Stabilization of Lasers

Dr. Rüdiger Paschotta

doi:10.61835/fkd

Stabilization of Lasers

Author: the photonics expert Dr. Rüdiger Paschotta (RP)

Definition: measures applied to lasers to improve their stability in terms of output power, optical frequency, or other quantities

Categories: article belongs to category laser devices and laser physics laser devices and laser physics, article belongs to category fluctuations and noise fluctuations and noise, article belongs to category methods methods

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DOI: 10.61835/fkd Cite the article: BibTex BibLaTex plain text HTML Link to this page! LinkedIn

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Introduction

As lasers exhibit various kinds of laser noise, which can be detrimental in applications, it is sometimes necessary to use techniques for suppressing noise and stabilizing certain laser parameters. There are active and passive stabilization schemes, as discussed in the following. Concerning frequency stabilization, see the article on frequency-stabilized lasers for more details.

See also the article on synchronization of lasers, which treats both timing and phase synchronization.

Active Laser Stabilization

Active stabilization schemes usually involve some kind of electronic feedback (or sometimes feedforward) system, where fluctuations in some parameters are converted to an electronic signal, which is then used to act on the laser in some way.

Examples are:

The output power of a laser may be stabilized with a scheme as shown in Figure 1. The laser power is monitored with a photodiode and corrected e.g. via control of the pump power or the losses in or outside the laser resonator. In this way, both spiking after turn-on and the intensity noise under steady-state conditions can be reduced.
Note that it is also possible to reduce intensity noise by acting on the output beam instead of the laser itself; see the article on noise eaters.

Figure 1: Diode-pumped solid-state laser with a feedback system stabilizing the output power.

The optical frequency of a single-frequency laser, or the frequency of one line of the frequency comb from a mode-locked laser, can be stabilized via resonator length control. The feedback signal can be obtained e.g. by recording a beat note with a second laser, by measuring the power which is transmitted or reflected at a very stable reference cavity or another kind of interferometer, or by measuring the transmission of a gas cell (e.g. an iodine cell), possibly using Doppler-free laser absorption spectroscopy. A frequently used technique for generating an error signal with a reference cavity is the Pound–Drever–Hall method [3, 4], using a weak phase modulation of the light which is sent to the reference cavity. A scheme not requiring such modulation is the Hänsch–Couillaud method [2]. Another method is tilt locking, where spatial mode interference is utilized [12, 16, 30]. (See the article on frequency-stabilized lasers.)
The stabilization of the carrier–envelope offset phase or frequency of a mode-locked laser (CEO stabilization) can be based on, e.g., a phase measurement with an ($f-2f$) interferometer and feedback via some wedge or tilted mirror in the laser resonator. This kind of stabilization is important for frequency metrology.
The timing of the pulses (→ timing jitter ) from a mode-locked laser can be monitored by comparing the phases of a photodiode signal and of an electronic reference oscillator, and stabilized e.g. via cavity length control.
Stabilization of the pointing direction of the output beam is possible via a beam position measurement (e.g. with a four-quadrant photodiode) and correction via piezo-controlled resonator mirrors.

The stability which is achieved with such active systems is determined by factors such as photodetection noise, the bandwidth of control elements, the design of the feedback electronics, and the stability of the reference standards (e.g. optical reference cavities).

Passive Laser Stabilization

Passive schemes do not involve electronics and are based on purely optical effects. Examples are:

The frequency of a laser can be stabilized via optical feedback from a stable reference cavity. (This may also be considered as using an extended laser resonator, being a kind of composite cavity.)
Synchronization of two mode-locked lasers is possible via cross-phase modulation in a Kerr medium, in which the intracavity pulses of both lasers meet.
One may also employ nonlinear optical effects such as frequency doubling, which causes higher losses for higher powers [33].

The optical frequency of a laser may also be stabilized by injection locking, i.e., injecting a beam with a highly stable optical frequency from another laser.

Frequently Asked Questions

This FAQ section was generated with AI based on the article content and has been reviewed by the article’s author (RP).

What is the difference between active and passive laser stabilization?

Active stabilization schemes use an electronic feedback system to measure fluctuations in a laser parameter and actively correct them. Passive schemes are based on purely optical effects and do not involve electronics.

How can the output power of a laser be stabilized?

Laser output power can be actively stabilized by monitoring it with a photodiode and using the signal in a feedback loop to control the pump power or the losses within or outside the laser resonator.

Which laser parameters are commonly stabilized?

Commonly stabilized parameters include the output power (intensity), optical frequency, pulse timing and carrier–envelope offset phase of mode-locked lasers, and the pointing direction of the output beam.

How can a laser's optical frequency be stabilized?

A laser's frequency can be stabilized by locking it to a highly stable reference, such as an optical reference cavity or a gas cell. An electronic feedback system then typically adjusts the laser's resonator length to correct for frequency drift.

Suppliers

Sponsored content: The RP Photonics Buyer's Guide contains 18 suppliers for laser stabilization. Among them:

⚙ hardware

The optical frequency discriminator (OFD) system of SILENTSYS smartly delivers a voltage signal that is proportional to the fluctuations of the optical frequency of the input laser beam. This turn-key module is suitable for laser frequency noise characterization and/or for laser frequency stabilization to drastically reduce its optical linewidth. The OFD features ultralow noise performances being successful in achieving frequency noise level as low as 0.01 Hz2/Hz with >60 dB noise reduction, and that is achieved in a compact and user-friendly package. This product is available in a huge wavelength range from UV, VIS to NIR, with one or two optical modules inside to be a very versatile tool.

The optical frequency correlator (OFC) system contains a common 2-input optical frequency discriminator (OFD). This makes it possible to frequency.stabilize two wavelength distant lasers onto the same optical reference in order to reduce their frequency fluctuations and to correlate them precisely.

Based on this fact, the optical beat frequency between the two stabilized lasers generates THz or GHz signals that reach a very low frequency noise level and are easily frequency tunable. Moreover, as a standard OFD, it smartly delivers a voltage signal that is proportional to the frequency fluctuations of the input laser beam. This turn-key device is suitable for laser frequency noise characterization and/or for laser frequency stabilization.

⚙ hardware

Sacher Lasertechnik offers equipment for the stabilization of laser diodes:

⚙ hardware

TOPTICA’s unique CHARM technology (Coherence-advanced regulation method) provides an active stabilization of the laser’s coherence. An integral feature of the TopMode laser family, this scheme ensures excellent long-term stability of the lasing wavelength and output power, as well as an extremely low intensity noise.

⚙ hardware

Menlo Systems offers ultrastable, frequency stabilized lasers at basically any wavelength. We supply fully characterized systems with linewidths < 1 Hz and Allan deviations of 2 ×ばつ 10⁻¹⁵ (in 1 s) as well as modules and components allowing for state-of-the-art systems tailored to your requirements.

⚙ hardware

The SLICE-OPL tightly locks frequencies from as low as 10 MHz up to > 9.3 GHz, making it well-suited for stabilizing frequency combs. A built-in touchscreen GUI allows the user to manipulate the error signal and engage the lock — all without an oscilloscope.

Ideal for precision spectroscopy and metrology applications, the SLICE-DLC Dual Laser Controller is an ultra-low-noise, two-channel current source, each channel with two temperature controls for sub-millikelvin diode stability to minimize frequency fluctuations and drift. A current servo input gives high-speed (≥10 MHz) control of the laser.

The D2-125 Laser Servo with Lock Guard auto-relocking enables low-noise servo control of lasers and other experimental systems. The PI2D loop filter, with two-stage integral feedback, provides tight locking to cavities and atomic/molecular transitions with full user control over the loop-filter parameters.

The D2-135 Offset Phase Lock Servo precisely controls and quickly adjusts the frequency detuning between a master and a follower laser, from 250 MHz to 9.3 GHz. The D2-135 forms a complete offset lock system when combined with the D2-250 Heterodyne Module and D2-260 Beat Note Detector.

⚙ hardware

Our sensitive and compact, HighFinesse/Ångstrom’ wavelength meters deliver high speed wavelength measurements of pulsed and continuous laser with absolute accuracy down to 2 MHz. A wide variety of models is available, covering wavelength ranges from 192 nm up to 11000 nm. The devices can not only accurately measure wavelengths, but can with their output used to stabilize a laser such that its emission wavelength remains very stable.

To fully meet the increasing demand of flexibility and integration of laser test equipment, the HighFinesse world famous WS wavemeters are available as rack and standalone systems. The latter do not require an external computer. They can be controlled locally by connecting screen, keyboard, mouse or via touch screen (not available for all models) and using Ethernet connection via the DLL-based API or SCPI commands.

Bibliography

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(Suggest additional literature!)

Questions and Comments from Users

2023年09月07日

What metrics are commonly used to quantify stability?

The author's answer:

Typically, one would quantify the opposite — noise. For example, it might be the relative intensity noise quantified in dBm/Hz or a linewidth in Hz.

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