dedicated to the memory of z.g.pinsker. (on the occasion of his 100 th anniversary ) electron...
TRANSCRIPT
Dedicated to the memory of Z.G.Pinsker. (on the occasion of his 100th anniversary)
ELECTRON DIFFRACTION STRUCTURE ANALYSIS,
PART 1.
Vera KLECHKOVSKAYA
Institute of Crystallography, Russian Academy of Sciences
SPECIMENS AND THEIR ELECTRON DIFFRACTION PATTERNS.
The basic modern data describing the atomic structure of matter have been obtained by the using of three diffraction methods – X-ray, neutron and electron.
Electron diffraction structure analysis is generally used to study thin films and finely dispersed crystalline materials and allows the complete structure determinations up to establishment of the atomic coordinates in the crystal lattice and refinement of atomic thermal vibrations and chemical bounding.
All three radiations are used not only for the structureanalysis of various crystals but also for the analysis of other condensed state of matter – quasi crystals, incommensurate phases, and partly disordered systems, namely, for high-molecular polymers, liquid crystals, amorphous substances and liquids, and isolated molecules in vapor and gases. analysis of various crystals but also for the analysis of other condensed state of matter – quasi crystals, incommensurate phases, and partly disordered systems, namely, for high-molecular polymers, liquid crystals, amorphous substances and liquids, and isolated molecules in vapor and gases.
SCHEMATIC ILLUSTRATING BRANCHES OF MODERN CRYSTALLOGRAPHY, THEIR APPLICATIONS, AND THE RELATION OF CRYSTALLOGRAPHY TO THE NATURAL
SCIENCES
“Heart”of this scheme
ZINOVII PINSKER BORIS VAINSHTEIN
1904 – 1986 1921 - 1996
“The PARENTS” OF ELECTRON DIFFRACTION STRUCTURE ANALYSIS
Electron Diffraction Camera have been constructed by Z.Pinsker and B.Vainshtein -- gold medal on the International Exhibition in Brussels, 1958.
the classical monographs:
B.K.Vainshtein (1964) Structure analysis by electron diffraction. Oxford, Pergamon Press (in Russia,1956)
Z.G.Pinsker (1953) Electron diffraction. London: Butterwords (in Russia, 1949)
MAIN STAGES OF ATOMIC STRUCTURE ANALYSIS
the obtaining of appropriate diffraction patterns and their geometrical analysis, the precision evaluation of diffraction-reflection intensities, the use of the appropriate formulas for recalculation of the reflection intensities into the structure factors, Ihkl
~ Kkin |F hkl |2 + K dyn |F hkl |
the solution of the phase problem, Fourier analysis of the structure. xyz) = 1/ Fhkl exp[2 i (hx+ky+lz)] hkl
ELECTRON DIFFRACTION PATTERNS
transmissionand reflectionmode
ELECTRON DIFFRACTION PATTERNS FOR STRUCTURE ANALYSIS
ONLY THREE TYPE SPECIMENS AND ELECTRON DIFFRACTION PATTERNS MAY BE USED FOR ATOMIC STRUCTURE ANALYSIS
UNKNOWN PHASESUNKNOWN PHASES
MOSAIC SINGLE CRYSTAL PLATELIKE TEXTURE POLYCRYSTAL
EWALD CONSTRUCTION FOR X-RAY END ELECTRON
k0, k – wave-vectors,
- wave – length,
a*, b* - parameters of reciprocal unit cell
THE RECIPROCAL LATTICE NET IS SAMPLED BY AN EWALD SCHERE ON RADIUS k0 =1/ .SINCE THE WAVELENGTH OF A 100 kV ELECTRON BEAM IS SOME 40 TIMES AS SMALL AS THAT OF A CuK X-RAY, IT IS OFTEN A SUFFICIENT APPROXIMATION TO SAY THAT THE EWALD SAMPLING SURFACE IS A PLANE IN THE CASE OF ELECTRONS .
GEOMETRICAL ASPECTS OF ELECTRON DIFFRACTION
SPOT-TYPE ELECTRON DIFFRACTION PATTERNS
A CRYSTAL REPRESENT A THREE DIMENTIONAL PERIODIC DISTRIBUTION OF SCATTERING MATERIAL. THE DISTRIBUTION OF POINTS AT WHICH THE SCATTERING AMPLITUDE DIFFERS FROM ZERO AND TAKES ON THE VALUE Fhkl IS PERIODIC IN RECIPROCAL SPACE AND FORMS THE SO-CALLED RECIPROCAL LATTICE
Hhkl = ha* + kb* = lc*a*, b*, c* are axial vectors,h,k,l are point indices
A SPOT PATTERN REPRESENTED A PARTICULAR PLANE OF THE RECIPROCAL LATTICE PASSING THROUGH OF THE POINT 000
INDEXING OF AN ELECTRON DIFFRACTION PATTERN OF MOSAIC SINGLE CRYSTAL
A spot pattern is most conveniently characterized by the general symbol of the reflection located on it. If the plane is a coordinate one of the indices must be equal to zero since the point 000 always lies in it. If the plane is non-coordinate, then none of its three indices (hkl) is equal to zero.
Coordinate plane Non-coordinate plane
SYMMETRY OF ELECTRON DIFFRACTION SPOT PATTERNS
Schematic representation of the structure of the zero layer of the reciprocal lattice for the six classesof geometry in spot electron diffraction patterns
The existence of a centre of symmety at a point 000 of the reciprocal lattice of symmetry being recognizable in diffraction phenomena, for only 11 classes of symmetry being recognizable in diffraction phenomena, although 32 classes of crystal symmetry exist. The symmetry of electron diffraction pattern is the symmetry of the plane nets of reciprocal lattice.
The relationships between the axis and anglesin unit cells:
Triclinic: a b c Monoclinic: a b c = Orthorhombic: a b c = = =900
Hexagonal: a = b c = = 900 Tetragonal: a = b c = = = 900
Cubic: a = b = c = = = 900
Having only one plane of reciprocal lattice for unknown crystal we can`tdetermined – this is coordinate odernon-coordinate plane. And we havenot an information about perpendicular direction for this plane.
Interrelationship between three reciprocal lattice section, i.e.
between three electron diffraction
patterns of different zones.
Schematic representation of the rotation method
There are two way:rotation method and
to have three patterns of different zones
POLYCRYSTAL-TYPE ELECTRON DIFFRACTION PATTERN
Electron diffraction patterns from samples containing very large number of small randomly distributed crystals consist of continuous rings. The radii of the rings are inversely proportional to the interplanar spacings dhkl of a latticeplanes of crystals. The formula rhkl dhkl = L , (r- radius of the ring)is used.
In reciprocal lattice of a polycrystal is obtained by “spherical rotation” of a reciprocal lattice of a single crystal around a fixed 000 point. It forms a system of sphere placed one inside the other.
A section through such a system of spheres produces a system of rings. Thus geometry of a polycrystalline pattern is a set of lengths Hhkl, i.e. a set of interplanar distances dhkl of a crystal lattice.
The calculation for orthogonal lattices
Simple division gives all dh00 = a/h, and, analogously, d0k0 and d00l. Further , using the scale, all dhk0 are found from (dhkl) = (dhk0) + (doko),then by fixing first l = 1 (one setting of the movable scale) and finding all dhk1, and repeating this operation
METHOD OF INVERSE SQUARES
The quadratic form for orthorhombic crystals is: 1/d2
hkl = h2/a2 + k2/b2 + l2/c2.
a – inverse scuares scale, b – method of finding dhk by using the mouvable scale
OBLIQUE TEXTURE ELECTRON DIFFRACTION PATTERNS
Distribution of reciprocal lattice points Distribution of circular scattering of a plate texture along straight lines regions of the reciprocal lattice of a parallel to the texture axis and texture on coaxial cylinders.perpendicular to the face lying on thesupport.
FORMATION of the circular scattering regions (rings) in the reciprocal lattice of a texture, and relationship
between their shape and the structure of the specimen
Transition from a point to a ring (a),for an ideal texture without disorder (c) and having distribution function (e)(d,f) – corresponding diagrams for a real texture with some disorder.
PROJECTION NET AND THE CORRESPONDING SET OF Rhk VALUES
FIVE PLANE CRYSTALLOGRAPHIC SYSTEMS OF POINTS
If there are layer lines on the pattern(for orthogonal lattice), for a zero layer line, Rhk = Hhk0. Thus having a set of values : R2
hk = h2A2 + k2B2 + 2hkAB cos ` R = r (L)-1
We can determined constant A,B, ` ofThe two-dimensional lattice.
DETERMINATION OF PERIOD c* and ANGLES
The best formed plate textures are found in crystals with a layer lattice. For the reciprocal lattice of plate texture, the distribution of points along vertical strain lines, parallel to axis z, is characteristic. An important part is played by the modulus of vector Hhkl.
Hhkl = x2 + y2 + z2 =R2 + z2
Orthogonal unit cells
The doubling of the number of circular scattering regions in the reciprocal lattice of a texture and therefore the number of reflections on the ellipse of a pattern for a non-orthogonal unit cell.
CONCLUSION
Mosaic single crystal, polycrystal, texture electron diffraction patterns provide valuable material for calculation the parameters of unit cell and then may be used for complete structural investigations of the crystal with unknown atomic structure.