fluorescence spectroscopy (original) (raw)

Definition: spectroscopy which is based on the analysis of fluorescence light

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Related: fluorescencespectroscopyfluorescence microscopy

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Contents

What is Fluorescence Spectroscopy?

Fluorescence spectroscopy denotes a class of spectroscopy methods which are based on the analysis of fluorescence light, particularly concerning the emission spectrum. Properties of the fluorescence are frequently used to identify substances, often including their concentrations, and in other cases properties of a medium which influence details of the fluorescence.

The term fluorescence spectrometry is sometimes used instead of spectroscopy to emphasize that certain quantities are measured in a quantitative manner.

In contrast to laser absorption spectroscopy, one usually does not measure what happens to the applied excitation light (e.g. its absorbance), but observes only the properties of the fluorescent emission.

Operation Principles

Fluorescence is actively excited by irradiating a sample with light from some light source which is part of the fluorometer (or fluorimeter). (In many cases, one uses ultraviolet light.) Further, there is some kind of photodetector, which may be combined with a tunable monochromator (or sometimes only a few simple optical filters) for spectral analysis. Figure 2 shows an example of a fluorometer setup.

excitation of fluorescence

Figure 1: Excitation of fluorescence at multiple wavelengths caused by the excitation with light at a single wavelength.

Some fluorophore in the sample usually absorbs the incident excitation light via linear absorption (with one photon per absorption process), but there are also cases where nonlinear absorption at high optical intensities is utilized, for example two-photon absorption or even multiphoton absorption, i.e., with two or more photons per excitation process. The absorption causes the excitation of atoms, ions or molecules to certain excited electronic states. Frequently, the excited objects first undergo some non-radiative transitions to lower excited states (see Figure 1). Finally, with some probability there will be emission of a photon from the excited state either to the electronic ground state or to another excited state, in the latter case with a correspondingly reduced photon energy and possibly followed by the emission of one or more additional photons. There are also cases with resonance fluorescence, which do not involve additional electronic transitions, and the emission wavelengths are close to the excitation wavelength. Part of the fluorescence may be quenched.

In free molecules, for example in gas spectroscopy, the involved excited states can involve vibrational and rotational states. In the case of solid materials, interactions with neighboring atoms can substantially modify the produced fluorescence. Similarly, there are solvent interactions in liquids.

fluorescence spectrometer

Figure 2: Setup of a fluorescent spectrometer (spectrofluorometer) with a pulsed laser, monochromator and fast photodetector. Other setups may contain a broadband light source and an excitation monochromator or another kind of detector, for example a spectrograph with a multichannel detector.

Some kind of samples contain natural kinds of fluorophores, which can be parts of certain larger molecules or separate fluorescent molecules. For example, tyrosine and tryptophan occur in biological samples. In other cases, one adds a fluorophore in the form of some fluorescent dye (frequently aromatic compounds such as fluorescein), which can help to reveal certain properties of the sample. For example, certain dyes preferentially get attached to certain structures and can therefore act as markers for those. Such methods are particularly used in fluorescence microscopy e.g. for biological research, where certain structures within biological cells can be marked.

In most cases, the excitation wavelength (or a broadband excitation spectrum) stays fixed. However, there are also methods where one scans the excitation wavelength through a certain range and sometimes detects only the overall optical power of the fluorescence (without spectral analysis). One then focuses on the details of the excitation mechanism rather than on the details of light emission. Maximum flexibility is obtained when combining a variable excitation wavelength with full spectral analysis of the fluorescence.

The excitation light can be a continuous-wave source or a pulsed source:

Instruments for fluorescence spectroscopy can be called spectrofluorometers. (There are also simpler fluorometers or fluorimeters without spectral resolution.) Apart from high-performance instruments for use in laboratories, there are also more compact ones, even in the form of handheld battery-powered devices.

The excitation and/or the light detection may be restricted to a small volume on the sample. Fluorescence spectroscopy measured with a high spatial resolution can be called fluorescence microscopy.

Light Sources for Fluorescence Spectroscopy

Depending on the chosen method, different kinds of light sources can be used for fluorescence spectroscopy:

If the used light source cannot produce light with a precisely constant optical power or pulse energy, one may also measure its output with an additional photodetector and use its output signal to eliminate power fluctuations from the results of the fluorescence measurements.

Photodetectors

Different kinds of photodetectors can be used, depending on the requirements. For instruments with continuous-wave excitation and a scanning monochromator, one simply requires a photodetector with high sensitivity in the relevant spectral range — for example, some type of photodiode. In conjunction with a dual monochromator for optimum suppression of stray light, one often requires a even higher detector sensitivity.

Another possibility is to use a kind of spectrograph containing a diffraction grating and a linear photodiode array or other kind of photodetector with spatial resolution. When using a two-dimensional sensor, such as otherwise used as an image sensor, one may achieve one-dimensional spatial resolution in combination with spectral resolution.

For fluorescence lifetime measurements, one requires a fast response (high bandwidth) in addition to the high sensitivity. This narrows the choice of suitable detectors; one often uses photomultipliers or avalanche photodiodes. There are also devices containing a microchannel plate.

Various Issues

One typically tries to eliminate any direct effect of excitation light on the detector, e.g. by spectral discrimination, possibly also with other methods, e.g. by detection in a direction where little excitation light is expected, e.g. perpendicular to an excitation beam in a transparent sample. Particularly in cases where the fluorescence is much weaker than the excitation light, or when the sample is strongly scattering the excitation light, strong suppression of excitation light in the detection system is required. For example, one may need to use a double monochromator.

For efficient light collection from the sample e.g. to the input slit of a monochromator, one can use a cylindrical lens.

The obtained fluorescence spectra may be modified by further interactions within the sample, for example by wavelength-dependent absorption. Such effects can be minimized by using thin samples.

In addition to fluorescence light, there may also be light arising from Raman scattering, which also exhibits some Stokes shift.

In some cases, the ultraviolet excitation light causes degradation (e.g. by photodecomposition) of the sample. Highly sensitive detection is then particularly desirable, since it allows one to reduce the exposure time.

Sometimes, one needs to monitor not only the amount of fluorescence from a certain fluorophore, but precisely detect minor changes in the emission spectrum, for example due to subtle interactions in the sample. A particularly high spectral resolution and low detection noise may be required in such cases.

Applications

Fluorescence spectroscopy is often used in chemistry, biology and environmental monitoring. Some examples:

Time-resolved fluorescence spectroscopy can be used to gain substantial additional information and is thus interesting for certain areas of fundamental scientific research.

Frequently Asked Questions

What is fluorescence spectroscopy?

Fluorescence spectroscopy is a method that analyzes the fluorescence light emitted by a sample after it has been excited by an external light source. It is used to identify substances, determine their concentrations, and study properties of the medium influencing the fluorescence.

How does fluorescence spectroscopy work?

A sample is irradiated with light, often ultraviolet light, which excites fluorescent molecules (fluorophores) to a higher energy state. These molecules then return to a lower state by emitting light (fluorescence), which is collected and spectrally analyzed.

What is the difference between continuous-wave and pulsed excitation?

With continuous-wave excitation, one typically analyzes the optical spectrum and polarization of the fluorescence. Pulsed excitation additionally allows for measuring the fluorescence lifetime (decay time), which can provide further spectroscopic information.

What light sources are used for fluorescence spectroscopy?

Common sources include gas discharge lamps, light-emitting diodes (LEDs), and various types of lasers. Lasers are powerful sources offering narrow linewidths and the ability to generate short pulses for time-resolved measurements.

What are typical applications of fluorescence spectroscopy?

It is widely used in chemistry, biology, and environmental monitoring. Applications include detecting impurities in products, monitoring air and water quality, identifying bacteria and viruses, cancer diagnostics, and using fluorescent markers in fluorescence microscopy.

What is a spectrofluorometer?

A spectrofluorometer is an instrument for fluorescence spectroscopy. It includes a light source for excitation, a sample holder, and a detection system, which often uses a monochromator for spectral analysis of the emitted fluorescence.

Why is it important to suppress the excitation light during detection?

The fluorescence signal is typically much weaker than the excitation light. If excitation light that is scattered by the sample reaches the detector, it can overwhelm the faint fluorescence signal, making accurate measurements impossible.

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