A simple replication method to fabricate polymer waveguide

We are approaching the invasiveness of cancer cells from the studies of their wet surface morphology which should distinguish them from their normal counterparts. In this report attempts have been made to provide physical basis and background work to a wet replication method with a differentially pumped hydration chamber (Fig. 1) (1,2), to apply this knowledge for obtaining replica of some specimens of known features (e.g. polystyrene latex) and finally to realize more specific problems and to improvize new methods and instrumentation for their rectification. In principle, the evaporant molecules penetrate through a pair of apertures (250, 350μ), through water vapors and is, then, deposited on the specimen. An intermediate chamber between the apertures is pumped independently of the high vacuum system. The size of the apertures is sufficiently small so that full saturated water vapor pressure is maintained near the specimen.

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Loss Characteristics of Polymer Waveguide Fabricated by UV Laser Drawing of an Optically-Sensitive Hybrid Silicone

IEICE Transactions on Electronics ◽

10.1587/transele.e94.c.1858 ◽

2011 ◽

Vol E94-C (12) ◽

pp. 1858-1860

Author(s):

Soichi KOBAYASHI ◽

Seigi OKI ◽

Takahiro ISHIKURA ◽

Keisuke KATO ◽

Toshihiro SUDA

Keyword(s):

Uv Laser ◽

Polymer Waveguide

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A synchronous/asynchronous multi-master replication method. (c2007)

10.26756/th.2007.39 ◽

2007 ◽

Author(s):

Amer Mohammad Kheir Chahine

Keyword(s):

Replication Method

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Polymer Optical Waveguide Sensor Based on Fe-Amino-Triazole Complex Molecular Switches

Polymers ◽

10.3390/polym13020195 ◽

2021 ◽

Vol 13 (2) ◽

pp. 195

Author(s):

Muhammad Shaukat Khan ◽

Hunain Farooq ◽

Christopher Wittmund ◽

Stephen Klimke ◽

Roland Lachmayer ◽

...

Keyword(s):

Molecular Complex ◽

Electromagnetic Interference ◽

Optical Power ◽

Uv Curing ◽

Molecular Complexes ◽

Core Material ◽

Absorption Bands ◽

Electronic Temperature ◽

Polymer Waveguide ◽

Temperature Detection

We report on a polymer-waveguide-based temperature sensing system relying on switchable molecular complexes. The polymer waveguide cladding is fabricated using a maskless lithographic optical system and replicated onto polymer material (i.e., PMMA) using a hot embossing device. An iron-amino-triazole molecular complex material (i.e., [Fe(Htrz)2.85(NH2-trz)0.15](ClO4)2) is used to sense changes in ambient temperature. For this purpose, the core of the waveguide is filled with a mixture of core material (NOA68), and the molecular complex using doctor blading and UV curing is applied for solidification. The absorption spectrum of the molecular complex in the UV/VIS light range features two prominent absorption bands in the low-spin state. As temperature approaches room temperature, a spin-crossover transition occurs, and the molecular complex changes its color (i.e. spectral properties) from violet-pink to white. The measurement of the optical power transmitted through the waveguide as a function of temperature exhibits a memory effect with a hysteresis width of approx. 12 °C and sensitivity of 0.08 mW/°C. This enables optical rather than electronic temperature detection in environments where electromagnetic interference might influence the measurements.

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UV Nanoimprint Lithography: Geometrical Impact on Filling Properties of Nanoscale Patterns

Nanomaterials ◽

10.3390/nano11030822 ◽

2021 ◽

Vol 11 (3) ◽

pp. 822

Author(s):

Christine Thanner ◽

Martin Eibelhuber

Keyword(s):

Layer Thickness ◽

Process Parameters ◽

Nanoimprint Lithography ◽

Failure Modes ◽

Production Method ◽

Efficient Production ◽

Comprehensive Overview ◽

Replication Method ◽

Wide Range ◽

Pattern Size

Ultraviolet (UV) Nanoimprint Lithography (NIL) is a replication method that is well known for its capability to address a wide range of pattern sizes and shapes. It has proven to be an efficient production method for patterning resist layers with features ranging from a few hundred micrometers and down to the nanometer range. Best results can be achieved if the fundamental behavior of the imprint resist and the pattern filling are considered by the equipment and process parameters. In particular, the material properties and pattern size and shape play a crucial role. For capillary force-driven filling behavior it is important to understand the influencing parameters and respective failure modes in order to optimize the processes for reliable full wafer manufacturing. In this work, the nanoimprint results obtained for different pattern geometries are compared with respect to pattern quality and residual layer thickness: The comprehensive overview of the relevant process parameters is helpful for setting up NIL processes for different nanostructures with minimum layer thickness.

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