Kristian Boroz scite author profile

Kristian Boroz

4Publications

33Citation Statements Received

20Citation Statements Given

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Leibniz University Hannover

Publications

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Flexible, fast, and low-cost production process for polymer based diffractive optics

Rahlves¹,

Rezem²,

Boroz³

et al. 2015

Opt. Express

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The generation of diffractive optical elements often requires time and cost consuming production techniques such as photolithography. Especially in research and development, small series of diffractive microstructures are needed and flexible and cost effective fabrication techniques are desirable to enable the fabrication of versatile optical elements on a short time scale. In this work, we introduce a novel process chain for fabrication of diffractive optical elements in various polymers. It is based on a maskless lithography process step, where a computer generated image of the optical element is projected via a digital mirror device and a microscope setup onto a silicon wafer coated with photosensitive resist. In addition, a stitching process allows us to microstructure a large area on the wafer. After development, a soft stamp of the microstructure is made from Polydimethylsiloxane, which is used as a mold for the subsequent hot embossing process, where the final diffractive optical element is replicated into thermoplastic polymer. Experimental results are presented, which demonstrate the applicability of the process.

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Digital mirror devices and liquid crystal displays in maskless lithography for fabrication of polymer-based holographic structures

Rahlves

Kelb

Rezem

et al. 2015

J. Micro/Nanolith. MEMS MOEMS

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Abstract. Polymer-based holographic and diffractive optical elements have gained increasing interest due to their potential to be used in a broad range of applications, such as illumination technology, micro-optics, and holography. We present a production process to fabricate polymer-based diffractive optical elements and holograms. The process is based on maskless lithography, which is used to fabricate optical elements in photoresist. We discuss several lab-level lithography setups based on digital mirror devices and liquid crystal devices with respect to illumination efficiency, resolution, and contrast. The entire optical setup is designed with emphasis on low-cost components, which can be easily implemented in an optical research lab. In a first step, a copy of the microstructures is replicated into optical polymeric materials by means of a soft stamp hot embossing process. The soft stamp is made from polydimethylsiloxan, which is coated onto the microstructure in the photoresist. The hot embossing process is carried out by a self-made and low-cost hot embossing machine. We present confocal topography measurements to quantify the replication accuracy of the process and demonstrate diffractive optical elements and holographic structures, which were fabricated using the process presented.

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Lab-level and low-cost fabrication technique for polymer based micro-optical elements and holographic structures

Rahlves

Rezem

Kelb

et al. 2015

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Polymer based diffractive optical elements have gained increasing interest due to their potential to be used in various applications such as illumination technology, micro optics and holography. We present a novel production process to fabricate polymer based diffractive optical elements and holograms. The process is based on maskless lithography, which is used to fabricate optical elements in photoresist. We discuss several lab-made lithography setups based on digital mirror devices and liquid crystal devices with respect to light efficiency, resolution and contrast. The whole optical setup is designed with an emphasis on low-cost setups, which can be easily implemented in an optical research lab. In a subsequent step, a copy of the microstructures is easily replicated into optical polymeric materials by means of a soft stamp hot embossing process step. The soft stamp is made from Polydimethylsiloxan, which is coated onto the microstructure in resist. The hot embossing process is carried out by a self-made and low-cost hot embossing machine. We present confocal topography measurements to quantify the replication accuracy of the process and demonstrate diffractive optical elements and holographic structures, which were fabricated using the process presented.

show abstract

Lab-level and low-cost fabrication technique for polymer based micro-optical elements and holographic structures

Rahlves

Rezem

Kelb

et al. 2015

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Kristian Boroz

Flexible, fast, and low-cost production process for polymer based diffractive optics

Digital mirror devices and liquid crystal displays in maskless lithography for fabrication of polymer-based holographic structures

Lab-level and low-cost fabrication technique for polymer based micro-optical elements and holographic structures

Lab-level and low-cost fabrication technique for polymer based micro-optical elements and holographic structures

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