The Chemistry Maths Book, Second Edition

3.2 Trigonometric functions 63

triangles,

1

and is important in structural and architectural design, astronomy, and

navigation. The trigonometric functions are important in the physical sciences for the

description of periodic motion, including circular motion, as in figure 3.1(i), and

wave motion, Figure 3.1(ii). They are also essential for the description of systems with

periodic structure, as in the use of Bragg’s law, equation (1.2) in Chapter 1, for the

interpretation of the diffraction of X-rays from the surfaces of crystal lattices.

The exponential function e

x

has the unique and definitive property that the slope of

its graph at any point (its derivative, see Chapter 4) is equal to the value of the func-

tion at that point. This makes it particularly useful for the modeling of all types of first-

order rate processes, in which the rate of change (growth or decay) of a property is

proportional to the value of the property. Figure 3.1(iii) show exponential growth (with

kpositive) which provides a model of, for example, population explosion, bacterial

growth in a culture, and a nuclear chain reaction. When kis negative, exponentialdecay

provides a model of first-order chemical reactions, radioactive decomposition of nuclei

and, more trivially, the popularity of fashions. In quantum theory, the function e

−r

is

the 1sorbital of the hydrogen atom if ris the distance of the electron from the nucleus.

The logarithmic function ln 1 xis the inverse function of e

x

. It is often used as an

alternative to the exponential, and is involved in the definition and representation of

fundamental physical concepts in thermodynamics, such as entropy and chemical

potential. The Arrhenius and Nernst equations, (1.3) and (1.4), provide an example of

the dual relation of the inverse functions. Another example is given in Figure 3.1(iv)

by alternative equations for the logarithmic spiral observed in natural phenomena, as

in the growth of shells of molluscs, flight behaviour of some birds and, on a larger

scale, the shape of hurricanes and some galaxies.

3.2 Trigonometric functions

Geometric definitions

The principal trigonometric functions of the angle θ, the internal angle at A of the right-

angle triangle in Figure 3.2, are the sine(sin), the cosine(cos), and the tangent (tan):

(3.1)

(3.2)

(3.3)

tan

sin

cos

θ

θ

θ

===

opposite

adjacent

BC

AB

cosθ==

adjacent

hypotenuse

AB

AC

sinθ==

opposite

hypotenuse

BC

AC

1

The earliest ‘trigonometric tables’ were constructed in about 150 BC by the astronomer Hipparchus of Nicaea

(modern Iznik in Turkey), to whom we owe the 360° circle, and by Claudius Ptolemy of Alexandria (c.100–178

AD) whose Syntaxis mathematica(Mathematical Synthesis), known as the Almagest, was called by the Arabs

al-magisti(the greatest) and whose tables were used by astronomers for over a thousand years. The tables in

the Hindu Siddhantas(about 400 AD) are essentially tabulations of the sine function. Arab mathematicians

(about 950 AD) added new tabulations and theorems. European trigonometry was developed by Johann Müller

(Regiomontanus) of Königsberg (1436–1476), and by Georg Joachim Rheticus (1514–1576) of Wittenburg, a

student of Copernicus, whose Opus palatinum de triangulis(The palatine work on triangles), 1596, focused for

the first time on the properties of the right-angled triangle. François Viète (1540–1603) built on this work with

extensive new tables for all six common functions, new formulas, and the use of trigonometric functions for the

solution of algebraic equations. The word ‘trigonometry’ came into use in about 1600.

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A B

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hyp otenu se opposi te

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θ

Figure 3.2