{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"Precipitation condition and nucleation of Ti2 03 during solidification of clean steel have been studied. The behavior of Ti2 03 during solidification as well as possibility of using Ti203 to refine as-cast grains as heterogeneous nucleation sites is discussed. It is shown that Ti2 03 can be formed provided that the steelmaking and solidification process is controlled strictly. And inoculating clean steel with Ti203 is an effective way to refine as-cast grains.","authors":[{"authorName":"G.G.Cheng","id":"7fa0c676-3bf3-4567-8629-b84a9a63efff","originalAuthorName":"G.G.Cheng"},{"authorName":" M.L.Wang","id":"c1ad4288-a7e7-4245-aac5-dbe155bc1457","originalAuthorName":" M.L.Wang"},{"authorName":" X.E.Yang","id":"afdcf242-6c2a-452e-8f51-0858d43dbf9c","originalAuthorName":" X.E.Yang"},{"authorName":" Y.L.Li","id":"cea9a04c-94d5-4af3-8450-bd783623212e","originalAuthorName":" Y.L.Li"},{"authorName":" Y.G.Wang","id":"0e64d18b-eaca-45bd-b7c9-eb3d02a37272","originalAuthorName":" Y.G.Wang"},{"authorName":" L.Y.Wang","id":"d57fd7cf-94ee-4cf7-8efa-499ddc427e0a","originalAuthorName":" L.Y.Wang"},{"authorName":" P.Zhao","id":"0304f9fe-19a4-46d8-b087-4bc1dd3b6c88","originalAuthorName":" P.Zhao"}],"categoryName":"|","doi":"","fpage":"379","id":"ca09b716-0d2b-4800-bf79-b7345badf702","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":"b227da8a-2d0f-49b5-b9b1-892d3a21f333","keyword":"clean steel","originalKeyword":"clean steel"},{"id":"b76e5da5-4f20-463c-9fd3-8d97309afa73","keyword":"null","originalKeyword":"null"},{"id":"bfb6336d-cab2-4275-a3c1-24ea052479cf","keyword":"null","originalKeyword":"null"}],"language":"en","publisherId":"1006-7191_2003_5_10","title":"RESEARCH ON AS-CAST GRAIN REFINING TECHNOLOGY BY INOCULATING CLEAN STEEL WITH TITANIUM OXIDE","volume":"16","year":"2003"},{"abstractinfo":"Clean high carbon heavy rail steel was prepared by the process of vacuum induction furnace smelting, forging and rolling. Mechanisms of RE on the impact toughness and fracture toughness for clean high carbon steel were investigated. In addition, the appropriate range of RE content for clean high carbon steel was determined. Both the austenite grain size and pearlite lamellar spacing decreased due to small amount of RE, consequently the impact toughness and fracture toughness were improved evidently. When the RE content exceeded a critical value, the pearlite lamellar spacing was increased, because RE was segregated on the austenite grain boundaries, damaged the orientation relationship of pearlite transformation, caused the disorder growth and morphology degenerating of pearlite. With the increasing of RE content, both the impact toughness and fracture toughness of clean high carbon steel were gradually increased at first and then decreased. It was found that when the RE content was between 00081% and 00088%, both the impact toughness and fracture toughness of clean high carbon heavy rail steel were the best. The maximum ballistic work was 212 J (20 ℃) and 122 J (-20 ℃), respectively. The maximum plane-strain fracture toughness was 4567 MPa·m1/2 (20 ℃) and 3704 MPa·m1/2 (-20 ℃), respectively.","authors":[{"authorName":"LIU Cheng-jun","id":"769d860e-a90c-4de8-b912-d894ebbeffcb","originalAuthorName":"LIU Cheng-jun"},{"authorName":"HUANG Ya-he","id":"794120bf-f4e7-464a-9a35-de7f00f80cc3","originalAuthorName":"HUANG Ya-he"},{"authorName":"JIANG Mao-fa","id":"203f7114-f014-4a46-b6a6-194c52ff6151","originalAuthorName":"JIANG Mao-fa"}],"categoryName":"|","doi":"","fpage":"52","id":"f59b7ec5-bfd5-4756-9b65-c55a144ac13b","issue":"3","journal":{"abbrevTitle":"GTYJXBYWB","coverImgSrc":"journal/img/cover/GTYJXBEN.jpg","id":"1","issnPpub":"1006-706X","publisherId":"GTYJXBYWB","title":"钢铁研究学报(英文版)"},"keywords":[{"id":"66157a44-6dbe-4ee5-8818-87ccf1c1dcaa","keyword":"rare earth ","originalKeyword":"rare earth "},{"id":"a63253b2-7052-4bd2-a479-813e379b91cf","keyword":" high carbon steel ","originalKeyword":" high carbon steel "},{"id":"cca9742a-8f9d-45e8-8a11-ad4cb779a48f","keyword":" heavy rail steel ","originalKeyword":" heavy rail steel "},{"id":"83074ee1-f270-4571-9529-5365d320a456","keyword":" clean steel ","originalKeyword":" clean steel "},{"id":"758dd04c-9889-498f-9dcb-18d58b296901","keyword":" impact toughness ","originalKeyword":" impact toughness "},{"id":"aee3448c-653b-4b0e-812c-b006497931a6","keyword":" fracture toughness","originalKeyword":" fracture toughness"}],"language":"en","publisherId":"1006-706X_2011_3_2","title":"Effects and Mechanisms of RE on Impact Toughness and Fracture Toughness of Clean Heavy Rail Steel","volume":"18","year":"2011"},{"abstractinfo":"Using density functional theory Calculations in conjunction with the climbing images nudged elastic band method, we studied the vacancy formation and migration in clean and Re-doped Ni(3)Al. Both the chemical potential of the species and the magnetic effect are considered to determine the vacancy formation energy. We also simulated the vacancy migration in a complete set of migration paths. The evaluated vacancy formation energy and activation energy for the motion of vacancy compared well with the experimental results. Also, the obtained migration ways for the diffusion of Ni and Al atoms are consistent with previous theoretical predictions and experimental observations. Magnetism is found to influence both the vacancy formation and migration. Our results reveal that Re doping can inhibit the formation of Ni vacancies but facilitate the formation of Al vacancies, and can also inhibit the migration of neighboring vacancies. While the doped Re atom on the At site is stable, the Re atom on the Ni site can diffuse within the Ni-sublattice mediated by Ni vacancies. (C) 2008 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved.","authors":[],"categoryName":"|","doi":"","fpage":"224","id":"fa286b84-3bd1-4746-91cd-671c36bbb427","issue":"1","journal":{"abbrevTitle":"AM","id":"473e1d60-024a-4fd2-8f59-9e3ede87721e","issnPpub":"1359-6454","publisherId":"AM","title":"Acta Materialia"},"keywords":[{"id":"fde8863a-5de5-461d-b086-41816ba62d39","keyword":"Nickel alloys;Bulk diffusion;Vacancies;Ab initio electron theory;augmented-wave method;molecular-dynamics;order relaxation;self-diffusion;ni3al;defect;energies;mechanism;kinetics;points","originalKeyword":"Nickel alloys;Bulk diffusion;Vacancies;Ab initio electron theory;augmented-wave method;molecular-dynamics;order relaxation;self-diffusion;ni3al;defect;energies;mechanism;kinetics;points"}],"language":"en","publisherId":"1359-6454_2009_1_2","title":"First-principles study of vacancy formation and migration in clean and Re-doped gamma '-Ni(3)Al","volume":"57","year":"2009"},{"abstractinfo":"The rheology feature of Sb, Bi melt and alloys was studied using coaxial cylinder high-temperature viscometer. The results showed that the curve of torsion-rotational speed for Sb melt presents a linear relation in all measured temperature ranges, whereas for the Bi melt, the curve presents obvious non-Newtonian feature within the low temperature range and at relative high shear stress. The rheology feature of Sb80Bi20 and Sb20Bi80 alloy melts was well correlated with that of Sb and Bi, respectively. It is considered that the rheology behavior of Sb melt plays a crucial role in Sb80Bi20 alloy and that of Bi melt plays a crucial role in Sb20Bi80 alloy.","authors":[{"authorName":"C.J. Sun","id":"41f712d0-0b30-4ee0-9444-d6440397cde9","originalAuthorName":"C.J. Sun"},{"authorName":" H.R. Geng","id":"c5d289c2-7740-402c-9980-30c64dd3f5e8","originalAuthorName":" H.R. Geng"},{"authorName":" Y.S. Shen","id":"4c9a4ac8-2ab0-4a4f-84ab-1585b71e6139","originalAuthorName":" Y.S. Shen"},{"authorName":" X.Y. Teng","id":"35974ae7-3ab3-4fb8-97ab-de7dc1fb89db","originalAuthorName":" X.Y. Teng"},{"authorName":" Z.X. Yang","id":"a36b592c-340c-463f-8ad8-d5a0ad9155b7","originalAuthorName":" Z.X. Yang"},{"authorName":"null","id":"62498f98-f6c4-4608-93d3-0c7b62bed3d3","originalAuthorName":"null"},{"authorName":"null","id":"d691a6fe-6118-4bc1-9c1c-cec7b754f83c","originalAuthorName":"null"},{"authorName":"null","id":"10bff4fc-c642-489b-8e22-6393b8124bc5","originalAuthorName":"null"},{"authorName":"null","id":"038d191c-4b04-4b5a-a584-13ebc89ea8a6","originalAuthorName":"null"},{"authorName":"null","id":"e50ac05e-dfa3-40de-8e5a-881bb4090d4c","originalAuthorName":"null"},{"authorName":"null","id":"e8f11731-529f-4394-a3f1-7229e3b61173","originalAuthorName":"null"},{"authorName":"null","id":"23fcb652-4bb6-47c6-9aca-8ca8a97b03c1","originalAuthorName":"null"},{"authorName":"null","id":"f49ece8e-af8d-428f-955c-1d9c10732f9b","originalAuthorName":"null"},{"authorName":"null","id":"83260c97-d8db-4642-a2a0-b71d81ba17ee","originalAuthorName":"null"},{"authorName":"null","id":"8b7036f8-2aa5-4436-b0d3-591ecbe23b54","originalAuthorName":"null"},{"authorName":"null","id":"e66bbc84-4c34-4e37-9a93-65dd99d2405f","originalAuthorName":"null"},{"authorName":"null","id":"4e6872b4-386c-4e34-9c70-c545c6615c0d","originalAuthorName":"null"}],"categoryName":"|","doi":"","fpage":"181","id":"5479fe99-9416-493b-8e5f-abd90a16f0fb","issue":"3","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":"910d6f1c-8f7c-4ea8-b1cb-69c0df09bd7e","keyword":"Newtonian liquid","originalKeyword":"Newtonian liquid"},{"id":"a3ffe8cc-be19-4bf1-917d-8dae7b847657","keyword":"null","originalKeyword":"null"},{"id":"77f6a774-bf44-4b0d-8fb5-92d100874266","keyword":"null","originalKeyword":"null"},{"id":"374f603c-ed04-43ee-8e8d-a1dead7a3883","keyword":"null","originalKeyword":"null"},{"id":"b8661273-7451-4c4a-aa9f-ce46ce730911","keyword":"null","originalKeyword":"null"}],"language":"en","publisherId":"1006-7191_2007_3_5","title":"Rheology Feature of Simple Metal Melt","volume":"20","year":"2007"},{"abstractinfo":"To increase the casting quality of hypoeutectic Al-Si alloys, the effects of melt thermal treatment on the solidification structure of the A356 alloy were analyzed by a factorial experiment, in which the overheated melt was mixed with the low temperature melt. Experimental results show that the elongation ratio and strength of the treated samples increase remarkably compared with the control sample. The primary dendrite size reduces dramatically and the dendrite changes from columnar to equiaxed, with a little change of the secondary dendrite arm spacing (SDAS). Combined with the measurement of the nucleation undercooling, it is concluded that the solidification structure and refining effect are dependent primarily on the low temperature melt. The refining mechanism is believed as a result of the multiplication of the nuclei in the melt thermal treatment procedure","authors":[{"authorName":"Jun WANG","id":"5a262cbf-5b16-4bd2-a715-257a54958c2c","originalAuthorName":"Jun WANG"},{"authorName":" Shuxian HE","id":"7ed72170-8b9d-48bd-b000-cf6b091b014a","originalAuthorName":" Shuxian HE"},{"authorName":" Baode SUN","id":"7a24f673-52cf-4d88-ab20-e7730785a409","originalAuthorName":" Baode SUN"},{"authorName":" Yaohe ZHOU","id":"cc7147d3-fde2-4cb7-83ef-ef2b6fd351c6","originalAuthorName":" Yaohe ZHOU"}],"categoryName":"|","doi":"","fpage":"152","id":"48ae8874-5816-4f6c-bb5b-0082f8c85700","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":[{"id":"da6ca12a-028c-4af3-bb5b-963fd9b29822","keyword":"A356","originalKeyword":"A356"},{"id":"20129b60-db5a-4ce8-ad5c-caec894613f9","keyword":"null","originalKeyword":"null"},{"id":"c53e4e9e-1eef-4dc9-9363-2d45938dffc5","keyword":"null","originalKeyword":"null"}],"language":"en","publisherId":"1005-0302_2003_2_10","title":"Effects of Melt Thermal Treatment on A356 Alloy","volume":"19","year":"2003"},{"abstractinfo":"The structure of NaAlO_2 melt has been studied by computerized simulation using Monte Carlo method.The radial distribution functions and Local structure of this melt are calculated.It has been found that NaAlO_2 melt contains ionic clusters formed by corner-sharing AlO_4 tetrahedra,sodium ions and xNa~+.yO~(2-) ionic clusters.","authors":[{"authorName":"Chi XU Ming LI Nianyi CHEN Shanghai Institute of Metallurgy","id":"e83448c7-41d3-4bb0-b9ef-2073aa1a7d81","originalAuthorName":"Chi XU Ming LI Nianyi CHEN Shanghai Institute of Metallurgy"},{"authorName":"Academia Sinica","id":"74a0e9f7-82fb-46dc-bf80-2f4f52752877","originalAuthorName":"Academia Sinica"},{"authorName":"Shanghai","id":"bad86061-b18c-4d0f-98a9-af03b147f08f","originalAuthorName":"Shanghai"},{"authorName":"200050","id":"90162de0-ab70-4fd2-bfe4-fbcd6a815cd5","originalAuthorName":"200050"},{"authorName":"China","id":"3f0b935f-8f45-41cf-9c2e-2d6874f0f59d","originalAuthorName":"China"}],"categoryName":"|","doi":"","fpage":"65","id":"e09e4cec-b7a3-41b8-9c6e-9bcf9e439647","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":"ff4386c8-0578-4374-86ec-d23d9bdf38fa","keyword":"computerized simulation","originalKeyword":"computerized simulation"},{"id":"3ff89a69-0032-4b8b-91bc-8805c88921f9","keyword":"null","originalKeyword":"null"},{"id":"14b46178-fb91-46eb-87ba-7cb9517fd9a0","keyword":"null","originalKeyword":"null"}],"language":"en","publisherId":"1005-0302_1993_1_1","title":"Computerized Simulation of Structure of NaAIO_2 Melt","volume":"9","year":"1993"},{"abstractinfo":"In order to investigate the magnetic force distribution, flow field distribution and joule heat distribution under the pulsed magnetic field (PMF), transient numerical simulation was carried out. Results show that the magnetic pressure force appears in the inner of the melt, while the magnetic pull force and the magnetic pressure force appear alternately in the exterior of the melt, which is caused by the skin vortex current. The axial direction magnetic force results in the convection Of the melt. The radial direction magnetic force produces vibration of the melt. The vibration will diffuse and superpose to produce the pressure wave. Finally, the fluctuation of the melt is caused by the pressure wave. The joule heat produced by pulsed magnetic field concentrates near the surface of the melt in the pulse applying period. (C) 2009 Elsevier Ltd. All rights reserved.","authors":[],"categoryName":"|","doi":"","fpage":"5285","id":"9bbd0da6-3076-4a8b-a891-f261b53959d8","issue":"23-24","journal":{"abbrevTitle":"IJOHAMT","id":"d94cc4c0-bc34-4af9-a530-b197fa26768c","issnPpub":"0017-9310","publisherId":"IJOHAMT","title":"International Journal of Heat and Mass Transfer"},"keywords":[{"id":"a05af912-3a83-47f6-8d05-d490240ae719","keyword":"Pulsed magnetic field;Transient finite element analysis;Magnetic force;distribution;Flow field;Joule heat distribution;electromagnetic vibrations;microstructural refinement;aluminum-alloys;stainless-steel;al;frequency","originalKeyword":"Pulsed magnetic field;Transient finite element analysis;Magnetic force;distribution;Flow field;Joule heat distribution;electromagnetic vibrations;microstructural refinement;aluminum-alloys;stainless-steel;al;frequency"}],"language":"en","publisherId":"0017-9310_2009_23-24_1","title":"Effect of pulsed magnetic field on superalloy melt","volume":"52","year":"2009"},{"abstractinfo":"Abstract: Growth process of δ-phase was studied during the solidification of carbon steel. Through analyzing the solute diffusion around cylindrical crystals in the melt, the mathematic representation of lateral growth rate of cylindrical crystals was confirmed; the calculation and analysis of lateral growth rate were carried out. In order to validate the theoretical calculation and analysis, the growth process of δ-phase during the solidification was in-situ observed using a confocal scaning laser microscope (CSLM) and the growth rates were measured through CSLM images. The results show that lateral growth rates of δ-phase in the carbon steel first rapidly decrease with the increase of the radius of the cylindrical crystal, and then slowly fall down or maintain invariable. The radius of δ-phase is the primary factor to affect the growth rate. The higher the temperature gradient is, the bigger the growth rate is. However, the effect of the temperature gradient is feeble. Good correlation is obtained between theoretical analysis and experiment results in absolute values of lateral growth rate and change rule.","authors":[{"authorName":"CHANG Guo-wei","id":"16d2b16a-1e62-4775-965d-e6303774f69a","originalAuthorName":"CHANG Guo-wei"},{"authorName":"CHEN Shu-ying","id":"f80f6bd3-433b-41aa-b358-dc365a96301a","originalAuthorName":"CHEN Shu-ying"},{"authorName":"LI Qing-chun","id":"7b64a668-dda0-4852-bf60-efbd0bdbcf99","originalAuthorName":"LI Qing-chun"},{"authorName":"YUE Xu-dong","id":"c334a3bd-1135-4753-bd5f-db7c2aa0a5d7","originalAuthorName":"YUE Xu-dong"},{"authorName":"JIN Guang-can","id":"402679a9-a449-4846-a5ce-7d17dc3d8016","originalAuthorName":"JIN Guang-can"}],"categoryName":"|","doi":"","fpage":"28","id":"7fe2ba51-30c0-45ed-83e3-5207d057eb8c","issue":"4","journal":{"abbrevTitle":"GTYJXBYWB","coverImgSrc":"journal/img/cover/GTYJXBEN.jpg","id":"1","issnPpub":"1006-706X","publisherId":"GTYJXBYWB","title":"钢铁研究学报(英文版)"},"keywords":[{"id":"e66ff7bd-b9c9-422a-840e-a34edc8a935d","keyword":"Key words: cell growth ","originalKeyword":"Key words: cell growth "},{"id":"f43a05ef-ddfa-4f97-8abf-7f5a73f43bb8","keyword":" solidification process ","originalKeyword":" solidification process "},{"id":"54ee7352-594f-4cea-9638-ddcd1a3f01f9","keyword":" carbon steel ","originalKeyword":" carbon steel "},{"id":"4a8fb7ed-59ef-45ea-a08a-d93e8d00a0eb","keyword":" in-situ observation","originalKeyword":" in-situ observation"}],"language":"en","publisherId":"1006-706X_2012_4_11","title":"Lateral Growth Rate of Cells in Melt","volume":"19","year":"2012"},{"abstractinfo":"Using liquid quenching technique,the change of growth mode of graphite in cast iron melt was analysed.Based on the interface structure theory of crystal growth,the concept of multiplication of spiral growth steps was advanced and two basic multiplication models were given.It was proposed that multiplication of spiral steps is responsible for the change of growth mode of graphite in cast iron melt.The modifying elements such as Ce promote multiplication of spiral steps,which is regarded as the core of modification.Origination of screw dislocation and branch of the sector blocks in radius direction,both of which are essential to spheroidization of graphite in the melt,are caused by multiplication of spiral steps:and so is thickening of graphite plates.","authors":[{"authorName":"LIU Yongkun Southwestern Institute of Technology and Engineering","id":"749adbb5-74a6-455d-9223-cf6871024978","originalAuthorName":"LIU Yongkun Southwestern Institute of Technology and Engineering"},{"authorName":"Chongqing","id":"f71d044c-ee8c-4aaa-8d07-19e15c672a5d","originalAuthorName":"Chongqing"},{"authorName":"ChinaYANG Shihao Shandong Polytechnical University","id":"82570d1c-7245-463b-9522-de50c2afdcc6","originalAuthorName":"ChinaYANG Shihao Shandong Polytechnical University"},{"authorName":"Jinan","id":"01d704fb-9c20-4d1e-a9dd-3f1e61f6f514","originalAuthorName":"Jinan"},{"authorName":"China","id":"e726aa33-8707-487a-9866-02587b1e5979","originalAuthorName":"China"}],"categoryName":"|","doi":"","fpage":"263","id":"67daf16c-c06c-4485-964c-990226591a33","issue":"10","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":"4673b7ec-f372-42c4-bf81-f530a1dbaee0","keyword":"graphite","originalKeyword":"graphite"},{"id":"4f077d39-2eb9-463b-a37e-10042c2dab30","keyword":"null","originalKeyword":"null"},{"id":"2882b11f-4976-41e0-97a7-660da101c450","keyword":"null","originalKeyword":"null"},{"id":"03d018fc-142c-403f-88f9-1986b09dcca4","keyword":"null","originalKeyword":"null"},{"id":"cabd9ae7-2f67-4ea7-a170-2bb8cac541ac","keyword":"null","originalKeyword":"null"}],"language":"en","publisherId":"1006-7191_1992_10_18","title":"GROWTH MODE AND MODIFICATION OF GRAPHITE IN CAST IRON MELT","volume":"5","year":"1992"},{"abstractinfo":"The motion of melt droplets in spray degassing process was analyzed theoretically. The height of the treatment tank in spray degassing process could be determined by the results of theoretical calculation of motion of melt droplets. To know whether the melt droplets would solidify during spraying process, the balance temperature of melt droplets was also theoretically analyzed. Then proof experiments for theoretical results about temperature of melt droplets were carried. In comparison, the experimental results were nearly similar to the calculation results.","authors":[{"authorName":"R.Z. Wu","id":"b2ffc09e-acb0-4ad8-8b8c-d2538c74e4eb","originalAuthorName":"R.Z. Wu"},{"authorName":" Z.K. Qu","id":"c9b5282f-132b-49ab-940c-8621f9901d78","originalAuthorName":" Z.K. Qu"},{"authorName":" B.D. Sun","id":"208620d5-7a48-4855-a17a-7539634d7ef5","originalAuthorName":" B.D. Sun"},{"authorName":" D. Shu","id":"caa2706f-8db1-48fd-b42b-0e0c2ad8abe4","originalAuthorName":" D. Shu"},{"authorName":" J. Wang","id":"126fccb4-f330-4873-a575-ce680a452c06","originalAuthorName":" J. Wang"},{"authorName":"null","id":"d416773d-a5f1-4f06-86d2-1b787466fdce","originalAuthorName":"null"},{"authorName":"null","id":"2cd9cce6-4777-42dd-9568-84b1c898ca49","originalAuthorName":"null"},{"authorName":"null","id":"5b681676-629e-4e2e-a79d-85cf08b786bb","originalAuthorName":"null"},{"authorName":"null","id":"0f4544a2-74f7-4655-84d0-de218c1d9119","originalAuthorName":"null"},{"authorName":"null","id":"a41ed1db-4689-4624-8150-1c96104381f3","originalAuthorName":"null"},{"authorName":"null","id":"0049cd9c-5077-42fc-a53d-095fa616198a","originalAuthorName":"null"},{"authorName":"null","id":"a1750440-ba15-4f0c-914b-1ca92cf62374","originalAuthorName":"null"},{"authorName":"null","id":"3bc870b9-5995-459b-a7a8-800325515e32","originalAuthorName":"null"},{"authorName":"null","id":"1fa5945d-0a3f-4d04-aa17-326161bbaabc","originalAuthorName":"null"},{"authorName":"null","id":"2067f151-d91b-43e9-b01c-55ea3295b3b3","originalAuthorName":"null"},{"authorName":"null","id":"8222d8f9-be69-482e-af6c-1ff4163bf403","originalAuthorName":"null"},{"authorName":"null","id":"40c71666-9111-4b4c-9b6d-f58736321e65","originalAuthorName":"null"}],"categoryName":"|","doi":"","fpage":"193","id":"a30d224d-37b7-46d7-bfb8-17a7aee7254f","issue":"3","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":"94c18886-a8ee-45f4-813c-820225bf21d5","keyword":"spray degassing","originalKeyword":"spray degassing"},{"id":"dea48d31-6060-4181-90fd-5e6e836bb06d","keyword":"null","originalKeyword":"null"}],"language":"en","publisherId":"1006-7191_2007_3_2","title":"Theoretical Analysis for the Motion and Temperature of Melt Droplets in Spray Degassing Process","volume":"20","year":"2007"}],"totalpage":53,"totalrecord":522}