Freezer Boxes for Frequency Combs: The First Team Trip to HET

Posted on April 18, 2014 by Paul M Robertson

HPF team members Suvrath Mahadevan, Larry Ramsey, Eric Levi, and Paul Robertson just returned from our team excursion to McDonald Observatory in west Texas.  The purpose of our trip was to set up an enclosure room for our instrument calibration system, but we made time for a number of other interesting detours as well.  The HET telescope is currently down while it is being upgraded to accommodate the HETDEX project, so we peeked behind the curtain of the takedown and re-assembly of the telescope.  Let’s look through some pictures and highlights from the trip!

Main Mission: HPF Calibration Enclosure

To achieve the Doppler precision necessary to discover habitable planets, HPF will employ a state-of-the-art wavelength calibration system, including a laser frequency comb being developed by our NIST colleagues.  While the frequency comb and the rest of the calibration system will be the subject of future posts, for now it suffices to say that the calibration equipment is a large system that must be housed in a controlled environment separately from the spectrograph itself.

The instruments installed on HET are kept in a basement below the telescope, and each one stays inside its own insulated enclosure.  While one might intuitively expect these enclosures to be made of some sort of “space-age” technology, the reality is a bit more mundane.  As it turns out, the same technology that keeps the meat fresh at your local butcher shop is more than adequate for insulating our instruments!  Lovingly known as “meat lockers,” commercial food refrigeration units are used by HET to house its instruments.  On this trip to McDonald, we laid out and assembled a “meat locker” for the HPF calibration system.

meatlocker_completeIMG_2858Left: Suvrath and Paul prepare to lift the roof onto the enclosure. Right: The complete “meat locker” for the HPF calibration system.

The enclosure for the HPF spectrograph itself will be quite a bit bigger, and is being custom ordered.  When it is installed, the HET basement will quickly become much more crowded!

Sightseeing at the Dismantled HET

Since the HET is down for the HETDEX installation, normal daytime operations allow for moments of looking around at the bits and pieces of the telescope that are currently undergoing maintenance and/or alteration.

HET mirror cleaning.

HET mirror cleaning.

The above image does a good job of illustrating the current overall state of the HET.  The net/tarp above the mirror is in place to prevent objects (wrenches, bolts, people!) involved in the dismantling and re-assembly of the telescope from falling onto the mirror.  Also note all the teal space around the mirror–those are normally covered with mirror segments!  The segments not currently on the telescope are being cleaned and re-coated so that when science operations resume we’ll have a pristine mirror.  For those remaining on the telescope, the technician on the lift is performing a regular cleaning with a carbon dioxide bath.

An HET technician cleans a bare Zerodur mirror segment. The HET primary mirror has 91 such segments!

Logan Schoolcraft carefully and painstakingly cleans a bare Zerodur mirror segment. The HET primary mirror has 91 such segments!

New hardware for the HETDEX wide-field upgrade is in house as well.  The support structure for the VIRUS spectrograph units is now mounted on the side of the telescope, but it is so big it’s difficult to photograph from the dome floor!  Perhaps more exciting is the hexapod unit, which will hold the new wide-field corrector on the telescope tracker:

Eric and Paul with the new HET hexapod assembly. Thanks to the mountain staff for the pretty pink hard hats.

Eric and Paul with the new HET hexapod assembly. Thanks to the mountain staff for the pretty pink hard hats.

While the hexapod is being installed as part of the HETDEX project, it is important for HPF as well, since its role in stably tracking telescope targets is crucial for the RV stability of the spectrograph.

The (long) Voyage Home: Bringing Back MRS

In order to make room for HPF at HET, we have recently decommissioned the Medium Resolution Spectrograph or MRS.  Since the instrument was built by Penn State (PI: Larry Ramsey), we had to transport the actual parts of the spectrograph back to State College.  Rather than have the equipment shipped at considerable cost and risk, we rented a truck and drove the instrument home ourselves.  If you thought loading your couch into a moving truck was tough, try doing the same thing with a 14-foot optical bench that weighs 2000 pounds!

Loading the large MRS optical bench for transport to PSU.

Loading the large MRS optical bench for transport to PSU.

Over the next few days, Eric and Paul saw quite a bit of the American landscape as they drove the truck back to State College.  They were actually on pace to make the trip in just two days, but an unfortunate transmission failure extended the journey by a day and forced an extremely difficult load swap to a new truck in a Nashville parking lot.

Eric Levi rides in the sleeper section of the 18-wheeler wrecker towing our broken-down truck to a service center.

Eric Levi rides in the sleeper section of the 18-wheeler wrecker towing our broken-down truck to a service center.

Eventually, MRS was delivered safe and sound to PSU, and the drivers got a visit to the delicious Chuy’s Mexican restaurant in Nashville for their troubles.

As you can see, building a world-class spectrograph requires quite the skill set.  An extensive background in physics, engineering, construction, food storage, and truck driving is recommended!

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The Echelle Grating

Posted on March 19, 2014 by Paul M Robertson

As fate would have it, the start of the HPF blog coincides with the arrival of the heart of the spectrograph itself: the echelle grating.  Since the grating is so important to the workings of HPF, let’s take a moment to go over its purpose and function.

Inspection of the grating (center) to ensure it was undamaged during shipping.

Suvrath Mahadevan (HPF PI) inspecting the echelle grating to ensure it was undamaged during shipping.

What is a grating?

A spectrograph operates by separating incoming light (in our case, starlight) into its constituent wavelengths in a process called diffraction.  Diffraction is observed most commonly with a prism; the rainbow of colors that emerges from the prism is just the incoming light separated into individual wavelengths.

While some spectrographs do use prisms, HPF will use a grating instead.  A grating works in a similar manner, but instead of splitting wavelengths by using glass to change the index of refraction, a grating uses finely-ruled or spaced surfaces to create interference between light waves.

Diffraction via grating (1) and prism (2). (Image courtesy Cmglee via Wikimedia Commons)

Diffraction via grating (1) and refraction via prism (2). (Image courtesy Cmglee via Wikimedia Commons)

Our grating works slightly differently from the image shown above, as it will reflect (rather than transmit) light.  In addition, our echelle grating is blazed so that the the light is efficiently dispersed into certain high orders to enable high dispersion and high efficiency.

What is it made of ?

The 125mm thick grating is made on a single block of Zerodur.  Zerodur has a very low coefficient of thermal expansion and helps to keep the grating length changes minimal, even at 180 K.  The top layer of the grating is coated with pure unprotected gold to enable high reflectivity in the near-infrared wavelengths.

How will HPF use the grating?

As described on our “What is HPF?” page, we will search for planets by looking for the Doppler motion of a star’s absorption lines as an orbiting planet’s gravity causes the star to “wobble.”  The grating is what allows us to observe the stellar lines in the first place.  When we observe a stellar spectrum (the rainbow from our prism example), there are dark bands where atoms in the star’s atmosphere have absorbed light at that particular wavelength.  These are the lines that we use to measure the stellar motion, or radial velocity.  Along with the telescope, the grating is the key to the whole project!

Of course, as a facility instrument at the Hobby Eberly Telescope, HPF will be used for all sorts of interesting science projects.  If you can think of an astronomical experiment that requires a high-resolution infrared spectrum, there’s a good chance that HPF will be used for it!

What makes this grating special?

Our grating is a specially replicated mosaic grating manufactured for us by Newport Richardson Grating Labs. The high blaze angle, size, stability and goal coating are all optimized for the particular application of searching for planets around low-mass stars.

The large mirror diameter of the HET (nearly 11 meters!) means the grating must also be physically very large.  Manufacturing something so delicate and precise on such a large scale is quite costly, making the grating one of the most expensive individual components of HPF.  Its 125 pound weight also makes handling difficult!

Suvrath, Eric and Ryan lift the grating onto the table for inspection. Not an easy lift!

Eric Levi, Ryan Terrien, and Suvrath lift the grating onto the table for inspection. Not an easy lift!

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