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    • 2. 发明申请
    • Method for preparation of anisotropic materials
    • 各向异性材料的制备方法
    • US20060016516A1
    • 2006-01-26
    • US10896182
    • 2004-07-21
    • Patricia BeckSean Zhang
    • Patricia BeckSean Zhang
    • C21D1/04H01L29/08
    • G11B7/244C08G61/02C08G61/10C08G61/123C08G73/18C08G73/22C08J3/24G02F1/15G11B7/245G11B7/246G11B7/249G11B7/25Y10T428/1005Y10T428/1009Y10T428/1041Y10T428/1082Y10T428/1157Y10T428/2809
    • Various embodiments of the present invention are directed to methods for manufacturing complex, anisotropic materials with desirable properties for information storage, processing, and display. Certain of these methods involve employing a magnetic field during manufacture to induce desired orientations of precursors, subunits, and/or molecular subassemblies. The applied magnetic field steers the precursors, subunits, and/or molecular subassemblies into desirable orientations while the precursors, subunits, and/or molecular subassemblies are assembled or self-assemble into a complex, anisotropic material. One embodiment of the present invention is a class of new, complex, well-ordered, network-like materials that include a ferromagnetic-material-based framework in which organic and/or organometallic compounds are organized. The ferromagnetic-molecule-based framework provides a scaffold for assembling the stable, precisely separated layers of organic and/or organometallic compounds and maintaining the layers of organic and/or organometallic compounds in well-ordered, anisotropic arrangements. Additional embodiments of the present invention are directed to methods for manufacturing the new ferromagnetic-molecule-based, network-like materials.
    • 本发明的各种实施方案涉及用于制造具有用于信息存储,处理和显示的所需特性的复杂的各向异性材料的方法。 这些方法中的某些涉及在制造过程中采用磁场来诱导前体,亚基和/或分子子组件的所需取向。 施加的磁场将前体,亚基和/或分子子组件转向所需的取向,同时将前体,亚基和/或分子子组件组装或自组装成复杂的各向异性材料。 本发明的一个实施方案是一类新的,复杂的,有序的网状材料,其包括其中组织有机和/或有机金属化合物的基于铁磁材料的框架。 基于铁磁分子的框架提供了用于组装稳定且精确分离的有机和/或有机金属化合物层的支架,并且将有机和/或有机金属化合物的层维持在有秩序的各向异性布置中。 本发明的另外的实施方案涉及用于制造新的基于铁磁分子的网络状材料的方法。
    • 3. 发明申请
    • Microneedles and Method Of Fabricating Thereof
    • 微针及其制造方法
    • US20060226016A1
    • 2006-10-12
    • US11420764
    • 2006-05-28
    • Ramesh S/O Govinda RajuMing-Li TanYusua AgabusPatricia Beck
    • Ramesh S/O Govinda RajuMing-Li TanYusua AgabusPatricia Beck
    • C25D5/02
    • C25D1/02B82Y30/00C25D1/10
    • Low cost methods for fabricating microneedles are disclosed. According to one embodiment, the fabrication method includes the steps of: providing a substrate; forming a metal-containing seed layer on the top surface of the substrate; forming a nonconductive pattern on a portion of the seed layer; plating a first metal on the seed layer and over the edge of the nonconductive pattern to create a micromold with an opening that exposes a portion of the nonconductive pattern; plating a second metal onto the micromold to form a microneedle in the opening; separating the micromold with the microneedle formed therein from the seed layer and the nonconductive pattern; and selectively etching the micromold so as to release the microneedle. In another embodiment, the micromold is not required. The method according to this embodiment includes: forming a recess with an apex in a substrate; forming a seed layer on the substrate; forming a nonconductive pattern on a portion of the seed layer that is on a sidewall surface of the recess; plating an electrically conductive material over the seed layer and over the edge of the nonconductive pattern to form a plated layer with an opening that exposes a portion of the nonconductive pattern; and separating the plated layer from the seed layer and the nonconductive pattern to release a hollow microneedle with an offset opening.
    • 公开了制造微针的低成本方法。 根据一个实施例,制造方法包括以下步骤:提供衬底; 在所述基板的顶表面上形成含金属的种子层; 在种子层的一部分上形成非导电图案; 在种子层上和非导电图案的边缘上镀覆第一金属以产生具有露出非导电图案的一部分的开口的微型金属; 将第二金属镀在微型玻璃上以在开口中形成微针; 用形成在其中的微针从种子层和非导电图案分离微型金属; 并选择性地蚀刻微型金属以便释放微针。 在另一个实施例中,不需要微型金属。 根据该实施例的方法包括:在基板中形成具有顶点的凹部; 在所述基板上形成种子层; 在所述种子层的位于所述凹部的侧壁表面上的部分上形成非导电图案; 在种子层上和非导电图案的边缘上镀覆导电材料以形成具有暴露非导电图案的一部分的开口的镀层; 并且将电镀层与种子层和非导电图案分离以释放具有偏移开口的中空微针。
    • 6. 发明申请
    • Custom electrodes for molecular memory and logic devices
    • 用于分子存储器和逻辑器件的定制电极
    • US20050026427A1
    • 2005-02-03
    • US10930062
    • 2004-08-30
    • Patricia BeckDouglas OhlbergDuncan StewartZhiyong Li
    • Patricia BeckDouglas OhlbergDuncan StewartZhiyong Li
    • H01L21/28G11C13/02H01L21/285H01L27/28H01L29/06H01L21/00
    • H01L27/28G11C13/02H01L2924/0002H01L2924/00
    • A method is provided for fabricating molecular electronic devices comprising at least a bottom electrode and a molecular switch film on the bottom electrode. The method includes forming the bottom electrode by a process including: cleaning portions of the substrate where the bottom electrode is to be deposited; pre-sputtering the portions; depositing a conductive layer on at least the portions; and cleaning the top surface of the conductive layer. Advantageously, the conductive electrode properties include: low or controlled oxide formation (or possibly passivated), high melting point, high bulk modulus, and low diffusion. Smooth deposited film surfaces are compatible with Langmuir-Blodgett molecular film deposition. Tailored surfaces are further useful for SAM deposition. The metallic nature gives high conductivity connection to molecules. Barrier layers may be added to the device stack, i.e., Al2O3 over the conductive layer.
    • 提供了一种用于制造分子电子器件的方法,该分子电子器件至少包括底部电极和底部电极上的分子开关膜。 该方法包括通过以下工艺形成底部电极,该方法包括:清洗要沉积底部电极的衬底的部分; 预溅射部分; 在至少部分上沉积导电层; 并清洁导电层的顶表面。 有利地,导电电极的性质包括:低或受控的氧化物形成(或可能钝化),高熔点,高体积弹性模量和低扩散。 光滑的沉积膜表面与Langmuir-Blodgett分子膜沉积相容。 定制的表面对于SAM沉积是更有用的。 金属性质使分子具有高导电性。 阻挡层可以被添加到器件堆叠,即在导电层上的Al 2 O 3。
    • 9. 发明申请
    • Apparatus and method for transverse characterization of materials
    • 材料横向表征的装置和方法
    • US20050242339A1
    • 2005-11-03
    • US10835943
    • 2004-04-29
    • Patricia Beck
    • Patricia Beck
    • G01N27/07G01Q60/00H01L21/4763H01L47/00
    • G01N27/07B82Y30/00Y10S977/836
    • An apparatus for transverse characterization of materials includes a lower pattern of contacts, separated by spacings, a material, and an upper pattern of a multiplicity of contacts, separated by spacings differing from the spacings of the lower pattern. The transverse characterization method includes receiving lower pattern of a multiplicity of contacts, separated by spacings along a surface, with a material above the surface, successively placing an upper contact near the upper surface of the material in an upper pattern of locations separated by spacings differing from the spacings of the lower pattern, measuring the characteristics between the upper contact and one or more contacts of the lower pattern and evaluating the measured characteristics to previous measurements, wherein the evaluation provides the transverse characterization.
    • 用于材料的横向表征的装置包括通过间隔分开的下部接触图案,材料和由与下部图案的间隔不同的间隔分开的多个触点的上部图案。 横向表征方法包括接收由表面间隔分开的多个接触部分的下部图案,其中在表面上方的材料连续地将上接触部分靠近材料的上表面放置在由不同间隔分开的位置的上部图案中 从下部图案的间隔,测量上部接触和下部图案的一个或多个触点之间的特性并将测量的特性评估为先前的测量,其中评估提供横向表征。
    • 10. 发明申请
    • Batch fabricated servo write head
    • 批量制造伺服写头
    • US20050068668A1
    • 2005-03-31
    • US10696824
    • 2003-10-30
    • Patricia BeckPaul PoormanGeorge CliffordRichard Henze
    • Patricia BeckPaul PoormanGeorge CliffordRichard Henze
    • G11B5/127G11B5/187G11B5/48G11B5/584G11B15/62
    • G11B5/187G11B5/1871G11B5/4893G11B5/584G11B15/62Y10T29/49032Y10T29/49043Y10T29/49048Y10T29/49055Y10T29/4906Y10T29/49789Y10T29/49798
    • A batch fabrication technique is described that increases the manufacturing efficiency of servo write heads and also improves servo pattern definition for fine features, while reducing tape and head wear. Multiple heads are fabricated as a batch from one or more ferrite wafers. A nominally flat, large wafer surface and a contour suitable for uniform photoresist application and planar photolithography permit fine servo pattern definition. A rounded leading edge on the head creates an air bearing to reduce wear of the tape and of the head. Moreover, any head wear occurs at the leading edge rather than in the region of the head where the servo pattern is formed. The servo write head may have a substantially planar head surface. A leading edge is disposed adjacent to the head surface such that the tape contacts the leading edge before passing over the head surface. The leading edge is rounded to form an air bearing between the head surface and the tape. A rounded trailing edge may be disposed adjacent to the head surface such that the tape passes over the trailing edge after passing over the head surface. The head may be formed from an upper ferrite wafer having a non-magnetic spacer. Non-magnetic material is photolithographically defined to produce gaps above the spacer. The non-magnetic material may be photoresist, semiconductor materials, glass, metal or the like. The material may even be removed later to leave air gaps. The non-magnetic material forms a region where the field loops out to intersect the passing tape, thereby transferring a magnetic pattern to tape. Additionally, a lower ferrite wafer may be mated to the upper ferrite wafer to complete a magnetic circuit around the gaps. The upper or lower ferrite wafer may have a channel through which an inductive winding passes. Multiple heads may be formed through batch processing of the upper and lower ferrite wafers.
    • 描述了一种批量制造技术,其提高了伺服写入头的制造效率,并且还改善了精细特征的伺服模式定义,同时减少了磁带和磁头磨损。 多个头部从一个或多个铁氧体晶片制成批次。 标称平坦,大的晶片表面和适用于均匀光刻胶应用和平面光刻的轮廓允许精细的伺服模式定义。 头部圆角的前缘形成一个空气轴承,以减少磁带和磁头的磨损。 此外,任何头部磨损发生在前缘而不是在形成伺服图案的头部的区域中。 伺服写入头可以具有基本平坦的头表面。 前缘邻近头表面设置,使得带在通过头表面之前接触前缘。 前缘是圆形的,以在头表面和带之间形成空气轴承。 圆形的后缘可以邻近头部表面设置,使得带在经过头表面之后越过后缘。 头部可以由具有非磁性间隔物的上部铁氧体晶片形成。 非磁性材料被光刻定义以在间隔物上方产生间隙。 非磁性材料可以是光致抗蚀剂,半导体材料,玻璃,金属等。 材料甚至可以稍后移除以留下空隙。 非磁性材料形成区域,其中磁场循环出来以与通过的磁带相交,从而将磁性图案转印到磁带上。 此外,下部铁氧体晶片可以与上部铁氧体晶片配合,以在该间隙周围形成磁路。 上或下铁素体晶片可以具有感应绕组通过的通道。 可以通过上下铁素体晶片的批量处理形成多个头。