Digital Micromirror Devices for rapid fabrication of large-area laser- ablated multicolour-grating patterns B. Mills, D. J. Heath, M. Feinaeugle, R. W.

Slides:

Advertisements

Similar presentations

High frequency annular arrays can provide very good resolution in ultrasound bio-microscopy Numerical simulation of their imaging patterns is essential.

Advertisements

Digital Micromirror Devices (DMD)

3.1 AS Unit F211: Cells, Exchange and Transport The cell is the basic unit of all living things. How to use a light microscope Why electron microscopes.

AVANEX Livingston, Starlow Park, Livingston, EH54 8SF

Using Your Classroom Projector to Demonstrate Properties of Light Dr. Michael Ottinger and Dr. Brian Bucklein Missouri Western State University St Joseph,

Show & Tell Digital Projectors By Alex Righolt, 18/03/2008 A&A Computers Ltd.

Spectral Resolution and Spectrometers

Micromirror Lithography David Chen EECS 277. Overview What is Lithography? What are Micromirrors? Successful Research Future.

Spectral Resolution and Spectrometers A Brief Guide to Understanding and Obtaining the Proper Resolution of the 785 Raman System.

Thin Diamond Radiator Fabrication for the GlueX Experiment Brendan Pratt with Richard Jones University of Connecticut NDNC

Large Multilayer Diffraction Gratings: Coating Uniformity Senior Student: Erik Krous Project Advisor: Dr. Carmen Menoni Collaborators: Dr. D. Patel, Dr.

FLASH Experiments with Photons High intensity laser light in the VUV spectral region Harald Redlin; HASYLAB.

VTSLM images taken again at (a) 4.5  (T=84.7K), (b) 3.85  (T=85.3K), (c) 22.3  (T=85.9K), and (d) 31.6  (T=86.5K) using F-H for current and A-C for.

Diffraction of “low energy” electrons from free-standing transmission gratings Ben McMorran and Alex Cronin University of Arizona.

IMEC - INTEC Department of Information Technology WAVEGUIDES IN BOARDS BASED ON ORMOCER  s

III. Results and Discussion In scanning laser microscopy, the detected voltage signal  V(x,y) is given by where j b (x,y) is the local current density,

© 2012 Pearson Education, Inc. { Chapter 36 Diffraction (cont.)

1 Audio Driven Laser Tetris Final Project Presentation Cameron Lewis and Xin Sun.

Case Studies in MEMS Case study Technology Transduction Packaging

Optical Design for an Infrared Multi-Object Spectrometer R. Winsor, J.W. MacKenty, M. Stiavelli Space Telescope Science Institute M. Greenhouse, E. Mentzell,

SIMULATION OF MATERIAL CHARACTERISTICS AND LASER PERFORMANCE OF Q-SWITCHED QUANTUM WELL SEMICONDUCTOR LASERS L. Chardee Allee NASA Space Grant.

Os, 9/16/99 MICROMACHINING AND MICROFABRICATION TECHNOLOGY FOR ADAPTIVE OPTICS Olav Solgaard Acknowledgements: P.M. Hagelin, K. Cornett, K. Li, U. Krishnamoorthy,

Advanced Ideal Backlight Illumination System  Illumination of a set of three red, green and blue pixels.  This micro-optical system is replicated many.

Biomedical Applications of Plasma Spectroscopy: A Preliminary Study Dr. Unnikrishnan V. K. Associate Professor Department of Atomic and Molecular Physics.

Other Applications using DMD By Walid. Introduction DMD, a dense array of hundreds of thousands of tiny switchable mirrors, whose pixel speed, contrast.

Ultra Scale High Density Hybrid DNA Memory Mohamad Al-Sheikhly, William Bentley, Aris Christou, Joseph Silverman Department of Materials Science and Department.

Aquatic Spectrometer & Turbidity Meter Preliminary Design Review ECE 4007 L1, Group 8 Paul Johnson Daniel Lundy John Reese Asad Hashim.

Principal maxima become sharper Increases the contrast between the principal maxima and the subsidiary maxima GRATINGS: Why Add More Slits?

High Throughput Microscopy

M. Zamfirescu, M. Ulmeanu, F. Jipa, O. Cretu, A. Moldovan, G. Epurescu, M. Dinescu, R. Dabu National Institute for Laser Plasma and Radiation Physics,

Digital two photon microscopy for multiple fast signals acquisition Laboratory of Advanced Biological Spectroscopy (L.A.B.S.) University of Milan - Bicocca.

Diamond Radiator Fabrication & Assessment Update Brendan Pratt Richard Jones University of Connecticut.

Role of Glass Composition in Waveguide Fabrication with Femtosecond Laser Pulses Denise Krol, University of California, Davis, DMR Tightly focused.

HOLOGRAMS. The object is hit with laser light. The data is recorded onto a plate by capturing the reflected, diffracted and scattered light. The.

EUV Maskless Lithography J. Vac. Sci. Technol. B 30, (2012); 9/25/20121K. Johnson

1 Use of gratings in neutron instrumentation F. Ott, A. Menelle, P. Humbert and C. Fermon Laboratoire Léon Brillouin CEA/CNRS Saclay.

Femtosecond laser fabrication of metamaterials for high frequency devices Marian Zamfirescu *a), Razvan Dabu *, Marius Dumitru *, George Sajin **, Florea.

Optical Trapping of Quantum Dots Based on Gap-Mode-Excitation of Localized Surface Plasmon J. Phys. Chem. Lett. 1, (2010) Ashida Lab. Shinichiro.

1 Use of gratings in neutron instrumentation F. Ott, A. Menelle, P. Humbert and C. Fermon Laboratoire Léon Brillouin CEA/CNRS Saclay.

Eric Dacquay Brian Freedman Lisa Harada.  Digital Light Processing (DLP) – What is it? ◦ Method of displaying images in a purely digital realm ◦ Made.

18-Dec-15 OUT LINES 1.INTRODUCTION 2.CONCEPT OF HOLOGRAM 3.REQUIREMENTS FOR HOLOGRAPHY 4.DIFFERENCE BETWEEN PHOTOGRAPHY & HOLOGRAPHY.

High Dynamic Range Beam Imaging with a Digital Optical Mask* Presented by Tim Koeth (UMD) on behalf of R.B. Fiorito, H.D. Zhang, A. Shkvarunets UMD, College.

Beam Halo Monitoring using Optical Diagnostics Hao Zhang University of Maryland/University of Liverpool/Cockcroft Institute.

Digital Cinema From Motion JPEG to Film projection A presentation by: Maxime Cassan Florent Rioult Neil Sinclair December 2008.

Applications of Micro Electro Mechanical Systems (MEMS) Jobin Philip.

Planar Chiral Metamaterials & their application to optoelectronics devices W. Zhang, A. Papakostas, A. Potts, D. M. Bagnall, N. I. Zheludev Microelectronic.

Jongbaeg Kim, Dane Christensen, and Liwei Lin

DIGITAL LIGHT PROCESSING (DLP) REVOLUTION IN VISION.

Date of download: 6/7/2016 Copyright © 2016 SPIE. All rights reserved. Schematic illustration of the pulsed laser deposition (PLD) setup. Figure Legend:

Yongjin Shin Sohee Park, Youngseop Kim, Jangwoen Lee, Woonggyu Jung, Zhongping Chen, and J. Stuart Nelson 1.

OPTICAL DATA SECURITY ARUNKUMAR P.S S 7 EC A ROLL NO- 16.

Assembly, Alignment, and Maintenance of an Automated Laser Cutter Zhenghao Ding, Lunjun, Gabriel Spalding* Physics Department, Illinois Wesleyan University.

D. J. Heath1, B. Mills1, J. A. Grant-Jacob1, M. Feinaeugle3, V

Thin Diamond Radiator Fabrication for the GlueX Experiment

AAFS 2004 Dallas Zeno Geradts

SEMINAR ON DIGITAL LIGHT PROCESSING

Using a digital micromirror device for high-precision laser-based manufacturing on the microscale Please use the dd month yyyy format for the date for.

Date of download: 10/13/2017 Copyright © ASME. All rights reserved.

Date of download: 10/20/2017 Copyright © ASME. All rights reserved.

From: Deburring Effect of Plasma Produced by Nanosecond Laser Ablation

Date of download: 11/8/2017 Copyright © ASME. All rights reserved.

Bill Brocklesby Optoelectronics Research Centre

Date of download: 1/1/2018 Copyright © ASME. All rights reserved.

Date of download: 1/3/2018 Copyright © ASME. All rights reserved.

From: Deburring Effect of Plasma Produced by Nanosecond Laser Ablation

by C. Sun, N. Fang, D.M. Wu, X. Zhang∗

Hybrid plasmonic multichannel spectroscopic sensor platform

MICROMACHINING AND MICROFABRICATION TECHNOLOGY FOR ADAPTIVE OPTICS

Unit 37 Further Transformations

Presentation transcript:

Digital Micromirror Devices for rapid fabrication of large-area laser- ablated multicolour-grating patterns B. Mills, D. J. Heath, M. Feinaeugle, R. W. Eason Optoelectronics Research Centre, University of Southampton, UK

2 Outline Introduction to digital mirror devices (DMD) Using a DMD for laser-ablation Fabrication of multi-colour surfaces Replication of a Morpho butterfly Conclusions

3 Digital Mirror Device (DMD) Used in majority of projectors Array of individually controlled ~10μm width mirrors Can be used as an intensity spatial light modulator (SLM) Fast switching speed (>30kHz) Schematic of a section of the digital mirror device (actual model used: Texas Instruments DLP3000, 608 x 684 mirrors)

4 Energy density on sample is 1-50J/cm 2 Energy density on DMD is ~1mJ/cm 2 Well below damage threshold of DMD due to magnification Experimental schematic

Sample fabrication schematic 5 Each laser pulse is shaped to a different pattern The sample is continuously translated input laser pulses  array of mirrors, showing the pattern (the DMD) focussing objective spatially-shaped laser pulses  sample is continuously translated sample movement direction 

Process repeated to make 2D arrays 6 direction of  stage movement After each line of letters, we start again on an adjacent line, to build up 2D arrays 50µm 10µm

Not letters but gratings, where each grating can have a different period 7 Each grating is 30 by 30µm and will diffract different colours of light to different angles We build up an array of 10,000s, over cm-squared regions Result is that the material surface appears to be coloured 10µm 50µm

Security and marking applications 8 1mm 3mm

Replication of a Morpho butterfly 9 Nature Fabricated SEM image Photograph 1µm 10µm 2mm

Conclusions Fabrication of cm-squared regions in 15 minutes (with faster stages  less than 1 minute) Diffraction-limited writing resolution Can be used to make a surface appear to be multi-coloured Applications in security / marking This work was supported under EPSRC (grant number EP/L022230/1) 10