Energy Is Quantized
After Max Planck determined that energy is released and absorbed
by atoms in certain fixed amounts known as quanta, Albert Einstein
took his work a step further, determining that radiant energy is also
quantized—he called the discrete energy packets photons. Einstein’s theory was that electromagnetic
radiation (light, for example) has characteristics of both a wave and a stream
of particles.
The Bohr Model of the Atom
In 1913, Niels Bohr used what had recently been discovered about
energy to propose his planetary model of the atom. In the Bohr model, the
neutrons and protons are contained in a small, dense nucleus, in which the
electrons orbit in defined spherical orbits. He referred to these orbits as
“shells” or “energy levels” and designated each by an integer: 1, 2, 3, etc. An
electron occupying the first energy level was thought to be closer to the
nucleus and have lower energy than one that was in a numerically higher energy
level. Bohr theorized that energy in the form of photons must be absorbed in
order for an electron to move from a lower energy level to a higher one, and is
emitted when an electron travels from a higher energy level to a lower one. In
the Bohr model, the lowest energy state available for an electron is the ground state, and all higher-energy states are excited states.
Orbitals and Quantum Numbers
In the 1920s, Werner Heisenberg put forth his uncertainty principle, which states that,
at any one time, it is impossible to calculate both the momentum and the
location of an electron in an atom; it is only possible to calculate the probability of finding an electron within a given space. This meant
that electrons, instead of traveling in defined orbits or hard, spherical
“shells,” as Bohr proposed, travel in diffuse clouds around the nucleus.
When we say “orbital,” the image below is what we picture in our
minds.
To describe the location of electrons, we use quantum numbers. Quantum numbers
are basically used to describe certain aspects of the locations of electrons.
For example, the quantum numbers n, l, and ml describe the position of the electron with respect to
the nucleus, the shape of the orbital, and its unique orientation, while the
quantum number ms describes the direction of the electron’s spin within a
given orbital.
Below are the four quantum numbers, showing how they are
depicted and what aspects of electrons they describe.
Principal quantum number (n)
|
Has positive values of 1, 2, 3, etc. As n increases, the orbital becomes larger—this
means that the electron has a higher energy level and is less tightly bound
to the nucleus.
|
Second quantum number or azimuthal quantum number (l )
|
Has values from 0 to n – 1. This defines
the shape of the orbital, and the value of l is designated by
the letters s, p, d, and f, which correspond to values for l of 0, 1, 2, and 3. In other words, if the
value of l is 0, it is
expressed as s; if l = 1 = p, l = 2 = d, and l = 3 = f.
|
Magnetic quantum number (ml)
|
Determines the orientation of the orbital in space relative to the
other orbitals in the atom. This quantum number has values from -l through 0 to +l.
|
Spin quantum number (ms)
|
Specifies the value for the spin and is either +1/2 or -1/2. No more
than two electrons can occupy any one orbital. In order for two electrons to
occupy the same orbital, they must have opposite spins.
|
Orbitals that have the same principal quantum number, n, are part of the same electron shell. For example,
orbitals that have n = 2 are said to be in the second shell. When orbitals
have the same n and l, they are in the
same subshell; so orbitals that
have n = 2 and l = 3 are said to be 2f orbitals, in the 2f subshell.
Finally, you should keep in mind that according to the Pauli exclusion
principle, no two electrons in an atom can
have the same set of four quantum numbers. This means no atomic orbital can
contain more than two electrons, and if the orbital does contain two
electrons, they must be of opposite spin.
Types of chemical bonds
Important Points
- What holds atoms together?
- Review the electron shell model of the atom, valence electrons
- Define chemical bond
- Six types of bonds: ionic, metallic, covalent, polar, hydrogen, and van der Waals. Be able to define each, provide examples, characterize their properties
- So far we discussed the nature of the atom in some detail, and
have a qualitative sense of how it looks. However, a lone, non-interacting
atom is rare. Most atoms are found in combination with others.
- After the big bang event, the universe began to rapidly expand, and
quite soon, within a few minutes, a major component was neutrons. Neutrons
are not stable by themselves, so many of them split into protons and
electrons, which form a significant component of the universe after about
10-15 minutes. It took about 100,000 years for the temperature of the
universe to cool enough for the electrons to attach themselves to the
protons and actually form atoms. So, about 100,000 years after the big
bang, atoms became a significant component of the universe.
- This tells us that the energies of keeping electrons around a
nucleus are much smaller than those associated with the nucleus or the formation of electrons.
- We live in a world of electrons, all our senses, and life itself, is manifest by variations in electronic interactions. Therefore life and humanity can only exist at the lower energy conditions in which electrons are bound to nuclei, i.e. Earth-like conditions and not Sun-like conditions.
- Electrons are the glue that holds groups of atoms
together.
Electron shells and chemical bonding
- Let's review the nature of the atom from the point of view of the
electrons.
- The atom is mainly low-density space with a very small but dense
nucleus that defines the center of the atom.
- Electrons are located around the nucleus.
- These electrons can be classified in terms of shells that correspond
to the rows in the periodic table. Each shell can fit a certain number of
electrons, depending on how far away from the nucleus it is. A shell
that is close to the nucleus can only contain a small number of electrons,
otherwise, the electrons are too close together, and electrostatic
repulsive forces push them apart.
- Shells of electrons are most stable when they contain the maximum
number of electrons that they can hold. On the one hand, if there are too
few electrons, the electrons are constantly whizzing about, trying to fill all available space. Therefore, they have high kinetic energy.
On the other hand, if there are too many electrons then electrostatic
repulsion takes over and pushes them apart.
- Define the electrons in an unfilled outer shell as valence electrons.
- Since these are the outermost electrons, these are the ones that
are perturbed by bringing another atom close by. These are the ones that
are involved in bonding.
- Define: a chemical
bond is the result
of a redistribution of electrons that leads to a more stable configuration
between two or more atoms.
