PROCESS FOR PREPARING SUBSTRATES WITH POROUS SURFACE
    1.
    发明申请
    PROCESS FOR PREPARING SUBSTRATES WITH POROUS SURFACE 审中-公开
    用多孔表面制备基材的方法

    公开(公告)号:US20090297853A1

    公开(公告)日:2009-12-03

    申请号:US12489943

    申请日:2009-06-23

    IPC分类号: B05D3/10 B01D15/08 B32B1/00

    摘要: A process for preparing nanoparticle coated surfaces including the steps of electrostatically coating surfaces with polyelectrolyte by exposing the surface to a solution or suspension of polyelectrolyte, removing excess non-bound polyelectrolyte, then further coating the particles with a multi-layer of charged nanoparticles by exposing the polyelectrolyte-coated surface to a fluid dispersion including the charged nanoparticles. The process steps can optionally be repeated thereby adding further layers of polyelectrolyte followed by nanoparticles as many times as desired to produce a second and subsequent layers. The polyelectrolyte has an opposite surface charge to the charged nanoparticles and a molecular weight at the ionic strength of the fluid that is effective so that the first, second, and subsequent layers independently comprise a multiplicity of nanoparticle layers that are thicker than monolayers.

    摘要翻译: 一种制备纳米颗粒涂层表面的方法,包括以下步骤:通过将表面暴露于聚电解质的溶液或悬浮液,去除多余的非结合聚电解质,然后用​​多层带电荷的纳米颗粒将所述颗粒暴露 聚电解质涂覆的表面到包含带电纳米粒子的流体分散体。 可以可选地重复该工艺步骤,从而根据需要添加多层聚电解质,然后再加入纳米颗粒以产生第二层和后续层。 聚电解质与带电荷的纳米颗粒具有相反的表面电荷,并且具有有效的离子强度的分子量,使得第一,第二和后续层独立地包含比单层厚的多个纳米颗粒层。

    Process for preparing substrates with porous surface
    3.
    发明申请
    Process for preparing substrates with porous surface 审中-公开
    用多孔表面制备底物的方法

    公开(公告)号:US20080277346A1

    公开(公告)日:2008-11-13

    申请号:US11705620

    申请日:2007-02-13

    IPC分类号: B01D15/08 B05D1/36 B32B15/02

    摘要: A process for preparing nanoparticle coated surfaces including the steps of electrostatically coating surfaces with polyelectrolyte by exposing the surface to a solution or suspension of polyelectrolyte, removing excess non-bound polyelectrolyte, then further coating the particles with a multi-layer of charged nanoparticles by exposing the polyelectrolyte-coated surface to a fluid dispersion including the charged nanoparticles. The process steps can optionally be repeated thereby adding further layers of polyelectrolyte followed by nanoparticles as many times as desired to produce a second and subsequent layers. The polyelectrolyte has an opposite surface charge to the charged nanoparticles and a molecular weight at the ionic strength of the fluid that is effective so that the first, second, and subsequent layers independently comprise a multiplicity of nanoparticle layers that are thicker than monolayers.

    摘要翻译: 一种制备纳米颗粒涂层表面的方法,包括以下步骤:通过将表面暴露于聚电解质的溶液或悬浮液,去除多余的未结合的聚电解质,然后通过暴露于多层带电荷的纳米颗粒 聚电解质涂覆的表面到包含带电纳米粒子的流体分散体。 可以可选地重复该工艺步骤,从而根据需要添加多层聚电解质,然后再加入纳米颗粒以产生第二层和后续层。 聚电解质与带电荷的纳米颗粒具有相反的表面电荷,并且具有有效的离子强度的分子量,使得第一,第二和后续层独立地包含比单层厚的多个纳米颗粒层。

    Porous microparticles with solid cores
    4.
    发明申请
    Porous microparticles with solid cores 审中-公开
    具有固体核的多孔微粒

    公开(公告)号:US20070189944A1

    公开(公告)日:2007-08-16

    申请号:US11705629

    申请日:2007-02-13

    IPC分类号: C01B33/26 G01N30/02 B01D15/08

    摘要: The present invention relates to microparticles, particularly spherical silica microparticles, which may be useful in liquid chromatography. Specifically, the microparticles include a solid core and an outer porous shell surrounding and irreversibly joined to the core. The shell is composed of a plurality of colloidal nanoparticles, which are applied using an electrostatic multi-multilayering method. The resulting microparticles have a small particle diameter, such as about 1 μm to 3.5 μm, a high particle density, such as about 1.2 g/cc to 1.9 g/cc, and a high surface area, such as about 50 m2/g to 165 m2/g. These microparticles can be used to form packed beds and liquid chromatographic columns, which are more efficient and rugged than conventional liquid chromatographic columns.

    摘要翻译: 本发明涉及可用于液相色谱的微粒,特别是球形二氧化硅微粒。 具体地说,微粒包括实心芯和围绕并不可逆地连接到芯的外多孔壳。 壳体由多个胶体纳米颗粒组成,其使用静电多层压法施加。 所得到的微粒具有例如约1μm〜3.5μm的小粒径,高的粒子密度例如约1.2g / cc〜1.9g / cc,高的表面积例如约50μm以下, 2 / g至165m 2 / g。 这些微粒可用于形成填充床和液相色谱柱,其比常规液相色谱柱更有效和坚固。