公开(公告)号：US09299796B2

公开(公告)日：2016-03-29

申请号：US14619594

申请日：2015-02-11

申请人： National Central University

发明人： Pei-Wen Li ,  Wei-Ting Lai ,  Ting-Chia Hsu ,  Kuo-Ching Yang ,  Po-Hsiang Liao ,  Thomas George

IPC分类号： H01L29/423 ,  H01L29/66 ,  H01L21/02 ,  H01L21/28 ,  H01L21/3065

CPC分类号： H01L29/42376 ,  H01L21/02164 ,  H01L21/0217 ,  H01L21/02236 ,  H01L21/02255 ,  H01L21/02532 ,  H01L21/28114 ,  H01L21/3065 ,  H01L29/1037 ,  H01L29/4236 ,  H01L29/66613

摘要： A method for manufacturing a metal-oxide-semiconductor (MOS) gate stack structure in an insta-MOS field-effect-transistor (i-MOSFET) includes the following steps of: forming a silicon nitride layer over a silicon substrate; forming a nanopillar structure including a silicon-germanium alloy layer in contact with the silicon nitride layer; and performing a thermal oxidation process on the nanopillar structure to cause germanium atoms in the silicon-germanium alloy layer to penetrate the underneath silicon nitride layer to form a silicon-germanium shell layer in contact with the silicon substrate and a germanium nanosphere located over the silicon germanium shell layer, and to form a separating layer between the silicon-germanium shell layer and the germanium nanosphere by oxidizing silicon atoms from the silicon nitride layer or the silicon substrate, thereby forming a germanium/silicon dioxide/silicon-germanium i-MOS gate stack structure capable of solving interfacial issues between silicon and germanium and between germanium and the gate dielectric.

摘要翻译： 本实施例的MOS场效应晶体管（i-MOSFET）中的金属氧化物半导体（MOS）栅极叠层结构的制造方法包括以下步骤：在硅衬底上形成氮化硅层; 形成包括与所述氮化硅层接触的硅 - 锗合金层的纳米柱结构; 以及对所述纳米柱结构进行热氧化处理以使所述硅 - 锗合金层中的锗原子穿透所述氮化硅层下面以形成与所述硅衬底接触的硅 - 锗壳层和位于所述硅上的锗纳米球 锗壳层，并且通过从氮化硅层或硅衬底氧化硅原子在硅 - 锗壳层和锗纳米球之间形成分离层，从而形成锗/二氧化硅/硅 - 锗i-MOS栅极 堆叠结构能够解决硅与锗之间以及锗与栅极电介质之间的界面问题。

公开(公告)号：US20160068397A1

公开(公告)日：2016-03-10

申请号：US14846218

申请日：2015-09-04

申请人： National Central University

发明人： Ching-Yuan Su ,  Yu Min Chen

IPC分类号： C01B31/04 ,  C23C16/46 ,  C23C16/511 ,  H01J37/32 ,  C23C16/26

CPC分类号： C23C16/466 ,  C01B32/186 ,  C23C16/0227 ,  C23C16/26 ,  C23C16/4408 ,  C23C16/452 ,  C23C16/46 ,  C23C16/511 ,  C23C16/545 ,  H01J37/32192 ,  H01J37/3277 ,  H01J2237/2001

摘要： An apparatus for continuous synthesis of carbon film or inorganic material film includes an external chamber having a gas intake gate and a gas exhaust gate; a substrate transporting apparatus disposed inside the external chamber and including a rolling-out member, a plurality of rollers, a rolling-in member, and a moving path; a substrate with metal conveyed along the moving path; a temperature controller correspondingly disposed above or under the substrate transporting apparatus, wherein when the substrate with metal passes through the temperature controller, the temperature controller heats the substrate with metal; a vacuum system connected to the external chamber and inhaling a gas through the gas intake gate and exhausting the gas through the gas exhaust gate; and a gas source controller connected to the external chamber and controlling a supply of the gas, wherein the gas includes a carbon source or an inorganic material source.

摘要翻译： 用于连续合成碳膜或无机材料膜的设备包括具有进气门和排气门的外部室; 设置在所述外部室内的基板输送装置，具有卷取部件，多个辊子，滚动部件和移动路径; 具有沿着移动路径传送的金属的基板; 相应地设置在所述基板输送装置的上方或下方的温度控制器，其中，当所述金属基板通过所述温度控制器时，所述温度控制器用金属加热所述基板; 连接到外部室并通过进气门吸入气体并通过排气门排出气体的真空系统; 以及气体源控制器，其连接到所述外部室并且控制所述气体的供应，其中所述气体包括碳源或无机材料源。

公开(公告)号：US20160035085A1

公开(公告)日：2016-02-04

申请号：US14642761

申请日：2015-03-10

申请人： Huan-Cheng Chang ,  National Central University

发明人： Syu-Jyun PENG ,  Jang-Zern TSAI ,  Yu-Wei CHEN ,  Kuo-Wei WANG

IPC分类号： G06T7/00 ,  A61B5/00

CPC分类号： G06T7/0012 ,  A61B5/0042 ,  A61B5/055 ,  A61B5/4064 ,  G06T7/11 ,  G06T7/136 ,  G06T2207/10088 ,  G06T2207/30016

摘要： A method for detecting a cerebral infarct includes receiving an image of a brain of a subject from a magnetic resonance imaging scanner, wherein the image has a plurality of voxels, and each of the voxels has a voxel intensity. Then, the voxel intensities are normalized, wherein the normalized voxel intensities have a distribution peak, and the normalized voxel intensity of the distribution peak is Ipeak. A threshold is determined, which is the Ipeak+ a value. Voxel having the normalized voxel intensity larger than the threshold is selected, wherein the selected voxel is the cerebral infarct. A method for quantifying the cerebral infarct is also provided.

摘要翻译： 检测脑梗塞的方法包括从磁共振成像扫描仪接收被检者的脑部图像，其中，图像具有多个体素，并且每个体素具有体素强度。 然后，体素强度被归一化，其中归一化体素强度具有分布峰，并且分布峰的归一化体素强度为Ipeak。 确定阈值，即Ipeak + a值。 选择具有大于阈值的归一化体素强度的体素，其中所选择的体素是脑梗死。 还提供了定量脑梗塞的方法。

公开(公告)号：US09192602B2

公开(公告)日：2015-11-24

申请号：US14487449

申请日：2014-09-16

申请人： NATIONAL CENTRAL UNIVERSITY

发明人： Wei-Hsin Sun ,  Shir-Ly Huang ,  Hsu-Shan Huang

IPC分类号： A61K31/433

CPC分类号： A61K31/433

摘要： Disclosed are anthra[2,1-c][1,2,5]thiadiazole-6,11-dione compounds and pharmaceutical composition thereof. The compounds of the invention have been demonstrated as having analgesic effects and therefore may be applicable for use as a novel agent in relieving acute or chronic pain.

摘要翻译： 披露了蒽[2,1-c] [1,2,5]噻二唑-6,11-二酮化合物及其药物组合物。 本发明的化合物已被证明具有镇痛作用，因此可适用于缓解急性或慢性疼痛的新型药物。

公开(公告)号：US20150329373A1

公开(公告)日：2015-11-19

申请号：US14525452

申请日：2014-10-28

申请人： National Central University

发明人： Anthony Shiaw-Tseh Chiang ,  Sho-Hsun Wang ,  Chin-Tung Pai ,  Chien-Wei Chen

IPC分类号： C01G25/02 ,  B01J13/00 ,  C01G25/00

CPC分类号： C01G25/02 ,  B01J13/0047 ,  C01P2002/54 ,  C01P2002/72 ,  C01P2002/82 ,  C01P2002/86 ,  C01P2004/64 ,  C01P2004/80 ,  C01P2006/12 ,  C07F7/003 ,  Y10T428/2982

摘要： A zirconia nanoparticle material includes a zirconia nanoparticle and a carbonate coordinated on a surface of the zirconia nanoparticle. The carbonate is 1 to 10 parts by weight of the zirconia nanoparticle.

摘要翻译： 氧化锆纳米颗粒材料包括在氧化锆纳米颗粒的表面上配位的氧化锆纳米颗粒和碳酸盐。 碳酸盐为1〜10重量份的氧化锆纳米粒子。

公开(公告)号：US20150323507A1

公开(公告)日：2015-11-12

申请号：US14707574

申请日：2015-05-08

申请人： National Central University

发明人： Norden. E. HUANG

IPC分类号： G01N29/46

CPC分类号： G06F17/14 ,  G01N29/46

摘要： The present invention provides a method of implementing the high dimensional Holo-Hilbert spectral analysis which transforms a data from time domain to frequency domain. At the first of the steps, obtaining an amplitude intrinsic mode component and an instantaneous frequency component of the data by a mode decomposition, such as using Empirical Mode Decomposition (EMD), adaptive filtering, or optimal basis pursue, etc to show a plurality of amplitude intrinsic mode functions (amplitude IMFs) and a plurality of frequency intrinsic mode functions (frequency IMFs). Then, analyzing each of the amplitude IMFs and the frequency IMFs to obtain a plurality value in different high order components. At the last, to establish a high dimensional Holo-Hilbert spectrum by combining the high order component with the original component to show the interaction between frequency and amplitude. Consequently, the present invention not only discloses a spectrum that can represent all the possible processes: additive and multiplicative, intra- and inter-mode, stationary and nonstationary, linear and nonlinear interactions, but also makes a new index for quantifying the inter-mode degree of nonlinearity possible.

摘要翻译： 本发明提供了一种实现高维霍尔希尔伯特谱分析的方法，该方法将数据从时域转换到频域。 在第一步中，通过使用经验模式分解（EMD），自适应滤波或最优基础追踪等模式分解来获得数据的振幅固有模式分量和瞬时频率分量，以显示多个 幅度固有模式函数（幅度IMF）和多个频率固有模式函数（频率IMF）。 然后，分析振幅IMF和频率IMF中的每一个以获得不同高阶分量的多个值。 最后，通过组合高阶分量与原始分量来建立高维霍夫希尔伯特谱，以显示频率和幅度之间的相互作用。 因此，本发明不仅公开了可以表示所有可能的过程的频谱：加和乘法，帧内和模式间，静态和非平稳，线性和非线性相互作用，而且还为量化帧间模式 非线性程度可能。

公开(公告)号：US20150191491A1

公开(公告)日：2015-07-09

申请号：US14323700

申请日：2014-07-03

申请人： National Central University

发明人： Fa-Kuen SHIEH ,  Shao-Chun WANG

IPC分类号： C07F3/06

CPC分类号： C07F3/003 ,  B01D53/02 ,  B01D2253/204 ,  B01D2257/504 ,  B01J20/226 ,  B01J20/28004 ,  B01J20/3085 ,  Y02P20/152 ,  Y10T428/2982

摘要： The present invention provides a preparation method of Zeolitic Imidazolate Framework-90 (ZIF-90) in water-based system, which uses pure water as a solvent, and the reaction is carried out at room temperature. In addition, the present invention provides a preparation method of ZIF-90, and the particle size and the uniformity of the obtained ZIF-90 are controllable by addition of adjuvant or additive (Polyvinylpyrrolidone).

摘要翻译： 本发明提供了使用纯水作为溶剂的水性体系中的沸石咪唑酸酯框架-90（ZIF-90）的制备方法，反应在室温下进行。 此外，本发明提供了ZIF-90的制备方法，通过添加佐剂或添加剂（聚乙烯吡咯烷酮）可以控制得到的ZIF-90的粒径和均匀性。

公开(公告)号：US09078331B2

公开(公告)日：2015-07-07

申请号：US13903190

申请日：2013-05-28

申请人： NATIONAL CENTRAL UNIVERSITY

发明人： Ching-Cherng Sun ,  Ching-Yi Chen ,  Hsin-Mei Wu ,  Cheng-Chien Chen

IPC分类号： H05B33/14 ,  H05B33/10 ,  H01L33/50 ,  C09K11/77

CPC分类号： H05B33/14 ,  C09K11/7774 ,  H01L33/502 ,  H01L2933/0041 ,  H05B33/10 ,  Y02B20/181

摘要： A light emitting device is provided to produce white light with a stable correlated color temperature and stable color coordinates. The light emitting device includes a blue LED chip and a yellow phosphor. The blue LED chip has a peak wavelength X slightly smaller than the peak wavelength Y of the phosphor such that when the light emitting device is subjected to a predetermined operating current, the phosphor decays due to thermal effect, and the LED chip has its emission spectrum red-shifted to substantially match with the excitation spectrum of the phosphor. At this time, the excitation ability of the LED chip is increased and causes an increase of yellow power output from the phosphor that substantially compensates a decrease of yellow light output caused by the phosphor.

摘要翻译： 提供发光器件以产生具有稳定的相关色温和稳定色坐标的白光。 发光器件包括蓝色LED芯片和黄色荧光体。 蓝色LED芯片的峰值波长X比荧光体的峰值波长Y稍小，因此当发光元件经受规定的工作电流时，荧光体由于热效应而衰变，LED芯片的发光光谱 红移以与荧光体的激发光谱基本匹配。 此时，LED芯片的激发能力增加，并且导致从荧光体输出的黄色功率的增加，其基本上补偿由磷光体引起的黄光输出的减少。

公开(公告)号：US20150060033A1

公开(公告)日：2015-03-05

申请号：US14046489

申请日：2013-10-04

申请人： NATIONAL CENTRAL UNIVERSITY

发明人： Te-Yuan CHUNG ,  Tso-Hung Chang

IPC分类号： F28F1/00

CPC分类号： H01L23/473 ,  H01L2924/0002 ,  H01L2924/00

摘要： The present invention discloses a cooling system with a passive heat dissipation structure, the cooling system includes plural heat conducting pipes, and a shielding tube included to surround the heat conducting pipes. The heat generated from a heat source placed below the cooling system heats the surrounding fluid (air) and turns it into heated fluid. The heated fluid is lower in density and is dissipated away through convection by the heat conducting pipes, leaves its original space to cooler fluid (at room temperature). The mixing of the heated fluid with the cooler fluid can be prevented by the heat conducting pipes, and the heat convection of the heat source by the cooler fluid is increased. With the implementation of the present invention, the benefits of easy implementing, easy to use, requiring no extra energy and saving costs are achieved, and the heat of the heat source is promptly dissipated away.

摘要翻译： 本发明公开了一种具有被动散热结构的冷却系统，该冷却系统包括多个导热管和包围导热管的屏蔽管。 从放置在冷却系统下方的热源产生的热量加热周围的流体（空气）并将其转化为加热的流体。 加热的流体密度较低，并且通过导热管的对流而消散掉，将其原始空间留给较冷的流体（室温）。 加热流体与较冷流体的混合可以通过导热管来防止，并且由较冷的流体引起的热源的热对流增加。 通过实施本发明，实现了易于实施，易于使用，不需要额外的能量和节省成本的优点，并且热源的热量迅速消散。

公开(公告)号：US20150060017A1

公开(公告)日：2015-03-05

申请号：US14050060

申请日：2013-10-09

申请人： National Central University

发明人： Te-Yuan CHUNG ,  Hao-Hsuan HUANG

IPC分类号： H05K7/20 ,  G06F1/20

CPC分类号： G06F1/20 ,  F28D20/02 ,  F28D2021/0029 ,  F28F1/40 ,  F28F1/42 ,  Y02E60/145

摘要： A cooling apparatus using solid-liquid phase change material (solid-liquid PCM) is disclosed. The cooling apparatus includes a pipeline, a housing enclosing the pipeline, and the solid-liquid PCM filling in an interior of the pipeline and a space between the pipeline and the housing. The solid-liquid PCM can contact a heat source and absorb the heat generated by the heat source, so as to transform from solid state to liquid state. The solid-liquid PCM in the liquid state can circulate inside the pipeline and the space between the pipeline and the housing. Thus, the heat is dissipated by the means of thermal convection. Meanwhile, the heat also can be dissipated through the housing. Therefore, the heat dissipation can be achieved by thermal conduction and heat convection simultaneously.

摘要翻译： 公开了一种使用固 - 液相变材料（固液PCM）的冷却装置。 冷却装置包括管道，封闭管道的壳体，以及固体液体PCM填充在管道的内部和管道与壳体之间的空间。 固液PCM可以接触热源并吸收由热源产生的热量，以便从固态转变为液态。 处于液态的固体液体PCM可在管道内部和管道与壳体之间的空间内循环。 因此，热量通过热对流消散。 同时，也可以通过外壳散热。 因此，散热可以通过热传导和热对流同时实现。