Infrared Telescopes
Jansky Units and Infrared Radio Telescopes
1 Jansky is 1e-26 W/m2-Hz. Hz implies bandwidth. The bandwidth of a radio telescope is obvious - the bandwidth in Hertz, probably after a chilled reflector into a chilled low noise amplifier, then through a filter. A wider filter picks up more power, and more thermal noise. So the power in Janksy units for a source is 
Power Received
(Area(f2−f1)
Infrared telescopes have much wider bandwidth, and infrared is typically characterized with wavelength (usually micrometers) rather than Hertz. We can recast the formula as
Jy~=~1e26*(P/A)*c*(1/\lambda_2-1/\lambda_1)~=~1e26*(P/A)*c(\lambda_1-\lambda_2)/(\lambda_1\lambda_2)
where c is the speed of light. Defining \Delta\lambda~=~\lambda_1-\lambda_2 and center wavelength \lambda = \sqrt{\lambda_1\lambda_2}, this simplifies to:
Jy ~=~ 1e26*(P/A)*c~\Delta\lambda/\lambda^2
So, how much is that? A parsec is 3.26 light years or 3.0857e16 meters, like a star that appears to move one arcsecond in the sky as the earth moves 1 AU across its orbit. So, a sphere 1 AU in diameter would appear one arc-second across from 1 parsec away. From 200 parsecs away ( 6.1714e18 meters ), a sphere 100 AU in radius or 200 AU in diameter, and heated by the entire sun's output (3.86e26 W), would be about 60K, and deposit all that power on a 200 parsec diameter sphere with an area of 4.786e38 square meters, a power density of 8.07e-13W/m2. We still don't know enough to compute the Jansky units, because we don't know the bandwidth. That is a function of the filtering and imager on our telescope - and if the telescope is not in orbit, the passband and emissions of the atmosphere.
Dyson Server Sky
A shell 100 AU in diameter at 60K enclosing the 3.84e26 Watt sun. Peak emissions at 48μm and a power flux of 0.1366 W/m2. The in-band fraction of total black body emissions as a function of the mean wavelength λ and the wavelength concentration λ/Δλ can be computed from this C program: irin01.c. The program expects three command line arguments - temperature T , λ, and λ/Δλ. irin01.c computes various parameters, including the fraction of total power in-band. It is a bit of a kludge!
James Webb Space Telescope
NASA's JWST Mid Infrared Instrument (MIRI), scheduled to deploy in 2018, will be the most powerful long distance infrared imager available, with a 6.5 meter mirror. The imager is a 1024x1024 pixel Raytheon Si:As sensor chip assembly (SCA) with 25 µm pixels. The pixels are 0.11 arcseconds. JWST seems to be optimized for looking for liquid water.
This table gives the sensitivity, recomputed below,
- (detection limit, 10 sigma, 10,000 seconds)
Assuming 3.84e26 Watts, The point source detection distance is sqrt( fraction * 3.84e26 / 4 π 3.0857e16 2 sensitivity ) parsecs
- = 1.8e-4 sqrt( fraction / sensitivity ) parsecs.
|
λ |
λ/Δλ |
sensitivity |
λ0 |
λ1 |
Δλ |
300K power |
300K |
60K power |
60K |
|
|
μm |
|
μJy |
W/m2 |
μm |
μm |
μm |
fraction |
parsec |
fraction |
parsec |
F560W |
5.6 |
5 |
0.16 |
1.7e-20 |
6.19 |
5.07 |
1.12 |
3.22e-02 |
250000 |
1.43e-13 |
0.5 |
F770W |
7.7 |
3.5 |
0.25 |
2.8e-20 |
8.88 |
6.68 |
2.20 |
1.30e-01 |
390000 |
6.32e-09 |
85 |
F1000W |
10 |
5 |
0.54 |
3.2e-20 |
11.05 |
9.05 |
2.00 |
1.35e-01 |
370000 |
6.72e-07 |
820 |
F1130W |
11.3 |
16 |
1.35 |
2.2e-20 |
11.66 |
10.95 |
0.71 |
4.54e-02 |
370000 |
1.24e-06 |
1300 |
F1280W |
12.8 |
5 |
0.84 |
3.9e-20 |
14.14 |
11.58 |
2.56 |
1.46e-01 |
350000 |
3.74e-05 |
5500 |
F1500W |
15 |
5 |
1.39 |
5.6e-20 |
16.57 |
13.57 |
3.00 |
1.36e-01 |
280000 |
2.79e-04 |
13000 |
F1800W |
18 |
6 |
3.46 |
9.6e-20 |
19.56 |
16.56 |
3.00 |
9.66e-02 |
180000 |
1.44e-03 |
22000 |
F2100W |
21 |
4 |
7.09 |
2.5e-19 |
23.79 |
18.54 |
5.25 |
1.19e-01 |
120000 |
7.98e-03 |
32000 |
F2550W |
25.5 |
6 |
26.2 |
5.1e-19 |
27.71 |
23.46 |
4.25 |
5.78e-02 |
19000 |
1.69e-02 |
33000 |
Herschel
ESA's Herschel Space Telescope, active from 2009 to 2013, has a 3.5 meter mirror and a wavelength range of 55 to 672 μm. The Photodetector Array Camera and Spectrometer (PACS) uses two low resolution arrays of bolometers:
Red |
16x32 |
6.4as |
Blue |
32x64 |
3.2as |
These measure in 3 bands, either 70 alone or 100 and 160 together:
70 |
60 to 85 μm |
5 mJy (5σ, 1h) |
100 |
85 to 130 μm |
5 mJy (5σ, 1h) |
160 |
130 to 210 μm |
10 mJy (5σ, 1h) |