Homer Antoniadis | OLED Product Development|page:1

Overview of OLED Display Technology

Homer Antoniadis, Ph.D.Product Development Group Manager

phone: (408) 456-4004cell: (408) 314-6460

email: homer.antoniadis@osram-os.com

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Outline

! OLED device structure and operation

! OLED materials (polymers and small molecules)

! Evolution of OLED performance

! OLED process and fabrication technologies

! Color capabilities

! White emitting OLEDs

! Passive and active matrix driving schemes

! OLED market potential

! Products and demonstrators

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Single pixel structure

Anode (ITO 1500 Å)

Conducting polymer layer ~ 1200 Å

Emissive polymer layer ~ 800 Å

Cathode (Ba,Ca/Al 2000 Å)

Conducting polymer layer

Glass substrate

Epoxy

Anode

Cathode

Cover glass

Emissive polymer layer

OLED Display and Pixel Structure

Display Pixel

Human hair is 200X the thickness of the OLED layers

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Lighth+ h+

h+

e- e-

Transparentsubstrate

Anode(ITO)

Conductingpolymer Emissive polymer

HOMO

LUMO

Cathode-layer (s)

ca. 100 nm 10 - >100 nm <100 nm

LUMO

HOMO

>100 nm

OLED device operation (energy diagram)

light

Anode+ ++ + ++ + ++

_

++ +

Cathode_ _ _ _ _ ___+_ _+

VEmissive polymer

Conducting polymer

OLED Device Operation Principles

OLEDs rely on organic materials (polymers or small molecules) that give off light when tweaked with an electrical current! Electrons injected from cathode! Holes injected from anode! Transport and radiative recombination of electron hole

pairs at the emissive polymer

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-8 -6 -4 -2 0 2 4 6 8

10-7

10-6

10-5

10-4

10-3

10-2

10-1

100

Voltage (Volts)

Cur

rent

Den

sity

(A/c

m2 )

Luminance-Current-Voltage Efficiency-Luminance-Voltage

0 2 4 6 810-1

100

101

102

103

104

105

Voltage (Volts)

Lum

inan

ce (c

d/m

2 )

0 2 4 6 80

2

4

6

8

10

12

Voltage (V)

Effic

ienc

y (c

d/A)

10 100 1000 100002

4

6

8

10

12

Luminance (cd/m2)

Effi

cien

cy (c

d/A

)

Optoelectronic Device Characteristics

LUMINANCE is the luminous intensity per unit area projected in a given direction

The SI unit is the candela per square meter (cd/m2), which is still sometimes called a nit

The footlambert (fL) is also in common use: 1 fL = 3.426 cd/m2

http://www.resuba.com/wa3dsp/light/lumin.html

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Evolution of LED Performance

SM OLED

PolymerOLED

Courtesy of Agilent Technologies

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Conducting polymers! Polyaniline (PANI:PSS)! Polyethylenedioxythiophene

(PDOT:PSS)

Emissive polymers! Polyphenylenevinylene

(R-PPV)! Polyfluorene (PF)

Processed by :Spin casting, Printing, Roll-to-roll web coating

IP owned by Cambridge Display Technology

R1R1

n

R1

R1n

NH

PANI PDOT

R-PPVPF

Electroluminescent Polymers

PSS

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Multiple emission colors achieved by Covion

300 nm 500 nm 700 nm

n

CNOR

ROS

PPP

PPV

PT orCN-PPV

Different emission colors can be obtained with a variety of chemical structures

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Multiple emission colors achieved by Dow Chemical

R1R1

n

PF

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Deposit and pattern anode (ITO)

Vacuum deposit and pattern cathode (Ba,Ca/Al)

Pattern polymer layers(first conducting then emissive)

Spin coatingInk Jet printing

Web coatingScreen printing

Polymer OLED display fabrication steps

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Ink Jet printing to define and pattern R, G, B emitting subpixels

Ink Jet Printing to Pattern Polymers(Full Color Applications)

Substrate

Greenemitter

Red emitter

Blue emitter

Ink Jet Head

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The Holy Grail: Flexible OLEDs

Sheila Kennedy, Harvard Univ., 1999

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Hole transport small molecules! Metal-phthalocyanines! Arylamines, starburst amines

Emissive small molecules! Metal chelates, distyrylbenzenes! Fluorescent dyes

Processed and deposited by :thermal evaporation in vacuum

IP owned by Eastman Kodak

NO

NO

Al O

N

N N

Alq3

NPD

Electroluminescent Small Molecules

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Small molecule

Anode - ITOHIL - CuPc

Substrate - glass

EML - doped Alq3

ETL - Alq3

HTL - NPB

Cathode - LiF/Al

Anode - ITO

Substrate - glass

ETL - PPV, PF

HIL - PDOT, Pani

Cathode – Ba, Ca/Al

Multi-layer structuremade all in vacuum

Bilayer structuremade from solution

Polymer

Polymer and Small Molecule Device Structures

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Alq3

substrate

NPD

Shadow mask

ITO

ITO

Shadow mask

ITO

Cathode separator

Small molecules are thermally evaporated in vacuum R, G, B pattering is defined by

shadow masking in vacuum

Full color patterning with small molecules

R emission layer

G emission layer

B emission layer

Shadow mask

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White emitting small molecule OLEDs

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Phosphorescent small molecule OLEDs

PHOLED technology offers significant room for further performance advances

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! Manufacturing started ! Pioneer 1997! TDK (Alpine, 2001)! Samsung-NEC Mobile Display (SNMD) (2002)! RiTdisplay (2003)! Sanyo-Kodak (2003)

! R, G, B colors available! limited lifetimes for blue

! Shadow masking allows easy patterning for area color ! presents challenges with scalability and high volume manufacturing

! Shadow masking challenging for full color! high throughput and scalability is a challenge

The Head-Start of Small Molecule OLEDs

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! Lower fabrication cost! fewer vacuum deposition steps - lower capital cost! advantageous materials usage and scalability (I/J printing)

! Solution processing techniques! compatible with printing techniques

- lower cost for full color! scalable to very large substrates (high volume manufacturing)! better mechanical integrity! compatible with roll process for flex manufacturing

Advantages of Solution Processing (Polymer) OLEDs

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Advantages:- well-established technology (LCD)- no patterning of emitter necessary- homogeneous aging of emitter (?)

Color filtersWhite emitter

Disadvantages:- power inefficient - ITO sputtering on filters- efficient white emitter necessary

RGB- polymer emitters

Advantages:- power efficient- lower production cost- mature ITO technology

Disadvantages:- emitters have to be optimized separately (common cathode?)

- differential aging of emitters- patterning of emitters necessary

Color Changing Media(CCMs)

Advantages:homogeneous aging of emitter (?)more efficient than filtersno patterning of emitter necessary

Disadvantages:ITO Sputtering on CCMsstable blue emitter necessary aging of CCMs

Full-color/Multi-color Approaches

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Ink Jet printing of R,G,B emissive polymers defines the R,G,B subpixels

(xR, yR) (xG, yG) (xB, yB)

AM TFT screen

Green polymer

Red polymer

Blue polymer

EL I

nten

sity

(nor

mal

ized

)

400 450 500 550 600 650 700 7500.0

0.2

0.4

0.6

0.8

1.0

Wavelength (nm)

Obtaining a Full Color OLED Display

G BR

Single pixel

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Output Current

Output Current

Output Current

Output Current

Output Current

Output Current

Courtesy of Philips Electronics

Passive Matrix Addressing

• Line by line multiplex scanning

• Duration of addressing is 1/mux rate

• Pixel pulsed luminance = mux rate times average luminance• if 64 rows then pixel L=6400 nits for an average of 100 nits

• Limited addressed lines

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Output Current

Output Current

Output Current

Output Current

Output Current

Output Current

Passive Matrix Addressing

• Line by line multiplex scanning

• Duration of addressing is 1/mux rate

• Pixel pulsed luminance = mux rate times average luminance• if 64 rows then pixel L=6400 nits for an average of 100 nits

• Limited addressed lines

Courtesy of Philips Electronics

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light

• Place a switching TFT at each pixel• Selected pixel stays on until next refresh

cycle (pixels are switched and shine continuously)

• Common cathode• Unlimited addressed lines

Active Matrix Addressing

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Worldwide OLED Market, 2000-2006

PM LCD6%

OLED4%

PDP12%

Other3%

TFT LCD75%

Flat panel market 2006 $57B

source: iSupply/SRI 2002, Display Search 2002

Other:VFD: vacuum fluorescent displayEL: electroluminescence DLP: Digital Light Processing

OLED Market will show strong growth

Value (Mio $) Thsd. units

$0

$500

$1,000

$1,500

$2,000

$2,500

$3,000

$3,500

2001 2002 2003 2004 2005 2006 2007 20080

50,000

100,000

150,000

200,000

250,000

value: iSuppli value: DisplaySearch

units: iSupply units: DisplaySearch

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Small Molecule Area Color Passive Matrix Displays

Lucky Goldstar (LG)

Motorola (by Appeal) Samsung Electronics

Examples of Wireless ProductsWith Kodak Display Technology

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Samsung Electronics

96x64 Full Color PM Display

Kodak Licensed SNMD to Manufacture PM OLED Displays

Fujitsu F505i GPS

With Pioneer Full Color (4,096 colors) PHOLED 1.1-inch 96x72 pixels display. Phosphorescent material developed by Universal Display Corp.

Small Molecule Full Color Passive Matrix DisplaysCaller ID Subdisplays

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Small Molecule Active Matrix Display Products

Eastman Kodak: Digital camera Sanyo: Cell Phone with Digital camera

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Kodak-Sanyo 15-in flat panel display (based on white)

15-inch HDTV format (1280x720) AM a-Si OLED display by Sanyo-Kodak Full Color based on white OLED with Integrated Color Filters.The two companies showed the prototype at the CEATEC JAPAN tradeshow (Sep 2002).

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Top Emission Adaptive Current Drive technology, allows OLEDs to be larger and higher in brightness and resolution. A 13-inch full-color AMOLED using poly-Si TFT was made where the light emits through the transparent cathode and thus, the filling factor does not depend on the TFT structure.

The schematic vertical structure of the device is substrate/TFT/metal anode/organic layers/transparent cathode/passivation layer/transparent sealing.

Display format: 800x600 (SVGA); pixel pitch 0.33x0.33mm2

Top Emitting Active Matrix OLED Display

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Polymer Passive Matrix Display Products

Delta Electronics: Display for MP3 playerPhilips: Electrical Shaver

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OSRAM Pictiva™ Evaluation Kit (www.pictiva.com)

San Jose, CA – May 15, 2003 -- Osram Opto Semiconductors, a global leader of solid-state lighting devices, today announced its Pictiva™ Evaluation Kit. Announced earlier this week, the Pictiva brand is Osram’s suite of organic light emitting diode (OLED) technologies. Pictiva displays offer a high level of brightness and contrast, video capabilities, wide viewing angles and a thin-profile, enabling developers and engineers to have greater design flexibility when developing the next-generation state-of-the-art electronics products.