Spin Effects in Organic Semiconductors

Spin Effects in Organic Semiconductors Sayani Majumdar Wihuri Physical Laboratory, Department of Physics and Astronomy University of Turku Wihuri ...
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Spin Effects in Organic Semiconductors

Sayani Majumdar

Wihuri Physical Laboratory, Department of Physics and Astronomy University of Turku

Wihuri Physical Laboratory

Magnetism and Spintronics study at WPL •

Preparation of bulk and thin film samples



Structural characterization – XRD, AFM



Magnetic Measurements (also under light and electric field)



Transport and Magneto-transport Measurements



Fabrication of Spintronic components (in collaboration with ÅA and MIT)



Characterization of Spintronic components

Spintronics Spin Valve Open Current High

Ferromagnet 1

Spacer layer Ferromagnet 2

Spin Valve Close Current Low

Spin injection, transport and detection FM1

NM

FM2

• Spin polarized Injection Injection

transport

Detection

• Spin polarized transport spin polarized transport NM

spin flip FM2

• Spin polarized detection Detection

Spin injection – Half metals •

Advantages: • Half metals (LSMO) have very high net spin polarization ~ 100% • Stable oxides • Lesser conductivity mismatch



Disavdantages: • Lower Tc and loss of spin polarization at the surface • surface roughness



Sollutions: • Higher Tc half metals (SFMO) • reducing surface roughness by optimization of thin film growth parameters • protecting the surface Park et. al. Nature 392, 794 (1998).

Spin transporter •

Spin-flips mainly due to –



Spin-Orbit interaction: Interaction between electron spin magnetic moment and orbital angular momentum.



Hyperfine interaction: Interaction between electron spin and nuclear spin.

Both effects are stronger for heavier atoms Organic molecules : Lighter atoms, better alternative

Organic Semiconductors • • • • • •

• • •

Advantages - chemical tuning of electronic functionality. Easy structural modification. Ability of self assembly. Mechanical flexibility. Large Area and low cost electronic applications. Thin film technology does not require high temperatures and lattice matching. Challenges – unstable in air Highly resistive Reproducibility

Hybrid spintronics – best of both world •

Half metallic spin injectors – La0.7Sr0.3MnO3, Sr2FeMoO6



Better spin transporting materials – organic semiconductor small molecules, Polymer, Graphene, Carbon naotubes



Different spintronic components – spin valves, magnetic tunnel junctions, magnetic sensors, spin LEDs, spin transistors and ....

Organic Spintronics • Organic spin valves • Organic magnetic tunnel junctions • Organic magneto resistance in OLED

Organic Spin-valves

Dediu et. al. Solid state comm. 122, 181 (2002).

Organic Spin-valves

Xiong et. al. Nature 427, 821 (2004).

Polymeric Spin-valves •

Room temperature operation of Organic spin valves.

RR-P3HT 0.7

T = 5K

T = 300K

1.5

80

0.4

40

1.0

109.6 109.2

0.5

108.8 0.0

0.3 0.2

0 -300 -200 -100

0

B (m T)

100 200 300

108.4 108.0 -300

-200

-100

0

100

200

-0.5 300

B (mT)

Majumdar et al., Appl. Phys.Lett. 89, 122114 (2006).

% MR

0.5

R (K )

110.0

% MR

-2

R (M cm )

0.6

110.4

120

Spin injection in Organics •







To achieve significant spin-current injection, the OS must be driven far out of local thermal equilibrium by an electric current. If the injecting contact has metallic conductivity, its electron distribution cannot be driven far from thermal equilibrium by practical current densities. Quasi-equilibration between the conjugated OS and the metallic contact must be suppressed to achieve effective spin injection. This requires a spin-dependent barrier to electrical injection that may be either due to tunneling through the depletion region of a large Schottky barrier or due to tunneling through a thin, insulating, interface layer.

Ruden and Smith, J. Appl. Phys. 95, 4898 (2004).

Photoelectron intensity (arb. units)

The FM- Organic interface (a)

s1

S 2p

s2

LSM O/P3HT

LSMO /HMDS/P3HT

LSMO/O DTS/P3HT

160

165

170

175

Binding energy (eV)

Pure P3HT P3HT/LSMO

Majumdar et al., Appl. Phys.Lett. 89, 122114 (2006).

The FM- Organic interface

• Introduction of Alq3 on LSMO creates a strong interface dipole of 0.9 eV. • Energy level shift of Alq3 with respect to the vacuum level makes electron injection into Alq3 more favorable than hole injection. • Interface of Alq3/Co on the detector side of the SV show a shift of about 1 eV. Zhan et al., Phys. Rev. B 76, 045406 (2007).

Loss of injection with temperature

• Irrespective of the spin injecting electrode, the SV response with increased temperature decreased substantially. • Spin polarizaion is lost at the LSMO/OS interface.

Majumdar et al., J. Appl. Phys. 104, 033910-1(2008).

Loss of injection with temperature

• OS Small molecules also showed similar temperature dependence of SV response. • Spin polarizaion is lost at the LSMO/OS interface.

Spin transport and relaxation •

SP carriers injected into the OS, travel by drift and diffusion under the influence of an electric field.



During transport, the SP carriers interact with their environment (trapping, spin precession around a local hyperfine field) and their initial spin direction is lost.



Different spin relaxation length in OS is reported.



The effect of disorder and impurity of the OS can play a major role. Majumdar et al., Comprehensive Nanoscience and Technology, 2011, Vol. 1, 109-142.

Effect of impurity on spin transport

Vinzelberg et al., J. Appl. Phys. 103, 093720-1(2008).

Spin detection

• Depending on top electrode penetration in OS, MR response changed substantially. • Two spin transport channels were detected. • For improved performance it is essential to have a well-defined interface.

Majumdar et al., New J. Phys. 11, 013022-1(2009).

Organic MTJ



Sizable Room-temperature TMR response was observed.



SP tunneling transport measurement showed more than 35% spin polarization of the Py/OS interface and spin injection in OS.



13 nm spin relaxation length in OS small molecule Rubrene was measured. Santos et al., Phys. Rev. Lett. 98, 016601 (2007).

LSMO based organic MTJs



LSMO/Alq3/Co nano MTJ

- 300% TMR with high bias and temp. dependence - TMR vanishes beyond 50 mV and 150K - Reproducibility - 65% working samples • Among those, 20% showed measurable magnetoresistance from 10 to 300%.

C. Barraud et al., Nature Phys.6, 615 (2010)

LSMO based organic MTJs



LSMO/Rubrene/V(TCNE)x (J-W.Yoo et al., Nature Mat. 9, 638 (2010)

-

~2 % TMR at 100 K with high bias and temp. dependence Below 100K, too high junction resistance ~1% TMR reported till 150K



LSMO/LaO/Rubrene/Fe J-W.Yoo et al., Synth Mat. 160, 216 (2010)

-

~10 % TMR with high bias and temp. dependence at 10 K Above 200 K, TMR vanished

LSMO based organic MTJs



LSMO/Rubrene/Co MTJ (Majumdar et al., Unpublished)

-

~ 8 - 14 % TMR observed at low temperature Bias dependence is not consistent from device to device Measurable TMR was observed at least until 150 K LSMO thickness plays a big role in the TMR response of the MTJs

MR without FM electrodes - OMAR

Francis et al., New Journal of Physics 6: 185-1 (2004).

Conclusions and future research •

Due to small spin orbit coupling and hyperfine interaction OS are promising as spin transporting materials.



Spin injection and transport have been successfully demonstrated in organic spintronic devices.



Any defect in the OS layer can modify the spin transport properties significantly.



Search is ON for higher spin injecting electrode and better spin transporter like carbon nanotubes and graphene.

Acknowledgements • Turku Collegium for Science and Medicine • Wihuri Foundation • Academy of Finland

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