Physical Chemistry , 1st ed.

Example 21.6 Monochromatic X rays having a wavelength of 10.4 Å are preferentially dif- fracted by a crystal at an angle of 25.5°. a.Assuming that this is the first-order diffraction, what is the dspacing between the crystalline planes? b.At what angle would the second-order diffraction be found?

Solution a.For n1 (that is, first-order diffraction), we can set up Bragg’s law as 10.4 Å 2 dsin (25.5°) and the only unknown in this equation is d, the spacing between crystalline planes. Solving for d:

d 2si

1

n

0.

(

4

25

Å

.5°)

d12.1 Å Notice how the units work out: the only unit is a unit of distance, Å. b.Knowing the value for d, we can find the angle for the second-order diffraction of these X rays. In this case,n2, and we can set up Bragg’s law as 2(10.4 Å) 2(12.1 Å) sin Now the angle is the only unknown in the expression. Solving for sin :

sin ^2 2

(

1

0

2

.

4

1

Å

)

sin 0.859 59.3°

Notice that mathematically, only so many orders of diffraction may be pos-
sible for any given spacing of crystal planes and a given X-ray wavelength. In
the previous example, if you were trying to determine the angle of the third-
order diffraction, you would get to the expression

sin

3

2

(

1

0

2

.

4

1

Å

)

where the 3 in the numerator represents the order n. Evaluating this fraction,
we get

sin 1.289

Sine functions can’t get above a value of 1, so having a sine of 1.289 is physi-
cally impossible. This shows that the given plane of atoms can diffract 10.4-Å
X rays only to the first and second order.
Although Bragg’s law is the fundamental basis of experimental crystallogra-
phy, its simplicity is potentially misleading. For the simplest of cubic lattices
(like many of the solid noble gases), only one type of atom can make a plane
that refracts X rays. Consider a molecular crystalline solid like water, H 2 O: not
only is the crystal more complicated because it’s a molecular solid, but each
atom in the molecule can be used to define a regular matrix of atoms that can
act as a refracting plane. The diffraction of X rays by any random compound

21.5 Determination of Crystal Structures 743

Physical Chemistry , 1st ed.

1

0.

(

4

25

Å

.5°)

(

(

1

1

0

2

.

.

4

1

Å

Å

)

)

3

2

(

(

1

1

0

2

.

.

4

1

Å

Å

)

)

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