Miscut: progress report

1. Miscut: progress report Christianne 12-03-07

2. Outline • Manganites (very quick reminder) • Brief history • Microstructured LCMO • Recent results • Conclusions & Future

3. Manganites LCMO / STO: t = 50 nm polaron hopping DE model • Manganites have a metal-insulator transition at TC • TC(~ 150 K) reduced due to strain (bulk LCMO ~ 270 K)

4. Micro-structured LCMO (1) Goal: control film properties on nanometer scale by inducing local strain variations through unit-cell sized steps on STO substrate. AFM picture of 1.0°miscut substrate terminate layer TiO2 Step height ~ 0.4 nm Terrace length: 24 nm E-beam lithography: Measured transport properties with strip || and ┴ to step edges Bridge: 5 μm x 20 μm

5. Micro-structured LCMO (2) Sample : L410, 10 nm LCMO on 1.0° STO Growth inhomogenieties at step edges? PPMS not a constant current measurement!

6. Micro-structured LCMO (3) Sample : L410, 10 nm LCMO on 1.0° STO Sun et al., APL 2005 4-point measurement! Current processing Ar-etched STO 2-point measurement Kan et al.

7. Unstructured LCMO (1) Sample : L434, 8 nm LCMO on 1.0° STO unstructured (wiresaw) No anisotropy: smaller roughness and/or larger sample size

8. Unstructured LCMO (2) Sample : L434, 8 nm LCMO on 1.0° STO unstructured (wiresaw) 2-point measurement Asymmetry caused by Ar-etching Electroresistance?? Percolation paths between metallic regions Growing FM regions through polarized current Zhao et al APL 2005: (show ER in mA range)

9. Questions • Can we restore insulating state of STO after Ar-etching? • Was the anisotropy intrinsic and can we get it back? • Is the nonlinearity of IV, “Electroresistance”, intrinsic?

10. STO problem solved? Sample: L438, 8 nm LCMO on 0.859° STO + Reference structure Bridge: 5 μm x 20 μm Spacing: ~ 100 μm Etching time 30 sec, only 4 sec over-etched. Only part of the STO substrate became conducting, thickness gradient? After etching, 4 runs of 15 sec in O2 plasma (resist MaN-2405). After every run checked resist and resistance. From reference structure measurement: STO fully recovered!

11. Transport properties (4-point) Sample: L438, 8 nm LCMO on 0.859° STO Strip || step edges No “Electroresistance”! Some Joule heating at higher T

12. Transport properties (4-point) Sample: L438, 8 nm LCMO on 0.859° STO Strip ┴ step edges No “Electroresistance”! Some Joule heating at higher T

13. 2-point vs. 4-point Sample: L438, 8 nm LCMO on 0.859° STO Strip ┴ step edges Resistance of 2-pt. order of magnitude higher → high contact resistance Resistance switching at high current; low R → high R Joule heating? “Electroresistance” feature of 2-point measurement → barrier at interface?

14. Joule heating (1) Padhan et al., PRB 70,134403 (2004) • Heat dissipation sample • Thermal conduction of substrate = transport current = resistivity = cross section of sample (5•10-6 x 8•10-9 m2) = thermal conductivity STO substrate (16 W m-1 K-1)

15. Joule heating (2) Sample: L438, 8 nm LCMO on 0.859° STO Strip ┴ step edges; T = 50 K 4 point measurement

16. Joule heating (3) Sample: L438, 8 nm LCMO on 0.859° STO Strip ┴ step edges; T = 50 K 2-point measurement Joule-heating raises sample temperature above transition

17. Conclusions & Future • We can recover insulating state of STO with O2 treatment. • Electroresistance might not be intrinsic to LCMO thin films • Current processing has no influence on I-V, Sun et al. • Measure 5 nm LCMO to reproduce recovery STO and maybe get anisotropy back