Roman Gregory T, Culbertson Christopher T
Department of Chemistry, Kansas State University, 111 Willard Hall, Manhattan, Kansas 66506, USA.
Langmuir. 2006 Apr 25;22(9):4445-51. doi: 10.1021/la053085w.
We report the coating of poly(dimethylsiloxane) (PDMS) microchannels using transition metal sol-gel chemistry and the subsequent characterization of the coatings. The channels were created using soft polymer lithography, and three metal alkoxide sol-gel precursors were investigated, titanium isopropoxide, zirconium isopropoxide, and vanadium triisobutoxide oxide. The metal alkoxides were diffused into the sidewalls of a PDMS channel and subsequently hydrolyzed using water vapor. This procedure resulted in the formation of durable metal oxide surfaces of titania, zirconia, or vanadia. The resulting surfaces were characterized using contact angle, X-ray photoelectron spectroscopy (XPS), Raman, transmission electron microscopy (TEM), scanning electron microscopy (SEM), atomic force microscopy (AFM), and electroosmotic mobility (EOM) measurements. All of the metal oxide-modified PDMS surfaces were significantly more hydrophilic than native PDMS. Contact angles for the coatings were 90 degrees for PDMS-ZrO2, 61 degrees for PDMS-TiO2, and 19 degrees for PDMS-vanadia. XPS showed the presence of titania, zirconia, and vanadia on the PDMS surface. XPS spectra also showed no chemical modification of the PDMS after the in situ deposition of the particles either in the Si-O, Si-C, or C-H bonds of the PDMS. The particles deposited in situ were imaged with TEM and were found to be homogeneously distributed throughout the bulk of the PDMS. EOM measurements of the inorganic coatings were stable over a period of at least 95 days. Both cathodic and anodic EOMs could be generated depending upon buffer pH used. The points of net zero charge for PDMS-TiO2, PDMS-ZrO2, and PDMS-vanadia channels were calculated using EOM versus pH measurements and were found to be 4.1 +/- 0.25, 6.1 +/- 0.2, and 7.0 +/- 0.43, respectively. In addition to modifying PDMS channels with inorganic coatings, these inorganic coatings were derivatized with various organic functionalities including oligoethylene oxide (OEO), amino, perfluoro, or mercapto groups using silane chemistry. Contact angle measurements for perfluoro, mercapto, amino, and OEO-coated surfaces yielded contact angles of 120 degrees , 76 degrees , 45 degrees , and 23 degrees , respectively. These contact angles did not change over the period of 95 days. OEO-coated channels reduced the EOM by 50% from native PDMS-TiO2 to 0.9 +/- 0.05 x 10(-4) cm2/V.s (n = 5, 5.5% RSD).
我们报道了使用过渡金属溶胶 - 凝胶化学对聚二甲基硅氧烷(PDMS)微通道进行涂层处理以及随后对涂层的表征。这些通道是通过软聚合物光刻技术制造的,并研究了三种金属醇盐溶胶 - 凝胶前驱体,异丙醇钛、异丙醇锆和三异丁氧基钒氧化物。金属醇盐扩散到PDMS通道的侧壁中,随后用水蒸气进行水解。该过程导致形成了耐用的二氧化钛、二氧化锆或氧化钒金属氧化物表面。使用接触角、X射线光电子能谱(XPS)、拉曼光谱、透射电子显微镜(TEM)、扫描电子显微镜(SEM)、原子力显微镜(AFM)和电渗迁移率(EOM)测量对所得表面进行了表征。所有金属氧化物改性的PDMS表面都比天然PDMS明显更亲水。PDMS - ZrO₂涂层的接触角为90度,PDMS - TiO₂为61度,PDMS - 氧化钒为19度。XPS显示PDMS表面存在二氧化钛、二氧化锆和氧化钒。XPS光谱还表明,在颗粒原位沉积后,PDMS的Si - O、Si - C或C - H键没有发生化学改性。原位沉积的颗粒用TEM成像,发现它们均匀分布在整个PDMS主体中。无机涂层的EOM测量在至少95天的时间内是稳定的。根据所使用的缓冲液pH值,可以产生阴极和阳极EOM。使用EOM对pH测量计算出PDMS - TiO₂、PDMS - ZrO₂和PDMS - 氧化钒通道的零电荷点分别为4.1±0.25、6.1±0.2和7.0±0.43。除了用无机涂层修饰PDMS通道外,这些无机涂层还使用硅烷化学用各种有机官能团进行衍生化,包括低聚环氧乙烷(OEO)、氨基、全氟或巯基。全氟、巯基、氨基和OEO涂层表面的接触角测量结果分别为120度、76度、45度和23度。这些接触角在95天内没有变化。OEO涂层通道将EOM从天然PDMS - TiO₂降低了50%,降至0.9±0.05×10⁻⁴ cm²/V·s(n = 5,相对标准偏差5.5%)。
