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(X-Ray Crystallography) X-RAY DIFFRACTION. I. X-Ray Diffraction  Uses X-Rays to identify the arrangement of atoms, molecules, or ions within a crystalline.

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Presentation on theme: "(X-Ray Crystallography) X-RAY DIFFRACTION. I. X-Ray Diffraction  Uses X-Rays to identify the arrangement of atoms, molecules, or ions within a crystalline."— Presentation transcript:

1 (X-Ray Crystallography) X-RAY DIFFRACTION

2 I. X-Ray Diffraction  Uses X-Rays to identify the arrangement of atoms, molecules, or ions within a crystalline solid  Quantitative and qualitative Ooi, L. Principles of X-ray Crystallography (2010)

3 A. X-Rays  0.1 – 100 Angstroms (Å)  Useful Range: 0.5 – 2.5 Å

4 B. Amorphous Substances 1. Gases and Liquids  Extremely difficult 2. Non-crystalline Solids  Atoms are not regularly arranged or regularly shaped  Interference  Fiber Diffraction

5  Atoms are regularly arranged  “The Unit Cell” – a cookie cutter C. Crystalline Solids Rhodes, G. Crystallography Made Crystal Clear, 3 rd ed. (2006)

6 II. X-Ray Crystallography A. Small-molecule crystallography  Up to ~100 atoms  Organic molecules, catalysts, newly synthesized drugs, etc.  Identify each atom B. Macromolecular (protein) crystallography  Large biological molecules – nucleic acids and proteins  Identify 2° structure Note: must show that the crystal structure (asymmetric unit) is comparable to structure in solution (biological unit)

7 III. X-Ray Diffractometer Ooi, L. Principles of X-ray Crystallography (2010)

8 A. X-Ray Source Rhodes, G. Crystallography Made Crystal Clear, 3 rd ed. (2006) 1. X-Ray Tube (a) 2. Rotating Anode (b)

9 3. Particle Storage Ring (Synchrotron Radiation)  Particle Accelerator Ooi, L. Principles of X-ray Crystallography (2010)

10 Rhodes, G. Crystallography Made Crystal Clear, 3 rd ed. (2006)  National Synchrotron Light Source at Brookhaven National Lab (Long Island)

11 B. Collimator  Narrow metal tube that selects and reflects the X-Rays into parallel paths Ooi, L. Principles of X-ray Crystallography (2010)

12 C. Crystal (Sample) Rhodes, G. Crystallography Made Crystal Clear, 3 rd ed. (2006) 1. Growth – Screens  Crystal vs. useless blob 2. Optimization  Quantity 3. Crystal Quality  Purity 4. Mount for Data Collection  Cryocrystallography Note: Diffracted in “mother liquor”

13 D. Camera Rhodes, G. Crystallography Made Crystal Clear, 3 rd ed. (2006)  Goniometer  Goniostat

14 Rhodes, G. Crystallography Made Crystal Clear, 3 rd ed. (2006)

15 E. Detector Rhodes, G. Crystallography Made Crystal Clear, 3 rd ed. (2006) 1. Charged Couple Device (CCD) 2. Image Plate (IP)

16 IV. Data Analysis  Measure intensity and position of diffracted X-Rays  Intensity: strength of diffracted beam  Position: direction in which beam was diffracted by the crystal Rhodes, G. Crystallography Made Crystal Clear, 3 rd ed. (2006)

17 Ooi, L. Principles of X-ray Crystallography (2010) Computer calculates this data from the diffraction pattern

18 A. Fournier Sum  Based on simple waves  f(x) = F cos 2π (hx + α)  F = f 0 + f 1 + f 2 + … Rhodes, G. Crystallography Made Crystal Clear, 3 rd ed. (2006)

19 B. Bragg’s Law  States: diffraction spots occur when 2 d sin θ = n λ Rhodes, G. Crystallography Made Crystal Clear, 3 rd ed. (2006)

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22  Molecular structure in solid crystalline state with extreme certainty  Direct inference of data  Provides limitless info.  Crystals  Slow  Hydrogen  Still just a model Benefits Downfalls

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