## Elements of X-ray Diffraction1 Properties of X-rays 2 Geometry of Crystals 3 Diffraction I: Directions of Diffracted Beams 4 Diffraction II: Intensities of Diffracted Beams 5 Diffraction III: Non-Ideal Samples 6 Laure Photographs 7 Powder Photographs 8 Diffractometer and Spectrometer 9 Orientation and Quality of Single Crystals 10 Structure of Polycrystalline Aggregates 11 Determination of Crystal Structure 12 Precise Parameter Measurements 13 Phase-Diagram Determination 14 Order-Disorder Transformation 15 Chemical Analysis of X-ray Diffraction 16 Chemical Analysis by X-ray Spectrometry 17 Measurements of Residual Stress 18 Polymers 19 Small Angle Scatters 20 Transmission Electron Microscope |

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Results 1-3 of 66

Page 220

The probable error" in a single count is 67 Probable error = 0.67 (relative or) = −

Relative standard Probable error pulses counted deviation (

1,000 3.2 ...

The probable error" in a single count is 67 Probable error = 0.67 (relative or) = −

**percent**. (6-9) VN These expressions give the following errors: Number ofRelative standard Probable error pulses counted deviation (

**percent**) (**percent**)1,000 3.2 ...

Page 320

But ordering can also take place in alloys containing somewhat more, or

somewhat less, than 25 atomic

Fig. 10-8. In an ordered alloy containing somewhat more than 25 atomic

gold, ...

But ordering can also take place in alloys containing somewhat more, or

somewhat less, than 25 atomic

**percent**gold, as shown by the phase diagram ofFig. 10-8. In an ordered alloy containing somewhat more than 25 atomic

**percent**gold, ...

Page 341

where W, and W. denote the relative weights of a and B if x, y, and z are

expressed in weight

in the alloy varies linearly with composition from 0 at point x to 1 at point y. The

intensity ...

where W, and W. denote the relative weights of a and B if x, y, and z are

expressed in weight

**percent**. It follows from Eq. (11-3) that the weight fraction of 3in the alloy varies linearly with composition from 0 at point x to 1 at point y. The

intensity ...

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User Review - ron_benson - LibraryThingExcellent reference book. Needs some updating in terms of advances in detector technology. Read full review

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### Common terms and phrases

alloy AuCu austenite axes axis back-reflection Bragg angle Bragg's law Bravais lattice calculated camera composition constant copper crystallite cubic curve decreases density detector determined diffracted beam diffracted intensity diffraction lines diffraction pattern diffractometer direction effect electrons energy equation error Ewald sphere example extrapolation face-centered face-centered cubic factor film fraction given grain hexagonal Hull/Debye–Scherrer incident beam indices integrated intensity lattice parameter lattice points Laue pattern Laue spots layer martensite measured metal normal observed obtained orthorhombic parallel peak percent phase photographic pinhole plane plot pole figure position powder pattern preferred orientation produce projection pulses radiation rays reciprocal lattice reciprocal space reflection relative rotation sample scattering shown in Fig shows slit solid solution space specimen stress substance superlattice surface symmetry temperature tetragonal texture tion transmission unit cell vector voltage wave wavelength x-ray diffraction x-ray tube