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Highresolution Electron Microscopy

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Goal: to reconstruct the atomic structure. Phase object ... Not necessarily corresponding to atomic structure: Projection of the potential ... – PowerPoint PPT presentation

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Title: Highresolution Electron Microscopy


1
Do we know the arrangement of atoms ?
High-resolution Electron Microscopy
HREM
2
Introducing the optical transfer function of the
lens system
r1Mr0
r0r0
S0(r0)
S1(r1)
System corresponding function
3
Fourier transform
Object diffraction pattern
Object transmission function
F
F
Image diffraction
Image wave function
T(u)
4
Effects of aberrations and astigmatism on the
transfer function
Defocus
Define q
5
Spherical aberration
?r
a
6
Chromatic aberration
V0 ?V0
V0
?ri
a
ai
U
V
?V
For electro-magnetic lens
7
Astigmatism
8
The transfer function of the objective lens
9
Explanation of the high-resolution image
  • Amplitude contrast vs. phase contrast
  • Amplitude contrast
  • Thick sample
  • Single beam or two beam condition
  • Wave amplitude modified
  • Phase contrast
  • Very thin sample
  • Many beam condition
  • Only phase modified

Goal to reconstruct the atomic structure
10
Phase object
For an ideal concept, when electron wave passing
through an object, only its phase but not the
amplitude changes
Change of the phasefield of potential
f (x,y,z)
z
11
Defining interaction constant
Integrate the whole thickness z
Projected potential along z direction
The transmission function of an ideal phase object
12
Weak phase object approximation
For light element/thin specimen
On the back focal plane, introduce the transfer
function
Then on the image plane
13
Contrast on the image plane
Ignore the second order terms of sf
Ignore the chromatic aberration in the transfer
function
O-Phase contrast diffraction sF
Phase contrast diffraction AC
F
O-Phase difference sf
F
Phase contrast C
A(u)
14
About
F
V
Rayleigh
Resolution defined by the diffraction limit
The effect is usually ignored
15
About
Contrast transfer function
However, if we take
16
  • In practice, the constant CTF is only an
    approximation due to the complicated form of Sinc
  • A wide constant band only occurs when Df lt 0 and
    c(u,v) is close to -p/2

Scherzer defocus
17
  • The wide bandsimilar phase shift on q(x,y),
    makes it possible to reconstruct the details of
    material structure without much distortion
  • Point resolution
  • The 1st zero crossing at Scherzer defocus
  • It corresponds to intuitively interpretable
    resolution for very thin sample
  • Image not at Scherzer defocus does not
    necessarily show the information up to point
    resolution correctly

18
Defocus effect
19
Spherical aberration effect
20
Electron wave length effect
21
Projected charge density approximation
If we ignore the OBJA and spherical aberration
Assuming ?f ltlt1
Knowing that
22
For phase object
23
Ignore higher order terms of s and ?f
24
Projection of electron density
  • ?f 0, zero contrast in the absence of
    aberration
  • ?f gt0, underfocus condition, C(x,y) lt0, the
    higher r is, the darker the area
  • ?f lt0, overfocus condition

Assumption ?f is not very large The contrast
is linear proportional to the defocus value
25
PCD vs. WPO
Thicker specimen Heavier elements
However, the Cs is ignored in the above analysis
Explanation of HREM image
  • The origin of HREM image
  • Interference of scattered (by the material)
    waves
  • Not necessarily corresponding to atomic
    structure
  • Projection of the potential
  • System imperfections

26
Coherence
  • Temporal coherence the electron wave is not
    monochromatic
  • native energy difference
  • Instability of the high-voltage system

Path difference between the two scattered waves
27
Spacial coherence the source is not an ideal
geometrical point
P1
P
P2
Coherence
Incoherence
28
Coherence effect on high-resolution imaging
K00
K0 wave vector (incident) in the reciprocal
space ri a point on the image plane (real
space) F(K0) distribution of the incident wave
vector
29
Define
30
Ideal coherence
Incoherence
31
Partial coherence
The information limit
when the damping envelope is too small, the
information is considered not transferable any
more
32
The concept of resolution
  • Rayleigh resolution (diffraction limit)
  • Not applicable
  • Resolution defined by lens aberrations and
    defocus value Normally referred to as the point
    resolution
  • Can be extended to smaller values through
    defocus series
  • Resolution defined by spatial coherence of the
    illumination source
  • A more precise concept is the information limit
    for the microscope
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