Ultrafast laser induced nanostructured ITO for liquid crystal alignment and higher transparency electrodes

Solodar, Asi; Cerkauskaite, Ausra; Drevinskas, Rokas; Kazansky, Peter G.; Abdulhalim, Ibrahim

doi:10.1063/1.5040692

Cited by 26 publications

(27 citation statements)

References 38 publications

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“…The research was based on the anchoring energy and to see its influence as a boundary condition on the polymer–LC interface and its influence on the diffractive properties of magnetically tunable optical diffraction gratings. In experiments top and bottom walls are composed of an ITO-coated glass plates and typical anchoring strength of LCs at ITO surface is ~1 μJ/m 2 [ 61 , 62 ]. However, in our simulations we considered that surface anchoring strength at top and bottom layers is zero.…”

Section: Discussionmentioning

confidence: 99%

Magnetically Tunable Liquid Crystal-Based Optical Diffraction Gratings

2020

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We present a theoretical analysis of optical diffractive properties of magnetically tunable optical transmission gratings composed of periodically assembled layers of a polymer and a ferromagnetic liquid crystal (LC). The orientational structure of the LC layers as a function of an applied magnetic field is calculated by minimization of the Landau-de Gennes free energy for ferromagnetic LCs, which is performed numerically and also analytically by using the one-constant approximation and the approximations of the high and the low magnetic fields. Optical diffractive properties of the associated diffraction structure are calculated numerically in the framework of rigorous coupled-wave analysis (RCWA). The presented methodology provides a basis for designing new types of diffractive optical element based on ferromagnetic LCs and simulating their operation governed by the in-plane magnetic field.

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Section: Discussionmentioning

confidence: 99%

Magnetically Tunable Liquid Crystal-Based Optical Diffraction Gratings

2020

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“…[ 16 ] The same structures were subsequently used for liquid crystal alignment layers. [ 18 ] More recently, a hybrid approach combining direct laser interference patterning (DLIP) and LIPSS has been used to produce anisotropic conductance structures. [ 17 ] The LIPSS period found (Λ ≈ 75 nm ≈ λ/4) was over‐imposed to the DLIP periodicity leading to a conductance anisotropy of ≈ 50 × 10 3 , as measured by two‐point probing measurements.…”

Section: Introductionmentioning

confidence: 99%

“…[13] This approach, when multi-pulse processing is used, has the additional consequence of generating laser-induced periodic surface structures (LIPSS), [14] an effect that has recently received attention due to its high potential for producing optical [15,16] or electrical anisotropies. [17,18] However, due to its long skin penetration depth in the vis-NIR, it is difficult to fabricate macroscopically continuous LIPSS [19,20] in ITO, a requirement for many practical applications. In what follows we provide a non-exhaustive summary of relevant results regarding LIPSS fabrication in ITO.…”

Section: Introductionmentioning

confidence: 99%

Anisotropic Resistivity Surfaces Produced in ITO Films by Laser‐Induced Nanoscale Self‐organization

López‐Santos

Puerto

Siegel

et al. 2020

Advanced Optical Materials

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emitting diodes, flat panel displays, etc.) and energy harvesting (photovoltaics, low emissivity coatings, etc.). [1] They are produced by creating electron degeneracy in a wide bandgap oxide either introducing non-stoichiometry (solid solutions) and/ or appropriate dopants, like Sb or F. [2] This is usually achieved in mixtures of different Group III oxides with metal oxides where the metal can be a part of the semiconductor oxide or act as dopant. This leads to different families of TCOs including AZO (aluminum zinc oxide), IZO (indium zinc oxide), ITO (indium tin oxide), GZO (gallium zinc oxide), and so on. Among them ITO (typically ≈90% wt% In 2 O 3 + 10 wt% SnO 2) plays a key role, especially to produce transparent conductive electrodes (TCEs) in flat-panel displays. Regarding the structuring of ITO films, although wet chemical etching is suitable for producing micron-width electrodes, the need for rapid, and mask-less patterning of large areas led to investigation of the use of laser structuring already in the late 90s. [3] A similarly important application of lasers for processing TCOs is their use for sintering spin-coated films formed by nanoparticles, especially on flexible substrates. [4-6] However, the peculiarities of its absorption spectrum and the regular use of transparent substrates impose limitations in Highly anisotropic resistivity surfaces are produced in indium tin oxide (ITO) films by nanoscale self-organization upon irradiation with a fs-laser beam operating at 1030 nm. Anisotropy is caused by the formation of laser-induced periodic surface structures (LIPSS) extended over cm-sized regions. Two types of optimized structures are observed. At high fluence, nearly complete ablation at the valleys of the LIPSS and strong ablation at their ridges lead to an insulating structure in the direction transverse to the LIPSS and conductive in the longitudinal one. A strong diminution of In content in the remaining material is then observed, leading to a longitudinal resistivity ρ L ≈ 1.0 Ω•cm. At a lower fluence, the material at the LIPSS ridges remains essentially unmodified while partial ablation is observed at the valleys. The structures show a longitudinal conductivity two times higher than the transverse one, and a resistivity similar to that of the pristine ITO film (ρ ≈ 5 × 10 −4 Ω•cm). A thorough characterization of these transparent structures is presented and discussed. The compositional changes induced as laser pulses accumulate, condition the LIPSS evolution and thus the result of the structuring process. Strategies to further improve the achieved anisotropic resistivity results are also provided.

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“…Заметим, что cмена подложки полезна для прогноза и осуществления работы жидкокристаллического модуляционного устройствапространственного временного модулятора света, при использовании допирования ЖК-мезофазы, в ближнем и среднем ИК-диапазонах спектра. ≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡≡ Предложенный способ упорядоченной укладки ЖК-молекул на таком рельефе может до-полнить как приведенные выше механизмы ориентирования [1][2][3][4][5][6][7][8][9][10], так и подходы, указанные в публикациях [18][19][20][21][22][23][24][25][26][27], где учитываются термодинамическое состояние вещества, его вязкость, влияние микропор поверхности, деформации самих наноструктур, а также ряд других физико-химических параметров. Кроме того, необходимо учитывать процесс шлифовки, полировки как самих подложек, так и способа нанесения на них полимерных органических композитов, что, естественно, требует дальнейшего более детального и скрупулезного исследования.…”

Section: результаты и обсуждениеunclassified

“…Известно, что разработка и оптимизация способов ориентирования жидкокристаллических (ЖК) системдовольно сложная и трудоемкая научно-техническая задача [1][2][3][4][5][6][7][8][9][10]. Решение этой задачи связано с рядом технологических и схемных операций, например, с подбором растворителей (если используются органические композиции в качестве ориентирующего покрытия с последующей их натиркой), с выбором голографических подходов (при учете пространственной частоты записи, регулирующей период записанной решетки на создаваемом рельефе поверхности), с УФ-облучением поверхности (при выборе режима и типа ламп или лазерных источников УФ-диапазона спектра), с процессом импринтинга, с методами лазерной направленной обработки (при варьировании мощности лазера и скорости движения лазерного луча) и др.…”

Section: Introductionunclassified

Correlation Between Concentration of Injected Nanoparticles and Surface Relief of Organic Matrices: a Promising Method for Liquid Crystal Molecules Orientation

Каманина¹,

Toikka²,

Likhomanova³

et al. 2021

Liq. Cryst. and their Appl.

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Рассмотрены результаты поисковых исследований по нахождению новых способов ориентирования жидкокристаллических молекул при использовании рельефа поверхности органических материалов, сенсибилизированных наночастицами. Установлено влияние каркаса наноструктур на рельеф поверхности модельных органических матриц. На примере полиимидов, поливинилового спирта, пиридиновых структур установлены корреляционные зависимости между углом смачивания поверхности тонкоплёночных органических материалов и концентрацией сенсибилизатора. В качестве сенсибилизаторов рассматривались фуллерены, углеродные нанотрубки, восстановленный оксид графена. Установленные зависимости предполагают расширение области применения модуляционных устройств для лазерной и дисплейной техники. Ключевые слова: органические материалы, жидкие кристаллы, процесс сенсибилизации мезофазы, фуллерены, углеродные нанотрубки, рельеф поверхности, смачивание поверхности.

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Ultrafast laser induced nanostructured ITO for liquid crystal alignment and higher transparency electrodes

Cited by 26 publications

References 38 publications

Magnetically Tunable Liquid Crystal-Based Optical Diffraction Gratings

Magnetically Tunable Liquid Crystal-Based Optical Diffraction Gratings

Anisotropic Resistivity Surfaces Produced in ITO Films by Laser‐Induced Nanoscale Self‐organization

Correlation Between Concentration of Injected Nanoparticles and Surface Relief of Organic Matrices: a Promising Method for Liquid Crystal Molecules Orientation

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