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XRD XRay Diffraction

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X-rays are generated by striking a target material with an accelerated e- which ... an infinite number of planes can exist, but certain ones diffract more strongly ... – PowerPoint PPT presentation

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Title: XRD XRay Diffraction


1
XRD X-Ray Diffraction
2
X-rays
  • Another part of the electromagnetic spectrum
    between 100 and 0.2 Å.
  • Plancks law Ehn hc/l
  • Where n is frequency, l is wavelength, h is
    Plancks constant, and c is the speed of light

3
X-ray generation
  • X-rays are generated by striking a target
    material with an accelerated e- which causes an
    excitation. When his excitation relaxes, or
    goes back down to standard state, an X-ray is
    emitted
  • Usually given in terms of the energy levels those
    e- come from and go to ? different levels yield
    X-rays of different energies (all dependent on
    the material)
  • K, L, M shells of a material, from that those
    shells have different transitions and
    characteristic relaxations (a, b, g)
  • Cu Ka is the most intense peak and most commonly
    used (though others are possible and have a
    different wavelength, which can be useful!)

4
X-Ray interaction
  • Scattering oscillation of incoming X-rays
    transfer energy to electrons in material,
    emitting secondary radiation at about the same
    frequency and energy as the incoming beam
  • Interaction of X-rays with same material causes
    some electrons to go into an excited state, which
    upon relaxation, emits radiation characteristic
    of the atom it excited ? basis for XRF, used to
    identify chemical makeup of materials
  • As with other interactions with minerals, there
    can also be reflection and transmission of X-rays
    (depending on thickness), but we dont typically
    use that information.

5
Interference
  • Constructive and destructive interference wave
    properties interact to either cancel out or
    amplify each other.
  • When 2 centers are emitting energy at some
    wavelength, they will interfere with each other

Plane view
6
Experiment
  • Relationship between light as particles vs. light
    as waves
  • Light scattered by mesh - as it travels and
    interacts, some waves compliment each other while
    different waves cancel each other

7
Diffraction
  • Combine elements of interference with striking
    the x-ray at an angle to the material
  • Relationship between wavelength, atomic spacing,
    and angle of diffraction for 3-D structures
    derived by von Laue
  • Braggs determined that you could simplify this
    and treat it as a reflection off of the planes
    within an atom

8
Braggs Law
  • nl2dsinT
  • Where n is the order of diffraction (always an
    integer), l is the wavelength of incident
    radiation, d is the spacing between planes, and T
    is the angle of incidence (or angle of
    reflection, they are equal)

9
Diffraction
  • Relationship between diffraction and wavelength
  • The smaller the diffracting object, the greater
    the angular spacing of the diffraction pattern
  • i.e. the smaller the separation between planes,
    the wider the spacing between diffraction lines
  • What then is diffraction??
  • The failure of light to travel in straight lines
    (much to Newtons dismay)
  • Youngs 2 slit experiment proved light could bend
    scattered and affected by constructive and
    destructive interference
  • Bright red constructive dark destructive

10
Braggs Law
  • nl2dsinT
  • Where n is the order of diffraction (always an
    integer), l is the wavelength of incident
    radiation, d is the spacing between planes, and T
    is the angle of incidence (or angle of
    reflection, they are equal)
  • Diffraction here is between parallel planes of
    atoms ? the space between them (d) determines the
    angle of diffraction.
  • Looking at the laser pattern again ? where is
    Braggs Law satisfied and how many orders of
    diffraction do we see?

11
Red Laser analogue
  • We see orders of diffraction resulting from light
    coming between grid spacing 2, 3, 4, 5, etc.,
    apart. In a mineral, multiple parallel planes
    yields similar patterns at higher orders of
    diffraction theoretically the angle keeps
    increasing ? what do we notice about the
    intensity though?

12
Braggs Law
  • nl2dsinT
  • Just needs some satisfaction!!

13
X-Ray Diffraction (XRD) equipment
XRD machines vary angle as 2T because that angle
is always relative to incident X-ray beam
trajectory
  • nl2dsinT
  • nl/2dsinT
  • Solution satisfied at specific angles (n MUST
    be an integer)

2T
14
XRD Part II
  • Theoretically, almost an infinite number of
    planes can exist, but certain ones diffract more
    strongly
  • Related to the atomic density both of of
    atoms and in those ions atomic density

15
XRD results
  • Diffraction pattern
  • Higher symmetry ? fewer, more intense lines
    because multiple planes are complimentary
    (identical d-spacings for different planes yields
    identical diffraction)

16
pyrite
fayalite
17
XRD extinctions
  • Some forms exhibit extinctions when planes
    should be present (i.e. satisfy Braggs Law) but
    are not due to destructive interference with
    another planes diffraction.
  • Useful for determining special conditions of
    symmetry in a single crystal ID for body, face
    centered minerals as well as ones with screw axes
    and glide planes ? method to see differences
    between space groups

18
XRD analyses
  • Can look at minerals as single crystals or as a
    powder
  • Single Crystal ? must be careful about orienting
    the crystal so Braggs Law is satisfied, use
    several different techniques, advanced machines
    manipulate the sample in 3 axes (x,y,z) to
    catch all the peaks ? required for structural
    determination
  • Powder has many particles with planes at many
    different orientations ? many orientations
    satisfy Braggs Law, intensities and locations
    (2T) are characteristic of specific minerals.
    Technique primarily used for identification

19
Powder XRD analyses
  • With a single crystal, alignment of planes which
    give strong diffraction returns is very exact
    requires precise alignment
  • With a fine powder, idea is to have crystals at a
    wide variety of orientations so hitting that
    exact alignment is possible without manipulating
    the sample i.e. in a powder we figure a few
    grains are lined up correctly

20
Powder X-ray Analyses
  • XRD analysis of a powder is a common, quick, and
    relatively easy way to identify minerals.
  • Having a mixture of minerals can be tricky, so
    grains are first separated if possible (small
    amounts of other minerals will give other peaks,
    but intensities are low enough that it is not a
    big deal)
  • Do lose the ability to see the details of the
    structure of the mineral however as the precise
    alignment of the mineral giving the peak is
    unknown and not changeable
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