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Due to the oscillating charge in the antenna Along this line one does not observe any acceleration Radiation from a dipole-antenna To get the dimension.

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Presentation on theme: "Due to the oscillating charge in the antenna Along this line one does not observe any acceleration Radiation from a dipole-antenna To get the dimension."— Presentation transcript:

1 due to the oscillating charge in the antenna Along this line one does not observe any acceleration Radiation from a dipole-antenna To get the dimension right ! Electromagnetic radiation Here one observes the full acceleration, but delayed in time by R/c ! Guess that 2

2 Polarisation P=cos 2 (ψ) P=1

3 Interference (mathematical) z r k’ Q Number density many wavecrest k 1 2 as drawn #2 is behind #1 for ”in” but ahead for ”out”, therefore ” – ” Phase 0.      1,2 … many

4 The dream experiment

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6 1,2 … many

7  Detector Viewing Field Detector X-ray beam Kr Gas cell Measuring atomic and molecular formfactors from gas scattering

8 a=[15.2354 6.70060 4.35910 2.96230]; b=[3.0669 0.241200 10.7805 61.4135]; c=1.71890; % Ga a=[16.6723 6.0710 3.4313 4.27790]; b=[2.63450 0.2647 12.9479 47.7972]; c=2.531; % As

9 Unit sphere dd dd  r Q r

10 Fourier transform of a Gaussian

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12 Convolution of 2 Gaussians i.e. h(x) is also Gaussian with

13

14 Side View Top View Ring wave (2D) or Spherical wave (3D) Energy density Surface area locally a plane wave

15 Aperture d Almost plane wave when Perfect plane wave k’ k A point scatterer in the beam Spherical wave Defines the scattering cross section Area is scattering length

16  2L L =(N+1)(  2L L =N No real beam is perfectly monochromatic From the 2 equations, derive the longitudinal coherence length P(   wavelength band

17 No real beam is perfectly collimated P(    D LTLT Here  and B beams in phase A and B out-of-phase show from the figure that With R being the distance from to source observation point A B The transverse coherence length

18 Absorption

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20 The experimental setup X-rays Sample Rotation Scintillator 20  m CCD  < 2 mdeg E = 8-27 keV 0.7 x 0.7 mm

21 Tomography Study the bulk structures, 3D Nondestructive Small lengthscales (350 nm) Fra http://www.unge-forskere.dk/ Galathea III Single slice 100 microns

22 Compton Scattering Energy and momentum conservation

23

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