The Light Spectrum and its Relationship with Fluorescence

Visible light spectrum

The visible spectrum is composed of light with wavelengths ranging from approximately 400 nanometers to 700 nanometers. Light waves with shorter wavelengths have higher frequency and higher energy. Light waves with longer wavelengths have lower frequency and lower energy.

Excitation range and maximum

An excited fluorophore molecule emits lower-energy light than the light it absorbs. Therefore, there is always a shift along the spectrum between the color of the light absorbed by the fluorophore during excitation, and the color emitted.

A fluorescent dye absorbs light over a range of wavelengths—and every dye has a characteristic excitation range. However, some wavelengths within that range are more effective for excitation than other wavelengths. This range of wavelengths reflects the range of possible excited states that the fluorophore can achieve. So for each fluorescent dye, there is a specific wavelength—the excitation maximum—that most effectively induces fluorescence.

Excitation range example

Let’s say that we have a tube that contains a particular fluorescent dye. If we shine 480 nanometer light at the dye solution, some of the fluorophore molecules will become excited. However, the majority of the molecules are not excited by this wavelength of light.  As we increase the excitation wavelength, say to 520 nanometers, more molecules are excited. However, this is still not the wavelength at which the proportion of excited molecules is maximal. For this particular dye, 550 nanometers is the wavelength that excites more fluorophores than any other wavelength of light. At wavelengths longer than 550 nanometers, the fluorophore molecules still absorb energy and fluoresce, but again in smaller proportions.  The range of excitation wavelengths can be represented in the form of a fluorescence excitation spectrum.

In summary, a fluorescent dye absorbs light over a range of wavelengths—and every dye has a characteristic excitation range. However, some wavelengths within that range are more effective for excitation than other wavelengths. This range of wavelengths reflects the range of possible excited states that the fluorophore can achieve.  So for each fluorescent dye, there is a specific wavelength—the excitation maximum—that most effectively induces fluorescence.

Emission range example

Now let’s look at the light that is emitted by the fluorophore molecules when they are excited at the optimal excitation wavelength.  Just as fluorophore molecules absorb a range of wavelengths, they also emit a range of wavelengths. There is a spectrum of energy changes associated with these emission events. When we excite the previously described dye solution at its excitation maximum of 550 nanometers, light is emitted over a range of wavelengths. A molecule may emit at a different wavelength with each excitation event because of changes that can occur during the excited lifetime, but each emission will be within the range.

Although the fluorophore molecules all emit the same intensity of light, the wavelengths, and therefore the colors of the emitted light, are not homogeneous. Collectively, however, the population fluoresces most intensely at 570 nanometers. Based on this distribution of emission wavelengths, we say that the emission maximum of this fluorophore is 570 nanometers. The range of wavelengths is represented by the fluorescence emission spectrum.

The summary points of this introduction to fluorescence are:

1. Fluorophores are molecules that, upon absorbing light energy, can reach an excited state, then emit light energy
2. The three-stage process of excitation, excited lifetime, and emission is called fluorescence.
3. Fluorophores absorb a range of wavelengths of light energy, and also emit a range of wavelengths. Within these ranges are the excitation maximum and the emission maximum. Because the excitation and emission wavelengths are different, the absorbed and emitted light are detectable as different colors or areas on the visible spectrum.