{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"目的 研究不同供油条件下织构表面的润滑性能.方法 首先,建立考虑表面织构的乏油润滑模型,求解修正雷诺方程获得乏油工况下考虑织构表面的润滑油膜厚度以及压力分布.然后,依据求得的润滑油膜厚度判断计算域内各点润滑状态,通过接触压力及油膜厚度分别计算边界润滑、混合润滑以及流体润滑状态下的切应力,并积分求得摩擦力进而得到摩擦系数.结果模拟了供油层厚度为50~500 nm以及充分供油条件下三种织构的润滑行为,获得了不同润滑状态下表面织构的摩擦系数.速度为0.1 m/s时,供油量对接触区油膜厚度的影响较小,不同润滑状态下织构表现出不同的润滑性能.速度为0.2 m/s时,供油层厚度对油膜厚度的影响较大,随着供油层厚度的增大,膜厚明显增加,摩擦系数在供油层厚度为200 nm时最小.结论 接触副处于流体润滑状态时,织构表面不具有减摩效果.接触副处于边界润滑状态时,织构表面具有减摩效果,并且织构较密时,摩擦系数较小.接触副处于混合润滑状态时,织构过于稀疏或密集时均不具有减摩效果,但是合理分布的织构具有减摩效果.","authors":[{"authorName":"<span style=\"color:red\">张生光</span>","id":"66937132-38f7-4027-b67e-128dbd2e4a88","originalAuthorName":"张生光"},{"authorName":"王文中","id":"6a9333a9-33de-41ac-8596-220b6760f538","originalAuthorName":"王文中"},{"authorName":"赵自强","id":"b646e3ec-9849-4052-a40a-8d2941dd50c4","originalAuthorName":"赵自强"}],"doi":"10.16490/j.cnki.issn.1001-3660.2017.06.001","fpage":"1","id":"f01bc6ec-70d2-408c-8f62-70bddda873de","issue":"6","journal":{"abbrevTitle":"BMJS","coverImgSrc":"journal/img/cover/BMJS.jpg","id":"3","issnPpub":"1001-3660","publisherId":"BMJS","title":"表面技术   "},"keywords":[{"id":"9829fa34-581e-417b-a521-690840e1ba17","keyword":"表面织构","originalKeyword":"表面织构"},{"id":"a91f346d-85c8-496a-b5d4-0138e5565e83","keyword":"乏油","originalKeyword":"乏油"},{"id":"aae6fd55-0572-406a-89ae-66957aeed3de","keyword":"摩擦系数","originalKeyword":"摩擦系数"},{"id":"54cf1422-a76b-45f1-a134-bb063131d8f3","keyword":"边界润滑","originalKeyword":"边界润滑"},{"id":"0dd2e6bd-4bf9-4ca0-805d-154fd6ae15fd","keyword":"混合润滑","originalKeyword":"混合润滑"},{"id":"38ac2a11-6a6d-4911-ac66-f49a6fa028dd","keyword":"流体润滑","originalKeyword":"流体润滑"},{"id":"53fc19a1-e3b6-4022-b36b-d73d1e613dcf","keyword":"减摩","originalKeyword":"减摩"}],"language":"zh","publisherId":"bmjs201706001","title":"表面织构及供油量对润滑性能影响的建模分析","volume":"46","year":"2017"},{"abstractinfo":"在可见光照射下,应用合成的新型仿<span style=\"color:red\">生光</span>催化剂HMS-FePcS,催化降解孔雀绿模拟废水.考察了温度、光源强度、催化剂用量、过氧化氢用量以及金属活性中心(Fe,Cu和Co)等一系列因素对降解反应的影响,得到了优化的反应条件.在此基础上推导出孔雀绿光催化降解的反应级数及反应速率常数.该降解反应分两个阶段,初始反应的速率与反应物的浓度无关,呈现出零级反应的特征;而后一阶段的反应呈现一级反应的特征.两段反应均可用经典的Langmuir-Hinshelwood多相催化动力学模型进行合理的解释.","authors":[{"authorName":"高冠道","id":"7d02314b-bc0c-4190-872d-ea3cfbb9eb6e","originalAuthorName":"高冠道"},{"authorName":"张爱勇","id":"13fb78e3-41a5-4e62-821f-5bdd6c649d60","originalAuthorName":"张爱勇"},{"authorName":"张萌","id":"70570fa7-dfed-410a-ac7a-1afa2479c407","originalAuthorName":"张萌"},{"authorName":"陈金龙","id":"7fd8cd31-c72a-443c-abf1-d546127e8c55","originalAuthorName":"陈金龙"},{"authorName":"张全兴","id":"03aaca29-14e1-4c34-a436-d08b04d5e451","originalAuthorName":"张全兴"}],"doi":"","fpage":"397","id":"d001824b-48aa-4bbd-b242-2805999c2bc9","issue":"4","journal":{"abbrevTitle":"CHXB","coverImgSrc":"journal/img/cover/CHXB.jpg","id":"18","issnPpub":"0253-9837","publisherId":"CHXB","title":"催化学报   "},"keywords":[{"id":"bc17efb9-8c98-4d21-850f-de6b44df03fd","keyword":"光催化","originalKeyword":"光催化"},{"id":"c2487904-6fed-4633-9d39-8ea8341d543e","keyword":"孔雀绿","originalKeyword":"孔雀绿"},{"id":"00c53aa1-a062-4114-a6ba-02e94c936be9","keyword":"磺酸铁酞菁","originalKeyword":"磺酸铁酞菁"},{"id":"cc953421-17c3-4dd0-90bf-e47789c15f2e","keyword":"反应因素","originalKeyword":"反应因素"},{"id":"a28d0b69-a154-43d1-80ca-11153a47664b","keyword":"反应动力学","originalKeyword":"反应动力学"}],"language":"zh","publisherId":"cuihuaxb200804017","title":"新型仿<span style=\"color:red\">生光</span>催化剂HMS-FePcS催化降解孔雀绿的反应因素及动力学","volume":"29","year":"2008"},{"abstractinfo":"采用简单的一步溶液浸渍法在大孔SiO2材料上负载四羧基酞菁铁(Fe(Ⅲ)-taPc),制备出有较高催化活性并可重复使用的新型大孔仿<span style=\"color:red\">生光</span>催化剂Fe(Ⅲ)-taPc/SiO2,通过扫描电镜(SEM)、透射电镜(TEM)、紫外-可见漫反射光谱(UV-Vis)、拉曼光谱(Raman)对该催化剂进行了表征,并以有机染料罗丹明B为目标降解物,考察了其可见光光催化性能及循环使用性.实验证明Fe(Ⅲ)-taPc分子与SiO2载体存在较为匹配的相互作用,因而负载后其分散性好、稳定性高,在可见光照射下该催化剂能快速催化降解罗丹明B,反应60min后的降解率最高达97.4％,经过6次循环使用后催化剂的活性没有明显变化.","authors":[{"authorName":"张钰","id":"41b9359d-f7b3-4932-b18a-077d63192d3e","originalAuthorName":"张钰"},{"authorName":"张瑞丰","id":"60a376c4-7b50-4e28-b7da-5cc0fd3026f1","originalAuthorName":"张瑞丰"}],"doi":"","fpage":"1001","id":"1b373bb5-3492-438a-b602-c8951620bd47","issue":"7","journal":{"abbrevTitle":"GNCL","coverImgSrc":"journal/img/cover/GNCL.jpg","id":"33","issnPpub":"1001-9731","publisherId":"GNCL","title":"功能材料"},"keywords":[{"id":"fe256b2e-9e71-4ea3-a30a-46a701e016c8","keyword":"大孔SiO2","originalKeyword":"大孔SiO2"},{"id":"2ea6c779-f294-4732-b262-cd7e447559bf","keyword":"酞菁铁","originalKeyword":"酞菁铁"},{"id":"b87ef612-90c1-4869-91bc-9b1d3c46f792","keyword":"罗丹明B","originalKeyword":"罗丹明B"},{"id":"b973e40a-1b8d-46b2-a094-3d6ce3f4a8c3","keyword":"可见光光催化","originalKeyword":"可见光光催化"}],"language":"zh","publisherId":"gncl201307021","title":"新型大孔仿<span style=\"color:red\">生光</span>催化剂Fe(Ⅲ)-taPc/SiO2的制备及其光催化降解性能","volume":"44","year":"2013"},{"abstractinfo":"在可见光照射下,采用合成的新型仿<span style=\"color:red\">生光</span>催化剂HMS-FePcS催化降解孔雀绿模拟染料废水. 由不同反应时间段反应液的HPLC谱和MS谱中产物峰的变化可知,孔雀绿的催化降解过程为先脱色后矿化. 采用固体萃取法对孔雀绿降解的中间产物进行了富集和分离,并使用GC-MS对所得的中间产物进行了鉴定,确定出10余种中间产物. 在此基础上对孔雀绿的降解历程进行了推测,指出孔雀绿的光催化降解主要从中心碳原子与二甲氨基苯基之间的 C - C 键处断裂, 4-二甲氨基苯甲酮是此反应最常见的中间产物. 当 4-二甲氨基苯甲酮被羟基自由基进攻时,生成苯甲酸、对二甲氨基苯甲酸及对二甲氨基苯酚等化合物. 这些小分子芳香类中间产物进一步发生羟基化反应,开环生成小分子脂肪酸类化合物.","authors":[{"authorName":"高冠道","id":"189bad5a-3bd8-4d14-9e5c-27da0ad6eadf","originalAuthorName":"高冠道"},{"authorName":"张爱勇","id":"7bedb9d0-79a7-4bcd-af66-eb4d1c470571","originalAuthorName":"张爱勇"},{"authorName":"张萌","id":"b6057b4b-90a1-48db-8af5-1d2d95cea052","originalAuthorName":"张萌"},{"authorName":"陈金龙","id":"4d59103c-79fb-4dc5-bdab-446541982c93","originalAuthorName":"陈金龙"},{"authorName":"张全兴","id":"19cbd039-4aff-4bf4-90a1-8422c59fd86b","originalAuthorName":"张全兴"}],"doi":"","fpage":"426","id":"2746a18f-2df6-4b61-8d86-ea886378a075","issue":"5","journal":{"abbrevTitle":"CHXB","coverImgSrc":"journal/img/cover/CHXB.jpg","id":"18","issnPpub":"0253-9837","publisherId":"CHXB","title":"催化学报   "},"keywords":[{"id":"112d1c72-0978-4dc2-af85-617c457f244a","keyword":"可见光","originalKeyword":"可见光"},{"id":"9714e788-7fa8-4192-9a8f-1ff1389382e9","keyword":"孔雀绿","originalKeyword":"孔雀绿"},{"id":"a334190c-a320-4eda-84f8-9b47a47e3514","keyword":"降解历程","originalKeyword":"降解历程"},{"id":"b0088167-5cc2-4a0d-b323-620f0eb560ea","keyword":"光催化","originalKeyword":"光催化"},{"id":"b8d088e9-b1de-4a9d-b427-2e95066c2b56","keyword":"磺酸铁酞菁","originalKeyword":"磺酸铁酞菁"}],"language":"zh","publisherId":"cuihuaxb200805004","title":"新型仿<span style=\"color:red\">生光</span>催化剂HMS-FePcS催化孔雀绿在可见光下的降解历程","volume":"29","year":"2008"},{"abstractinfo":"通过付-克反应用磺酸铁酞菁(FePcS)修饰中孔分子筛HMS,首次得到了一种新型光反应催化剂(简称为HMS-FePcS),并用XRD,TG,FT-IR, SEM/TEM,元素分析及固体紫外漫反射光谱等手段对催化剂进行了表征. 实验结果表明,催化剂能高效地催化H2O2氧化降解孔雀绿染料,光照下,在500 ml浓度为0.1 mmol/L的孔雀绿溶液中加入0.3 ml 30%的H2O2和20 mg HMS-FePcS催化剂,于50 ℃下反应 1?200 min,脱色率接近100%,总有机碳的去除率达到73%. 对孔雀绿光催化降解的机理进行了初步探讨.","authors":[{"authorName":"高冠道","id":"e377c70b-4cd9-48bf-be15-18e3ad9fe786","originalAuthorName":"高冠道"},{"authorName":"陈金龙","id":"8d8591a2-8ca3-4f65-845a-714a73ba1c28","originalAuthorName":"陈金龙"},{"authorName":"郑寿荣","id":"98c8bde4-15e5-46a9-a7ee-19a9961d41ec","originalAuthorName":"郑寿荣"},{"authorName":"费正皓","id":"8ce71f33-2e7b-4d81-88c8-d6523f1992c9","originalAuthorName":"费正皓"},{"authorName":"刘福强","id":"025e9bc5-d1a7-4c5d-b601-be9402218455","originalAuthorName":"刘福强"},{"authorName":"李爱民","id":"74df0414-99fc-46b4-8687-58792b42672f","originalAuthorName":"李爱民"},{"authorName":"鲁秀国","id":"c7c9a747-838b-49d7-93e8-a97a15485b4f","originalAuthorName":"鲁秀国"},{"authorName":"张全兴","id":"2204dab1-4461-4406-8dd6-7737237b2ce6","originalAuthorName":"张全兴"}],"doi":"","fpage":"545","id":"ae3e5b48-6332-4a20-903d-b317749f4d04","issue":"7","journal":{"abbrevTitle":"CHXB","coverImgSrc":"journal/img/cover/CHXB.jpg","id":"18","issnPpub":"0253-9837","publisherId":"CHXB","title":"催化学报   "},"keywords":[{"id":"2c35f261-8541-407b-adeb-5b48928b719f","keyword":"光催化氧化","originalKeyword":"光催化氧化"},{"id":"5ea915ed-5427-46ed-98c1-f0dabe107a86","keyword":"孔雀绿","originalKeyword":"孔雀绿"},{"id":"4a3deeb0-354d-409a-8b5b-2024e0305639","keyword":"磺酸铁酞菁","originalKeyword":"磺酸铁酞菁"},{"id":"18d0d7f8-5dfa-4d6b-b9f9-008fcc6a84da","keyword":"HMS分子筛","originalKeyword":"HMS分子筛"},{"id":"248fc2df-acb1-45f7-bb3e-fbf7cc157d26","keyword":"可见光","originalKeyword":"可见光"}],"language":"zh","publisherId":"cuihuaxb200507006","title":"新型仿<span style=\"color:red\">生光</span>催化剂的合成及在孔雀绿光催化降解中的作用","volume":"26","year":"2005"},{"abstractinfo":"综述了碱性锌酸盐体系锌及锌铁合金电镀添加剂的研究和发展，添加剂产<span style=\"color:red\">生光</span>亮作用的机理。","authors":[{"authorName":"王云燕","id":"db32850b-36ef-4bbf-b984-cbb152109a54","originalAuthorName":"王云燕"},{"authorName":"舒余德","id":"dcb63183-9621-4f71-a952-e15c17077fe8","originalAuthorName":"舒余德"},{"authorName":"谢勤","id":"ab38cd72-0e3d-438e-87e2-e22ce180b958","originalAuthorName":"谢勤"},{"authorName":"符德学","id":"8d7669fd-2c3c-4c76-8c13-b8ad1f60efb1","originalAuthorName":"符德学"}],"doi":"10.3969/j.issn.1004-227X.2001.03.004","fpage":"12","id":"e50976f5-67b0-4542-abd2-e97fff78c101","issue":"3","journal":{"abbrevTitle":"DDYTS","coverImgSrc":"journal/img/cover/DDYTS.jpg","id":"21","issnPpub":"1004-227X","publisherId":"DDYTS","title":"电镀与涂饰   "},"keywords":[{"id":"13c389c3-b913-403d-8ab0-6530f65081df","keyword":"锌酸盐体系","originalKeyword":"锌酸盐体系"},{"id":"d2f956f5-4da2-4784-90d3-ac0f1cd8965a","keyword":"电镀","originalKeyword":"电镀"},{"id":"1ebfac93-f2f2-4591-9a38-ef5c98645434","keyword":"锌及锌铁合金","originalKeyword":"锌及锌铁合金"},{"id":"78460f6a-18f4-486d-851e-4e1da5c07b74","keyword":"添加剂","originalKeyword":"添加剂"}],"language":"zh","publisherId":"ddyts200103004","title":"碱性锌酸盐体系锌及锌铁合金电镀添加剂","volume":"20","year":"2001"},{"abstractinfo":"采用射频磁控溅射法,分别以聚四氟乙烯(PIFE)和辞为靶,在聚对苯二甲酸乙二醇酯(PET)基底上沉积氟碳(FC)膜以及FC/ZnO的有机.无机纳米杂化材料.用SEM、UV、XPS对氟碳膜和杂化材料进行了表征.结果表明,氟碳膜形成了一种由纳米粒子-纳米孔洞组成的双纳米结构,随着ZnO沉积时间的不同,FC/ZnO杂化膜呈现出不同的表面形貌,杂化膜的生长模式是一种依附于有机核的沉积-扩<span style=\"color:red\">张生</span>长模式;杂化材料的F/C较低,随着氧化锌沉积时间的增加,F/C出现逐渐增大的趋势;杂化膜是一种多重抗紫外线辐射的功能膜.","authors":[{"authorName":"张浴晖","id":"8bcb5024-0a9d-4e6f-96a9-d91f41a34bd0","originalAuthorName":"张浴晖"},{"authorName":"齐宏进","id":"07a5b63b-7259-4f8e-9cbf-1b57978ccfb9","originalAuthorName":"齐宏进"}],"doi":"","fpage":"83","id":"2d39f0cb-1e7a-4b8e-9054-9b3a6e71880f","issue":"10","journal":{"abbrevTitle":"GFZCLKXYGC","coverImgSrc":"journal/img/cover/GFZCLKXYGC.jpg","id":"31","issnPpub":"1000-7555","publisherId":"GFZCLKXYGC","title":"高分子材料科学与工程"},"keywords":[{"id":"743d445b-e7a2-42a1-8be9-3428de92b9f0","keyword":"磁控溅射法","originalKeyword":"磁控溅射法"},{"id":"3d8178e1-53de-4488-ace1-9d7b5df9fb1f","keyword":"杂化材料","originalKeyword":"杂化材料"},{"id":"3011251a-61b2-43c5-9dd2-6aabba7916a4","keyword":"氟碳","originalKeyword":"氟碳"},{"id":"c060e393-d12c-4528-bff1-e1893db2ff39","keyword":"氧化锌","originalKeyword":"氧化锌"}],"language":"zh","publisherId":"gfzclkxygc200810022","title":"FC/ZnO杂化材料的制备及结构与性能","volume":"24","year":"2008"},{"abstractinfo":"评述了铋分光光度法分析概况,内容包括:高灵敏新有机显色剂,多元络合物,萃取光度法,动力学光度法,固相光度法,KI-硫脲光度法,氢化物发<span style=\"color:red\">生光</span>度法等.引用文献71篇.","authors":[{"authorName":"曹岳辉","id":"a6a0fa52-abf0-4c0e-8d1a-e58bb11a9d9d","originalAuthorName":"曹岳辉"},{"authorName":"黄坚","id":"466c664d-c365-46e1-9daa-80de02205823","originalAuthorName":"黄坚"}],"doi":"10.3969/j.issn.1000-7571.2000.06.009","fpage":"26","id":"da48fc57-4e80-478a-a986-95398c4cb49f","issue":"6","journal":{"abbrevTitle":"YJFX","coverImgSrc":"journal/img/cover/YJFX.jpg","id":"71","issnPpub":"1000-7571","publisherId":"YJFX","title":"冶金分析   "},"keywords":[{"id":"c64810a0-c419-4abe-b620-1873b35d58a6","keyword":"分光光度法","originalKeyword":"分光光度法"},{"id":"eb2dbef0-431e-41d7-aadd-b787068f6dbc","keyword":"铋","originalKeyword":"铋"},{"id":"218a465d-b3d4-42d1-ab78-2f1245ae4384","keyword":"概况","originalKeyword":"概况"}],"language":"zh","publisherId":"yjfx200006009","title":"铋的分光光度法分析概况","volume":"20","year":"2000"},{"abstractinfo":"磁性液体是一种特殊的高分子稳定胶体,对外施磁场特别敏感.通过实验观察和计算分析发现磁性液体在外施磁场下弱絮凝行为表现异常明显,又显示出特有的方向性.而且弱絮凝与絮凝不同,它不会使胶体系统失稳,合乎产<span style=\"color:red\">生光</span>学各向异性的事实,从而揭示了磁性液体在外施磁场作用下的方向性弱絮凝是产<span style=\"color:red\">生光</span>学各向异性的机理.","authors":[{"authorName":"王正良","id":"fa11b494-3f3d-467f-94df-7e1676a758a3","originalAuthorName":"王正良"},{"authorName":"陈善飞","id":"a32dab81-181e-426f-98b6-563e5957bf5c","originalAuthorName":"陈善飞"},{"authorName":"虞秀平","id":"c652a21d-6cad-4015-b943-3e42519624b6","originalAuthorName":"虞秀平"}],"doi":"10.3969/j.issn.1007-4252.2002.03.016","fpage":"285","id":"d5528cfa-5917-4050-90f4-00ca51e25ae9","issue":"3","journal":{"abbrevTitle":"GNCLYQJXB","coverImgSrc":"journal/img/cover/GNCLYQJXB.jpg","id":"34","issnPpub":"1007-4252","publisherId":"GNCLYQJXB","title":"功能材料与器件学报   "},"keywords":[{"id":"1ad0e627-3091-473d-80e5-4c90defd196b","keyword":"光波","originalKeyword":"光波"},{"id":"36f70fb0-0663-49b0-8ec8-faa942f047f1","keyword":"磁性液体","originalKeyword":"磁性液体"},{"id":"017ab394-b3b4-496d-87aa-9127d2d2e96d","keyword":"方向性弱絮凝","originalKeyword":"方向性弱絮凝"}],"language":"zh","publisherId":"gnclyqjxb200203016","title":"磁性液体的磁光效应机理研究","volume":"8","year":"2002"},{"abstractinfo":"在激光雷达测量平流层下部臭氧时,我们发现光电倍增管接收到较低高度的强信号后,回波信号会产<span style=\"color:red\">生光</span>子并合现象.数据处理分析表明,光子并合现象对平流层下部臭氧测量的影响很大.为避免产<span style=\"color:red\">生光</span>子并合现象的产生,可以利用在接收光路上加装中性衰减片、提高光电倍增管开始工作的高度和降低光电倍增管增益等措施来分段测量,提高臭氧测量的精度.","authors":[{"authorName":"胡顺星","id":"368e3f33-5fbc-4cda-8f0a-74f54c46ca07","originalAuthorName":"胡顺星"},{"authorName":"胡欢陵","id":"8af1f4e0-5a3e-4997-8174-e70931a670aa","originalAuthorName":"胡欢陵"},{"authorName":"吴永华","id":"6b2d9c89-d196-47b9-8c3b-8d8baac8b2c1","originalAuthorName":"吴永华"},{"authorName":"周军","id":"38854128-c3d7-4b7c-a1fc-4b6c0cd7c810","originalAuthorName":"周军"}],"doi":"10.3969/j.issn.1007-5461.2002.06.017","fpage":"550","id":"393dec18-08a0-4b8e-8f53-2b80d5d272ff","issue":"6","journal":{"abbrevTitle":"LZDZXB","coverImgSrc":"journal/img/cover/LZDZXB.jpg","id":"53","issnPpub":"1007-5461","publisherId":"LZDZXB","title":"量子电子学报   "},"keywords":[{"id":"bd2a9c68-f8b6-40e5-892f-bc6ecd013b15","keyword":"激光雷达","originalKeyword":"激光雷达"},{"id":"b0010da5-8bdc-4620-86b5-85b7b0726f35","keyword":"光子并合","originalKeyword":"光子并合"},{"id":"bb412ecb-da3e-434c-ab38-01fe0a5e95bf","keyword":"臭氧","originalKeyword":"臭氧"}],"language":"zh","publisherId":"lzdzxb200206017","title":"光子并合作用对激光雷达测量臭氧的影响分析","volume":"19","year":"2002"}],"totalpage":9,"totalrecord":82}