Spatial Frequency and Transfer Function. columns of atoms, where the electrostatic potential is higher than in vacuum

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Image Formation Spatial Frequency and Transfer Function consider thin TEM specimen columns of atoms, where the electrostatic potential is higher than in vacuum electrons accelerate when entering the specimen wavelength decreases interaction of a plane wave 0 with the specimen merely introduces a (spatially varying!) phase shift s [r], such that e = 0 Exp[ i s [] r ] imaging with an ideal lens yields an image with the intensity distribution []= F 1 F 0 Exp i s [] r I r [ [ [ ]]] 2 = 0 Exp[ i s [ r] ] 2 2 = 0 213

no contrast! (compare explanation of phase contrast ) real lens, however: finite aperture truncates spectrum in the focal plane lens aberrations cause additional phase shifts distortion of the Fourier spectrum prior to inverse Fourier transformation distortion of image wave function i analogy: audio amplifier amplifier has particular transfer characteristics different audio frequencies (basses, trebles) are transferred with different quality HRTEM: consider crystal: periodic repetition of a motive in space period: a The repeat rate a 1 of a motive that occurs with a period a in space is denoted as Dimension: m 1. spatial frequency. special case: lattice planes of a crystal, parallel to the primary beam, plane spacing d 214

Bragg condition for small diffraction angles: = 2d Sin[ B ] 2d B = d diffraction angle is proportional to the spatial frequency d 1 : = d 1 the spatial frequency d 1 corresponds to the length of the scattering vector q = k k 0, which lies approximately normal to the primary beam: d 1 = = k k 0 = q spatial frequency corresponds to audio frequency in the example of an audio amplifier microscope (objective lens) has particular transfer properties different spatial frequencies ( basses, trebles ) are transferred with different quality note: contrast is obtained only because the transfer is not ideal mathematical description of the transfer properties: transfer function Example: Effect of a Limited Aperture circular aperture in the focal plane limits the spectrum of plane waves with wave vectors k that can contribute to the image aperture function: A[ k]= 1 k x,k y k a 0 otherwise k x, k y : components of the wave vector normal to the primary beam. 215

the wave at the exit surface of the specimen is e = 0 Exp[ i s [] r ] instead of f [ k]= F [ 0 Exp[ i s [ r] ]], however, the wave function in the focal plane is now [ [ []]] f [ k]=ak [ ] F 0 Exp i s r under these conditions, inverse Fourier transformation yields i r [ [ ]F [ 0 Exp[ i s [ r] ]]] = F -1 [ A[ k] ] F -1 F 0 Exp i s r []= F -1 A k [ [ [ []]]] the wave function i in the image plane is convoluted ( spread ) with the Fourier transform of the aperture function concrete example: A[k] and F 1 [A[k]] for different aperture sizes k a : Ak [ x ] Ak [ x ] F 1 k x F 1 k x [ ] F -1 [ Ak [ x ]] F -1 Ak [ x ] x x 216

the narrower A[k], the broader F 1 [A[k]] and the larger the discrepancy between i (image wave function) and e (object wave function) Phase Shifts Introduced by the Objective Lens Spherical Aberration spherical aberration: the lens refracts rays far from the optic axis too strongly (compared with paraxial rays) in the image plane the ray far from the axis arrive at some distance r away from the ideal image point R s f ' B O g f lens b r = C s 3 M P relation between r and angle, at which the rays travel with respect to the optic axis on the object side: r = M C s 3 217

the constant proportionality factor C s characterizes the degree of spherical aberration Defocusing two possibilities: change object distance g by g change focal length f of the lens by f 218

Transfer Function spherical aberration and defocusing of a lens generate a phase shift of [ ]= s [ ]+ g [ ]+ f [ ] = 2 1 4 C s f 4 1 ( f g) R 2 2 f 2 R 4 f and g have the same effect, thus we always consider them together and denote f g as underfocus recalling R/f = we obtain for the phase shift introduced by the lens [ ]= 2 C s 4 2 expressing by the spatial frequency q = / that diffracts at (corresponds to th length of the scattering vector) yields the Phase shift introduced by the objective lens: []= q C s 3 q 4 /2q 2 Example JEM 4000 EX (JEOL) accelerating voltage: 400 kv de Broglie wavelength: 0.001644 nm spherical aberration: C s = 1,0 mm = 10 6 nm 219

phase shift [q] for spatial frequencies up to 10 nm 1 (spacings down to 0.1 nm) and different defoci : the minimum of [q] occurs where the first derivative of [q] with respect to q vanishes: 2C s 3 q 3 2q = 0 the positive, non-vanishing solution for q is 220

q = C s 2 the phase shift at the minimum amounts to C s 3 2 2C 2 s 4 C s 2 = 2 2 C s = C s 40 nm approximately yields the ideal phase shift of /2 over an extended interval of spatial frequencies ( Scherzer focus ) Ansatz for the mathematical describing the effect of limited aperture and phase shifts introduced by spherical aberration and defocusing: Transfer function Tq []= Aq [ ] []exp i [ q] q = q = u 2 + v 2 : length of the scattering vector; A[q] = A[k]: aperture function, A[ q ] = 1 for ( u 2 + v 2 ) < r 2, 0 otherwise; [ q ]: phase shift introduced by the lens. with this definition the wave function in the image plane is [ [ [ ]]] i [ x, y]= F 1 Tq []F e x, y assumption: completely coherent illumination (coherence potential for interference) 221

Image of a Weak Phase Object assumption: object (specimen) so thin that no absorption occurs pure phase object Vx, [ y, z] y z x d z t t/2 V t [ x, y]:= Vx, [ y,z]dz -t/2 phase shift after transmission through a layer of infinitesimal thickness dz (compared to wave through vacuum): d = [ x, y, z]d z [x,y,z]: variation of the electrostatic potential; : interaction constant 2( E 0 + eu ) ( U (2E 0 + eu ) 1. phase shift at location (x, y) at the exit surface of the specimen: t/2 [ x, y]= [ x, y, z]d z =: t x, y t/2 [ ] t : projected variation of the electrostatic potential projected potential. thus the (pure) phase object does nothing to a plane wave 0 = 1 but advance its phase (the phase shift depends on the spatial coordinates): e [ x,y]= 0 Exp[ i t [ x, y] ] Exp i t x, y [ [ ]] 222

additional simplifying assumptions: very thin object (a single atom of uranium would be too thick!) at every location (x,y) the phase shift is small compared to unity approximate exponential function linearly: Exp[ i t [ x, y] ] 1 i t [ x,y] image wave function of this (unrealistic!) object: [ [ [ ]]] [ ]q [ ] i F t [ x,y] i [ x, y]= F 1 Tq [ ]F 1 i t x, y = F 1 Tq [ ( [ ])] applying the convolution theorem F 1 [ fu [ ] gu [ ]]=F 1 [ fu []]F 1 gu [ [ ]] yields i [ x,y]= T [] 0 if 1 [ Tq [ ]F [ t [ x,y] ]] = 1 i t [ x,y]f 1 Tq [ ] [ ] the image of every object point is spread with t[x,y] := F 1 [T[q]] t[x,y] is denoted as point spread function or impulse response function intensity distribution in the image plane? split t[ x,y ] into real and imaginary part: 223

t[x, y] = c[x, y] + i s[x, y] since convolution is a linear operation, the wave function in the image plane becomes i [x, y] = 1 i t [x,y] c[x,y]+ t [x,y] s[x, y] intensity: I[x, y] i [x,y] 2 = i [x,y] i * [x, y] = 1+ 2 t [ x,y] s[x,y]+ 2 ( t [x,y] c[x,y] ) 2 + 2 ( t [x,y] s[x,y] ) 2 weak phase object: neglect 2 terms, Image intensity of a weak phase object: I[x, y] 1 + 2 t [x, y] s[x, y] interpretation: intensity varies proportional to the projected potential t the image of every object point is convoluted ( spread ) by s[x,y] by definition, s[x,y] is the imaginary part of the point spread function: [ ]= F 1 Aq []Exp i q F 1 Tq [ ] [ [ [ ]]] A[q] Exp[i [q]] has the form Aq [ ]Exp[ i [ q] ]= Aq [ ]Cos[ [] q ]+ i Aq [ ]Sin q A[q] and [q] are real-valued [ [ ]] 224

the imaginary part corresponds to the right term: Im[ Aq []Exp[ i [] q ]]= Aq []Sin q [ []] linearity of the Fourier transformation imaginary part of the Fourier transform corresponds to the Fourier transform of the imaginary part: [ [ []]] sx, [ y]= F 1 Aq []Sin q contrary to the case of the general phase object, the intensity distribution in the image of the weak phase object is entirely determined by the imaginary part [ [ [ ]]] Aq [ ]Sin[ [ q] ]= Im Aq []Exp i q of the transfer function A[q] Sin[[q]] is denoted as contrast transfer function ( do not confuse contrast transfer function with transfer function ) applying the convolution theorem yields [ [ []]] sx, [ y]= F 1 [ Aq []]F 1 Sin q for increasing aperture size A[q], F 1 [A[q]] approaches a delta function and F 1 [Sin[[q]] determines the point spread function: [ [ []]] sx, [ y] F 1 Sin q intensity distribution in the image of the weak phase object: [ [ [ ]]] I[x, y] 1 + 2 t [x, y] F 1 Sin q 225

Discussion of the Contrast Transfer Function Sin[[q]] < 0 implies positive constrast: atom columns appear dark (in the print, not the negative!) Sin[[q]] > 0 implies negative contrast: atom columns appear bright Sin[[q]] = 0 implies no transfer of the respective spatial frequency at all! even under the unrealistic assumption of imaging a weak phase object, the complex properties of Sin[[q]] hinder a straight-forward interpretation of HRTEM images example: hypothetical crystal with four different sets of planes parallel to the viewing direction plane spacings: d 1 > d 2 > d 3 > d 4 corresponding spatial frequencies: 1/d 1 < 1/d 2 < 1/d 3 < 1/d 4 226

the planes with spacing d 1 appear with positive contrast the planes with spacing d 2 appear with negative contrast the planes with spacing d 3 do not appear at all it is difficult to predict the contrast of the planes with spacing d 4 : fast oscillation of the transfer function at (d 4 ) -4 alignment (defocusing and direction of the primary beam) is not infinitely precise focal plane coordinate q is not exactly known avoid these problems by introducing an objective aperture at which spatial frequencies does the contrast transfer function Sin[[q]] exhibit minima, maxima, or a value of zero? at the exit surface of the specimen, the plane waves that represent the respective spatial frequency exhibit a phase shift of /2 versus the incident plane wave in order for regions of high projected potential to appear dark in the image, the electron optics needs to introduce an additional phase shift of /2 (modulo 2) minima in Sin[[q]] occur at spatial frequencies where the electron optics shifts the phase by /2 (modulo 2) accordingly, maxima occur where the electron optics shifts the phase by +/2 (modulo 2) the contrast transfer vanishes where the phase shift amounts to an integer multiple of in this case the phase difference of /2 with respect to the incident wave remains unaltered and no contrast results an ideal transfer of all spatial frequencies, in contrast, would require a transfer function of the following shape: 227

Sin[ [ q] ] +1 1 1 1 1 d 1 d 2 d 3 d 4 0 1 q actually, this ideal shape can be realized approximately over at least some extended intervals of spatial frequencies passbands under which conditions does Sin[[q]] exhibit a passband? [q] has a shallow minimum 0 at some spatial frequency q 0 > 0 a passband for positive phase contrast occurs if the minimum 0 lies at /2 (modulo 2) in this case the required phase shift of /2 extends over a certain interval of spatial frequencies in general, the minimum 0 of [q] occurs at the spatial frequency q 0 at which the first derivative of the phase shift with respect to the spatial frequency vanishes first derivation of the phase shift with respect to the spatial frequency (see above example of the JEM 4000 EX): 228

d dq []= q 2C s 3 q 3 2q = 2q ( C s 2 q 2 ) since > 0 and q 0 > 0, the condition for the spatial frequency q 0 at which [q] adopts its minimum reduces to: C s 2 q 0 2 = 0 thus q 0 = C s 2 therefore, a first passband occurs if C s 2 = 2 the phase shift 0 [q 0 ] at this spatial frequency amounts to 0 = C s 3 C s 2 4 /2 = 2 2C s 2 = 2 2C s C s C s 2 2 phase shift and contrast transfer function for = C s (most important case, see above example of the JEM 4000 EX and section Scherzer focus ): 229

the first passband for negative phase contrast needs to fulfill the condition 3 C s 2 = 2 (this corresponds to a phase shift of +/2) in analogy to the first passband for positive phase contrast this condition implies an underfocus of = 3 C s 230

phase shift and contrast transfer function for = 3 C s : [ q] +2 + 0 2 Sin[ [ q] ] q +1 0 1 q in general, one obtains passbands in the contrast transfer function at defoci of the form = n C s n = 1, 3, 5, n = 1, 5, 9, yields passbands for positive phase contrast (atom columns dark in the image) 231

n = 3, 7, 11, yields passbands for negative phase contrast (atom columns bright in the image) even n do not yield passbands at all Scherzer Defocus and Point Resolution the defocus at which the first passband occurs in the contrast transfer function Sin[[q]] plays a particularly important role at this defocus the contrast transfer function most closely resembles the contrast transfer function of an ideal microscope with increasing underfocus, the first passband occurs when the phase shift [q] amounts to about /2 for an extended interval of spatial frequencies in particular, a passband occurs if the minimum 0 of [q] adopts the value of /2 (see above) the corresponding defocus is known as Scherzer (de)focus: S = C s the larger the width of the passband, the larger the interval of spatial frequencies that the microscope can transfer in an intuitively interpretable way which defocus 0 yields a passband of maximum width? 232

Ansatz for the allowed interval of phase shifts 2 3 [ q]1 3 this yields a minimum phase shift of 0 = 2 3 insert in the expression for the phase shift 0 [q 0 ] (see above): 0 2 2C s = 2 3 solving for the defocus yields: 0 = 4 3 C s result: a first passband of maximum width results from a defocus 4/3 1.2 larger than Scherzer defocus since this defocus optimizes the resolution (when imaging a weakphase object), it is designated as Optimum defocus: 0 1.2 C s 1.2 Scherzer comparison between Scherzer defocus and optimum defocus: 233

[ q] +2 + 0 2 Scherzer Defokus Optimaler Defokus Sin[ [ q] ] +1 0 Optimaler Defokus Scherzer Defokus q q P 1 q up to the first zero of the contrast transfer function the microscope transfers all spatial frequencies with similar phase shifts and contrast spatial frequencies within the first passband, therefore, are directly resolved in the image (intuitively interpretable) the maximum width of the first passband determines the point resolution a broader passband implies intuitively interpretable transfer of higher spatial frequencies and thus smaller spacings 234

the point resolution d P of the microscope corresponds to the inverse of the spatial frequency at which the first zero occurs in the contrast transfer function the corresponding zero of q P of the contrast transfer function is obtained from [ q]= 0; q > 0, = 4 3 C s and the Ansatz C s 3 4 4 q P /2 3 C 2 s q P = 0 C s 3/2 q P 2 = 2 4 3 q P = 2 3 1/ 4 C s 1/ 4 3/ 4 1, 52 C s 1/4 3/4 the inverse of q P constitutes the Point resolution: d P = 0.66 C s 1/ 4 3/4 the point resolution improves more rapidly with decreasing the wavelength (increasing the accelerating voltage) than with decreasing the spherical aberration typical order of magnitude: JEM 4000 EX (JEOL) C s = 1.0 mm, = 1.644 pm d P = 0.170 nm (experimental: 0.175 nm) 235

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