We report that the diffraction limit of conventional optical lithography can be overcome by exploiting the transitions of organic photochromic derivatives induced by their photoisomerization at low light intensities.1-3 This paper outlines our fabrication technique and two locking mechanisms, namely: dissolution of one photoisomer and electrochemical oxidation.
This protocol describes the fabrication and characterization of nanostructures using a novel nanolithographic technique called Patterning via Optical Saturable Transitions (POST). In this technique the chemical properties of organic photochromic molecules that undergo single-photon reactions are exploited, enabling rapid top-down nanopatterning over large areas at low light intensities, thereby, allowing for the circumvention of the far-field diffraction barrier.4 Simple, cost-effective, high throughput and resolution alternatives to nanopatterning are being explored, such as, two-photon polymerization5,6, beam pen lithography (BPL)7, scanning electron beam lithography (SEBL), and focused ion beam (FIB) patterning. However, multi-photon approaches require high light intensities, which limit their potential for high throughput and offer low image contrast. Although, electron and ion beam lithographic processes offer increased resolution, the serial nature of the process is limited to slow writing speeds, which also prevents patterning of features over large areas. Beam-pen lithography is an approach towards parallel near-field optical lithography. However, the gap between the source of the beam and the surface of the photoresist needs to be controlled extremely precisely for good pattern uniformity and this is very challenging to accomplish for large arrays of beams. Patterning via Optical Saturable Transitions (POST) is an alternative optical nanopatterning technique for patterning sub-wavelength features1-3. Since this technique uses single photons instead of electrons, it is extremely fast and does not require high light intensities1-3, opening the door to massive parallelization.
光学光刻是具有关键的重要性在纳米级的结构和设备的制造。在新的光刻技术的进步提高了能力,使新的一代新型设备8-11在这篇文章中,回顾,提出一类是取得使用新型的光开关分子深亚波长光学分辨率的光刻技术。这种方法被称为经光学-饱和转换(POST)图案。1-3
POST是独特地结合的饱和光致变色分子的光转换,具体地(1,2-双(5,5'-二甲基-2,2'- bithiophen基))的想法一新颖的纳米加工技术perfluorocyclopent -1-烯。通俗地,该化合物被称为BTE, 图1中 ,例如在受激发射损耗(STED)显微镜12使用时,与干涉光刻,这使得它的强大工具LARG深亚波长特征的e-区域并行纳米图案上的各种潜在扩展表面的至2-和3-维。
光致变色层最初是在一个均匀的状态。当该层暴露于λ1的均匀的照明,将其转换成所述第二异构态(1c)中 , 图2,然后将样品在λ2,其中样品进入所述第一异构态(转换暴露于聚焦节点1O)无处不在,除了在节点的酒店附近。通过控制曝光剂量,未转化的区域的尺寸可以被任意小。异构体中的一个的后续定影步骤可以选择性地和不可逆变换(锁定)到第三状态(黑色)以锁定模式。接着,对层被均匀地暴露于λ1,它转换以外的所有锁定区域恢复到原来的状态。该的步骤顺序可以重复与相对于光学样品的位移,导致2锁定区域的间隔比所述远场衍射极限小。因此,任意的几何形状可被图案化在一个“点阵”时尚1-3
The fabrication, experimental setup and related operational procedures of Patterning via Optical Saturable Transitions (POST) have been described. By exploiting the linear switching properties of thermally stable photochromic molecules, POST offers new perspectives on circumventing the far-field diffraction limit.1-2,4
Previously long-term storage requirement of the samples was solved by storing the samples under N2, directly after the initial evaporation.2 How…
The authors have nothing to disclose.
Thanks to Michael Knutson, Paul Hamric, Greg Scott, and Chris Landes for helpful discussions and assistance related to the custom inert atmosphere sample holder and assistance in the University of Utah student machine shop. P.C. acknowledges the NSF GRFP under Grant No. 0750758. P.C. acknowledges the University of Utah Nanotechnology Training Fellowship. R.M. acknowledges a NSF CAREER Award No. 1054899 and funding from the USTAR Initiative.
Name of Material/ Equipment | Company | Catalog Number | Comments/Description |
Isopropanol | Fisher Scientific | P/7500/15 | CAUTION: flammable, use good ventilation and avoid all ignition sources. |
Buffered Oxide Etch | |||
Methanol | Ricca Chemical | 48-293-2 | CAUTION: flammable, use good ventilation and avoid all ignition sources. |
Ethylene Glycol | Sigma-Aldrich | 324558 | CAUTION: Harmful if swallowed |
Silicon wafer | |||
Diamond Scribe | |||
Glass Beakers | |||
Tweezers | Ted Pella | 5226 | |
Reactive Ion Etching System | Oxford | Plasma Lab 80 Plus | |
Inert Atmosphere Sample Holder | Proprietary In-house Designed | ||
Polarizing beamsplitter cube | Thorlabs | PBS052 | |
HeNe Laser | Melles Griot | 25-LHP-171 | CAUTION: Wear safety glasses |
Half-wave plates | Thorlabs | WPH05M-633 | |
Thermal Evaporator | Proprietary In-house Designed | ||
TMV Super | TM Vacuum Products | TMV Super | |
Voltammograph | Bioanalytical Systems | CV-37 | |
Shortwave UV lamp 365nm | UVP Analytik Jena Company | UVGL-25 | CAUTION: Wear UV safety glasses |