Mirror Cleaning Experiment: I. Interim report
Sloan Digital Sky Survey Telescope Technical Note 19960113
Bruce
Balick, G. H. Kim, Wayne Kimura, Mark
Klaene,
Walter Siegmund and Patrick Waddell
Introduction
Contamination on optical surfaces degrades the throughput of an
optical system. Equally troublesome is the increase in scattered
light due to contamination. Contamination is particularly pernicious
on the unprotected aluminum that is commonly used on the large
first-surface mirrors of reflecting telescopes. Unprotected aluminum
is so soft that vigorous cleaning damages the coating. As the
aluminum coating corrodes, the short wavelength scattering and
reflective properties degrade especially rapidly. Because of their
size, such mirrors are costly to realuminize. Furthermore, risk to
the optic from the handling necessary for realuminization can be
minimized, but not eliminated.
Unprotected aluminum mirrors are often realuminized at one to two
year intervals. Significant degradation of performance often occurs
prior to aluminization. It is believed that much of the irreversible
portion of degradation is due to corrosion of the aluminum
coating.
We can speculate as follows regarding the mechanism for the
degradation of the aluminum surface. As long as surface contamination
is dry, it is likely that little degradation occurs. However, when
exposed to the night sky, the particles radiate more energy in the
thermal infrared than they absorb from the sky and cool below the
ambient air temperature. If they cool below the dew point, water
vapor will condense on the particles. Moreover, many contaminants are
hygroscopic and will absorb water at temperatures well above the dew
point. Occasionally, despite the best efforts of the telescope
operators, precipitation may fall directly on the mirror thereby
wetting the contamination.
Once contamination is wet, soluble substances will be dissolved.
Often, the result will be an alkaline solution that will rapidly
attack the aluminum coating. Upon drying, deposited salts and the
parent contamination are likely to be strongly attached to the
surface and cleaning is not likely to dislodge them.
It is obvious that the longer contamination resides on the mirror
surface, the more likely it is that it will become wet and degrade
the surface. (We imagine that wetting events are episodic, e.g.,
associated with high humidity or precipitation.) Consequently,
frequent cleaning should minimize degradation.
The experiment
Six test mirrors are exposed to contamination and cleaned on a
nominal biweekly schedule (Table 1). Each mirror is a ø102 mm
polished silicon wafer coated with 100 nm of aluminum. The mirrors
are mounted on the 3.5-m telescope for a week at a time. During that
period, the covers of their protective cases is opened whenever the
3.5-m telescope primary mirror cover is opened for nighttime
observing.
Table 1: Schedule of mirror exposure and cleaning.
Week #1
Monday
Frequent Flyer (FF) case arrives at Apache Point Observatory (APO).
Tuesday AM
FF case reinstalled in 3.5 telescope.
FF case covers and Sessile (SS) case covers removed.
Measure FF, SS, and control mirrors with scatterometer.
Install control mirror cover.
Week #2
Tuesday AM
Remove control mirror cover.
Measure FF, SS, and control mirrors with scatterometer.
Install FF case covers, dismount, and ship to STI.
Install control mirror cover.
CO2 clean exposed mirrors in SS case.
Install SS case cover.
Thursday
FF arrives at STI, Bellevue, Washington.
Friday
FF#1 mirrors are CO2 cleaned.
FF#2 mirrors are laser cleaned.
Light scattering measurements performed on cleaned mirrors.
Ship FF case to APO.
Scattering measurements at APO were made using a µScan
Scatterometer manufactured by TMA Technologies, Inc., P.O. Box 3118,
Bozeman, MT 59715, (406)586-7684. To describe this instrument, we use
zenith angle and azimuth angle with the surface assumed horizontal.
The reflected beam azimuth angle is zero. This instrument uses a 670
nm laser diode light source located at 25° from the surface
normal (25°,180°). One scatter detector is located on the
surface normal (0°,0°). The other is 50° from the
surface normal (50°,180°). The reflectance detector is
mounted in a light trap (25°,0°).
Measurements were made at the center of the test mirrors. The
specular reflectance and bidirectional scattering distribution
function (BSDF) at the angles of the two scatter detectors were
recorded. The BSDF is a generic term that is identical to the
bidirectional reflectance distribution function (BRDF) for a
reflective surface.
where
=
measured scattered power
,
solid angle given by receiver aperture (A) and sample to receiver
radius (R)
= measurement position from surface normal
=
power incident on the sample
For the special case of an ideal Lambertian surface, the BSDF is
and is
independent of angle.
A calibration mirror is measured each time scattering is measured
to monitor the performance of the µScan instrument. This mirror
has a highly reflective, protected and enhanced silver coating.
The laser and CO2 cleaning techniques have been described
elsewhere ("Comparison of Laser and CO2 Snow for Cleaning Large
Astronomical Mirrors", Kimura, W.D., Kim, G.H., and Balick, B.,
PASP 107: 888-895, 1995 September).
Results from the STI Optronics measurements will be reported
later.
Results
Data were taken beginning July 3, 1995 except for a period between
October 17 and November 21 when the telescope was shut down for
maintenance. On November 28 and December 12, the sessile mirrors were
not cleaned due to a lack of CO2.
A plot of all the scattering measurements shows a zig-zag behavior
(Figure 1). The scattering performance is
degraded by exposure. Cleaning tends to restore the surface to
approximately its pre-exposure level although slow secular
degradation occurs. This trend can be seen clearly in those data
obtained after cleaning (Figure 2).
Measurements of the calibration mirror (cal in the Figures) are
quite consistent and small. This we interpret as indicating proper
operation of the instrument. This leaves unexplained the puzzling
behavior of the control mirror that shows more degradation than the
exposed mirrors.
Fig. 1: All scattering measurements.
Fig. 2: Scattering after cleaning.
Discussion
Presumably the amount of degradation that occurs during exposure
is proportional to the integral of the airborne dust concentration
during the interval that the mirrors are exposed, i.e., during
telescope operation. Thus the degradation during exposure is
modulated by both dust concentration and weather. Without examining
observing logs to get exposure time, it is not possible to separate
the two effects. However, independent measurements provide evidence
for time variable dust concentrations at the Very Large Telescope
(VLT) site ("Survey of airborne particle density and the aging of
mirror coatings in the open air at the VLT Observatory", P. Giordano,
M.S. Sarazin, Proc. of S.P.I.E., 2199, 1994, p.977-985). In the next
month or so we plan to implement a dust concentration monitoring
program at Apache Point Observatory to help understand these effects.
In an effort to understand the control mirror measurements, we are
adding a second control mirror.
Acknowledgements
It is a pleasure to thank Eddie Bergeron, Karen Gloria, Dan Long,
and Bruce Gillespie of Apache Point Observatory for their
assistance.
Date created: 01/13/96
Last modified: 03/17/96
Copyright © 1996, Walter A. Siegmund
Walter A. Siegmund
siegmund@astro.washington.edu