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  4. 铝钛渣固相反应合成六铝酸钙材料的研究

人工晶体学报, 2013, 42(5): 981-984.

铝钛渣固相反应合成六铝酸钙材料的研究

罗旭东 1, , 曲殿利 2, , 张国栋 hydrogen blister formation on as-cast AZ91 magnesium alloy was investigated in 0.1 M NaOH solution using galvanostatic test. The results showed that cathodic charging of AZ91 alloy resulted in hydrogen blister formation, and blister rupture caused the nucleation and propagation of transgranular micro-cracks around the ruptured blister. (C) 2009 Elsevier Ltd. All rights reserved.","authors":[],"categoryName":"|","doi":"","fpage":"1197","id":"44b8648d-e9ae-40e5-8891-40e84663c8f0","issue":"5","journal":{"abbrevTitle":"CS","id":"36011533-0ced-443e-899a-7c7323dae3b5","issnPpub":"0010-938X","publisherId":"CS","title":"Corrosion Science"},"keywords":[{"id":"32fcd38c-6d35-48d3-b5f9-392e489bce60","keyword":"Magnesium;Galvanostatic;stress-corrosion cracking;in-situ observation;mg-al alloy;sodium-sulfate solution;wet-dry conditions;na2so4 solution;behavior;initiation;hydride;steels","originalKeyword":"Magnesium;Galvanostatic;stress-corrosion cracking;in-situ observation;mg-al alloy;sodium-sulfate solution;wet-dry conditions;na2so4 solution;behavior;initiation;hydride;steels"}],"language":"en","publisherId":"0010-938X_2009_5_5","title":"Formation of hydrogen blister on AZ91 magnesium alloy during cathodic charging","volume":"51","year":"2009"},{"abstractinfo":"In this work, blister of the Cu-Sn plus Cr coating on solid cantilevers of hydraulic supports for coal mining was investigated by hydrogen-charging, Devanathan-Stachurski method and electrochemical impedance spectroscopy (EIS) measurement. It was found that the permeation hydrogen during the pickling process and the electroplating process was responsible for the blisters. The residual tensile stress due to the machining process would increase the permeation hydrogen amount during pickling and electroplating processes.","authors":[],"categoryName":"|","doi":"","fpage":"3183","id":"9f4cd1dd-b829-401f-835c-1c507b82c88a","issue":"12","journal":{"abbrevTitle":"SCS","id":"8e02334e-0007-4675-9eda-1bc1d39b75d9","issnPpub":"1674-7321","publisherId":"SCS","title":"Science China-Technological Sciences"},"keywords":[{"id":"46ca7763-6974-4cfe-afac-e83b6ef466e2","keyword":"hydrogen blister;hydrogen permeation;EIS;sub-surface hydrogen;concentration;ph-microscopy;hydrogen;permeation;steel;metals","originalKeyword":"hydrogen blister;hydrogen permeation;EIS;sub-surface hydrogen;concentration;ph-microscopy;hydrogen;permeation;steel;metals"}],"language":"en","publisherId":"1674-7321_2010_12_1","title":"Study on blister of the coating on solid cantilevers of hydraulic supports for coal mining","volume":"53","year":"2010"},{"abstractinfo":"通过扫描电镜观察和能谱分析研究了一种工业纯铁中第二相和夹杂物粒子对氢鼓泡或氢致裂纹形成的影响.结果表明,每一个氢鼓泡均有一个形核点,氢致裂纹起源于形核点处.氢鼓泡通过裂纹在氢压作用下连续或不连续扩展而长大.大多数(88%)氢鼓泡的形核点处发现有第二相或夹杂物粒子.这些夹杂物的化学成分主要为Ti、Al、Si、Mn、和S.对这些氢鼓泡的形成进行了分析,并且提出了氢鼓泡形核的新机理.","authors":[{"authorName":"任学冲","id":"7e0606a3-3b51-4fce-ae5d-2bbfa0530798","originalAuthorName":"任学冲"},{"authorName":"褚武扬","id":"d676834a-6df2-4a15-b276-5a5b19d2846c","originalAuthorName":"褚武扬"},{"authorName":"李金许","id":"9722ea2e-fce8-4265-8fae-eb682f5c2514","originalAuthorName":"李金许"},{"authorName":"宿彦京","id":"11320d0a-3972-4989-b2dc-69620667c728","originalAuthorName":"宿彦京"},{"authorName":"乔利杰","id":"d505e875-9f38-457f-b053-016cfcc9e4a0","originalAuthorName":"乔利杰"}],"categoryName":"|","doi":"","fpage":"673","id":"07d54b4f-7ce1-4463-8e03-b5b9e476b931","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":"a78fef55-cd51-464d-ba0f-90c37642bb85","keyword":"第二相","originalKeyword":"第二相"},{"id":"b6083307-5136-4f50-81d9-92efa98aadd5","keyword":"second phase","originalKeyword":"second phase"},{"id":"30333f17-095e-48fa-bb05-acd6ed4286d3","keyword":"hydrogen blister","originalKeyword":"hydrogen blister"},{"id":"96edf4b8-cb3d-442a-8ae4-ed0718188216","keyword":"nucleation","originalKeyword":"nucleation"},{"id":"2ebc4b24-0ea3-42a8-a1de-85483cdf6b8a","keyword":"iron","originalKeyword":"iron"}],"language":"zh","publisherId":"0412-1961_2007_7_10","title":"夹杂对氢鼓泡形成的影响","volume":"43","year":"2007"},{"abstractinfo":"The model of hydrogen diffusion formerly de- veloped [1] has been applied successfully to the hydrogen permeation experiment results of three kinds of materials,α—Fe,Fe—Ti alloy and Fe—Ti—C alloy by the mathematical fitting method.From the fitting results it was shown that the model can re- fiect well the diffusion of hydrogen in the materials with trapping.The obtained trapping parameters(α and β)can be used to explain well the diffusion of hydrogen in the samples with trapping.","authors":[{"authorName":"YANG Ke","id":"308c82a8-6249-493a-b5f0-fc08c44fef7a","originalAuthorName":"YANG Ke"},{"authorName":"CAO Mingzhou","id":"a8eb97de-e7e2-4371-ad64-96efe9cf6f91","originalAuthorName":"CAO Mingzhou"},{"authorName":"WAN Xiaojing","id":"ee2aa638-d38b-48ef-af8e-af0992287c58","originalAuthorName":"WAN Xiaojing"},{"authorName":"SHI Changxu Institute of Metal Research","id":"a42367ee-a440-41bb-ba1c-96c308c078bd","originalAuthorName":"SHI Changxu Institute of Metal Research"},{"authorName":"Academia Sinica","id":"9e9fa10d-abdb-4b96-b2f5-39a95a798292","originalAuthorName":"Academia Sinica"},{"authorName":"Shenyang","id":"4f9718b2-9fe0-4666-b276-c476b1485d85","originalAuthorName":"Shenyang"},{"authorName":"110015","id":"a5bed489-7be7-4d3e-95c1-f493a3bf725d","originalAuthorName":"110015"},{"authorName":"China.","id":"47f915e0-93ea-487e-9913-61280c8b2ab9","originalAuthorName":"China."}],"categoryName":"|","doi":"","fpage":"421","id":"28eaf562-0747-4519-9c33-b2c820ca1f08","issue":"6","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":"448b13aa-c6d8-41d3-8dc7-2c46dff2aa8c","keyword":"hydrogen diffusion","originalKeyword":"hydrogen diffusion"},{"id":"c27beea6-e958-4ca2-95fd-83518584f0ba","keyword":"null","originalKeyword":"null"},{"id":"4ecc116c-7b1a-4108-b6a5-48c27f80d563","keyword":"null","originalKeyword":"null"},{"id":"28afe10a-c1df-4e8c-b49e-487618dc1877","keyword":"null","originalKeyword":"null"}],"language":"en","publisherId":"1005-0302_1990_6_9","title":"Application of the Hydrogen Diffusion Model to the Hydrogen Permeation","volume":"6","year":"1990"},{"abstractinfo":"Microporous zeolites as media for hydrogen storage have been paid more and more attention in recent years. However, the reports on hydrogen adsorption mechanism, hydrogen storage capacity of the materials and its relevant factors are quite controversial. In this review, the results of adsorption experiments as well as theoretical modeling for hydrogen storage of various structure-type zeolites are briefly reviewed. The influence of many factors on hydrogen storage capacity is emphatically analyzed, such as the zeolitic structures, Si/Al ratio, type of cations in zeolites and the difference of adsorption experimental conditions, etc. And the progress of supercritical adsorption theory models also is discussed. Finally, the possibility and the research trend of zeolites for hydrogen storage are discussed.","authors":[],"categoryName":"|","doi":"","fpage":"248","id":"62daec44-7d57-4738-8263-0e84d033e870","issue":"1","journal":{"abbrevTitle":"PIC","id":"eafe01e2-8d91-4919-8797-f4c0fbee9a5a","issnPpub":"1005-281X","publisherId":"PIC","title":"Progress in Chemistry"},"keywords":[{"id":"ef7718fc-51c0-4c3e-83b0-3340f650ee41","keyword":"zeolites;hydrogen storage;adsorption;ion-exchanged zeolites;molecular-hydrogen;gas-adsorption;drift;spectra;storage;sodalite;silica;physisorption;faujasites;diffusion","originalKeyword":"zeolites;hydrogen storage;adsorption;ion-exchanged zeolites;molecular-hydrogen;gas-adsorption;drift;spectra;storage;sodalite;silica;physisorption;faujasites;diffusion"}],"language":"en","publisherId":"1005-281X_2010_1_1","title":"The Study of Adsorption of Hydrogen on Zeolites","volume":"22","year":"2010"},{"abstractinfo":"Hydrogen is the cleanest, sustainable and renewable energy carrier, and a hydrogen energy system is expected to progressively replace the existing fossil fuels in the future, the latter are being depleted very fast and causes severe environmental problems. In particular, one potential use of hydrogen lies in powering zero-emission vehicles via a proton exchange membrane fuel cell to reduce atmosphere pollution. To achieve this goal feasible onboard hydrogen storage systems have to be developed. The recent discovery of the high and reversible hydrogen storage capacity of carbon nanotubes makes such a system very promising. In this overview, theoretical predictions and experimental results on the hydrogen uptake of carbon nanotubes and nanofibers are summarized, and we point out that, in order to accelerate the development of carbon nanotubes and nanofibers as a practical hydrogen storage medium in fuel cell-driven vehicles, many efforts have to be made to reproduce and verify the results both theoretically and experimentally, and to investigate their volumetric capacity, cycling characteristics and release behavior. (C) 2001 Elsevier Science Ltd. All rights reserved.","authors":[],"categoryName":"|","doi":"","fpage":"1447","id":"732d9ef3-6ee0-4c15-8298-e4dca7ef0989","issue":"10","journal":{"abbrevTitle":"C","id":"910a0838-fa53-4fb8-b68c-5d74c721edf4","issnPpub":"0008-6223","publisherId":"C","title":"Carbon"},"keywords":[{"id":"64f42961-0804-4329-96af-3d8880797877","keyword":"carbon nanotubes;adsorption;gas storage;monte-carlo simulations;graphite nanofibers;adsorption;physisorption;pores","originalKeyword":"carbon nanotubes;adsorption;gas storage;monte-carlo simulations;graphite nanofibers;adsorption;physisorption;pores"}],"language":"en","publisherId":"0008-6223_2001_10_1","title":"Hydrogen storage in carbon nanotubes","volume":"39","year":"2001"},{"abstractinfo":"The discrete variational method (DVM)and cluster model are used to study the electronic structure and atomic configuration of the hydrogen-vacancy complex in iron.The optimum location of hydrogen atom in the monovacancy in iron is determined by minimizing the total energy and the bond characteristic between hydrogen and iron atoms is analyzed Meanwhile, the positron annihilation characteristics of the hydrogen -vacancy complex is also calculated.","authors":[{"authorName":"WANG Xiaogang(Hunan Normal University","id":"a729a28d-10c1-4951-8981-5694e8bb05f7","originalAuthorName":"WANG Xiaogang(Hunan Normal University"},{"authorName":" Changsha. China Manuscript received 3 June 1994)","id":"d92d141b-e7ff-4b77-8073-a5aecff573cc","originalAuthorName":" Changsha. China Manuscript received 3 June 1994)"}],"categoryName":"|","doi":"","fpage":"181","id":"097697ae-219b-403e-8642-a7a379508ade","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":"9b25eefa-f7e7-494d-bb70-499b3e34127b","keyword":":vacancy hydrogen-vacancy complex","originalKeyword":":vacancy hydrogen-vacancy complex"},{"id":"0b549b4b-2346-4ee0-8ce8-c2a0187f8d80","keyword":"null","originalKeyword":"null"},{"id":"3362e611-8460-417e-a766-45924d2cbaac","keyword":"null","originalKeyword":"null"}],"language":"en","publisherId":"1006-7191_1995_3_3","title":"HYDROGEN-VACANCY INTERACTION IN IRON","volume":"8","year":"1995"},{"abstractinfo":"Hydrogen storage is a key to the utility of hydrogen as a renewable energy source The encapsulation of hydrogen on porous materials has its special advantages In this review, the fundamentals of the encapsulation are briefly introduced The relevant porous materials of zeolites, metal coordination compounds, hollow glass microspheres, fullerenes and their derivative, and their characteristics on encapsulation of hydrogen are addressed in details Recent progresses on the studies of the encapsulation of hydrogen on porous materials are summarized The differences between the encapsulation and physical adsorption of hydrogen on porous materials are analyzed based on their required operation conditions, material specifications and energy barriers Finally, the perspectives of the applications and further studies on the encapsulation of hydrogen are discussed","authors":[],"categoryName":"|","doi":"","fpage":"2238","id":"b7685ae2-d9c2-456d-9932-e340c09c282f","issue":"11","journal":{"abbrevTitle":"PIC","id":"eafe01e2-8d91-4919-8797-f4c0fbee9a5a","issnPpub":"1005-281X","publisherId":"PIC","title":"Progress in Chemistry"},"keywords":[{"id":"6effb779-c067-474a-a868-f58bf29e9e27","keyword":"hydrogen storage;encapsulation;porous materials;molecular-orbital calculations;hollow glass microspheres;boron-nitride;fullerene;diffusion;zeolites;carbon;gases;frameworks;sodalite","originalKeyword":"hydrogen storage;encapsulation;porous materials;molecular-orbital calculations;hollow glass microspheres;boron-nitride;fullerene;diffusion;zeolites;carbon;gases;frameworks;sodalite"}],"language":"en","publisherId":"1005-281X_2010_11_1","title":"Hydrogen Storage by Encapsulation on Porous Materials","volume":"22","year":"2010"},{"abstractinfo":"A general model for hydrogen adsorption was derived using Ono-Kondo lattice theory. The maximum monolayer adsorption capacities of hydrogen molecules on zeolites of NaX, CaA, NaA, and ZSM-5 were determined by fitting experimental adsorption data at different temperatures to the general model. The interaction potential between hydrogen molecules and pore surface atoms in the zeolite was calculated using gas-surface Virial coefficients and the Lennard-Jones (12-6) potential model for cylindrical pores. Results show that the general model can correctly describe supercritical experimental adsorption data of hydrogen on zeolites. Maximum monolayer adsorption capacities of hydrogen molecules on zeolites are dependent on the type of zeolite but independent of temperature. The adsorption interaction potential of the hydrogen-zeolite obtained from the above cylindrical pore model and gas-surface Virial coefficients agrees with a previously reported isosteric heat of hydrogen on zeolites. Our results indicate that the adsorption of hydrogen into zeolite pores is predominately caused by physisorption and a hydrogen-hydrogen attractive interaction.","authors":[],"categoryName":"|","doi":"","fpage":"549","id":"de403d76-913d-4c1b-8ed7-a858be30dd8d","issue":"3","journal":{"abbrevTitle":"APS","id":"917def08-6dcf-48e9-9603-bf5509ffd610","issnPpub":"1000-6818","publisherId":"APS","title":"Acta Physico-Chimica Sinica"},"keywords":[{"id":"15491ae5-efa8-4689-a846-9fd2adf1e86d","keyword":"Hydrogen;Zeolite;Adsorption capacity;Adsorption interaction potential;metal-organic frameworks;monte-carlo simulations;gas-adsorption;critical-temperature;activated carbons;high-pressures;storage;physisorption;compression;nanotubes","originalKeyword":"Hydrogen;Zeolite;Adsorption capacity;Adsorption interaction potential;metal-organic frameworks;monte-carlo simulations;gas-adsorption;critical-temperature;activated carbons;high-pressures;storage;physisorption;compression;nanotubes"}],"language":"en","publisherId":"1000-6818_2009_3_1","title":"Behavior of Adsorbed Hydrogen Molecules on Zeolites","volume":"25","year":"2009"},{"abstractinfo":"Hydrogen damage in iron or 99.99% purity has been investigated by Doppler broadening measurement.Experimental results show that when the iron is charged with hydrogen in 0.5mol/L H_2SO_4 solution,the critical current density to cause hydrogen damage is 20mA/cm~2.While a little As_2O_3,saying 250mg/L,added to H_2SO_4 solution,even rather small current density.≤0.2mA/cm~2,would cause hydrogen damage.With the help ofi slow tensile test,it revealed that the hydrogen damage occurred in the specimen may be influential to the subsequent process of deformation and fracture.","authors":[{"authorName":"WU Yichu CHANG Xiangrong TIAN Zhongzhuo XIAO Jimei University of Science and Technology Beijing","id":"9480e442-e7c4-4d5e-ba7c-422f75172f7c","originalAuthorName":"WU Yichu CHANG Xiangrong TIAN Zhongzhuo XIAO Jimei University of Science and Technology Beijing"},{"authorName":"Beijing","id":"0b5d3383-21b2-4b69-9552-8bbfc11581e2","originalAuthorName":"Beijing"},{"authorName":"China","id":"07a8534f-e7de-42cc-aea8-36ce38dfc3df","originalAuthorName":"China"}],"categoryName":"|","doi":"","fpage":"305","id":"a89d6fce-3839-442f-90c4-fb5538bd9f87","issue":"4","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":"0cce2991-7d38-4a2a-803f-282b32d95852","keyword":"hydrogen damage","originalKeyword":"hydrogen damage"},{"id":"a862ff53-01bc-427d-b91c-952bdc4520e5","keyword":"null","originalKeyword":"null"},{"id":"8225fdfb-5d26-4cff-aec6-293f2dbb8c0e","keyword":"null","originalKeyword":"null"},{"id":"a3bb330a-2361-4318-a191-20aff859a9a6","keyword":"null","originalKeyword":"null"}],"language":"en","publisherId":"1006-7191_1992_4_12","title":"HYDROGEN DAMAGE IN HIGH PURITY IRON","volume":"5","year":"1992"}],"totalpage":93,"totalrecord":927}