Tag: Mt. Wilson

Science’s First Rough Draft

It has often been said that newspapers are “history’s first rough draft.”  The same is true of science.  One could argue that journals fill the role, but historically, the vast majority of the public reads of scientific discoveries and/or events in the newspaper.  It is quite interesting to see how these events were interpreted at the time without the benefit of hindsight.  The New York Times online archive dates back to the paper’s origins in the 1850’s and represent a rich source of historical material that can be used in the class or for personal research.  Here are some historical articles pertaining to astronomy and physics.

Auroral Phenomena – September 5, 1851.  This article describes the aftermath of the Carrington Event, the most powerful magnetic storm in recorded history.  The aurora was seen across America and telegraph operators could still send messages even after disconnecting the batteries.  Below, NASA presents a computer model of the 1859 magnetic storm.

Glowing After – Sunset SkiesDecember 1, 1883.  Three months after the Krakatoa eruption, the skies around the world appeared deep red after sunset as a result of aerosols ejected into the atmosphere.  The cause of these sunsets were not known at the time – the article never refers to the Krakatoa eruption.

A Comet Visible by DaylightSeptember 20, 1882.  The Great Comet of 1882, considered the brightest comet of the past 1,000 years, is visible during the day.  The image atop this post is this comet.  In 2015, the Rosetta mission became the first to attempt a landing on a comet.

The Roentgen DiscoveryFebruary 7, 1896.  The discovery of x-rays and possible applications in the medical field.  A century later, astronomers would use the orbiting Chandra X-Ray Observatory to discover the universe to be a violent place.

Wireless Signals Across the OceanDecember 15, 1901Guglielmo Marconi receives radio signals in Newfoundland from London to open the era of mass communication.  Decades later, astronomers use radio telescopes to discover pulsars and peer into the center of the galaxy.

The Greatest Telescope in the WorldJanuary 27, 1907.  Plans to build a 100-inch telescope on the summit of Mt. Wilson in California.  Opened in 1917, this telescope is where Edwin Hubble discovered the universe was expanding.

Mt. Wilson 100-inch telescope. Credit: Gregory Pijanowski
Mt. Wilson 100-inch telescope. Credit: Gregory Pijanowski

Comet Gazers See Flashes –  May 19, 1910.  Report on Earth passing through tail of Halley’s Comet.  The comet tail was 100 degrees long and 10 degrees wide in the sky.  Whatever was seen that night, comet tails are much too tenuous to cause flashes in the atmosphere.

Lights All Askew in the Heavens – November 10, 1919.  Eddington Expedition proves Einstein’s General Relativity theory correct by measuring the bending of starlight during a total solar eclipse.  Relativity has passed every test since, including the recent observation of gravity waves.

Ninth Planet Discovered on Edge of Solar System – March 14, 1930.  Pluto is discovered.  Since reclassified as a dwarf planet, the New Horizons mission gave us the first close up images of Pluto in 2015.

Nebula Velocities Support EinsteinJune 12, 1931.  Edwin Hubble discovers the expansion of the universe as predicted by Einstein’s relativity theory.  Actually, Einstein was originally skeptical the universe could expand.  It was Fr. Georges Lemaitre, Catholic priest and physicist, who proposed what was later called the Big Bang theory.  The word nebula in the title refers to what we now call galaxies.

Lemaitre Follows Two Paths to TruthFebruary 19, 1933Fr. Georges Lemaitre does not find a conflict between science and religion.  Einstein and Lemaitre, “Have a profound respect and admiration for each other”.  Article quotes Einstein as stating, “This is the most beautiful and satisfactory explanation of creation to which I have ever listened” regarding Lemaitre’s Big Bang theory.

Fr. Georges Lemaitre (center) and Albert Einstein, January 10, 1933. To the left is Robert Millikan who was the first to measure the charge of an electron. Credit: California Institute of Technology.

Bohr and Einstein at OddsJuly 28, 1935.  The conflict between relativity and quantum mechanics.  The quest to unify the theory of relativity, which governs large objects, and quantum mechanics, which explains physics on an atomic scale, continues to this day.

Science and the BombAugust 7, 1945.  One day after Hiroshima, nuclear fission as a weapon and the implications for humanity are explained.

Palomar Observers Dazzled in First Use of 200-inch LensJune 5, 1948.  Delayed by World War II for five years, Mt. Palomar Observatory finally opens for business.

Palomar
Mt. Palomar 200-inch telescope. Largest in the world from 1948-97. Credit: Gregory Pijanowski

Radio Telescope to Expose SpaceJune 19, 1959.  Navy to build largest radio telescope in West Virginia.  The current radio observatory in Green Bank, WV is surrounded by a 13,000 square mile (slightly larger than the state of Maryland) radio quiet zone, meaning no cell phones, radio, or microwave ovens.

New Clues to the Size of the UniverseMarch 26, 1963.  The brightest objects in the universe, dubbed quasars, are discovered.  Located over 10 billion light years away, these objects are so bright some astronomers thought they must reside within the Milky Way.  However, further research would prove quasars to be the most distant objects observed by humans.

Signals Imply a Big Bang UniverseMay 21, 1965.  The discovery of the cosmic microwave background radiation (CMB) proves the universe was born in a hot, dense state aka the Big Bang.  The CMB was most recently mapped by the ESA Planck mission.  The map shows the state of the universe when it was 380,000 years old.

*Image on top of post is the Great Comet of 1882 from the Cape of Good Hope.  Credit:  David Gill.

Mount Wilson – the Birthplace of Solar Physics

Perched 5,710 feet above the Los Angeles Basin in the San Gabriel Mountains, Mt. Wilson Observatory is noted for the ground breaking work of Edwin Hubble during the 1920’s.  In that decade, Hubble would discover galaxies beyond the Milky Way and the expansion of the universe at the observatory’s 100-inch telescope, then the world’s largest.  Located a few hundred feet from the famous telescope lies three solar telescopes whose observations provided the groundwork for our current understanding of the Sun.  This story did not begin in the warm climes of Southern California, but in the Upper Midwest at Yerkes Observatory, 90 miles northwest of Chicago.

The first director of Yerkes Observatory was George Ellery Hale.  The observatory, established in the 1890’s, is dubbed the birthplace of modern astrophysics.  Hale was the guiding force behind the building of the observatory and wanted to move astronomy from the study of the positions of celestial bodies in the night sky to the physics behind those objects.  Hale had an intense interest in the study of the Sun and set out to build a solar telescope on the grounds at Yerkes.  The result was the Snow Solar Telescope built in 1903.  The name of the telescope is not derived from Wisconsin winters, but from Helen Snow of Chicago who anted up $10,000 ($258,000 in 2014 dollars) to build it.  However, poor optical quality necessitated a move of the Snow from Wisconsin to California.

Driving down a highway on a hot summer day, you have probably seen heat waves rising from the ground and distorting your vision.  This effect is magnified if you attempt to take a picture through a telephoto lens.  The Snow Solar Telescope design had a movable mirror (coelostat) reflect the Sun’s image to a 30-inch mirror which in turn reflected the light 60 feet to 24-inch mirror that projected the final 6-inch image of the Sun.  Heats waves from the ground interfered with the image quality as the light traveled its 60 foot path horizontally to its final destination.  Hale thought relocating the Snow to an area with thinner air would reduce the heat interference problem.

As a result, the Snow was dismantled and transported to Mt. Wilson in California in 1904.  One does not normally associate the Los Angeles basin with good optics, but the summit of Mt. Wilson lies above the atmospheric inversion layer that traps the infamous Los Angeles smog like a lid on a pot.  This, combined with the thinner air of the higher altitude, improved the image quality of the Snow.  Hale set out to study sunspots, which would provide the first significant scientific finding from Mt. Wilson.

The Sun on July 28, 1906. Earth superimposed for scale. Credit: Mt. Wilson Observatory.

The oldest known observations of sunspots dates back to 800 B.C. both from ancient Chinese and Korean astronomers.  Historical recordings of sunspot numbers dates back to the 1600’s and constitute one of the longest ongoing scientific programs of observation.  At the dawn of the 1900’s, the nature of these spots on the Sun’s surface were not known.  Among the competing theories at the time were sunspots as debris clouds from solar tornadoes, areas hotter than the surrounding surface, and one of the most colorful ideas, sunspots as holes in a shroud of the Sun that hid a solid surface underneath.  The Snow Solar Telescope would begin the process to clarify the nature of sunspots.

The Snow was equipped with a high resolution spectrograph.  With this, Hale was able to record and compare spectra lines from regions of the Sun’s surface with and without sunspots.  These spectra lines were in turn compared to spectra produced in a laboratory under different temperature regimes.  In the cooler regime, many spectra lines were strengthened, and a few were weakened.  The spectra obtained from sunspots correlated with the spectra obtained in the laboratory in the cooler regime.  Hence, sunspots were regions on the solar surface that are cooler and thus, darker than the surrounding area.  The question remained, why were these regions cooler?  To answer this would require better solar images than the Snow could provide.

As George Ellery Hale was wont to do, he built a bigger and better telescope.  Despite the thinner air at Mt. Wilson, heat interference still proved to be an issue with the Snow.  To solve this, Hale built a telescope with a vertical, rather than horizontal design.  At 60-feet, the new solar tower was completed in 1908.  In his observations of sunspots, Hale was reminded how their structures were similar to the classic iron filings magnetic field experiments.  Based on this hunch, Hale set off to detect the presence of Zeeman lines in sunspot spectra.

60-foot Solar Tower (left) next to Snow Solar Telescope (right). Credit: Gregory Pijanowski
60-foot Solar Tower (left) next to Snow Solar Telescope (right). Credit: Gregory Pijanowski

The black lines seen in spectra are absorption lines.  Different elements absorb light at different wavelengths and this is how astronomers can figure out what stars, including the Sun, are made of.  If an atom absorbs light of the same energy as the difference between two electron orbital levels, the light energy is converted to energy that moves an electron to a higher orbit.  The result is the absorbed light creates a black line on a spectra.  The presence of a magnetic field creates more potential electron orbital levels.  As a consequence, a single absorption line can split into several absorption lines as can be seen below:

Credit: Astrophysics and Space Research Group, The University of Birmingham.

Using the new 60-foot solar tower, Hale was able to detect the presence of Zeeman lines in the spectra of sunspots.  In fact, the magnetic field in sunspots are several thousands times stronger than Earth’s magnetic field.  The intense magnetic fields in these areas of the Sun push plasma convection to areas outside of sunspot regions.  As it is this convection that transports heat to the solar surface, the magnetic blockage of this convection causes sunspots to be cooler by about 2,000 Celsius than the surrounding region.

Hale published this result in 1908six years after Zeeman won the Nobel Prize for his discovery of this effect.  This was the first time a magnetic field was discovered beyond Earth.  Hale would be nominated for a Nobel as a result of this discovery, but ultimately was not awarded.  Health issues eventually forced Hale away from Mt. Wilson, but not before building what would be the largest solar observatory from 1912 to 1962.

Mt. Wilson 150-foot Solar Tower. Photo: Gregory Pijanowski
Mt. Wilson 150-foot Solar Tower. Photo: Gregory Pijanowski

The 150-foot solar tower would be Hale’s last major contribution to solar astronomy.  The 150 foot vertical focal length produces a 17-inch image of the Sun at its base.  It was with this facility that Hale was able to determine the magnetic polarity of sunspots and the 22-year solar cycle.  The 11-year solar cycle had been long known and pertains to sunspot numbers only.  It usually takes 11 years (sometimes longer, sometimes shorter) for the solar cycle to reach one maximum to the next.

Magnetic fields are dipoles.  That is, a magnetic field will have a north and south pole.  Sunspots occur in pairs with one being the north pole and the other being the south pole, albeit at times a single spot in a pair will break up into several spots with the same polarity.  Hale discovered that sunspot pairs exhibit the opposite order of polarity in each solar hemisphere.  The polarities then reverse at the end of each 11-year cycle.  Consequently, a Hale 22-year solar cycle would look like this:

     Cycle (11-years)    Northern Hemisphere   Southern Hemisphere
                   1                        N-S                    S-N
                   2                        S-N                    N-S

The most recent occurrence of polarity reversal happened on January 4, 2008.  This event heralded the arrival of the current solar cycle.

By the mid-1920’s, Hale spent most of his time at his private solar observatory located in his residence in Pasadena.  He passed away in 1938 as work was ongoing for the 200-inch Mt. Palomar Observatory.  A new generation of solar astronomers would carry on his legacy at Mt. Wilson.

In 1957, Horace Babcock would install the first magnetograph in the 150-foot tower.  Rather than just study the strong magnetic fields of sunspots, the magnetograph was sensitive enough to map the magnetic field across the entire solar surface.  Essentially, the magnetograph maps the Zeeman effect across the entire solar disk.  Astronomers would take the work at the 150-foot tower a step further in the 1960’s by using it to study the Sun’s interior with a field called helioseismology.

In 1962, Robert Leighton discovered oscillations all across the solar surface which occurred in 5 minute cycles.  The theoretical modeling of these oscillations were refined by Roger Ulrich, who also kept the 150-foot Solar Tower in operation after the Carnegie Institution pulled their financial support in 1984.  These oscillations are caused by acoustic waves trapped inside the Sun.  Measurements of these waves allowed for modelling the solar interior.  One of the findings is the amount of hydrogen converted to helium in the solar core via fusion reactions.  This finding verified current models of solar evolution.  In other words, we know the Sun will be around for another 5 billion years or so.

The mapping of the solar magnetic field and helioseismology forms a key part of NASA’s current Solar Dynamics Observatory’s mission, as explained in the video below:

During the late 1990’s, I had the opportunity to go inside all three of the Mt. Wilson solar telescopes as a student in the observatory’s CUREA program.  The Snow was used primarily and I’ll never forget cleaning off the direct current switches, seemingly straight out of Frankenstein’s laboratory.  Also had encounters with both tarantulas and rattlesnakes.  In between those adventures, got to study the Sun’s spectrum (just as Hale did 90 years earlier), imaged the Moon at night, and gaze out over the cliff into Pasadena and the Rose Bowl.  The  60-foot solar tower had AC/DC blasting in the observation room, while the 150-foot tower had a visitor’s book signed by both Albert Einstein and Stephen Hawking.

Looking down the ladder on the 150-foot Solar Tower. Credit: Gregory Pijanowski
Looking down the ladder on the 150-foot Solar Tower. Credit: Gregory Pijanowski

Since then, there has been two recessions and a major financial crash.  The result has been cutbacks in funding and a need for the solar towers to reduce staff like many businesses have.  The Snow is still used by CUREA students every summer.  The 60-foot solar tower is run by USC.  The 150-foot tower had its funding shut down and is run on a volunteer basis.  The historic magnetograph made its last observation in 2013.  It could be much worse, in 2009, a forest fire came within a few hundred yards of the observatory which was saved by the efforts of several hundred firefighters.

Below is a video on the current effort to keep the 150-foot solar tower’s record of observations unbroken:

The observatory continues to reinvent itself.  The Pavilion, closed in the 1990’s, is now home to the popular Cosmic Cafe.  The grounds, once open to the public only on weekends is now open daily.  Public viewing is now offered on both the 60 and 100-inch telescopes.  The CHARA interferometer, which had started construction when I was there, is producing scientific results.  How do the solar towers fit in?  The 150-foot tower has been an important link in the continuous observations of sunspots since the early 1600’s.  In fact, those records compose 25% of that history.  And so far, it has been able to continue to do so.  I truly hope that chain is not broken.

*Image on top of post is the 60 and 150-foot towers keeping their vigil on the Sun.  Photo:  Gregory Pijanowski

To Catch a Star

Prior to the New Horizons flyby this month, the best image we had of Pluto came from the Hubble Space Telescope:

Credit: NASA, ESA, and M. Buie (Southwest Research Institute)

This struck me as being very similar to our best image of a stellar surface besides the Sun.  Very few stars have had their surfaces resolved.  Most stars appear as points of light in even the largest of telescopes.  Below is an image of Betelgeuse taken by the Hubble:

Credit: Andrea Dupree (Harvard-Smithsonian CfA), Ronald Gilliland (STScI), NASA and ESA

So the question to ask is, how can we obtain high resolution images of stellar disks as we did with Pluto?  Barring radical advancements in spacecraft propulsion, sending a mission to a star is not feasible.  The nearest star, Proxima Centauri, is 4.24 light years away from us.  The New Horizons probe, which is traveling at 35,000 mph (56,000 km/hr), would take over 100,000 years to reach that destination.  Obviously, the solution is constrained to be Earth bound or near Earth technology.  We need to build telescopes with higher resolution.

The theoretical resolution capability of a telescope is measured by the following equation:

R = 1.22(λ/d)

Where R is resolution in radians, λ is light wavelengths, and d is the diameter of the telescope’s primary mirror.  The smaller the value R, the higher the resolution and the greater the ability of a telescope to resolve finer detail.  Thus, to improve resolution, we’re gonna need a bigger telescope.

The other factor to consider is a telescope’s light gathering ability.  This is directly related to the area of the primary mirror.  If the mirror is circular in shape, this is described as:

A = πr2

Where A is area, π is the constant pi (about 3.14), and r is the radius of the mirror.  The larger A is, the larger a telescope’s ability to collect light.  Thus, a larger telescope can detect dimmer objects in the sky.  It can also detect objects farther away from Earth.  A mirror with a radius of 1 meter has an area of 3.14 square meters.  A mirror with a radius of 2 meters has an area of 12.56 square meters.  In other words, doubling the radius increases the area by four times.  Thus, what a mirror with a radius of 1 meter (diameter of 2 meters) can see 10 light years away, a mirror with a radius of 2 meters (diameter of 4 meters) can see 40 light years away.

To sum up the above, mirror diameter resolves finer detail on an object while surface area will enable more targets to be imaged.

As you might gather from the above, the best stellar targets to resolve would be stars that are very large (and hence, very bright) and relatively close.  And that is why Betelgeuse was the first star to be resolved in 1995 by the Hubble.  Betelgeuse is a red giant whose diameter could fit the orbit of Mars.  It is fairly close at 642 light years.  However, observing time is scarce on the Hubble as competition is fierce to use it.  Utilizing surface observatories can open up more opportunities for this line of research.

Besides the Hubble, another telescope to resolve a stellar disk is the CHARA array at Mt. Wilson.  CHARA relies on a technique referred to as interferometry.  An array of telescopes can have the same resolving ability of a single telescope the same size.  This is dependent upon the lightwaves received from all the telescopes in the array to be synced in phase together.

Credit: Mt. Wilson Institute

Radio astronomy was the first to use interferometry.  Radio waves are much larger than light waves.  In fact, radio waves can be several kilometers long.  Hence, it was easier to synch radio waves together than optical lightwaves.  The Very Large Array (VLA) in New Mexico uses this technique.  If you seen the movie Contact, you may be familiar with the VLA.  The VLA is an array of 27 radio antennas that in its widest configuration can provide the same resolution as a single antenna 22 miles (36 kilometers) wide.

Credit: Wikipedia/Hajor

Both economics and physics play a role here.  It is less expensive and structurally easier to build an array of small antennas rather than build a single dish 22 miles wide.  The tradeoff is gaining resolution at the cost of collecting ability.  The VLA does not collect the same amount of radio waves as a single 22 mile wide dish.  This plays a role in optical interferometry as well.

Optical interferometry presents a couple of challenges radio interferometry does not.  Visible light waves are disturbed by atmospheric turbulence, that is what causes the twinkling you see when you look at the stars at night.  The other is light waves are much smaller than radio waves.  In fact, radio waves are 1,000 – 1,000,000 times longer than visible light waves.  As a result, optical interferometry took longer than radio interferometry to develop.  Adaptive optics solved the turbulence problem.  Computer guided optical tracks solved the problem of combining very small visible light waves.

Credit: MRO/NMT

In the above example, light from the star travels a longer path to telescope 1 than to telescope 2.  Consequently, the light from telescope 2 must take an equally longer optical path before it is combined with the light from telescope 1 to ensure both are in phase together.  If the optical path is not calibrated correctly, the waves will arrive out of phase such as below:

Credit: Wiki Commons

The optical path is adjusted so that the red wavelength travels the distance θ longer than the optical path traveled by the blue wave so both waves are in synch and are combined where the peaks and valleys of the wave match up to produce a sharp image.

The CHARA interferometer currently has the longest baseline with six 1-meter telescopes spread out with a diameter of 330 meters.  The CHARA is located adjacent to the 100-inch telescope at Mt. Wilson where Edwin Hubble made his historic discovery of the expanding universe.

In 2007, the first resolved image of a disk from a near sun-like star was produced by the CHARA.  The star was Altair located 17 light years from Earth.  The image is below:

Credit: CHARA/GSU

Altair’s differs from the Sun in that its rotation rate is much faster.  The Sun rotates once every 25 days.  Altair rotates once every 9 hours.  Consequently, Altair is not spherical but bulges out from its equator.  This also causes Altair to have a cooler temperature at the equator and is thus darker in those regions.  This is the type of detail we can obtain when stars can be resolved as disks rather than points of light.

So what does the future hold?  Can future telescopes provide high resolution detail of stellar surfaces just as New Horizons provided for Pluto?  What should we hope to find if we can?  Stars, like planets, come in many sizes with differing physical characteristics.  The only star we can see with fine detail is the Sun.  The Solar Dynamics Observatory (SDO) images the Sun in both visible and ultraviolet light.  This video is an excellent overview of the solar surface detail provided by the SDO.

Given that attempts to resolve stars light years away from Earth is still in its nascent stage, it will be many years before we achieve that kind of quality imaging.  Nonetheless, there are promising developments that should improve our ability to acquire more detail of the features on stellar surfaces.

The first is a new generation of 30-40 meter telescopes set to go online in the 2020’s.  Combined with adaptive optics technology, they will have resolution on the order of 10-12 times that of the Hubble Space Telescope.  That, along with their immense light collecting ability, should improve the amount of suitable stellar targets to resolve.

The second, is the Magdalena Ridge Observatory Interferometer (MROI) in New Mexico.  The MROI will consist of an array of ten 1.4 meter telescopes with a maximum baseline of 1115 feet (340 meters).  The anticipated resolution will be 100 times that of the Hubble.  No definite timeline is given for completion of the MROI as it is a matter of obtaining funding to continue construction.  However, it is partially completed and hopefully will be up and running within ten years.

Credit: MROI

The next logical step is to build an optical interferometer in space.  Since 2000, NASA has been working on preliminary plans for the Stellar Imager (SI) mission.  The SI would consist of an array of 20-30 one meter mirrors with a baseline of 0.5 km (1,640 feet).  The array would be located in the Lagrange L2 point.  The L2 point is a gravitationally stable region 1.5 million km (1 million miles) from Earth.  This is also where the James Webb Space Telescope will reside a few years from now.

Credit: NASA/GSFC

Why should we endeavor to resolve stellar surfaces?  This is key to understanding the magnetic activity of a star and the stellar wind that emanates from the star towards orbiting planets.  These results can be integrated from the findings of exoplanet research.  Questions to be answered are, does the star generate space weather that could prevent life from forming on orbiting planets?  How strong a magnetic field does an orbiting planet require to protect life from local space weather conditions?  Does the star’s magnetic and irradiance cycle oscillate  in a manner that might inhibit the formation of life in its planetary system?  Detailed information from  main sequence stars older than the Sun could give us a look at the future of the Sun and how its evolution will impact life on Earth.

The SI is currently projected to start sometime around 2025-30.  More than likely, it will be later than that.  That is not unusual for cutting edge space missions.  The concept for an orbiting telescope was first proposed by Lionel Spitzer in 1946.  It took 44 more years to become reality as technical, funding, and political hurdles had to be overcome culminating with the launch of the Hubble Space Telescope in 1990.

I may never see the SI become reality in my lifetime, but it is important for my generation to lay down the ground work for our children to benefit from the results.  Astronomy, just like the building of the great cathedrals, can often be a multi-generational effort.

*Image on top of post are stars resolved by CHARA.  These stars are rapid rotators whose swift spinning motion flattens out their shape at the equator.  The images are false color and are designed to demonstrate temperature gradients on the surface of each star.  The brighter the color, the hotter the star is at that region.  The arrow on top indicates the true color of each star.  Credit:  CHARA/MIRC