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Semiconducting Diblock Copolymers Chemistry 765 Peter Dorff.

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Presentation on theme: "Semiconducting Diblock Copolymers Chemistry 765 Peter Dorff."— Presentation transcript:

1 Semiconducting Diblock Copolymers Chemistry 765 Peter Dorff

2 Diblock Copolymers Commercial applications: thermoplastics Polymers as Semiconductors?

3 Why Semiconducting polymers? Combines properties of metals into polymers  flexibility & processing Range of conductivities Electroluminescence: LEDs Very important! = $$$$$$

4 Semiconducting Polymers Initial work in 1968 by Dall’Olio et al. 2 synthesis of polypyrrole on Pt electrode electrical conductivities of  = 8 Ω -1 cm -1 Diaz, A et al. in 1979 synthesized stable, manageable polymeric films electrical conductivities of  = 100 Ω -1 cm -1 Skotheim, T.A, Handbook of Conducting polymers (New York and Basel, New York, 1986)

5 Doping of Polymer Popular Method developed in 1970s “doping”with e - donor & acceptor permits charge transfer iodine polyacetylenes (  = 360 Ω -1 cm -1 ) (CH) x + D + + A -  (CH) x + A - + D (CH) x + D + + A -  D + (CH) - x + A

6 Photovoltaic Cell Inexpensive renewable energy resource Benefit of Polymer PV cells: Low cost fabrication, durable & flexible Reaction:

7 Poly(p-phenylenevinylene) Excellent charge transfer, however: Discontinuous  ionization potential Photoexcitable at  450 nm Present use in LEDs Skotheim, T.A, Handbook of Conducting polymers (New York and Basel, New York, 1986)

8 Evolution of Polymer PV cells Research by Sariciftci, N.S et al. in 1992 Dope PPV with C 60 & spin cast into film C 60 accepts 6 e - Sariciftci, N. S et al. ibid. 62, 585 (1992)

9 Luminescent Studies PPV’s photoluminescent properties disappear  charge transfer!

10 Progression Research by Yu, G et al in 1995: 1/3 energy lost via luminescence Charge transfer occurs at D-A interface  Soluble C 60 derivatives >5.5% energy conversion Yu, G., Gao, J., Hummelen, J, Wudl, A, Heeger, J; Science, 270, (1995) 1789

11 A New Approach Stalmach, U et al. & their goal structured morphology »microphase separation of blocks »self-assembled monolayers poly(PPV)-block-poly(___-C 60 ) Stalmach, U et al. J. Am. Chem Soc., 2000, 122, 5464 Stupp, S. et al., Science, 1997, 276, 384

12 Objective

13 Synthesis Step 1: Polymerization of PPV Monodispersed MW End Functional Group

14 Synthesis Step 2: Preparation of TEMPO linker

15 Synthesis Step 3: Attachment of TEMPO Facilitates diblock formation between very different groups

16 Synthesis Step 4. Synthesis of a Diblock copolymer NMRP leads to monodispersed block Random styrene / CMS block (1:1 ratio)

17 Synthesis Step 5. Functionalize with C 60

18 Conclusions Successful synthesis of rod-coil block copolymers Self-assembly into honeycomb monolayers Quenching of luminescence with excitation Future work in applying polymer to prototype photovoltaic cell

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