a009-4dcb-814d-0c5ef5b78357","keyword":"Copper chloride liquid waste","originalKeyword":"Copper chloride liquid waste"},{"id":"267e78e0-d703-4250-bc25-489f9bb71365","keyword":"null","originalKeyword":"null"},{"id":"19b6efa1-c3f5-400e-bd4c-95a08f490b1b","keyword":"null","originalKeyword":"null"},{"id":"621c1125-435f-4025-bae4-07c0fbe39cfd","keyword":"null","originalKeyword":"null"}],"language":"en","publisherId":"1005-0302_2008_1_8","title":"Preparation of Pure Copper Powder from Acidic Copper Chloride Waste Etchant","volume":"24","year":"2008"},{"abstractinfo":"A microporous separator (Daramic) was impregnated by soaking in a 5 wt.% Nation solution to obtain a proton conducting composite membrane with modified properties for the vanadium redox flow battery (VRB). Nation uptake by Daramic with thickness 0.25 mm is 6.5 wt.%. Infrared spectroscopy (IR), then nogravimetric analysis (TGA) and ion exchange capacity (IEC) have also been carried out to confirm incorporation of Nation into the Daramic membrane. The new Daramic/Nation composite membranes give acceptable low electrical resistance, although the measured area resistances are higher for the composite membranes with different thickness than that for the untreated membranes. A reduction in water uptake of the membranes is observed after impregnation. Open circuit voltage measurement with time of the proton conducting composite membrane showed promising results compared with that of the untreated Daramic membrane when used in the VRB. (C) 2004 Elsevier B.V. All rights reserved.","authors":[],"categoryName":"|","doi":"","fpage":"51","id":"3982204b-518b-47e2-af25-0c49cbe644d9","issue":"42737","journal":{"abbrevTitle":"JOMS","id":"cf3ef46c-e76b-4f3c-97de-7e95d32b8b05","issnPpub":"0376-7388","publisherId":"JOMS","title":"Journal of Membrane Science"},"keywords":[{"id":"9e969ce7-4e97-4d56-91a4-8f2011b22300","keyword":"Daramic;Nafion;vanadium redox flow battery;composite membrane;ion-exchange membrane","originalKeyword":"Daramic;Nafion;vanadium redox flow battery;composite membrane;ion-exchange membrane"}],"language":"en","publisherId":"0376-7388_2004_42737_1","title":"Proton conducting composite membrane from Daramic/Nafion for vanadium redox flow battery","volume":"234","year":"2004"},{"abstractinfo":"在X射线暴高温高密度的环境中,18Ne(α, p)21Na很可能是由热CNO循环突破到rp过程的一个重要反应。到目前为止,人们测得的反应率还存在很大的不确定性。实验中用CRIB(CNS Radioactive Ion Beam separator)提供的21Na放射性束轰击8.8 mg/cm2的聚乙烯厚靶,利用放置在θlab=-14°,0°,14°处的3套硅条探测器望远镜阵列对反冲轻粒子进行鉴别和测量,测得在一段能区(Ex=5.5~9.2 MeV)内21 Na(p, p)21 Na的激发函数。通过对21 Na(p, p)共振弹性散射截面进行R矩阵拟合,得到了22 Mg共振能级的自旋宇称以及质子宽度等信息,从而为计算18Ne(α, p)21Na反应率提供了实验参数。","authors":[{"authorName":"张立勇","id":"a0c8ac8a-c80f-442c-9756-249527220a37","originalAuthorName":"张立勇"},{"authorName":"许世伟","id":"b9704d93-c1bf-48fb-b9aa-088a4cfa2f95","originalAuthorName":"许世伟"},{"authorName":"何建军","id":"7bb0d4ee-8dc6-4d39-b58c-fe8a2c8e5b10","originalAuthorName":"何建军"},{"authorName":"H. Yamaguchi","id":"8999e492-6626-495f-a0fc-2acff4ee76c0","originalAuthorName":"H. Yamaguchi"},{"authorName":"S. Kubono","id":"8b5b64e3-8d06-4098-8c33-fc9364ae1302","originalAuthorName":"S. Kubono"},{"authorName":"Y. Wakabayashi","id":"1d38c6e2-d736-4d53-9f6c-e4613326f7f1","originalAuthorName":"Y. Wakabayashi"},{"authorName":"陈思泽","id":"f8853c4e-2be7-4143-8ad6-13e1d59da089","originalAuthorName":"陈思泽"},{"authorName":"胡钧","id":"2afbb7c7-1e60-45a6-91e6-486bd39fa797","originalAuthorName":"胡钧"},{"authorName":"马朋","id":"25e68934-f543-4439-9538-116b28da78ee","originalAuthorName":"马朋"},{"authorName":"Y. Togano","id":"d5e9835c-33fb-4c13-861a-b7b41d420678","originalAuthorName":"Y. Togano"},{"authorName":"T. Hashimoto","id":"2e473c49-0557-4d9e-8156-4a520bcd0339","originalAuthorName":"T. Hashimoto"},{"authorName":"D. Kahl","id":"2f2341e2-30ae-474b-b274-3e416ad9579c","originalAuthorName":"D. Kahl"},{"authorName":"T. Teranishi","id":"77e39742-94cf-48c2-a3b1-cf614026daca","originalAuthorName":"T. Teranishi"},{"authorName":"陈若富","id":"6737a27c-47c6-4a68-9326-2e4d4a8a6455","originalAuthorName":"陈若富"},{"authorName":"王宏伟","id":"fe60e0aa-cd8f-4d83-8f92-4e07b3c56a28","originalAuthorName":"王宏伟"},{"authorName":"田文栋","id":"35784b3d-6499-4ba2-b8be-bb05fb27979f","originalAuthorName":"田文栋"},{"authorName":"郭冰","id":"e39d6c48-c1ed-49d4-bbb4-bf4d3793df00","originalAuthorName":"郭冰"},{"authorName":"S. Hayakawa","id":"455ef457-19e3-4cca-8c49-1459be740fdd","originalAuthorName":"S. Hayakawa"},{"authorName":"N. Iwasa","id":"538e580e-8070-438b-85e6-cb93f4727bf9","originalAuthorName":"N. Iwasa"},{"authorName":"T. Yamada","id":"e6a36e1e-c134-4400-9633-6c03e811db81","originalAuthorName":"T. Yamada"},{"authorName":"T. Komatsubara","id":"7e7a6b17-18de-4891-a9bd-390af35e0de9","originalAuthorName":"T. Komatsubara"}],"doi":"10.11804/NuclPhysRev.30.04.385","fpage":"385","id":"74b4e4c1-a7b1-4de4-9072-baa5dabfe911","issue":"4","journal":{"abbrevTitle":"YZHWLPL","coverImgSrc":"journal/img/cover/YZHWLPL.jpg","id":"78","issnPpub":"1007-4627","publisherId":"YZHWLPL","title":"原子核物理评论 "},"keywords":[{"id":"72744217-be57-4b5e-a5ec-e20a203accd2","keyword":"核天体物理","originalKeyword":"核天体物理"},{"id":"0a73c120-d222-482c-a24b-63aa4b668153","keyword":"X射线暴","originalKeyword":"X射线暴"},{"id":"4420f9cb-677b-4b7c-8eb1-ffb5157b989c","keyword":"放射性束","originalKeyword":"放射性束"},{"id":"e43cb335-2774-4ce4-b03c-875365e1edcc","keyword":"厚靶方法","originalKeyword":"厚靶方法"},{"id":"69788408-e9e5-46d7-be90-bb0bfb1ec141","keyword":"共振散射","originalKeyword":"共振散射"}],"language":"zh","publisherId":"yzhwlpl201304001","title":"关键天体反应18Ne(α,p)21Na的实验研究","volume":"","year":"2013"},{"abstractinfo":"北京放射性核束装置在线同位素分离器(Beijing Radioactive Ion-beam Facilities Isotope Separator On-line)利用回旋加速器提供的100 MeV高能质子束轰击靶材料产生放射性核束。高能质子束轰击靶材料产生的最高1014 n/s的中子及很强的γ射线会对靶附件的设备造成严重的活化。为了解决靶源系统设备的维护问题,靶源系统采用模块化设计。靶源系统共分为3个模块,每个模块具有独立的水冷、供电及电信号馈入。真空、水、电、气等可以伴随模块的插拔自动接通或者断开。各模块可以通过特制的吊钩远程抓取或者释放,借助监控系统,实现各个模块从靶源间到热室的远程转运。该系统已完成了安装和调试,并已投入使用。","authors":[{"authorName":"黄青华","id":"228eab22-7047-4e44-9aa3-2acec0d62159","originalAuthorName":"黄青华"},{"authorName":"崔保群","id":"c93cfe20-477f-4e2d-aa73-a8b18f3b0c7b","originalAuthorName":"崔保群"},{"authorName":"陈立华","id":"8f296c64-eb2f-436f-ac1c-af74f1552df9","originalAuthorName":"陈立华"},{"authorName":"唐兵","id":"8243372a-1ecc-4689-97f5-21c3d7b4e392","originalAuthorName":"唐兵"},{"authorName":"马瑞刚","id":"92e6680a-3ff2-484e-ab74-0fd5276f39ab","originalAuthorName":"马瑞刚"},{"authorName":"马鹰俊","id":"a5d33278-121a-4a56-948d-ff8a8a7156e7","originalAuthorName":"马鹰俊"},{"authorName":"葛帅","id":"08938d5b-9d8e-4d0f-892e-d5dac78c6bb2","originalAuthorName":"葛帅"},{"authorName":"马燮","id":"4a52a53f-fd88-4aa9-8edc-485a81b55cac","originalAuthorName":"马燮"},{"authorName":"姜冲","id":"6bdd4785-6b7f-467a-818b-5773b5061731","originalAuthorName":"姜冲"}],"doi":"10.11804/NuclPhysRev.32.S1.29","fpage":"29","id":"6569c515-eecc-474c-83f7-e10ca00bdf30","issue":"z1","journal":{"abbrevTitle":"YZHWLPL","coverImgSrc":"journal/img/cover/YZHWLPL.jpg","id":"78","issnPpub":"1007-4627","publisherId":"YZHWLPL","title":"原子核物理评论 "},"keywords":[{"id":"2ec15deb-c9b6-43dc-b4b9-acc30858cc14","keyword":"在线同位素分离器","originalKeyword":"在线同位素分离器"},{"id":"11d176ca-29e9-45dd-9280-f3180d347523","keyword":"靶源系统","originalKeyword":"靶源系统"},{"id":"df36f928-1fa6-4fe9-b736-8154e6bbc43c","keyword":"快速接头","originalKeyword":"快速接头"},{"id":"67b58d94-9183-4461-a806-9ec1fab0bc14","keyword":"遥控操作","originalKeyword":"遥控操作"}],"language":"zh","publisherId":"yzhwlpl2015z1007","title":"BRISOL靶源的远控操作系统","volume":"","year":"2015"}],"totalpage":1,"totalrecord":7}