论文信息 - Electrically Switchable Diffraction Grating Using a Hybrid Liquid Crystal and Carbon Nanotube-Based Nanophotonic Device

Electrically Switchable Diffraction Grating Using a Hybrid Liquid Crystal and Carbon Nanotube-Based Nanophotonic Device

A hybrid liquid crystal and carbon nanotube-based device which shows the capacity to perform as a switchable diffraction grating is demonstrated. A liquid crystal layer was sandwiched between two electrodes (patterned into gratings). The bottom electrode consists of a two dimensional square array of carbon nanotubes, while the top electrode comprises an ITO-based in-plane switching electrode on glass. The carbon nanotubes, due to their high aspect ratios, produce defects within the liquid crystal layer, producing a two dimensional grating. The device displays distinct voltage-dependent diffraction patterns due to the two different electrodes. The diffraction patterns are studied both computationally and experimentally, with good agreement between the results obtained. Both the diffraction pattern and efficiency from the device could be switched by varying the applied voltage across the liquid crystal layer.

[1] M. Fayer. Dynamics of Molecules in Condensed Phases: Picosecond Holographic Grating Experiments , 1982 .

[2] Timothy D. Wilkinson,et al. Electrically reconfigurable nanophotonic hybrid grating lens array , 2010 .

[3] Timothy D. Wilkinson,et al. Sparse Multiwall Carbon Nanotube Electrode Arrays for Liquid‐Crystal Photonic Devices , 2008 .

[4] K. Singer,et al. Electrically controlled surface diffraction gratings in nematic liquid crystals. , 2000, Optics letters.

[5] Timothy D Wilkinson,et al. Nanophotonic three-dimensional microscope. , 2011, Nano letters.

[6] R. Caputo,et al. Development of a new kind of switchable holographic grating made of liquid-crystal films separated by slices of polymeric material. , 2004, Optics letters.

[7] Haider Butt,et al. Optical phase modulation using a hybrid carbon nanotube-liquid-crystal nanophotonic device. , 2009, Optics letters.

[8] Philip J. Bos,et al. An electro‐optically controlled liquid crystal diffraction grating , 1995 .

[9] Timothy D. Wilkinson,et al. Adaptive lenticular lens array using a hybrid liquid crystal-carbon nanotube nanophotonic device , 2011 .

[10] Gabriella Cipparrone,et al. Highly efficient liquid crystal based diffraction grating induced by polarization holograms at the aligning surfaces , 2006 .