{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"介绍了3D显示的基本原理,重点介绍了目前3D显示的主流技术类型,包含了眼镜式3D技术以及裸眼式3D技术,其中眼镜式3D技术包含色差式3D技术、偏光式3D技术和主动快门式3D技术;裸眼式3D技术包含视差屏障式3D技术、柱状透镜式3D技术、指向光源式3D技术和多层显示式3D技术.阐述了各种3D显示技术的基本实现原理和应用领域、并对涉及液晶显示的几种3D技术的优缺点进行了对比.结合液晶材料的特点与3D液晶显示的实际要求,阐述了3D液晶面板对液晶材料快速响应方面的要求,以及液晶透镜对液晶材料光学各向异性参数的要求.","authors":[{"authorName":"张兴","id":"9d60cd30-33e6-4259-b19e-3fbaacf153a8","originalAuthorName":"张兴"},{"authorName":"郑成武","id":"6d465d6d-1cb1-4fc2-8f65-1ee450518dab","originalAuthorName":"郑成武"},{"authorName":"李宁","id":"3cc0f6d4-1c65-42ba-9667-a48f4bb3cff4","originalAuthorName":"李宁"},{"authorName":"周兴丹","id":"262f896b-1244-4eca-abdd-58707f9c22c6","originalAuthorName":"周兴丹"},{"authorName":"李正强","id":"b1e627b1-b53e-41a8-8fb9-59b6fb8dfbfb","originalAuthorName":"李正强"},{"authorName":"华瑞茂","id":"45c5456c-c684-47a6-9fbc-ee8361eb5ae4","originalAuthorName":"华瑞茂"}],"doi":"10.3788/YJYXS20122704.0448","fpage":"448","id":"b563cc2f-f281-41fc-9ce8-9f5e33db8212","issue":"4","journal":{"abbrevTitle":"YJYXS","coverImgSrc":"journal/img/cover/YJYXS.jpg","id":"72","issnPpub":"1007-2780","publisherId":"YJYXS","title":"液晶与显示 "},"keywords":[{"id":"85fe7de4-abf9-4bc8-9f4b-fc44c2916f81","keyword":"3D显示","originalKeyword":"3D显示"},{"id":"e8ef8f0e-70ef-41a0-b0e4-9f78eab11296","keyword":"眼镜式3D显示","originalKeyword":"眼镜式3D显示"},{"id":"75bda9ae-d305-4f56-8bd6-f4a68160e970","keyword":"裸眼式3D显示","originalKeyword":"裸眼式3D显示"},{"id":"7ce28d72-2469-4845-be53-37ca190c9184","keyword":"液晶材料","originalKeyword":"液晶材料"}],"language":"zh","publisherId":"yjyxs201204005","title":"液晶材料与3D显示","volume":"27","year":"2012"},{"abstractinfo":"生物基小分子来源广、价廉,同时大多具有手性,使其在绿色化学盛行的今天作为良好的非介晶基元广泛应用于液晶材料合成研究领域.联苯类液晶因为其良好的物理化学稳定性、较宽的工作温度范围、适当的低黏度,以及快速响应与低电压驱动等优点,在光电显示材料等领域得到了广泛应用.文中综述了近年来薄荷醇、乳酸、糖醇、氨基酸等生物基小分子在联苯类液晶材料合成中的应用进展,指出多生物手性基团结合,特别是与高分子材料的完美组合,是未来研究的新方向.","authors":[{"authorName":"罗时荷","id":"a627d631-2e54-4e3c-8f2d-bb5070a7c6d4","originalAuthorName":"罗时荷"},{"authorName":"熊金锋","id":"262ba9e7-43c2-4a04-89bc-37ef6f5ad514","originalAuthorName":"熊金锋"},{"authorName":"彭湃","id":"2134f9ad-05bf-484d-b556-e0ff4504e893","originalAuthorName":"彭湃"},{"authorName":"汪朝阳","id":"7cb5dbfd-705f-44fd-9607-c302ea682645","originalAuthorName":"汪朝阳"}],"doi":"","fpage":"173","id":"5630f401-9759-408c-96f0-a469a1df80d9","issue":"5","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":"ae0faf17-548f-4124-b88f-dfdc20fd0456","keyword":"生物基小分子","originalKeyword":"生物基小分子"},{"id":"a1156f22-612c-46c9-83e9-7a51a1969bd8","keyword":"联苯","originalKeyword":"联苯"},{"id":"e267aa5e-d970-4d6d-8a6d-d534b2716521","keyword":"液晶材料","originalKeyword":"液晶材料"},{"id":"cef8ffdd-4f37-43b8-8ab3-4e57f605f675","keyword":"合成","originalKeyword":"合成"}],"language":"zh","publisherId":"gfzclkxygc201305043","title":"生物基小分子在联苯类液晶材料合成中的应用进展","volume":"29","year":"2013"},{"abstractinfo":"列举了一批近年来得到开发应用的TFT LCD显示用液晶材料,并分析了其发展趋势.TFT LCD要求液晶材料具备高电压保持率、低粘度、低双折射率等特性,而传统的液晶材料无法满足上述要求.含氟液晶、环己烷类液晶、乙烷类液晶因其极性较低,分子粘度低,电阻率高,电压保持率高,在TFT LCD中得到广泛应用.初步阐明了其分子结构与物理性能之间的关系,为新型液晶分子设计及配方设计提供了线索.","authors":[{"authorName":"李建","id":"7154be12-95f2-4616-8f4a-8d90b56e4fa3","originalAuthorName":"李建"},{"authorName":"安忠维","id":"6f0f2528-5a62-41b3-8baf-77f27361d0fe","originalAuthorName":"安忠维"},{"authorName":"杨毅","id":"282cbab0-de19-44d0-b416-00d00c2973cf","originalAuthorName":"杨毅"}],"doi":"10.3969/j.issn.1007-2780.2002.02.005","fpage":"104","id":"cc7457f9-5f84-4db4-92a3-4602b3847c7e","issue":"2","journal":{"abbrevTitle":"YJYXS","coverImgSrc":"journal/img/cover/YJYXS.jpg","id":"72","issnPpub":"1007-2780","publisherId":"YJYXS","title":"液晶与显示 "},"keywords":[{"id":"a4d3a632-f4c0-4251-8da5-86f16094efdd","keyword":"液晶材料","originalKeyword":"液晶材料"},{"id":"deaa1b0b-cc5e-4640-905a-461f16f31cc8","keyword":"显示","originalKeyword":"显示"},{"id":"282922f0-8675-4c1b-9bec-daf9c0b1ce3d","keyword":"TFT","originalKeyword":"TFT"}],"language":"zh","publisherId":"yjyxs200202005","title":"TFT LCD用液晶显示材料进展","volume":"17","year":"2002"},{"abstractinfo":"液晶显示(LCD)的响应速度与液晶材料黏度成反比关系.到目前为止,液晶低温黏度及其低温响应速度对温度依赖性大的问题一直没有解决,成为液晶显示技术与应用发展的瓶颈.文章利用二氟亚甲氧基烷基苯两环液晶化合物作为液晶组分和溶剂,探讨液晶化合物和液晶混合物的低温黏度行为及其对温度的依赖性.实验结果表明:二氟亚甲氧基烷基苯两环液晶化合物不仅能有效降低液晶的低温黏度,减小液晶低温黏度对温度的依赖性,而且可作为液晶溶剂和液晶组分配置液晶组合物,有效地降低液晶材料的低温黏度和减小低温黏度对温度的依赖性.","authors":[{"authorName":"刘运","id":"703fa373-e172-44cf-bead-04cc6f71a0cd","originalAuthorName":"刘运"},{"authorName":"张智勇","id":"7fb71574-050c-40ca-9fff-b0e62c1707ef","originalAuthorName":"张智勇"},{"authorName":"任占冬","id":"f14fb38e-19be-40ce-b9b2-86cca3c5aea9","originalAuthorName":"任占冬"},{"authorName":"戴志群","id":"2fdafe85-c439-4c3f-9cc2-dcee14f6327c","originalAuthorName":"戴志群"},{"authorName":"未本美","id":"df6ed2f2-478d-4e41-8d84-25263bf826e9","originalAuthorName":"未本美"},{"authorName":"宣丽","id":"81cdc5b1-dd97-4d08-963d-fa6edcb02b03","originalAuthorName":"宣丽"}],"doi":"10.3969/j.issn.1007-2780.2010.04.005","fpage":"490","id":"b07b3d3d-e2f0-4d08-88ce-1b4f5c375db2","issue":"4","journal":{"abbrevTitle":"YJYXS","coverImgSrc":"journal/img/cover/YJYXS.jpg","id":"72","issnPpub":"1007-2780","publisherId":"YJYXS","title":"液晶与显示 "},"keywords":[{"id":"f717c750-88b2-4e3d-8f3b-bc07acf7211b","keyword":"二氟亚甲氧基烷基苯","originalKeyword":"二氟亚甲氧基烷基苯"},{"id":"e3e5101a-d706-4ac6-85f2-9ad701491ed9","keyword":"液晶材料","originalKeyword":"液晶材料"},{"id":"8bb8498a-1435-4c86-b7c4-ab6ad5b33ce9","keyword":"低温黏度","originalKeyword":"低温黏度"},{"id":"69d70531-458d-4f67-8d93-2991d078717a","keyword":"温度依赖性","originalKeyword":"温度依赖性"}],"language":"zh","publisherId":"yjyxs201004005","title":"二氟亚甲氧基化合物对液晶低温黏度的影响","volume":"25","year":"2010"},{"abstractinfo":"利用外加电场法提纯液晶材料单体和混合液晶材料.研究表明,该方法对不同类型液晶材料单体均有很好提纯效果,酯类液晶的电阻率可以从1010Ω·cm提高到1012Ω·cm以上,含氰基类液晶的电阻率可以从1010Ω·cm提高到1012Ω·cm左右,结构稳定的含氟苯类液晶的电阻率可以从1011Ω·cm提高到1013Ω·cm以上.对一般混合液晶组合物而言,其电阻率的提高也很明显,从109Ω·cm提高到1012Ω·cm或从1010Ω·cm提高到1013Ω·cmm.此外,考察了外加电场强度、提纯时间和液晶材料用量对提纯效果的影响.","authors":[{"authorName":"朱玉婵","id":"d345acec-b278-4915-ad55-98b5625985bc","originalAuthorName":"朱玉婵"},{"authorName":"任占冬","id":"c4fd08e5-651e-4cb7-a93d-f16c471f306f","originalAuthorName":"任占冬"},{"authorName":"张智勇","id":"0f74af90-ac2d-4a72-9f32-0bf297846ac2","originalAuthorName":"张智勇"},{"authorName":"张开诚","id":"3a351dfe-4081-42f6-adda-fa5702593100","originalAuthorName":"张开诚"},{"authorName":"汪小燕","id":"ca91339d-9631-4238-bdf3-fe4f97b293e5","originalAuthorName":"汪小燕"}],"doi":"10.3969/j.issn.1007-2780.2010.04.004","fpage":"486","id":"1b48debd-7d3d-4178-85e2-36f2028425f5","issue":"4","journal":{"abbrevTitle":"YJYXS","coverImgSrc":"journal/img/cover/YJYXS.jpg","id":"72","issnPpub":"1007-2780","publisherId":"YJYXS","title":"液晶与显示 "},"keywords":[{"id":"9c82e684-0d0e-425a-ad61-add208ffffcc","keyword":"液晶材料","originalKeyword":"液晶材料"},{"id":"784d4f76-46d0-4ccb-8e2d-7fe7fc435866","keyword":"电场","originalKeyword":"电场"},{"id":"c2d1c136-c265-4576-afec-5845796ca171","keyword":"电阻率","originalKeyword":"电阻率"}],"language":"zh","publisherId":"yjyxs201004004","title":"用外加电场法提纯高电阻率液晶材料","volume":"25","year":"2010"},{"abstractinfo":"建立了一种液晶材料中微量有机膦杂质的FPD气相色谱分析测试方法,可以同时测试液晶材料中微量三苯基氧膦和三苯基膦杂质.方法重现性好,结果相对标准偏差(RSD,n=5)分别为 4.4%和5.6%,有机膦杂质的添加回收率为80%~110%.实验对于液晶材料工业化过程中膦成分的分析方法建立具有较好的指导意义.","authors":[{"authorName":"霍学兵","id":"108e112e-c829-421d-9c5d-9eea3b3e677a","originalAuthorName":"霍学兵"},{"authorName":"韩锦伟","id":"b54d69e5-f0b3-46e6-beb1-29e6f68e6454","originalAuthorName":"韩锦伟"},{"authorName":"张鹏","id":"a197cab0-c4b1-40e7-93d5-190e6a0d5034","originalAuthorName":"张鹏"},{"authorName":"耿红超","id":"9d999a79-6829-443c-a2f1-460ac9ae511c","originalAuthorName":"耿红超"},{"authorName":"葛强","id":"8bd99d43-399c-47bf-9d57-dc370636d92a","originalAuthorName":"葛强"},{"authorName":"丁兴立","id":"14d0fc47-2c13-455f-9f52-c4c47080e428","originalAuthorName":"丁兴立"}],"doi":"10.3788/YJYXS20173205.0357","fpage":"357","id":"cc80d2fa-f2f9-4fd8-afd9-41acce3edfd4","issue":"5","journal":{"abbrevTitle":"YJYXS","coverImgSrc":"journal/img/cover/YJYXS.jpg","id":"72","issnPpub":"1007-2780","publisherId":"YJYXS","title":"液晶与显示 "},"keywords":[{"id":"ebe28113-2427-45c6-938f-d5d0f7e3c51c","keyword":"液晶材料","originalKeyword":"液晶材料"},{"id":"0a091658-8a66-4ae8-b6c3-8119770e4985","keyword":"有机膦杂质","originalKeyword":"有机膦杂质"},{"id":"4257214f-ba26-4731-83e5-e8370826193d","keyword":"FPD","originalKeyword":"FPD"}],"language":"zh","publisherId":"yjyxs201705005","title":"FPD气相色谱法测定液晶材料中微量有机膦杂质","volume":"32","year":"2017"},{"abstractinfo":"介绍了目前人们对改善STN-LCD特性所取得的一些研究进展,主要包括反射式STN-LCD彩色显示,高分辨率STN-LCD用液晶材料,彩色STN-LCD用彩色滤光膜,以及STN-LCD用光学膜,如偏振片、相位差补偿膜等.","authors":[{"authorName":"凌志华","id":"d5713cde-d3c1-44bc-b707-3cf275afb823","originalAuthorName":"凌志华"}],"doi":"10.3969/j.issn.1007-2780.2002.04.001","fpage":"233","id":"4ec563f8-6ddb-4604-b1c7-67df14fcf5f9","issue":"4","journal":{"abbrevTitle":"YJYXS","coverImgSrc":"journal/img/cover/YJYXS.jpg","id":"72","issnPpub":"1007-2780","publisherId":"YJYXS","title":"液晶与显示 "},"keywords":[{"id":"7462e66f-eb37-4bc2-a775-198de7b78b90","keyword":"STN-LCD","originalKeyword":"STN-LCD"},{"id":"31bb016b-b687-4817-adc3-dedb3f93238e","keyword":"彩色滤光膜","originalKeyword":"彩色滤光膜"},{"id":"2b888124-51d9-4522-9b02-79e936d25bb5","keyword":"液晶材料","originalKeyword":"液晶材料"},{"id":"b13f098d-4ec0-42eb-a664-d8e97f99ebf2","keyword":"光学膜","originalKeyword":"光学膜"}],"language":"zh","publisherId":"yjyxs200204001","title":"STN-LCD技术的发展","volume":"17","year":"2002"},{"abstractinfo":"响应型液晶材料是指既具有液晶特性又能对外场的刺激做出相应尺寸变化的一类材料.目前,光机械效应液晶材料是响应型液晶材料研究的重点.文章对单层、聚合物以及液晶弹性体这三类主要的响应型材料体系进行了介绍和分析,探讨了它们对外界光刺激的尺寸响应及其致动机理,并对响应型材料的应用前景进行了展望.","authors":[{"authorName":"冀彬","id":"911a295b-11be-4ab2-a5fd-221a390c1942","originalAuthorName":"冀彬"},{"authorName":"马永正","id":"56105f1a-a496-4a7b-bcab-f98a516db5fe","originalAuthorName":"马永正"},{"authorName":"冯喜增","id":"5d332a5b-0816-4365-9979-8a7dde70530f","originalAuthorName":"冯喜增"}],"doi":"10.3969/j.issn.1007-2780.2008.06.012","fpage":"700","id":"40b8ab6b-188a-4d83-87d2-f667ed791ff7","issue":"6","journal":{"abbrevTitle":"YJYXS","coverImgSrc":"journal/img/cover/YJYXS.jpg","id":"72","issnPpub":"1007-2780","publisherId":"YJYXS","title":"液晶与显示 "},"keywords":[{"id":"4cb4392a-a8df-4ca1-aa88-d0fc19c5a166","keyword":"响应型液晶材料","originalKeyword":"响应型液晶材料"},{"id":"36507baa-501d-4e73-8762-3d9c9bcb9ddf","keyword":"单层","originalKeyword":"单层"},{"id":"c983c77d-5146-4e82-b9a6-2f3d3f07fdec","keyword":"聚合物","originalKeyword":"聚合物"},{"id":"e2bdd1eb-6c76-496a-99c7-6d4da522ae0b","keyword":"液晶弹性体","originalKeyword":"液晶弹性体"}],"language":"zh","publisherId":"yjyxs200806012","title":"响应型液晶材料研究","volume":"23","year":"2008"},{"abstractinfo":"液晶性高分子兼有了液晶和高分子的特性,是一类很有前途的新型材料。本文介绍液晶性高分子的基本结构、性能特点以及近年来作为结构性材料和功能性材料,在应用方面的研究和进展。","authors":[{"authorName":"徐懋","id":"4fd86703-151b-4647-ae44-f651a3ae9278","originalAuthorName":"徐懋"}],"categoryName":"|","doi":"","fpage":"143","id":"b5daf6e9-f53f-459b-b3bb-9728c72d5e92","issue":"2","journal":{"abbrevTitle":"CLYJXB","coverImgSrc":"journal/img/cover/CLYJXB.jpg","id":"16","issnPpub":"1005-3093","publisherId":"CLYJXB","title":"材料研究学报"},"keywords":[{"id":"9a88f20d-93ba-45cf-8e20-e673b44eec9f","keyword":"液晶性高分子材料","originalKeyword":"液晶性高分子材料"},{"id":"742b017d-50e9-4430-bd07-7bc425c1f7c6","keyword":"polymer materials","originalKeyword":"polymer materials"},{"id":"94ce7e71-06a3-4a10-a53f-dd2d385b19fd","keyword":"functional materials","originalKeyword":"functional materials"}],"language":"zh","publisherId":"1005-3093_1990_2_3","title":"液晶性高分子材料","volume":"4","year":"1990"},{"abstractinfo":"介绍了用电流法测定液晶电阻率的方法.用该方法测得的电阻率数据比较稳定,基本上能够准确反映液晶材料的纯度及功耗.","authors":[{"authorName":"冯凯","id":"900e945a-287a-4f7c-bdb3-94865fe30c7a","originalAuthorName":"冯凯"},{"authorName":"安忠维","id":"5ca6728d-485f-4e91-bf0d-5a5d44719267","originalAuthorName":"安忠维"}],"doi":"10.3969/j.issn.1007-2780.2000.02.007","fpage":"120","id":"6a02f715-b04f-4c8b-a776-b84541d7b808","issue":"2","journal":{"abbrevTitle":"YJYXS","coverImgSrc":"journal/img/cover/YJYXS.jpg","id":"72","issnPpub":"1007-2780","publisherId":"YJYXS","title":"液晶与显示 "},"keywords":[{"id":"5883d545-86c8-427d-ac45-fba3f078f9b2","keyword":"液晶","originalKeyword":"液晶"},{"id":"036bd00a-c519-437a-858b-2aa4182a08e3","keyword":"电阻率","originalKeyword":"电阻率"},{"id":"1b385fa2-a9fc-4b73-a802-d5ef109f9b86","keyword":"功耗","originalKeyword":"功耗"}],"language":"zh","publisherId":"yjyxs200002007","title":"液晶材料电阻率测试方法研究","volume":"15","year":"2000"}],"totalpage":5632,"totalrecord":56315}