Presentation is loading. Please wait.

Presentation is loading. Please wait.

Tuesday, May 15 - Thursday, May 17, 2007

Similar presentations


Presentation on theme: "Tuesday, May 15 - Thursday, May 17, 2007"— Presentation transcript:

1 Tuesday, May 15 - Thursday, May 17, 2007
Thin Film Scattering: Epitaxial Layers Second Annual SSRL Workshop on Synchrotron X-ray Scattering Techniques in Materials and Environmental Sciences: Theory and Application Tuesday, May 15 - Thursday, May 17, 2007

2 Thin films. Epitaxial thin films.
What basic information we can obtain from x-ray diffraction Reciprocal space and epitaxial thin films Scan directions – reciprocal vs. real space scenarios Mismatch, strain, mosaicity, thickness How to choose right scans for your measurements Mosaicity vs. lateral correlation length SiGe(001) layers on Si(001) example Why sometimes we need channel analyzer What can we learn from reciprocal space maps SrRuO3(110) on SrTiO3(001) example Summary

3 What is thin film/layer?
Material so thin that its characteristics are dominated primarily by two dimensional effects and are mostly different than its bulk properties Source: semiconductorglossary.com Material which dimension in the out-of-plane direction is much smaller than in the in-plane direction. A thin layer of something on a surface Source: encarta.msn.com

4 Epitaxial Layer A single crystal layer that has been deposited or grown on a crystalline substrate having the same structural arrangement. Source: photonics.com A crystalline layer of a particular orientation on top of another crystal, where the orientation is determined by the underlying crystal. Homoepitaxial layer the layer and substrate are the same material and possess the same lattice parameters. Heteroepitaxial layer the layer material is different than the substrate and usually has different lattice parameters.

5 Thin films structural types
Structure Type Definition Perfect epitaxial Single crystal in perfect registry with the substrate that is also perfect. Nearly perfect epitaxial Single crystal in nearly perfect registry with the substrate that is also nearly perfect. Textured epitaxial Layer orientation is close to registry with the substrate in both in-plane and out-of-plane directions. Layer consists of mosaic blocks. Textured polycrystalline Crystalline grains are preferentially oriented out-of-plane but random in-plane. Grain size distribution. Perfect polycrystalline Randomly oriented crystallites similar in size and shape. Amorphous Strong interatomic bonds but no long range order. P.F. Fewster “X-ray Scattering from Semiconductors”

6 What we want to know about thin films?
Crystalline state of the layers: Epitaxial (coherent with the substrate, relaxed) Polycrystalline (random orientation, preferred orientation) Amorphous Crystalline quality Strain state (fully or partially strained, fully relaxed) Defect structure Chemical composition Thickness Surface and/or interface roughness

7 Overview of structural parameters that characterize various thin films
Thickness Composition Relaxation Distortion Crystalline size Orientation Defects Perfect epitaxy Nearly perfect epitaxy Textured epitaxy Textured polycrystalline Perfect polycrystalline Amorphous P.F. Fewster “X-ray Scattering from Semiconductors”

8 Relaxed Layer Cubic: aL> aS Cubic (00l) (10l) (20l) (000) (100)
(200) Cubic: aL> aS Cubic

9 Tetragonal Distortion
cL aL aL=aS aS aS aS aS Before deposition After deposition

10 Strained Layer Tetragonal: aIIL = aS, aL > aS Tetragonal
(000) (100) (200) Tetragonal: aIIL = aS, aL > aS Tetragonal distortion Cubic

11 Perfect Layers: Relaxed and Strained
(hkl) (hkl) Reciprocal Space (000) (000) aL > aS Cubic Tetragonal Cubic Cubic

12 Scan Directions Reciprocal Lattice Point q q Symmetrical Scan
Diffracted beam Incident beam Scattering vector q q (000) (00l) (hkl) Symmetrical Scan Asymmetrical (00l) scan (h00) scan (h00) (-hkl) Relaxed Layer Strained Layer

13 Scan Directions Symmetrical Scan q - 2q scan q 2q Asymmetrical Scan
(hkl) Asymmetrical Scan w - 2q scan a a = q - w w 2q Sample Surface

14 (00l) Scan Directions (hkl) Sample Surface

15 Scan directions w scan w scan 2q scan Symmetrical w - 2q scan
(hkl) w scan w scan 2q scan Symmetrical w - 2q scan Asymmetrical w - 2q scan Sample Surface

16 Real RLP shapes cL < aS Finite thickness effect L S Homoepitaxy
Heteroepitaxy Tensile stress Heteroepitaxy d-spacing variation Heteroepitaxy Mosaicity

17 Partially Relaxed Partially Relaxed + Mosaicity (00l) (00l) (hkl)
(000) (00l) (hkl) Partially Relaxed (00l) (hkl) (000) Partially Relaxed + Mosaicity

18 Defined by receiving optics (e.g. slits)
w-2q direction (00l) Defined by receiving optics (e.g. slits) w direction Mosaicity (000)

19 Symmetrical Scan receiving slit analyzer crystal d-spacing variation
mosaicity Symmetrical Scan (000) (00l) w direction w-2q direction

20 (002) SrTiO3 With receiving slit With channel analyzer (220) SrRuO3

21 Mismatch True lattice mismatch is:
Si(004) SiGe(004) The peak separation between substrate and layer is related to the change of interplanar spacing normal to the substrate through the equation: If it is (00l) reflection then the “experimental x-ray mismatch”: And true mismatch can be obtained through: where: n – Poisson ratio

22 Layer Thickness Interference fringes observed in the scattering pattern, due to different optical paths of the x-rays, are related to the thickness of the layers Substrate Layer Separation S-peak: L-peak: Separation: Omega(°) Omega(°) Omega(°) 2Theta(°) Theta(°) Theta(°) Layer Thickness Mean fringe period (°): Mean thickness (um): ± 0.003 2Theta/Omega (°) Fringe Period (°) Thickness (um) _____________________________________________________________________________

23 Relaxed SiGe on Si(001) Shape of the RLP might provide much more information

24 w-scan h-scan w-2q scan l-scan Symmetrical Asymmetrical Scan Scan
(hkl) (00l) (hkl) Symmetrical Scan Asymmetrical Scan (000) (h00) (000) (h00) scan

25 Relaxed SiGe on Si(001) (oo4) RLM Si(004) SiGe(004)

26 w-scan w-2q scan (00l) (hkl) (000) (004) (113)

27 Mosaic Spread and Lateral Correlation Length
The Mosaic Spread and Lateral Correlation Length functionality derives information from the shape of a layer peak in a diffraction space map recorded using an asymmetrical reflection The mosaic spread of the layer is calculated from the angle that the layer peak subtends at the origin of reciprocal space measured perpendicular to the reflecting plane normal. The lateral correlation length of the layer is calculated from the reciprocal of the FWHM of the peak measured parallel to the interface. MS To Origin QZ LC QX

28 Superlattices and Multilayers
dhkl Substrate

29 Superlattices and Multilayers
2 (000) (00l) 4 (000) (00l) 6 (000) (00l) 10 (000) (00l)

30

31

32 Orthorhombic Tetragonal Cubic
Structure of SrRuO3 Orthorhombic Tetragonal Cubic a = Å b = Å c = Å a = Å c = Å a = Å C C

33 (110) (001) SrRuO3 (1-10) (001) (010) SrTiO3 (100)

34 X-ray Diffraction Scan Types
w – 2q scan Reciprocal Space Map Q scan (-2 0 4) (0 0 2) SrTiO3 (2 0 4) (2 2 0) SrRuO3 (2 6 0) (4 4 4) (6 2 0) (4 4 –4) Tetragonal SrRuO3 Orthorhombic SrRuO3 a b

35 Finite size fringes indicate well ordered films
w – 2q symmetrical scans SrTiO3 (002) Thickness 3200 Å SrRuO3 (220) Finite size fringes indicate well ordered films SrTiO3 (002) Thickness 3100 Å SrRuO3 (220)

36 Reciprocal Lattice Map of SrRuO3 (220) and SrTiO3 (002)
w – 2q scan (0 0 2) SrTiO3 Distorted perovskite structure: Films are slightly distorted from orthorhombic, g = 89.1 – 89.4 (2 2 0) SrRuO3 f angle 0o o o o Substrate 5.53 Å 5.58 Å g (110) (100) (010) Layer

37 High-Resolution Reciprocal Area Mapping
b Orthorhombic SrRuO3 Substrate Layer Orthorombic to Tetragonal Transition (260) (444) (620) (444)

38 Transition Orthorhombic to Tetragonal ~ 350 C
Cubic Literature: C Transition Orthorhombic to Tetragonal ~ 350 C

39 Structural Transition, (221) reflection
(221) Peak Orthorhombic Present Tetragonal Absent O – T Transition Tetragonal Orthorhombic Cubic Literature: C Transition Orthorhombic to Tetragonal ~ 310 C Transition Orthorhombic to Tetragonal ~ 310 C

40 Structural Transition, (211) reflection
(211) peak is absent in cubic SrRuO3 a

41 Structural Transition, (211) reflection
O – T Transition = 310 oC Tetragonal Attempt for T – C Transition ? Orthorhombic Cubic

42 Refined Unit Cells We used (620), (260), (444), (444), (220) and (440) reflections for refinement a b c g V PLD 1 5.583 5.541 7.807 90.0 89.2 241.52 PLD 2 7.811 241.61 PLD 3 5.590 5.544 7.809 89.1 242.03 PLD 4 7.810 MBE 1 5.572 5.534 7.804 89.4 240.64 MBE 2 5.577 5.528 7.808 240.70 MBE 3 5.578 5.530 7.812 240.98 MBE 4 240.88 MBE 5 5.574 5.531 7.806 90.1 240.63 Bulk 5.586 5.550 7.865 243.85 242.5 242.0 PLD 241.5 Volume (Å) 241.0 MBE 240.5 240.0 Sample # (RRR) PLD 1 (3) PLD 2 (3) PLD 3 (4) PLD 4 (5) MBE 1 (10) MBE 2 (18) MBE 3 (26) MBE 4 (40) MBE 5 (60)

43 Summary Reciprocal space for epitaxial thin films is very rich.
Shape and positions of reciprocal lattice points with respect to the substrate reveal information about: Mismatch Strain state Relaxation Mosaicity Composition Thickness …. Diffractometer instrumental resolution has to be understood before measurements are performed.

44 Preferred orientation
Single crystal Polycrystalline


Download ppt "Tuesday, May 15 - Thursday, May 17, 2007"

Similar presentations


Ads by Google