Fluorescent penetrant materials usually contain several dye compounds that are especially suited for the production of fluorescence. Fluorescence is the process wherein a molecule absorbs a photon
of radiant energy at a particular wavelength and then quickly
re-emits the energy at a slightly longer wavelength. It is the
rapid and short-term re-emittance of energy that distinguishes
fluorescence from phosphorescence. Phosphorescence is usually
the result of a chemical reaction which sustains the release of
energy for a significant period of time. Fluorescence was first
described in the sixteenth century and was probably observed long
before that time since a large number of plant and animal products
fluoresce.
The phenomenon of fluorescence requires a short lesson in quantum
mechanics which explains why fluorescence was not understood until
the twentieth century. In the nineteenth century, Huygen's wave
theory of light had replaced Newton's concept of the particulate
nature of light and fluorescence was one of the embarrassing phenomena
which simply could not be explained by use of the wave theory.
The wave theory, as with most classical physics, generally assumes
change to be a continuous process with no abrupt changes. Near
the beginning of the twentieth century, Max Planck suggested that
energy changes might occur in a stepwise manner. This concept
forms the basis of quantum mechanics and Einstein applied the
quantum concept of energy to light and revived the idea of the
particulate nature of light. Planck formalized the relationship
with the equation shown below:
E= hn
Where:
E = energy
h = a constant
n = the frequency of light
This
equations shows that the size of the energy steps change with
the frequency or wavelength of the light. Einstein introduced
the term photon to describe the smallest increments of light.
In today's current model of the atom, protons and neutrons are found
in the nucleus and electrons are found spinning around outside
the nucleus. Electrons spin and rotate around the nucleus billions
of times a second. According to modern theory, electrons are arranged
in energy levels as they rotate around the nucleus. When electrons
gain or lose energy, they jump between energy levels as they are
rotating around the nucleus. As electrons gain energy, they move
to the third, or outer level and as they lose energy, they move
to the inner or first energy level. Since the energy of the system
is restricted to certain energy values, the atom is said to be
quantized. In the animated image below, it can be seen that the
electrons move to a different energy state only when a specific
amount of energy is added to or removed from the system.
Another way of illustrating this point is with an energy
diagram as presented below. This diagram shows the quantized energy
levels for an atom. Each energy level corresponds to a quantum
state of the atom. The lowest energy state is called the ground
state and is the E0 line in the diagram. If energy is added to
the system, an electron or electrons will jump to a higher level
and the atom is said to be at an excited state. The upward arrow
in the illustration represents a quantum jump of the atom from
the ground state to the second excited state. Depending on the amount
of energy input into the atom, the energy jump could have been
to any of the levels. However, the jump must be to one of the
levels shown, as the atom cannot have an intermediate value of
energy. Atoms will generally be in their ground state.
When considering fluorescence, energy must be considered
at a molecular level. When molecules form, two or more atoms form
an association where the energy of the molecule is lower than
that of the constituent atoms when they were separate. The total
energy of the molecule is the sum of the energies holding the
nuclei together and the energy of the chemical bonds holding the
molecule together. Molecules have rotational, vibrational and
electronic (due to the electrons) energy. It is the vibrational
and electronic energies of the molecule that contribute to fluorescence.
Molecules, like atoms, will generally be in their ground state.
Molecules can move to a greater energy state only when energy
is added to their system. One of the ways a molecule can gain
energy is by absorbing light. If a molecule absorbs light, the
energy of the light must be equal to the energy required to put the
molecule in one of the higher energy states. When a molecule reaches
an excited state, it does not stay there for very long. Rather it quickly
returns to a lower energy state either by emitting light or
colliding with another atomic particle. When a molecule emits
light, the energy of that light is equal to the energy difference
between the quantum levels that molecules has moved between.
This
equations shows that the size of the energy steps change with
the frequency or wavelength of the light. Einstein introduced
the term photon to describe the smallest increments of light.