Astronomical Observing Techniques 2019 Lecture 11: How to ...por/AOT2019/docs/AOT_2019_L11... ·...
Transcript of Astronomical Observing Techniques 2019 Lecture 11: How to ...por/AOT2019/docs/AOT_2019_L11... ·...
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Content
1. Introduction2. Prisms3. Diffraction Gratings4. Echelle Spectrographs + Cross-Dispersion5. Grisms6. Multi-Object & Integral Field Spectrographs7. Fourier Transform Spectrometers
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Solar spectrum
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Courtesy: SDSS
Sloan Digital Sky Survey Spectra
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Spectroscopy of Extended Objects• 3 dimensions to measure
– two spatial/angular dimensions, one wavelength dimension
while in general detectors are 2D
• Slicing the 3D data cube– (narrow-band) filters: scan in wavelength
– slit spectrograph: spectra along one spatial dimension
– multi-object spectroscopy, integral field units (IFU)5
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1. Slit: sample one dimension of telescope image2. Collimator: collimate (make parallel) diverging
light3. Disperser: spectrally disperses the light4. Camera: focus spectrum onto detector
Slit spectrography: Components
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Spectrograph Characteristics• Spectral range• Spectral resolution element: Δλ
• smallest spectral feature that can be resolved• FWHM of line that is not resolved• not the same as pixel size
• Spectral resolution (or resolving power) R:R=λ/Δλ
• R < 100: low spectral resolution• R ≈ 100-10000: medium spectral resolution• R > 10000: high spectral resolution
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Spectrograph Characteristics• Instrumental profile P(λ) broadens infinitely
narrow line: • to observed line width:
• Instrumental profile often determines spectral resolution element, which should be Nyquist-sampled
• Transmission determines throughput
η λ( ) = Iout λ( )Iin λ( )
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For unresolved spectral lines, both the S/N and the line/continuum contrast increase with increasing resolution
Model spectra of C2H2 at 900K and HCN at 600K (assumed Doppler broadening ~4 km/s) at different spectrograph resolutions (figure provided by F. Lahuis).
Spectral Resolution and S/N
R=2000 R=50000
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Prism
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δ(λ)
• good for low-resolution spectroscopy
• no order overlap• angular dispersion dδ/dλ
depends on wavelength
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∂δ
∂λ=
sinα
cosθo cos ′θ i
⋅∂n
∂λsin ′θ i =
sinθ i
nsinθo = n sin α − ′θ i( )
See Kitchen on Prisms, Chapter 4
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• angular dispersion dδ/dλ maximized with high-dispersion dn/dλ glass
Angular Dispersion
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Diffraction GratingGrating introduces optical path difference as function of angle to surface normal
λ = wavelengthd = distance between
equally spaced grooves
α = angle of incoming beam
β = angle of reflected beam
θB = Blaze angle
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Condition for constructive interference given by grating equation:
• Maximum spectral resolution R given by R=mN *N = number of groovesm = diffraction order
• Angular dispersion: *
Grating Spectral Resolution
mλ = d ⋅ sinα ± sinβ( )
dβ / dλ = md cosβ
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m = order of diffraction
* A non-trivial derivation: this is the limiting case of considering imaging by a linear ensemble of equidistant small apertures illuminated by a plane wave. For derivations see Kitchin: Astrophysical Techniques. .
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Blaze Angle• Periodic structure distributes energy over many orders• Observing only one arbitrary order is inefficient• For blazed gratings the directions of constructive
interference and specular reflection coincide:
Advantage:• High efficiency
Disadvantage:• Blaze angle θB (and blaze
wavelength λB) fixed by construction
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Blaze angleA blazed grating has grating lines lines that possess a triangular, sawtooth-shaped cross section, forming a step structure. The steps are tilted at the so-called blaze angle θB with respect to the grating surface. Accordingly, the angle between step normal and grating normal is θB. The blaze angle is optimized to maximize efficiency for the wavelength of the used light. Descriptively, this means θB is chosen such that the beam diffracted at the grating and the beam reflected at the steps are both deflected into the same direction. Commonly blazed gratings are manufactured in the so-called Littrow configuration.
16https://en.wikipedia.org/wiki/Blazed_grating
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Free Spectral RangeDifferent diffraction orders overlap with each other:
Free spectral range is largest wavelength range for a given order that does not overlap with an adjacent order
mλ = d sinα + sinβ( ) = m +1( ) ′λ
mfreellll¢
=¢-=D18
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Overlapping Grating Orders
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www.stargazing.net/david/spectroscopy/SpectraL200F4T5Dorders.html
𝜆
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Grating equation in Littrow configuration (α=β): mλB=2d sinβ
Want high dispersion
and high spectral resolution
α and β large, high order m (≈ 50): grating is strongly tilted
Echelle Gratingsdβdλ
= md cosβ
= sinα + sinβλ cosβ
R = Nm
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Linear dispersion in length Lon detector per wavelength, often in mm/nm:"#"$= 𝑓 ' "(
"$with f the focal length of the camera lens/mirror
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Littrow configuration The Littrow configuration is a special geometry in which the blaze angle is chosen such that diffraction angle and incidence angle are identical. For a reflection grating, this means that the diffracted beam is back-reflected into the direction of the incident beam (blue beam in picture). The beams are perpendicular to the step and therefore parallel to the step normal. Hence it holds in Littrow configuration
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Diffraction at a blazed grating. The general case is shown with red rays; the Littrow configuration is shown with blue rays
https://en.wikipedia.org/wiki/Blazed_grating
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Cross-Dispersion
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Spatially separate orders with an additional dispersive element such as low-dispersion prism/grating with dispersion direction perpendicular to that of high-dispersion grating
è
high dispersion
cros
s di
sper
sion
Pre-disperser
Echelle grating
Detector
order n
order n+1
order n+2
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Echelle SpectrographOperation in high order à cross-disperser is essential
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McMath-Pierce Spectrograph
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Cross-Dispersed Echelle Spectrum
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echelle spectrum of V454 Aur
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GrismsGrism = transmission GRating + prISMFor one wavelength and diffraction order, refraction of grating and prism may compensate and optical axis remains (almost) unchanged.Advantage:• ideal to bring in and out of a
collimated beam (“filter wheel”)Disadvantages:• difficult to manufacture (replication
and gluing or by direct ruling).• can be quite “bulky” (ß filter wheel)
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Multi-Object Spectrographs
Use numerous “slits” in the focal plane simultaneously à multiple source pick-ups using fibers or mirrors.
Needs different slit masks for different fields.
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Hydra Arbitrary Fiber Positioning
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Hydra Arbitrary Fiber Positioning
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Multi-Object Spectrograph Spectra
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Integral Field SpectrographsCut area on sky into adjacent slices or sub-portions, realign them optically into one long slice and treat it as a long slit spectrograph.
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Fourier Transform Spectrometer (FTS)
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• Michelson interferometer with one moving arm to change optical pathlength
• Mostly single pixel as detector
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• Output intensity I(x) for a monochromatic input intensity I0 (with wave number k=2π/λ and path length difference x) is:
• Source with spectrum I0(k) in range [k1,k2] produces signal
• Constant term plus real part of Fourier transform of spectrum
FTS – Measured Intensity
I x( ) = I021+ coskx( )
I x( ) = 12
I0 k( )k1
k2
∫ 1+ coskx( )dk
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FTS – Measured Intensity• For each path-length difference x, all spectral
elements of incident spectrum contribute to signal
• Only one Fourier component is measured at any given path-length difference x
• Spectral resolution with maximum path length difference xmax is R=2xmax/λ
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FTS – Output Signal
• For each moving mirror position, broadband (integrated over wavelength) intensity is measured
• Measured signal is an interferogram• Interferogram is Fourier transform of object spectrum
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Pros & Cons of Different Spectrographs
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Spectrometer Advantages DisadvantagesLong-slit • relatively simple à high
throughput• easy to calibrate and to remove skylines
• only one object at a time• inefficient use of detector space
Echelle • high spectral resolution• efficient use of detector
• challenging grating/optics• limited instantaneous λ range
Integral field • instantaneous 2D info• ideal for resolved objects
• complex optics• single objects only
Multi-object • up to thousands of spectra• ideal for spectral surveys
• complex mechanisms to select fields• fibre transmission limits λ
Fourier-transform (FTS)
• very high resolution• imaging FTS possible
• less gain with high background• high resolution ó wide interval• difficult in cryo instruments