Metal-mesh optical filters are optical filters made from stacks of metal meshes and dielectric. They are used as part of an optical path to filter the incoming light to allow frequencies of interest to pass while reflecting other frequencies of light.
Metal-mesh filters have many applications for use in the far infrared (FIR)[1] and submillimeter regions of the electromagnetic spectrum. These filters have been used in FIR and submillimeter astronomical instruments for over 4 decades,[2] in which they serve two main purposes: band-pass or low-pass filters are cooled and used to lower the noise equivalent power of cryogenic bolometers (detectors) by blocking excess thermal radiation outside of the frequency band of observation,[3] and band-pass filters can be used to define the observation band of the detectors. Metal-mesh filters can also be designed for use at 45° to split an incoming optical signal into several observation paths, or for use as a polarizing half-wave plate.[4]
Transmission line theory can be applied to metallic meshes to understand how they work and the overall light transmission properties of groups of metallic meshes grouped together.[5] Modeling the properties of these metallic meshes allows for reliable manufacture of filters with the desired transmission properties.
In 1967 Ulrich showed that the optical transmission properties of a metallic mesh can be modeled by considering the mesh to be a simple circuit element on a free space transmission line. To develop the theory of metallic meshes, he focused on the properties of two types of mesh structure: a metallic grid with square openings; and a grid of metallic squares supported on a thin dielectric substrate. Using the transmission line method, he then modeled the behavior of each of these meshes as either lumped inductance (square openings) or a lumped capacitance (free-standing squares). These two types of meshes are commonly referred to as inductive or capacitive meshes.[2]
The theory developed by Ulrich to explain light transmission by metallic meshes makes a few assumptions and idealizations, which will be used here as well in explaining the theory. This theory is valid for thin meshes, i.e.
t<<a
λ>g
Electromagnetic theory of light can be used to describe how light incident on both capacitive and inductive metallic meshes will behave in transmission, reflection, and absorption.
If an incident plane wave of electromagnetic radiation hits a metallic grid of either type perpendicular to its path it will scatter, and the only propagating parts will be the zeroth order reflected wave and the zeroth order transmitted wave. The frequency of both of these electric fields will be equal, and the ratio of their amplitudes is
\Gamma(\omega)
\Gamma
\omega=g/λ
\tau(\omega)
\tau(\omega)=\left[1+\Gamma(\omega)\right]
Since we are neglecting losses, the amplitude squared of the reflected and transmitted waves must equal unity:
\left|\Gamma(w)\right|2+\left|\tau(\omega)\right|2=1
Given these two relations, the phase of the reflection coefficient,
\phi\Gamma(\omega)
\phi\tau(\omega)
\left|\tau(\omega)\right|2
\sin2\phi\Gamma=1-\left|\tau(\omega)\right|2
\sin2\phi\tau=\left|\tau(\omega)\right|2
Solving these equations lets us find the amplitude of the scattered wave in terms of the phases of the reflected and transmitted waves:
\left|\Gamma(\omega)\right|2=\sin2\phi\Gamma(\omega)=1-\sin2\phi\tau(\omega)
The result of drawing
\Gamma(\omega)
\omega
\left[Re(-1/2),Im(0)\right]
\left(Im(\Gamma(\omega))>0\right)
\left(Im(\Gamma(\omega))<0\right)
\omega
\left(\phi\tau(\omega)\ne\phi\Gamma(\omega)\right)
Until now, the theory has been general—whether the mesh was inductive or capacitive has not been specified. Since
\tau(\omega)
\Gamma(\omega)
\left[\tauind+\taucap\right]=1
Given the relations between the reflected and transmitted waves found earlier, this means that the transmitted wave in an inductive grid is equal to the negative of the reflected wave in a capacitive grid and vice versa, and also that the transmitted powers for capacitive and inductive grids sum to unity for a unit incident wave.
\tauind\left(\omega\right)=-\Gammacap(\omega)
\taucap\left(\omega\right)=-\Gammaind(\omega)
\left|\taucap(w)\right|2+\left|\tauind(\omega)\right|2=1
Solving for the exact form of
\taucap\left(\omega\right)
\tauind\left(\omega\right)
\omega → 0
\tauind\left(\omega → 0\right)=0
\taucap\left(\omega → 0\right)=1
Because the grids are complements of each other, these equations show that a capacitive mesh is a low-pass filter and an inductive mesh is a high-pass filter.
Up until now, the theory has only been considering the ideal case where the grids are infinitely thin and perfectly conducting. In principle grids with finite dimensions could also absorb some of the incident radiation either through ohmic losses or losses in the dielectric supporting material.
Assuming that the skin depth of the metal being used in the grids is much smaller than the thickness of the grid, the real part of the surface impedance of the metal is
\rho=1/\delta\sigma
\sigma
\delta
\Gamma(\omega)
2\Gamma(\omega)
\bar{J}=\Gamma(\omega)*c/4\pi
Given the average surface current and the surface impedance, we could calculate the power dissipated as
PD=2\rho\bar{J}2
η
η=g/2a
η=1/(1-2a/g)
PD=2\rhoη\bar{J}2
A=Pd/Po
Po
A=\left|\Gamma\right|22\rhoη=\left|\Gamma\right|2η\left(
| c | |
| λ\sigma |
\right)1/2
For microwave and infrared radiation incident on copper, this unitless absorptivity comes out to be
10-4
10-2
For single layer metallic grids, the simple theory Ulrich laid out works quite well. The functions
\left|\taucap(\omega)\right|2
\left|\tauind(\omega)\right|2
\phicap\left(\omega\right)
\phiind\left(\omega\right)
\Gamma(\omega)\phi(\omega)
In order to build filters out of metallic meshes with the desired properties, it is necessary to stack many metallic meshes together, and while the simple electromagnetic theory laid out above works well for one grid, it becomes more complicated when more than one element is introduced. However, these filters can be modeled as elements in a transmission line, which has easily calculable transmission properties.
A transmission line model of metallic meshes is easy to work with, flexible, and is readily adapted for use in electronic modeling software. It not only handles the case of a single metallic grid, but is easily extended to many stacked grids.
Under the conditions of normal incidence and
\omega<1
2Y(\omega)
\Gamma(\omega)
\tau(\omega)
\Gamma(\omega)=
| -Y(\omega) | |
| 1+Y(\omega) |
\tau(\omega)=
| 1 | |
| 1+Y(\omega) |
which of course satisfy the original relation between the transmission and reflection coefficients:
\tau(\omega)=\left[1+\Gamma(\omega)\right]
In a lossless circuit, the admittance becomes a purely imaginary susceptance,
Y\left(\omega\right)=iB(\omega)
B\left(\omega\right)
\omega
Bind\left(\omega\right)Bcap(\omega)=-1
To calculate the behavior of an ideal metallic grid, only
B\left(\omega\right)
B\left(\omega\right)
L
C
R
2C
L/2
Lind=Ccap
\omega → 1
\taucap\left(\omega → 1\right)=0
\tauind\left(\omega → 1\right)=1
The behavior of the transmission in the two limiting cases can be replicated with the transmission line model by adding an extra element. In addition, losses can be taken into account by adding another resistance
R
\left(\omega=\omegao\right)
Zo=i\omegaL=1/i\omegaC
Zo
\omegao
a/g
R
R=η/2\left(
| c | |
| λ\sigma |
\right)1/2
| Normalized Impedance Zo\left(\omegao\right) | Zo=i\omegaL=1/\left(i\omegaC\right) | |||||||||||||||||||||||||||||||||||||||||||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Generalized frequency \Omega\left(\omega\right) | \Omega\left(\omega\right)=\left(\omega/\omegao\right)-\left(\omegao/\omega\right)=\left(λo/λ\right)-\left(λ/λo\right) | |||||||||||||||||||||||||||||||||||||||||||||||||||
| Normalized admittance Y\left(\omega\right) |
|
| ||||||||||||||||||||||||||||||||||||||||||||||||||
| Reflectivity \left | \Gamma\left(\omega\right)\right | ^2 |
|
| ||||||||||||||||||||||||||||||||||||||||||||||||
| Transmissivity \left | \tau\left(\omega\right)\right | ^2 |
|
| ||||||||||||||||||||||||||||||||||||||||||||||||
| Reflected phase \phi\Gamma\left(\omega\right) | \pi-\arctan{\left(
\right)} | \pi+\arctan{\left(
\right)} | ||||||||||||||||||||||||||||||||||||||||||||||||||
| Transmitted phase \phi\tau\left(\omega\right) |
\right)} |
\right)} | ||||||||||||||||||||||||||||||||||||||||||||||||||
| Absorptivity A\left(\omega\right) | 2R\left | \Gamma\right | ^2 | |||||||||||||||||||||||||||||||||||||||||||||||||
The real power in this model is it allows prediction of the transmission properties of many metallic grids stacked together with spacers to form interference filters. Stacks of capacitive grids make a low-pass filter with a sharp frequency cutoff above which transmission is almost zero. Likewise, stacks of inductive grids make a high-pass filter with a sharp frequency cutoff below which transmission is almost zero. Stacked inductive and capacitive meshes can be used to make band-pass filters.
The transmission line model gives the expected first-order transmission of the stacked metal mesh filters; however, it cannot be used to model transmission of light that is incident at an angle, loss in the supporting dielectric materials, or the transmission properties when
λ<g
The manufacture of metal-mesh filters starts with photolithography of copper on a substrate, which allows fine control over the parameters
a
g
t
≈ .4\mum
.9\mum
1.5\mum
There are two ways to create a multi-layer metal-mesh filter. The first is to suspend the separate layers in supporting rings with a small gap which is either filled with air or under vacuum between the layers. However, these filters are mechanically delicate. The other way to build a multi-layer filer is to stack sheets of dielectric between the layers of metallic mesh and hot press the whole stack together. This results in a filter that is one solid piece. Hot pressed filters are mechanically robust and when impedance matched to vacuum show a pass-band fringe due to Fabry-Perot interference in the underlying dielectric material.
These filters have been used in FIR and submillimeter astronomical instruments for over 4 decades, in which they serve two main purposes: band-pass or low-pass filters are cooled and used to lower the noise equivalent power of cryogenic bolometers by blocking excess thermal radiation outside of the frequency band of observation, and band-pass filters can be used to define the observation band of the detectors. Metal-mesh filters can also be designed for use at 45° to split an incoming optical signal into several observation paths, or for use as a polarizing half-wave plate.