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Home , Organic semiconductor

Physics of Organic Devices: Materials, Fundamentals, Technologies and Applications

Dr. Alex Zakhidov Assistant Professor, Physics Department Core faculty at Materials Science, Engineering and Commercialization Program.

http://zakhidov.wp.txstate.edu/

Physics Colloquium 10/07/2015 , Dr. Alex Zakhidov Outline

1. Why and what is it good for?

2. How to save the world with organic perovskite solar cells?

Physics Colloquium 10/07/2015 , Dr. Alex Zakhidov Organic Electronics Devices: Smart, Flexible, Cheap!

Organic Light Organic Organic Emitting (OLED) (OSC) (OTFT)

Samsung

Heliatek

Other devices: organic lasers, organic memory, organic bio(chemical) sensors

Physics Colloquium 10/07/2015 , Dr. Alex Zakhidov “Evolution” of organic electronics

New material synthesis: design, , small progress Chemistry Structure, filmmorphology Mobility,properties, optical Materials properties: Materials Materials Used for mobile Science Science displays and TVs (2012) Physics Physics Commercial prototypes (2000s) Fundamentals, mechanism of mechanism Fundamentals,

operation, new device new concepts device operation, First devices (late 1980s) Engineering Materials (1960-70)

Enabling technologies: Processing, patterning, , encapsulation

Physics Colloquium 10/07/2015 , Dr. Alex Zakhidov Organic compounds contain

S.R. Forrest ,Nature 428 (2004)

Physics Colloquium 10/07/2015 , Dr. Alex Zakhidov Organic – π - conjugated organic molecules

linear

aromatic

Physics Colloquium 10/07/2015 , Dr. Alex Zakhidov Organic Semiconductors – π - conjugated organic molecules

In 1977, they discovered that can be oxidized with halogensto produce conducting materials from either insulating or semiconducting materials. + I

Physics Colloquium 10/07/2015 , Dr. Alex Zakhidov General Features of Organic Semiconductors

Advantages Challenges 1. Device engineering. (Lithography, 1. Unlimited material design options Doping, Materials purity, Horizontal and 2. Varity of structures and morphologies vertical integration) 3. engineering 2. Stability, Lifetime 4. Light, flexible, inexpensive 3. Organic/Inorganic Interfaces 5. Electronic and Ionic transport* 4. Disorder: highly localized charge carriers 6. Disorder: highly localized

amorphous lamella nano-crystalline microcrystalline crystalline L

1 nm 10nm 100nm 1µm 10 µm 100 µm 1 mm

*Al.A. Zakhidov, B. Jung, J.D. Slinker, H.D. Abruña, G.G. Malliaras, “A light-emitting ”, Organic Electronics 11, 150 (2010). Physics Colloquium 10/07/2015 , Dr. Alex Zakhidov Electronic properties of Organic Semiconductors

Graphene p-Si GaAs, Organic semiconductors CMOS InSb, GaN, Organic semiconductors InAs a-Si Mobility cm2/Vs 10-6 10-5 10-4 10-3 10-2 10-1 1 10 102 103 104 105

Amorphous Highly crystalline

T. Sekitani, et. al. Nature Materials 9 (2010)

H. Klauk, Chemical Society Reviews, 39 (2010 ) Google *Y. Yuan, et al Nature Communications 5 (2013). Lens to monitor glucose level in tear

Physics Colloquium 10/07/2015 , Dr. Alex Zakhidov Optical properties of Organic Semiconductors

Organics: Frenkel Inorganics: Wannier-Mott excitons

εorg<< εinorg

2 Eex=e /(ε·rex)

Molecular picture Semiconductor picture

kbTroom~26 meV

Ground State Frenkel exciton Ground State WM exciton

Binding energy ~ 1 eV Binding energy ~ 10 meV Radius ~ 10 Å Radius ~ 100 Å

Physics Colloquium 10/07/2015 , Dr. Alex Zakhidov Happy Life…

Physics Colloquium 10/07/2015 , Dr. Alex Zakhidov How much do we need?

Eco Friendly

In fact can help us to “deal” with global climate change

Physics Colloquium 10/07/2015 , Dr. Alex Zakhidov Why are we not doing this already?

Physics Colloquium 10/07/2015 , Dr. Alex Zakhidov

National Renewable Energy Lab Solar chart $$ 20%

$$$$ $, but…. $$$

Physics Colloquium 10/07/2015 , Dr. Alex Zakhidov Perovskite structure and processing

Organic Inorganic Spin/dip-coating CH3NH3 precursor precursor Pb X CH3NH3I + PbX2 Vacuum co-deposition Where X - Br, I or Cl.

Generic perovskite solar cell Perovskite layer top view

Ag Hole Selective layer

perovskite absorber

Electron Selective layer ITO/FTO

Physics Colloquium 10/07/2015 , Dr. Alex Zakhidov Organic Perovskite Solar Cells

Advantages Challenges 1. Stability 1. Efficiency >20% 2. High optical absorption 2. Replacement of lead with tin 3. Low recombination rates 4. High carrier transport mobility 3. Reliable, scaled-up production 5. Tunable band gap 6. Room temperature processing 7. Low-cost, abundant materials

The Energy Pay Back Time EPBT = Einput/Esaved

organic solar cells Physics Colloquium 10/07/2015 , Dr. Alex Zakhidov Take home message

Physics Colloquium 10/07/2015 , Dr. Alex Zakhidov