pulse duration (original) (raw)

Author: the photonics expert

Definition: the duration of an optical pulse

Categories: article belongs to category light detection and characterization light detection and characterization, article belongs to category optical metrology optical metrology, article belongs to category light pulses light pulses

Units: s

Formula symbol: <$\tau_\textrm{p}$>

DOI: 10.61835/bnv [Cite the article](encyclopedia%5Fcite.html?article=pulse duration&doi=10.61835/bnv): BibTex plain textHTML Link to this page LinkedIn

The duration of light pulses (also called pulse width or pulse length) can vary in a huge range:

Here is an overview on the common prefixes:

Definition of the Pulse Duration

There are actually different definitions of a pulse duration:

Particularly in cases with significant pulse pedestals, different methods can lead to substantially different pulse duration values.

The Time–Bandwidth Product, Minimum Possible Pulse Duration

The product of pulse duration and spectral bandwidth is called the time–bandwidth product. Typically, it is calculated using FWHM values of duration and bandwidth (see above). It can not be significantly smaller than ≈ 0.3, depending on the pulse shape and the exact definition of pulse duration and bandwidth. This means that e.g. a 10-fs pulse must at least have a bandwidth of the order of 30 THz, and attosecond pulses have such a large bandwidth that their center frequency must be well above that of any visible light.

As optical pulses can have an extremely large bandwidth, they can also become extremely short. The shortest pulses directly generated with mode-locked lasers (titanium–sapphire lasers) are ≈ 5 fs short. Substantially shorter pulses, even down to attosecond durations, can be done with high harmonic generation, but these are no longer light pulses in a normal sense; their center frequencies are far higher, e.g. in the extreme ultraviolet light.

See also the article on the transform limit.

Measurement of Pulse Durations

Pulse durations down to roughly 10 ps can be measured with the fastest available photodiodes in combination with fast sampling oscilloscopes. For the measurement of shorter pulse durations, streak cameras can be used.

Another approach is optical sampling (or cross-correlation), using another source generating even shorter reference pulses. In most cases, however, one uses optical autocorrelators, not requiring any reference pulses.

Note that there are also techniques such as FROG or SPIDER (→ spectral phase interferometry), which can be used to obtain much more information on pulses than e.g. just the pulse duration and energy; see the article on pulse characterization.

In many cases, for example when using an autocorrelator, a large number of subsequent pulses is used to measure a pulse duration – assuming that all pulses are essentially identical. That assumption is often valid, but can be wrong in some cases, e.g. when a mode-locked laser is not operated in a stable regime, where substantial pulse-to-pulse fluctuations can occur. The results of pulse duration measurements can then be misleading.

There are also single-shot measurement techniques which can measure the duration of a single pulse. Typically, they require substantially higher pulse energy. They can be useful, for example, for characterizing pulses from amplifier systems where significant pulse-to-pulse fluctuations are expected.

Spatial Width of a Pulse

The spatial width of a pulse in the propagation direction is given by the group velocity times the temporal pulse width. Despite the high velocity of light, ultrashort pulses can also be very short in the spatial domain. Whereas e.g. a 1-ns pulse still has a length of ≈ 30 cm in air, the shortest pulses which can be generated directly with a laser – with a duration of roughly 5 fs – have a spatial length of just 1.5 μm in air or vacuum. This corresponds to only a few wavelengths, or temporally a few optical cycles (few-cycle pulses).

As the transverse dimensions, characterized e.g. with a beam radius, are usually much larger than that, few-cycle pulses can be imagined to be like pancake-shaped bullets of light. This aspect is important; it explains e.g. why the apparent pulse duration as measured with an intensity autocorrelator can be increased when this measurement apparatus involves pulses crossing each other at some significant angle.

Effects Which Can Affect the Pulse Duration

While pulses with durations of nanoseconds or longer hardly experience any changes of pulse duration during propagation even over long distances, ultrashort pulses are sensitive to various effects:

In the steady-state operation of a mode-locked laser, the circulating pulses experience various effects which affect the pulse duration, but these effects are in a balance, so that the pulse duration is restored after every round trip. In some femtosecond lasers, the pulse duration undergoes substantial changes during each resonator round trip.

Spatio-Temporal Effects

The definition and measurement of the pulse duration becomes considerably more complicated in cases where spatial and temporal pulse properties are coupled with each other. An example is the phenomenon of pulse front tilt, where a locally measured pulse duration may be smaller than a duration based on the whole beam profile.

More to Learn

Encyclopedia articles:

Suppliers

Questions and Comments from Users

Here you can submit questions and comments. As far as they get accepted by the author, they will appear above this paragraph together with the author’s answer. The author will decide on acceptance based on certain criteria. Essentially, the issue must be of sufficiently broad interest.

Please do not enter personal data here. (See also our privacy declaration.) If you wish to receive personal feedback or consultancy from the author, please contact him, e.g. via e-mail.

By submitting the information, you give your consent to the potential publication of your inputs on our website according to our rules. (If you later retract your consent, we will delete those inputs.) As your inputs are first reviewed by the author, they may be published with some delay.