Inorganic chemistry
Modern chemistry, which
dates more or less from the acceptance of the law of conservation of mass in the late 18th century, focused
initially on those substances that were not associated with living organisms.
Study of such substances, which normally have little or no carbon, constitutes the discipline of inorganic chemistry. Early work sought to identify the simple
substances—namely, the elements—that are the constituents of all more complex
substances. Some elements, such as gold and carbon, have been known since antiquity, and many others were
discovered and studied throughout the 19th and early 20th centuries. Today,
more than 100 are known. The study of such simple inorganic compounds as sodium chloride (common salt) has led to some of the
fundamental concepts of modern chemistry, the law of definite proportions providing one notable example.
This law states that for most pure chemical substances the constituent elements
are always present in fixed proportions by mass (e.g., every
100 grams of salt contains 39.3 grams of sodium and 60.7 grams of chlorine). The crystalline form of salt, known as halite, consists of intermingled sodium and chlorine atoms, one sodium atom for each one of chlorine. Such a compound, formed solely by the
combination of two elements, is known as a binary compound. Binary compounds are very
common in inorganic chemistry, and they exhibit little structural variety. For
this reason, the number of inorganic compounds is limited in spite of the large
number of elements that may react with each other. If three or more elements
are combined in a substance, the structural possibilities become greater.
After a period of quiescence in the early part of the 20th
century, inorganic chemistry has again become an exciting area of research.
Compounds of boron and hydrogen, known as boranes, have unique structural features that
forced a change in thinking about the architecture of inorganic molecules. Some
inorganic substances have structural features long believed to occur only in
carbon compounds, and a few inorganic polymers have even been produced. Ceramics are materials composed of
inorganic elements combined with oxygen. For centuries ceramic objects have
been made by strongly heating a vessel formed from a paste of powdered
minerals. Although ceramics are quite hard and stable at very high
temperatures, they are usually brittle. Currently, new ceramics strong enough
to be used as turbine blades in jet engines are being manufactured. There is
hope that ceramics will one day replace steel in components of
internal-combustion engines. In 1987 a ceramic containing yttrium, barium, copper, and oxygen, with the approximate formula YBa2Cu3O7, was found to be a superconductor at a temperature of about 100 K. A superconductor offers no resistance to the
passage of an electrical current, and this new type of ceramic could very well
find wide use in electrical and magnetic applications. A superconducting
ceramic is so simple to make that it can be prepared in a high school laboratory. Its discovery illustrates the unpredictability of
chemistry, for fundamental discoveries can still be made with simple equipment
and inexpensive materials.
Many of the most interesting developments in inorganic
chemistry bridge the gap with other disciplines. Organometallic chemistry investigates compounds that
contain inorganic elements combined with carbon-rich units. Many organometallic
compounds play an important role in industrial chemistry as catalysts, which are substances that are able
to accelerate the rate of a reaction even when present in only very small
amounts. Some success has been achieved in the use of such catalysts for
converting natural gas to related but more useful chemical
substances. Chemists also have created large inorganic molecules that contain a
core of metal atoms, such as platinum, surrounded by a shell of different
chemical units. Some of these compounds, referred to as metal clusters, have
characteristics of metals, while others react in ways similar to biologic
systems. Trace amounts of metals in biologic systems are essential for
processes such as respiration, nerve function, and cell
metabolism. Processes of this kind form the object of study of bioinorganic
chemistry. Although organic molecules were once thought to be the
distinguishing chemical feature of living creatures, it is now known that
inorganic chemistry plays a vital role as well.