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Organic & Polymer Electronics Laboratory Lynn Loo Office: CPE 4.422; Labs: 3.436 & 3.438 471-6300

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Presentation on theme: "Organic & Polymer Electronics Laboratory Lynn Loo Office: CPE 4.422; Labs: 3.436 & 3.438 471-6300"— Presentation transcript:

1 Organic & Polymer Electronics Laboratory Lynn Loo Office: CPE 4.422; Labs: 3.436 & 3.438 471-6300 http://www.engr.utexas.edu/che/directories/faculty/loo.cfm “Water-proof plastic circuitry by lamination,” Featured in Materials Today, October, 2002. “Towards large-area flexible displays: solventless thermal laser ablation printing of conductive polymers,” Featured in Nature Materials, January, 2003.

2 Introduction: The World’s First Electronic Paper Rogers et al., Proc. Nat. Acad. Sci. USA 2001.

3 Backplane: Organic Transistors on Plastic Substrate Rogers et al., Proc. Nat. Acad. Sci. USA 2001.

4 Why Organic Materials and Plastic Substrates? Improved mechanical flexibility and bendability Large-area coverage Compatible with high-speed reel-to-reel fabrication Low production costs Potential applications in large-area flexible displays, disposable RF tags, wearable electronics, etc. e.g., the first OLED active matrix display digital camera by Kodak (March, 2003) Kodak LS 633 http://www.kodak.com

5 Group Focus Design and synthesis of new materials for electronic applications (Bucholz, Guloy, Smith) Understanding structure-property interrelationships and how they can impact device performance (Krapchetov, Lee, Khan) Developing unconventional, non-invasive materials processing, patterning, and printing technologies specifically for organic device fabrication (Felmet, Lee, Mitchell)

6 Group photo, December 2003.

7 Design & Synthesis of Functional Polymers Structure & Property Relationships Device Fabrication & Testing Downstream ASG TLB QAS DAK KCF MFK KSL SMM Organic and Polymer Electronics Laboratory 1 polymer chemistry/physics project available; can be co-advised with Prof. Ganesan 1 patterning project available

8 Kwang Seok Lee: Patterning Water-Soluble, Conductive Polyaniline 1. Surface treat SiO x 3. Hydrophobic/hydrophilic pattern from microcontact printing 4. Dip-coat polyaniline PDMS stamp coated with octadecyltrichlorosilane 200  m 2. Stamp hydrophobic molecules on surface Partially supported by DuPont Young Professor Grant

9 Preliminary Electrical Characterization  = 0.06 S/cm Conductivity measurements: Organic transistors that use PANI electrodes: Results will be presented at the Spring ACS Meeting, Anaheim, CA; 03/2004. Collaborators: Graciela Blanchet and Feng Gao, DuPont Central Research, Wilmington, DE Si gate SiO x dielectric PANI electrodes pentacene

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