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Light waves White light is a mixture of different colors.

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Presentation on theme: "Light waves White light is a mixture of different colors."— Presentation transcript:

1 Light waves White light is a mixture of different colors.
Each color has a well-defined wavelength. Prism Grating Blue Red Ch

2 Electromagnetic waves
Ch. 9.6

3 The Laser A laser produces light with well-defined wavelength.
Lasers provide the most accurate length and time measurements. Atomic clocks use the frequencies of atoms to measure time with an accuracy of better than (minutes over the age of the universe). Atomic clocks using lasers can reach an accuracy of (seconds over the age of the universe).

4

5 Diffraction Interference of waves creates a diffraction pattern.
Diffraction becomes important when the size of the object is comparable to the wavelength of the light. X-rays have much shorter wavelength than visible light. Therefore, one can observe diffraction from much smaller objects (e.g. molecules). In protein crystallography, one uses the interference between x-ray waves originating from different atoms in the protein molecule.

6 Diffraction patterns reveal small structures
X-Ray Diffraction Optical Diffraction

7 X-ray diffraction image of the protein myoglobin
This image contains about 3000 diffraction spots. All that information is needed to determine the positions of all the atoms in myoglobin. Protein crystallography has become essential for biochemistry, because the structure of a protein determines its function.

8 Rosalind Franklin’s x-ray diffraction pattern of DNA, which led to the double-helix model

9 Diffraction test patterns
Single helix Double helix

10 X-ray diffraction of DNA
Diffraction pattern The double helix of DNA p = period of one turn b = base pair spacing  = slope of the helix p b p 1 b

11 Real space and reciprocal space

12 Real space versus reciprocal space
Diffraction patterns live in reciprocal space, which corresponds to the projection screen. Everything is backwards in reciprocal space: Large distances in real space become small in reciprocal space and vice versa. The direction of a wave in real space corres-ponds to a point in reciprocal space. Since a direction can be described by the momentum (mv), reciprocal space is momentum space. Even physicists have a hard time thinking in reciprocal space. But they use it heavily to describe waves (x-ray diffraction, electrons in solids, collisions of elementary particles).

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