Bragg Mirrors
Author: the photonics expert Dr. Rüdiger Paschotta (RP)
Acronym: DBR = distributed Bragg reflector
Definition: mirror structures based on Bragg reflection at a period structure
Alternative terms: Bragg reflectors, quarter-wave mirrors, quarter-wave stacks, distributed Bragg reflectors
Related: mirrorsBragg gratingsfiber Bragg gratingsdielectric mirrorscrystalline mirrorschirped mirrorsdispersive mirrorslaser mirrorsdistributed Bragg reflector lasersdistributed feedback lasers
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DOI: 10.61835/hac Cite the article: BibTex BibLaTex plain textHTML Link to this page! LinkedIn
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What are Bragg Mirrors?
A Bragg mirror (also called distributed Bragg reflector) is a mirror structure which consists of an alternating sequence of layers of two different optical materials. The most frequently used design is that of a quarter-wave mirror, where each optical layer thickness corresponds to one quarter of the wavelength for which the mirror is designed. The latter condition holds for normal incidence; if the mirror is designed for larger angles of incidence, accordingly thicker layers are needed.
The principle of operation of such a reflector can be understood as follows. Each interface between the two materials contributes a Fresnel reflection. For the design wavelength, the optical path length difference between reflections from subsequent interfaces is half the wavelength; in addition, the amplitude reflection coefficients for the interfaces have alternating signs. Therefore, all reflected components from the interfaces interfere constructively, which results in a strong reflection. The reflectance (reflectivity) achieved is determined by the number of layer pairs and by the refractive index contrast between the layer materials. The reflection bandwidth is determined mainly by the refractive index contrast; if that is too small, even using a very large number of coating layers will not work.
Figure 1 shows the field penetration into a Bragg mirror made of eight layer pairs of TiO2 and SiO2. The blue curve shows the intensity distribution of a wave with the design wavelength of 1000 nm, incident from the right-hand side. Note that the intensity is oscillating outside the mirror due to the interference of the counterpropagating waves. The gray curve shows the intensity distribution for 800 nm, where a significant part of the light can get through the mirror coating.
Figure 2 shows the reflectance and the group delay dispersion as functions of the wavelength. The reflectance is high over some optical bandwidth, which depends on the refractive index contrast of the materials used and on the number of layer pairs. The dispersion is calculated from the second derivative of the reflection phase with respect to the optical frequency. It is small near the center of the reflection band, but grows rapidly near the edges.
Figure 3 shows with a color scale how the optical field penetrates into the mirror. It can be seen that there is little field penetration well within the reflection band.
Figure 4 shows reflectance spectra of a Bragg mirror for different angles of incidence. The larger that angle, the more the reflection spectrum is shifted towards shorter wavelengths.
Types of Bragg Mirrors
Bragg mirrors for applications in optics can be fabricated with different technologies:
- Dielectric mirrors based on thin-film coating technology, fabricated for example with electron beam evaporation or with ion beam sputtering, are used as laser mirrors in solid-state bulk lasers. The mirror structure then consists of amorphous materials.
- Fiber Bragg gratings, including long-period fiber gratings, are often used in fiber lasers and other fiber devices. They can be fabricated by irradiating a fiber with spatially patterned ultraviolet light. Similarly, volume Bragg gratings can be made in photosensitive bulk glass.
- Semiconductor Bragg mirrors can be produced with lithographic methods. They are used, for example, in surface-emitting semiconductor lasers and in semiconductor saturable absorber mirrors, but also as separate optical components (→ crystalline mirrors).
- There are various types of Bragg reflectors used in other waveguides, based on, e.g., corrugated waveguide structures which can be fabricated via lithography. This kind of gratings are used in some distributed Bragg reflector or distributed feedback laser diodes.
There are other multilayer mirror designs which deviate from the simple quarter-wave design. They generally have a lower reflectance for the same number of layers, but can be optimized e.g. as dichroic mirrors or as dispersive chirped mirrors for dispersion compensation.
Designing Modified Bragg Mirrors
It is common to start with a simple Bragg mirror design and then modify it to obtain certain features. A highly flexible simulation and design tool such as the RP Coating software is indispensable for such work. For example, you can define a modified Bragg mirror design with some additional parameters (e.g. for a chirp) and numerically optimize those for any given design goal.
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 a Bragg mirror?
A Bragg mirror, or distributed Bragg reflector, is an optical mirror constructed from a sequence of alternating layers of two different materials. This structure is designed to strongly reflect light within a specific range of wavelengths.
How do Bragg mirrors work?
Bragg mirrors operate on the principle of constructive interference. Each interface between the layers contributes a small reflection, and the layer thicknesses are chosen so that all these reflected waves are in phase and add up, resulting in a strong overall reflection.
What factors determine the properties of a Bragg mirror?
The reflectance is determined by the number of layer pairs and the refractive index contrast between the materials. The reflection bandwidth depends primarily on the refractive index contrast.
How does the angle of incidence affect a Bragg mirror?
When the angle of incidence increases, the reflection spectrum of a Bragg mirror shifts towards shorter wavelengths.
What are common examples of Bragg mirrors?
Common types include dielectric mirrors used for solid-state lasers, fiber Bragg gratings in fiber optic systems, and semiconductor mirrors integrated into devices like surface-emitting lasers and DBR laser diodes.
Suppliers
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FFA-01 is a fiber array sensor with configurable number of FBG elements and their spacing over the fiber length. FFA-01 is typically used for direct gluing to the measured surface to capture strain changes of the monitored structure.
Bibliography
| [1] | Analysis of a Bragg mirror with the RP Coating software |
| [2] | R. Paschotta, case study on a Bragg mirror |
(Suggest additional literature!)
Questions and Comments from Users
2020-12-09
Does the reflectance spectrum of a Bragg mirror depend on whether the light is incident from the air side or from the glass substrate side? For example, could a 'hot mirror' be laminated between two sheets of glass and still have the same reflectance spectrum as one where the light is incident from air? Or would the alternating sequence of layers need to be changed to obtain the same reflectance spectrum?
The author's answer:
The reflectance of such a device cannot depend on the direction of light propagation. So if you take the same device both times and only come with light from different sides, you get the same reflectance.
However, the reflectance can change if you modify the setup, for example by putting a layer of glass on top of a mirror.
2021-02-09
Why do the spectral features shift to shorter wavelengths when the mirror is tilted? Shouldn't the wavelength grow since the optical distance between the films also grows?
The author's answer:
It is surprising indeed, but I have explained that in a blog article.
2021-07-25
What is the origin of the reflection bandwidth of a Bragg mirror?
The author's answer:
The Bragg condition is still approximately fulfilled for wavelengths which are close enough to the Bragg wavelength. More precisely, the optical phase changes caused by the wavelength deviation are small enough not to cause substantial changes in the reflectance. If the refractive index contrast is strong, a relatively small number of layers is relevant, so that the involved phase changes are relatively small for a given wavelength deviation.
2022-01-08
Why does the thickness need to be 1/4 of the wavelength, not 1/2 the wavelength?
The author's answer:
The λ/4 thickness implies λ/2 for the way back and forth through one layer, or a ($\pi$) phase shift. That looks like the wrong condition at first glance. However, in addition there is a ($\pi$) phase difference between subsequent reflections because it makes a difference whether you go from higher refractive index to a lower one or vice versa. As a result, the phases of reflected contributions from different interfaces are the same, so that they can add up constructively.
2024-08-25
If you fabricate multiple Bragg mirrors with different properties on top of each other, is it possible to reflect all wavelengths from 200 to 2500 nm, effectively reflecting our the whole solar spectrum?
The author's answer:
Theoretically yes, but there are practical limitations.
2020-10-07
For a Bragg mirror, why are there smaller reflectivity peaks outside the main one?
The author's answer:
That's not easy, but best understood in cases with a few layer pairs and a low reflectivity per layer pair, where we can neglect effects of multiple reflections. The reflected light amplitude is then the superposition of one amplitude contribution per layer pair. The wavelength offset from the wavelength of peak reflectivity determines the phase change between two such contributions. If you had only two of those, you would get a purely oscillatory behavior of reflectivity vs. wavelength. With more of them, it gets more complicated, but certainly you shouldn't expect the reflectivity to monotonously decay for increasing phase changes.
Mathematically, you can approach that with a Fourier transform, e.g. applied to a rectangular function resembling amplitude contributions from some finite length in which you have the refractive index oscillations.