MOL-33236 X-ray Diffraction, 5 cr

Additional information

This course is suitable for post graduate studies, but not recommended as such for Materials Science students. Materials Science students with specific needs in XRD should talk to their superviser and Dr. Hokka for a tailored implementation with better suitability for PhD studies.
Suitable for postgraduate studies

Person responsible

Mikko Hokka

Lessons

Implementation 1: MOL-33236 2015-01

Study type P1 P2 P3 P4 Summer

Lectures
Assignment

4 h/per
40 h/per
+4 h/per
+40 h/per

Lecture times and places: Wednesday 12 - 15 K3104

Requirements

Examination on lectures and literature. Passed exercises.

Learning Outcomes

After completing this course the student knows and understands the basics of X-Ray diffraction. S/he can explain what factors influence the directions of diffracted beams, and s/he understands and can explain quantitatively what factors influence the intensities of the diffracted beams. S/he can describe the basics of most used application techniques, including quantitative and qualitative chemical analysis, texture, residual stress, and small angle x-ray scattering. The student can solve some basic problems typically encountered in material characterization with X-Ray diffraction. The student can also plan tests, analysis, and specimen preparation procedures for solving various simple scientific problems.

Content

Content Core content Complementary knowledge Specialist knowledge

1. Bragg's law and its applications. Interaction of XRays with crystalline material. Calculations of theoretical intensity

2. Applications of XRD in materials science; including but not limited to quantitative and qualitative (Rietveld) chemical analysis, texture, stress, and SAXS. Mathematical analyses of obtained data, such as line profile analysis, crystallize size measurement, and details of the Rietveld analysis.

3. Operation and structure of a modern XRD diffractometer Practical work with a diffractometer Performing and designing special tests

Study material

Type Name Author ISBN URL Additional information Examination material

Book Elements of X-Ray Diffraction, 3rd ed. B.D.Cullity, S.R. Stock Available as an Ebook Yes

Book Two Dimensional X-Ray Diffraction Bob He Available as an Ebook through library database Yes

Other literature X-Ray Diffraction Lecture Notes Veli-Tapani Kuokkala Yes

Prerequisites

Course Mandatory/Advisable Description

MOL-11220 Kideoppi Mandatory

MOL-11230 Materiaalitieteen tutkimusmenetelmät Mandatory

Correspondence of content

There is no equivalence with any other courses

Last modified 24.03.2015

Study type	P1	P2	P3	P4	Summer
Lectures Assignment			4 h/per 40 h/per	+4 h/per +40 h/per

Content	Core content	Complementary knowledge	Specialist knowledge
1.	Bragg's law and its applications. Interaction of XRays with crystalline material.	Calculations of theoretical intensity
2.	Applications of XRD in materials science; including but not limited to quantitative and qualitative (Rietveld) chemical analysis, texture, stress, and SAXS.	Mathematical analyses of obtained data, such as line profile analysis, crystallize size measurement, and details of the Rietveld analysis.
3.	Operation and structure of a modern XRD diffractometer	Practical work with a diffractometer	Performing and designing special tests

Type	Name	Author	ISBN	URL	Additional information	Examination material
Book	Elements of X-Ray Diffraction, 3rd ed.	B.D.Cullity, S.R. Stock			Available as an Ebook	Yes
Book	Two Dimensional X-Ray Diffraction	Bob He			Available as an Ebook through library database	Yes
Other literature	X-Ray Diffraction Lecture Notes	Veli-Tapani Kuokkala				Yes

Course	Mandatory/Advisable	Description
MOL-11220 Kideoppi	Mandatory
MOL-11230 Materiaalitieteen tutkimusmenetelmät	Mandatory