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Gold Nanohole Array with Sub-1 nm Roughness by Annealing for Sensitivity Enhancement of Extraordinary Optical Transmission Biosensor

机译：退火后粗糙度小于1 nm的金纳米孔阵列可增强非凡光学传输生物传感器的灵敏度

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Nanofabrication technology plays an important role in the performance of surface plasmonic devices such as extraordinary optical transmission (EOT) sensor. In this work, a double liftoff process was developed to fabricate a series of nanohole arrays of a hole diameter between 150 and 235 nm and a period of 500 nm in a 100-nm-thick gold film on a silica substrate. To improve the surface quality of the gold film, thermal annealing was conducted, by which an ultra-smooth gold film with root-mean-square (RMS) roughness of sub-1 nm was achieved, accompanied with a hole diameter shrinkage. The surface sensitivity of the nanohole arrays was measured using a monolayer of 16-mercaptohexadecanoic acid (16-MHA) molecule, and the surface sensitivity was increased by 2.5 to 3 times upon annealing the extraordinary optical transmission (EOT) sensor.

机译：纳米制造技术在诸如非凡光学传输（EOT）传感器等表面等离子体设备的性能中起着重要作用。在这项工作中，开发了一种双重剥离工艺，以在二氧化硅衬底上的100 nm厚的金膜中制造一系列孔径在150至235 nm之间，周期为500 nm的纳米孔阵列。为了改善金膜的表面质量，进行了热退火处理，从而获得了具有小于1 nm的均方根（RMS）粗糙度的超光滑金膜，并且孔径缩小。使用16-巯基十六烷酸（16-MHA）分子的单层测量纳米孔阵列的表面灵敏度，并且在对非常规光学传输（EOT）传感器进行退火处理后，表面灵敏度提高了2.5到3倍。

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期刊名称 Nanoscale Research Letters
作者
Jian Zhang; Mehrdad Irannejad; Mustafa Yavuz; Bo Cui;
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作者单位

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年(卷),期 2015(10),-1
年度 2015
页码 238
总页数 8
原文格式 PDF
正文语种
中图分类生化遗传学;生化药理学;
关键词
Extraordinary optical transmission Sensitivity 16-Mercaptohexadecanoic acid Double liftoff Annealing Nanohole array;

机译：非凡的光传输;灵敏度;16-巯基十六烷酸;双重剥离;退火;纳米孔阵列;

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专利

1. Enhanced extraordinary optical transmission and refractive-index sensing sensitivity in tapered plasmonic nanohole arrays [J] . Chen Zhiquan, Li Ping, Zhang Shi, Nanotechnology . 2019,第33期

机译：增强了锥形等离子体纳米隆阵列中的非凡光学传输和折射率感应灵敏度
2. Giant-enhancement of extraordinary optical transmission through nanohole arrays blocked by plasmonic gold mushroom caps [J] . Zhang Qing, Hu Pidong, Liu Chengpu Optics Communications: A Journal Devoted to the Rapid Publication of Short Contributions in the Field of Optics and Interaction of Light with Matter . 2015,第Null期

机译：通过等离子金蘑菇帽阻止的纳米孔阵列极大地增强了非凡的光传输
3. Rayleigh-Wood anomaly approximation with FDTD simulation of plasmonic gold nanohole array for determination of optimum extraordinary optical transmission characteristics [J] . Superlattices and microstructures . 2019,第Juna期

机译：用等离激元金纳米孔阵列的FDTD模拟进行的瑞利伍德异常逼近，以确定最佳的非凡光学传输特性
4. Enhanced Transmission through Gold Nanohole Arrays Fabricated by Thermal Nanoimprint Lithography for Surface Plasmon Based Biosensors [C] . J. Martinez-Perdiguero, A. Retolaza, A. Juarros European Conference on Solid-State Transducers . 2013

机译：通过热纳米压印光刻制造的金纳米孔阵列来增强传输，用于表面等离子体的生物传感器
5. Thermal Analysis of Chemical Reactions in Microcalorimeter Using Extraordinary Optical Transmission Through Nanohole Arrays [D] . Modaresifar, Masoud. 2019

机译：使用非凡的光传输通过纳米孔阵列在微量量热仪中进行化学反应的热分析
6. Extraordinary sensitivity enhancement of Ag-Au alloy nanohole arrays for label-free detection of Escherichia Coli [O] . Charles Soon Hong Hwang, Myeong-su Ahn, Ki-Hun Jeong 2021

机译：Ag-Au合金纳米纳孔阵列的非凡敏感性增强用于无标记检测大肠杆菌
7. Gold Nanohole Array with Sub-1 nm Roughness by Annealing for Sensitivity Enhancement of Extraordinary Optical Transmission Biosensor [O] . 2015

机译：退火后粗糙度小于1 nm的金纳米孔阵列，可增强非凡光学传输生物传感器的灵敏度

Gold Nanohole Array with Sub-1 nm Roughness by Annealing for Sensitivity Enhancement of Extraordinary Optical Transmission Biosensor

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