Marine-based deoxyribonucleic acid (DNA) has been identified as a promising new biopolymer in the field of nonlinear optic materials for electro-optic, optical memory and optical amplifier applications. DNA has demonstrated low optical loss at the communications wavelengths, is an abundant and inexpensive green material, is temperature stable up to 200°C, and has a unique double helical structure that may aid in chromophore alignment for poled polymer applications. The DNA is purified from salmon roe and milt sacs, waste products of the Japanese fishing industry. To be compatible with photonics applications, the water soluble DNA is precipitated with a surfactant complex, cetyltrimethl-ammonium chloride (CTMA), to form a water insoluble complex, DNA-CTMA, for application as a nonlinear optical material. Several novel processes have been developed specifically for using this biopolymer in photonics applications.; In order to fabricate an all-DNA-CTMA waveguide (using DNA-CTMA for both the core and cladding layers), it is necessary to crosslink the DNA-CTMA films. Crosslinking makes the films resistant to their initial solvent; this permits spin-coating of successive DNA-CTMA layers without solvent damage. A chromophore dye is added to the core layer to allow for an electro-optic coefficient to be induced through contact poling. The dye also provides the index of refraction difference between the core and cladding layers to meet waveguiding conditions. Through contact poling, an electro-optic (EO) coefficient comparable to that in other polymers was demonstrated in crosslinked DNA-CTMA films with the chromophore dye Disperse Red 1. This EO effect allows for the creation of an all-DNA EO waveguide modulator.; DNA was successfully developed into a useful polymer material for application in an all-DNA-based EO waveguide modulator. This research demonstrated several firsts with this material: the first example of a poled DNA-based chromophore film was demonstrated, the first three-layer all-DNA-based waveguide was demonstrated, and the first three-layer all-DNA based EO modulating device was demonstrated. Additionally, many unique processing and fabrication techniques were developed specifically for integration of DNA into a photonics device. This research demonstrates that the DNA-based biopolymer can successfully be integrated into photonics applications.
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机译:海洋基脱氧核糖核酸(DNA)已被认为是用于电光,光学存储器和光放大器应用的非线性光学材料领域中一种有前途的新型生物聚合物。 DNA在通讯波长处显示出低的光损耗,是一种丰富而廉价的绿色材料,在200°C的温度下稳定,并具有独特的双螺旋结构,可有助于发色聚合物在极性聚合物应用中的排列。该DNA是从鲑鱼卵和鱼鳞囊(日本渔业的废品)中纯化得到的。为了与光子学应用兼容,水溶性DNA用表面活性剂复合物十六烷基三甲基氯化铵(CTMA)沉淀,形成水不溶性复合物DNA-CTMA,用作非线性光学材料。已经专门开发了几种新颖的方法来将该生物聚合物用于光子学应用。为了制造全DNA-CTMA波导(芯层和包层都使用DNA-CTMA),必须交联DNA-CTMA膜。交联使薄膜对初始溶剂具有抵抗力。这允许旋涂连续的DNA-CTMA层而不会损坏溶剂。将生色团染料添加到芯层中,以允许通过接触极化来感应电光系数。该染料还提供芯层和包层之间的折射率差,以满足波导条件。通过接触极化,在具有发色团染料Disperse Red 1的交联的DNA-CTMA薄膜中证明了与其他聚合物相当的电光(EO)系数。这种EO效应可以创建全DNA EO波导调制器。 ; DNA已成功开发为可用于基于全DNA的EO波导调制器的有用聚合物材料。这项研究证明了这种材料的多个开创性:展示了基于极化DNA的发色团膜的第一个实例,展示了第一个三层基于全DNA的波导,以及第一个三层基于全DNA的EO调制装置被证明。此外,还专门开发了许多独特的处理和制造技术,用于将DNA集成到光子学设备中。这项研究表明,基于DNA的生物聚合物可以成功地集成到光子学应用中。
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