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    • 2. 发明申请
    • MASSIVELY PARALLEL LITHOGRAPHY WITH TWO-DIMENSIONAL PEN ARRAYS
    • 具有两维笔阵列的大规模并行平版印刷
    • US20080105042A1
    • 2008-05-08
    • US11690738
    • 2007-03-23
    • Chad A. MirkinKhalid SalaitaYuhuang WangJoseph S. FragalaRaymond R. Shile
    • Chad A. MirkinKhalid SalaitaYuhuang WangJoseph S. FragalaRaymond R. Shile
    • G01B5/28
    • G03F7/0002
    • Massive parallel printing of structures and nanostructures at high speed with high resolution and high quality using two dimensional arrays comprising cantilevers and tip-based transfer of material to a surface. The array is designed so only tips touch the surface. This can be accomplished by long tips and bent cantilevers and alignment. An article comprising: a two-dimensional array of a plurality of cantilevers, wherein the array comprises a plurality of base rows, each base row comprising a plurality of cantilevers, wherein each of the cantilevers comprise tips at the cantilever end away from the base, wherein the number of cantilevers is greater than 250, and wherein the tips have an apex height relative to the cantilever of at least four microns, and a support for the array. Combinatorial arrays and bioarrays can be prepared. The arrays can be manufactured by micromachining methods.
    • 以高分辨率和高质量高结构和纳米结构的大规模平行印刷,使用二维阵列,其包括悬臂和基于尖端的材料转移到表面。 该阵列设计为只有尖端触摸表面。 这可以通过长尖端和弯曲的悬臂和对准来实现。 一种制品,包括:多个悬臂的二维阵列,其中所述阵列包括多个基列,每个基列包括多个悬臂,其中每个所述悬臂包括远离所述基座的所述悬臂端处的尖端, 其中所述悬臂的数量大于250,并且其中所述尖端具有相对于至少四微米的所述悬臂的顶点高度,以及所述阵列的支撑。 可以制备组合阵列和生物阵列。 阵列可以通过微加工方法制造。
    • 3. 发明申请
    • MASSIVELY PARALLEL LITHOGRAPHY WITH TWO-DIMENSIONAL PEN ARRAYS
    • 具有两维笔阵列的大规模并行平版印刷
    • US20120297509A1
    • 2012-11-22
    • US13530006
    • 2012-06-21
    • Chad A. MirkinKhalid SalaitaYuhuang WangJoseph S. FragalaRaymond R. Shile
    • Chad A. MirkinKhalid SalaitaYuhuang WangJoseph S. FragalaRaymond R. Shile
    • G01Q70/16B82Y40/00
    • G03F7/0002
    • Massive parallel printing of structures and nanostructures at high speed with high resolution and high quality using two dimensional arrays comprising cantilevers and tip-based transfer of material to a surface. The array is designed so only tips touch the surface. This can be accomplished by long tips and bent cantilevers and alignment. An article comprising: a two-dimensional array of a plurality of cantilevers, wherein the array comprises a plurality of base rows, each base row comprising a plurality of cantilevers, wherein each of the cantilevers comprise tips at the cantilever end away from the base, wherein the number of cantilevers is greater than 250, and wherein the tips have an apex height relative to the cantilever of at least four microns, and a support for the array. Combinatorial arrays and bioarrays can be prepared. The arrays can be manufactured by micromachining methods.
    • 以高分辨率和高质量高结构和纳米结构的大规模平行印刷,使用二维阵列,其包括悬臂和基于尖端的材料转移到表面。 该阵列设计为只有尖端触摸表面。 这可以通过长尖端和弯曲的悬臂和对准来实现。 一种制品,包括:多个悬臂的二维阵列,其中所述阵列包括多个基列,每个基列包括多个悬臂,其中每个所述悬臂包括远离所述基座的所述悬臂端处的尖端, 其中所述悬臂的数量大于250,并且其中所述尖端具有相对于至少四微米的所述悬臂的顶点高度,以及所述阵列的支撑。 可以制备组合阵列和生物阵列。 阵列可以通过微加工方法制造。
    • 4. 发明授权
    • Massively parallel lithography with two-dimensional pen arrays
    • 大尺寸平行光刻与二维笔阵列
    • US08220317B2
    • 2012-07-17
    • US11690738
    • 2007-03-23
    • Chad A. MirkinKhalid SalaitaYuhuang WangJoseph S. FragalaRaymond R. Shile
    • Chad A. MirkinKhalid SalaitaYuhuang WangJoseph S. FragalaRaymond R. Shile
    • G01B5/28
    • G03F7/0002
    • Massive parallel printing of structures and nanostructures at high speed with high resolution and high quality using two dimensional arrays comprising cantilevers and tip-based transfer of material to a surface. The array is designed so only tips touch the surface. This can be accomplished by long tips and bent cantilevers and alignment. An article comprising: a two-dimensional array of a plurality of cantilevers, wherein the array comprises a plurality of base rows, each base row comprising a plurality of cantilevers, wherein each of the cantilevers comprise tips at the cantilever end away from the base, wherein the number of cantilevers is greater than 250, and wherein the tips have an apex height relative to the cantilever of at least four microns, and a support for the array. Combinatorial arrays and bioarrays can be prepared. The arrays can be manufactured by micromachining methods.
    • 以高分辨率和高质量高结构和纳米结构的大规模平行印刷,使用二维阵列,其包括悬臂和基于尖端的材料转移到表面。 该阵列设计为只有尖端触摸表面。 这可以通过长尖端和弯曲的悬臂和对准来实现。 一种制品,包括:多个悬臂的二维阵列,其中所述阵列包括多个基列,每个基列包括多个悬臂,其中每个所述悬臂包括远离所述基座的所述悬臂端处的尖端, 其中所述悬臂的数量大于250,并且其中所述尖端具有相对于至少四微米的所述悬臂的顶点高度,以及所述阵列的支撑。 可以制备组合阵列和生物阵列。 阵列可以通过微加工方法制造。
    • 8. 发明授权
    • Phase separation in patterned structures
    • 图案结构中的相分离
    • US08057857B2
    • 2011-11-15
    • US11480557
    • 2006-07-05
    • Chad A. MirkinKhalid Salaita
    • Chad A. MirkinKhalid Salaita
    • B05D5/00
    • G03F7/0002G01Q80/00Y10S438/962Y10T428/24802
    • Novel phase-separation behavior by a mixture, including binary mixture, of patterning compounds, including alkanethiols, when deposited onto a surface, including a gold surface, using micro and nano-deposition tools such as tip and stamp methods like micro-contact printing (μCP), and Dip-Pen Nanolithography (DPN). This behavior is significantly different than that observed in the bulk. This behavior was demonstrated using three examples of compounds: 16-mercaptohexadecanoic acid (MHA), 1-octadecanethiol (ODT), and CF3(CF2)11(CH2)2SH (PFT). The identity of the resulting segregated structure was confirmed by lateral force microscopy (LFM), and by selective metal-organic coordination chemistry. This phenomenon is exploited to print sub-100 nm wide alkanethiol features via conventional μCP and to form sub-15 nm features using DPN printing, which is below the ultimate resolution of both these techniques. These nano-patterned materials also can serve as templates for constructing more complex architectures.
    • 当使用微型和纳米沉积工具(诸如尖端和印模方法,如微接触印刷)沉积到包括金表面在内的表面上时,包括二醇混合物的混合物(包括二醇混合物)的新型相分离行为(包括烷基硫醇) μCP)和Dip-Pen Nanoithography(DPN)。 这种行为与大量观察到的显着不同。 使用化合物的三个实例证明了该行为:16-巯基十六烷酸(MHA),1-十八烷硫醇(ODT)和CF 3(CF 2)11(CH 2)2 SH(PFT)。 通过横向力显微镜(LFM)和选择性金属 - 有机配位化学证实了所得到的分离结构的身份。 这种现象被利用以通过常规的μCP打印亚100nm宽的链烷硫醇特征,并且使用DPN印刷形成低于15nm的特征,其低于这两种技术的最终分辨率。 这些纳米图案材料也可以用作构建更复杂结构的模板。