By Virginia Postrel and Steven Postrel
When she became
an astronomer, Sallie Baliunas never thought she'd be posing for
magazine photos. But her life as a scientist hasn't been a matter
of pure research. In her quest to study the stars, she has found
herself drawn into the world of entrepreneurship and public policy.
An astronomer at the Harvard-Smithsonian Center for Astrophysics
in Massachusetts, Baliunas is also the deputy director of the
Mount Wilson Institute in the San Gabriel Mountains north of Pasadena,
California. She spends about a week a month on the West Coast,
using Mount Wilson's historic 100-inch telescope to study "sun-like
stars."
Baliunas came
to the observatory as a graduate student in 1977. On her very
first night, a lightning bolt struck a tree outside the dining
room. "All the windows in the building were shattered from the
shock wave of the tree disintegrating," she recalls. "This was
an omen whose meaning was not clear until years later."
The observatory
where modern astronomy was born would go through similar shocks
in the years to come, as its owners turned their attention elsewhere.
But for the dedication of a handful of technical staffers and
astronomers, Baliunas among them, Mount Wilson would have been
essentially abandoned. Instead, the observatory has not only a
new lease on life but some of the best observational equipment
in the world. The reborn facility is demonstrating how private
funding and advanced technology can nurture innovative science.
Baliunas's
own work benefited from Mount Wilson's years of neglect. Telescope
time is rare, and few astronomers have the luxury of studying
the same stars night after night, year after year. She's the first
to admit that her research "could only have been done at an essentially
`abandoned' facility, where the competition for telescope time
had disappeared." Baliunas is returning the favor, working without
pay to raise funds, improve equipment, and manage the operations
so such long-term research can continue. She never expected to
be a manager but, she says, "The choice seemed clear: either grow
the observatory or lose the research program."
In between
observing and management, Baliunas can also be found testifying
before congressional committees and giving papers at conferences
on global climate change--a subject she was drawn to by her research
on the sun's fluctuating magnetic field. She is a leading greenhouse
skeptic. How, she wondered, could climate models be so specific
when we hardly understand the sun or its effect on the earth?
Baliunas talked
about this and other questions with REASON Editor Virginia Postrel
and her husband, Steven Postrel, an economist who teaches business
strategy at U.C.-Irvine, under the Mount Wilson dome in late June.
Reason: What
do you study?
Sallie Baliunas:
I'm interested in why the sun has a regular cycle of magnetism.
There's a clock, so to speak. Sunspots come and go every 11 years,
and the sun's energy output changes in step with those changes
in magnetism. The sun also changes on longer time scales. That
has an influence on the earth's environment. So the question is,
Why does the sun do that? There is no good basic theory that says
why the sun would have a magnetic clock.
Reason: So
you look at other stars to try to figure out what's going on with
the sun?
Baliunas:
Right. Here's an analogy. You're an extraterrestrial and you come
to Earth, and you have 24 hours and you want to study the life
cycle of a human. You can do one of two things. You can sit and
follow one human for 24 hours and watch tiny microscopic changes
in that human, or you can gather together a whole town and take
information and look at the commonality. You can say, here's an
infant and he needs to be taken care of, and here's a kid, and
here's a young adult, and put together a picture of the human
life span that way. I look at what I call "sun-like stars" at
different phases of long-term evolution. It's a great deal quicker
than waiting around for the sun to do something.
Question:
Have you gotten any interesting results?
Baliunas:
My mentor here--who is buried outside the dome, Olin Wilson--asked
the question, Is the sun's 11-year cycle common on other stars,
or is it something peculiar about the sun? He began a program
here at the telescope in 1966 to follow 100 stars, month after
month, year after year. When he retired, I came aboard, and now
we have over three decades of records. We see at first glance,
what the sun does is not unique. It's a universal trait.
Question:
Eleven years?
Baliunas:
Eleven years, on average, if the stars are as old as the sun is.
Age seems to make a big difference. When the sun was younger and
life was forming on Earth--the sun was about a billion years old,
about 3.5 billion years ago--the sun was spinning several times
faster than today. That meant that the dynamo that powers the
surface magnetism was working much more efficiently, and so the
magnetism was much higher. There were more sunspots, there were
more high-energy particles, there was more variability of ultraviolet
and X-rays.
Question:
How would that affect conditions on the earth?
Baliunas:
In several ways. One way is, with that higher amount of activity,
there's much more X-ray and ultraviolet flux. The X-ray flux would
be about 100 times larger than today. That energy certainly has
biological effects--effects on DNA; it can even kill cells. So
the environment was much more dangerous to life than today. The
ultraviolet fluxes would also be larger, maybe 10 times larger.
In addition, the changes over time scales of years or so would
also be much larger. So not only are they at a higher sustained
level, but they vary, and the variations are larger. The total
energy of the sun would have been varying by several percent over
a time scale of a few years, during the sunspot cycle. That would
play havoc with the climate.
Question:
You've been writing some papers suggesting that terrestrial climate
today may be affected by solar variations. In fact you've suggested
that some of the warming that people have attributed to burning
fossil fuels may actually be the result of natural fluctuation.
How did you get involved in that?
Baliunas:
Nearly 15 years ago, I started hearing that there now were models--simulations--of
the earth's climate system that could be projected 100 years into
the future. I was curious and thought, "Wow, that's a significant
leap in meteorology and climatology. I want to learn about that."
So I began looking at the models and how they can make predictions
so far in advance. I also began to look at climate simulations
run on computers and ask the question, What is the natural level
of climate change? What is the influence of the sun? The reason
for asking how the sun might influence it is that there is lots
of direct evidence that the sun has an impact. For example, the
sun changes in its brightness [an average of] every 11 years with
the magnetic cycle. We know that from recent satellite measurements.
But going back further in time, we know the sun changes every
few centuries. During the 17th century, which was an unusually
cold period on Earth, the sun had very little magnetic activity
for about a century--the Maunder Minimum, coincident with the
Little Ice Age.
Question:
What is the Maunder Minimum?
Baliunas:
The Maunder Minimum is this episode in the 17th century where
the 11-year cycle was suppressed--was very quiet--and the sun
dropped to very low levels of magnetism.
Question:
The 11-year cycle disappeared?
Baliunas:
Almost. There were certainly long months of time, and even a decade
toward the end of the 17th century, when sighting a sunspot was
very rare.
Question:
Is there any theory for what caused that?
Baliunas:
That's the hot question. We have to explain the 11-year cycle
in the first place. There's a crude picture that says we know
the sun's magnetism changes with time because of the way the sun
spins and the way the outer layer rolls with convection. Beyond
that, it's not a good theory. Making an 11-year repeating cycle
is difficult in most theories. Making it disappear every few centuries
is even more difficult.
Question:
How do you know magnetic records of the sun from the 17th century?
Baliunas:
The records of sunspots go back to 1609, to Galileo's day, and
that's almost long enough to see this episode. But we have some
unbiased records: The sun has a wind that carries the magnetic
field toward the earth and acts as a shield. There's a rain of
cosmic rays coming from deep space. When the sun's magnetic field
is strong, these cosmic rays tend to be deflected. When the magnetic
field is weak, these cosmic rays penetrate the upper atmosphere
of the earth. When the cosmic rays come in, they make radiocarbon
in the upper atmosphere, and that carbon-14 ends up in carbon
dioxide molecules. It's breathed in by a tree and put in its tree
ring, so the amount of carbon-14 over time in tree rings tells
you what the sun has been doing in the past. Those records trace
the sun back about 10,000 years. So we know the ups and downs
of the sun's magnetism for the last 10,000 years or so. After
looking at this, I began to ask, How well do the climate simulations
handle this relatively new knowledge about the sun? And the answer
is, not very well. We don't know the mechanism for change in the
sun very well. We don't know the response of the earth to such
changes. So I thought, How do you make predictions 100 years in
the future if you don't even know what all the sources of change
are?
Question:
If the magnetic activity on the sun is changing, what mechanisms
are there that might affect the earth's climate?
Baliunas:
It depends what time scale one is talking about. The sun brightens
and fades over the sunspot cycle, the 11-year cycle. But also
the intensity of the 11-year cycles has been building over the
centuries.
Question:
What do you mean by "intensity"?
Baliunas:
Looking back several hundred years, the sun's magnetism is at
an all-time high. The last four peaks have been quite high.
Question:
Do these fluctuations produce a big effect?
Baliunas:
It's relatively small from cycle to cycle, but we estimate that
from the 17th century to now it could have been four or five tenths
of a percent of the sun's energy output. Run that through a climate
model, and that's enough to explain the temperature change.
Question:
Using the current models...
Baliunas:
Using the current models...
Question:
Which you're not sure are right anyway...
Baliunas:
Nobody's sure--all models have similar problems. We're saying
[with] a few tenths percent change, which we don't think is unreasonable
for the sun, you can explain everything. Now that's not the only
mechanism. That's the first one, which one might think of as brightness
change. There's some new work coming out of Europe on clouds.
The amount of cloud coverage on the earth is changing by a few
percent every 11 years --it's anti-phased with the cycle. The
latest idea is that it's the sun modulating the cosmic rays that
are coming in making nuclei of clouds. So after looking at all
these vast unknowns, I then saw the key problem for the greenhouse
extremists. We always read about how the temperature has warmed
about a degree Fahrenheit--a half degree centigrade--in the last
100 years. But if you look at the temperature records, it's quite
clear: All the warming occurs early in the century. But most of
the greenhouse gases are put in the atmosphere after World War
II, in the last 50 years. So they can't cause most of the warming
of the last 100 years. Something else had to. The sun's changes
fit that very well. That just may be a coincidence, but that's
what we're pursuing.
Question:
What has the sun's effect since 1940 been?
Baliunas:
That's a harder question because we consider changes of the sun
on time scales of several decades or more. So asking me what has
gone on since 1940 is almost at the limit of what I'm looking
at. If you want to look back over the last 100, 200, or 300 years,
it's a little easier for me to talk about it.
Question:
Would this solar variability research say anything about what
would happen if we were really to increase greenhouse gases in
the atmosphere a lot?
Baliunas:
That experiment has been done. We've increased the amount of greenhouse
gases by an equivalent of going halfway to a doubling of carbon
dioxide--and doubling is the benchmark that everyone talks about.
And then you look at how the earth's temperature has responded,
and it has not warmed more than a tenth or two-tenths of a degree.
So a simple back-of-the-envelope calculation says a doubling is
a few tenths of a degree. That's not significant, because it's
not noticeable above the natural background changes. The real
test of this is the last 20 years, with very precise satellite
measures of the earth's temperature made globally. The global
average temperature of the atmosphere, just above the surface
of the earth, has not warmed at all. There's been no warming trend
in the past 20 years, and the models all say that there should
have been a warming of several tenths of a degree centigrade in
that time.
Question:
I've seen flat denials of this by people who claim that the satellite
data are either inaccurate or who say they don't care about the
air up there, they care about the air down here.
Baliunas:
It's true that people live at the surface and not where satellites
measure, which is a few kilometers above the surface. But the
models make predictions at that layer of the atmosphere, and most
of the models make a prediction that that layer should be warming
more than the surface, so in fact it's a good test of the models.
The satellite data make measurements essentially globally, unlike
the surface data, which are very, very irregularly sampled and
spaced and have significant systematic errors.
Question:
Where do those systematic errors come from?
Baliunas:
There are systematic errors arising, first of all, because of
coverage. There is very little coverage of the polar regions of
the earth and there's little coverage of the southern hemisphere
oceans. People don't live there; there are no thermometers there.
But the satellites measure these areas dutifully. Systematic errors
also come from the urban heat island effect, which says that as
cities have grown--buildings, concrete, pavement, tree clearing--they
have warmed that environment. So you can look at the population
growth in a city and you can look at its temperature just going
hand in hand.
Question:
Critics of the satellite data have argued that you get different
results at different altitudes that satellites do reach.
Baliunas:
That is true.
Question:
And the atmosphere has warmed at certain levels.
Baliunas:
No. There's been no warming in the satellite data. There's been
a cooling in the lower stratosphere, and no warming in the lower
troposphere. And at the surface, I should mention that the continental
U.S. has very good measurements over the last 100 years and there's
been no net warming there either.
Question:
How does this fit in with your solar explanations?
Baliunas:
We're trying to subtract the sun's influence [from climate fluctuations
caused by other sources]. The sun is particularly good at explaining
this early 20th-century warming, which can't have been caused
by the greenhouse gases. If we had a good prediction for what
the sun would do next, given the past calibrations that we've
done, we then could make a prediction. But we're not at the point
where we can predict what the sun will do 50 years from now.
Question:
There was an International Panel on Climate Change, whose results
have been widely disseminated. What do you think about the IPCC
report?
Baliunas:
The IPCC report actually is very careful to say that the models
have not been validated. That tells you that you can't make a
prediction with them. The executive summary says that there's
a discernible human influence, but the information in the chapter
on which that conclusion was based has been overturned by the
scientific process. The report is obsolete.
Question:
What overturned it?
Baliunas:
The executive summary's conclusion was based on the results of
new climate simulations that made predictions both in three dimensions
and time. That's the way to go: Global warming won't be uniform
over the globe--certain areas or different levels of the atmosphere
will warm more than others. So you look at the regions that are
supposed to warm first--for example, the Arctic or, in the case
of that report, a region of the lower atmosphere over the southern
hemisphere oceans. And in the report, it was claimed that there
was good agreement between the theory and the observations. But
when that underlying paper was published, it was very quickly
overturned by a longer stretch of data.
Question:
By whom?
Baliunas:
One paper is by Pat Michaels and Chip Knappenberger. That was
published in Nature. There had been a short uptick in the temperature
of that region, but when looking at a longer temperature record
that was both earlier and later, it was seen that that uptick
was just part of a long-term null trend. So the models had predicted
wrongly. There had been no increase in that area.
Question:
The idea of looking for places where the models make strong predictions
is that if it's right anywhere it should be there?
Baliunas:
It should be right where the warming is felt first-- for example,
the polar regions, the Arctic. In the last 50 years, the Arctic
has cooled. And the models say it should be warming profoundly.
Then the area over the southern hemisphere oceans should be warming,
but it has not been warming either.
Question:
There's a particularly compelling figure you've used in your publications,
which is a graph of North American land temperature data vs. the
magnetic activity of the sun, with multiple turning points that
are coincident. [See graph.] First a technical question: What
are the units for the magnetic activity?
Baliunas:
This is the length of the sunspot cycle. The cycle averages 11
years or, if you count polarity, 22 years. But the cycle can be
short, say, eight years, or it can be longer, say, 12, 15 years.
So you look at the length of the cycle and plot that to see the
relation.
Question:
If the cycle is short, what does that mean?
Baliunas:
If the cycle is short, the sun's magnetism is much more intense,
and that leads you to the expectation that the sun's brightness
would have been greater than if the cycle is long.
Question:
And that correlates beautifully with the turning points...
Baliunas:
Right, so the mechanism is that you're still seeing changes in
the brightness of the sun, and you're just using as a marker for
that something we have a measurement of going back that far, which
is the length of the magnetic cycle.
Question:
Given that you've said that the radiant effect, just the pure
heat, probably isn't enough to explain it, that's a very striking
concordance.
Baliunas:
The [radiant] effect is borderline. And it may be that we have
the wrong mechanism or that our model has the wrong response,
since nobody's model has the right response. Some people have
worked on not just looking at the total energy of the sun but,
say, a portion of spectrum such as the ultraviolet. A woman in
England, Joanna Haigh, would say that the ultraviolet changes
in sun, although they seem small, profoundly affect the ozone
layer and that those changes in the ozone layer then change the
dynamics of the climate system strongly. We may be looking at
the right marker but the wrong reason, and that may be why models
are still equivocal.
Question:
Mount Wilson was closed for a while...
Baliunas:
The 100-inch telescope was closed in 1986. The owners, the Carnegie
Institution, had built a large telescope in Chile, and to conserve
resources, they wanted to focus on that. By then, a group of us
from other universities were already using the other resources
on the mountain. I was working my long-term project on the 60-inch
telescope; the solar towers were in use. The 100-inch telescope
was closed for about eight years while we raised the money to
refurbish the telescope, put in modern computerized pointing,
and also redirect where it was going. It wasn't going to do cosmology
at the faint edges of the universe--the telescope was now only
a modest-sized telescope compared to the 10-meter telescope [at
Mauna Kea in Hawaii], and the lights of L.A. were getting too
bright. So it took a turning point around 1991. When George Ellery
Hale founded the observatory, he noticed that there was something
priceless here: The air is very still, calm, and steady. That
means the images from space, celestial objects, as they come down
through the atmosphere are least disturbed. We have clarity here
that is unmatched by any site in North America, and it's on par
with the best sites in the world like Chile and Hawaii. It's a
little more convenient being here than at, say, 14,000 feet in
Hawaii. So that still air, which astronomers call the "seeing,"
and the development of technology, opened up some new areas. We
now do high-resolution astronomy. This 80-year-old telescope has
now been sharpened up so it takes out the blurring effect of the
earth's atmosphere, and it sees images as sharp as if it were
out in space. That took about $3 million of mostly private money
and some special high-tech equipment developed mostly by the Defense
Department during the Strategic Defense Initiative days.
Question:
When did that "adaptive optics" system go in?
Baliunas:
This became operational in late 1995.
Question:
Have people using it made any noteworthy discoveries?
Baliunas:
We've got the first map of the surface of the asteroid Juno, for
example. This is one of these large asteroids very similar to
the junk out of which the earth was made. But unlike the earth,
which has been processing everything with plate tectonics and
its ocean and atmosphere, this asteroid sits out in space virtually
untouched in 4 billion years. So you're looking at the primordial
state of what made the earth. We're looking at the mineralogy
of that. We're also looking at the volcanos on one of the satellites
of Jupiter, which blow up because it's in such proximity to Jupiter.
The gravitational pull of Jupiter makes a liquid core in that
little satellite. We're looking at other stars, how stars form,
what kind of dust and debris they have around them at various
stages. We're taking a census of all the nearby stars and whether
or not they're double or triple star systems.
Question:
Is that easier to tell with this technology than with what had
gone before?
Baliunas:
Yes, because you can look closer in toward the vicinity of the
star, and that information had been lost in the blur.
Question:
So the main limit is how far the telescope can see?
Baliunas:
Yes, how far, but we can see detail lost by bigger telescopes.
Question:
Why is that?
Baliunas:
Because the atmosphere sets the limit of the detail. When the
big telescopes get this kind of technology going they will start
retrieving it, but right now we're one of the very few that can
do this.
Question:
Is the technology making astronomy significantly less expensive
to do?
Baliunas:
You get images as sharp as if the telescope were in space, for
a capital cost of $3 million for the new equipment and the retrofits--compared
to the space program. A launch of the Shuttle is half a billion
dollars, and if you settle for a Delta rocket, it's a $100 million
dollar launch, plus building space-worthy equipment. So it's extremely
cost-effective to do things on the ground when you can. This makes
the space instruments more effective, because they focus then
on the things that they do best.
Question:
You're about to open something called the CHARA Interferometer.
What is an interferometer?
Baliunas:
An interferometer is a clever way, a very sneaky way of getting
detailed information on objects in space without spending a fortune
in building a telescope. The optical interferometer will be six
smaller telescopes, each one meter across, spread out over a radius
of 1,000 feet. And then the light of each individual telescope
is brought together and stacked, so the crests and troughs of
the waves of light match up. The computer is very carefully measuring
the distance to each telescope, which changes subtly. When you
do that with these smaller, inexpensive telescopes you get the
equivalent detail--spatial detail--as if you had a 1,000-foot
diameter single telescope.
Question:
What makes that possible?
Baliunas:
It's the ability to stack the wavelengths of the light coming
to each telescope with a tolerance of one four-millionth of an
inch. That requires sophisticated computer control, engineering
control, and lasers all working to calculate the distance to stack
these beams of light.
Question:
What sort of research are they expecting to do with that?
Baliunas:
One of the more interesting things is to try to start looking
for planets around other stars--direct sightings.
Question:
What is it about this array that will make that more likely?
Baliunas:
The array can see spatial detail much finer than any other optical
ground-based or space-based telescope. It can see very close in
to the vicinity of these stars.
Question:
So it can see better than the Hubble?
Baliunas:
Sharper detail, finer detail. It could see something as small
as an astronaut's bootprint on the moon. And that's something
like 100 times finer detail than the Hubble can see.
Question:
But it can't see as far?
Baliunas:
Not as far. Technology is making niches, as usual, and this is
our niche: fine detail, of objects either in our galaxy or nearby
galaxies. Whereas Hubble can see to the faint reaches of the far
universe.
Question:
What is your operating budget?
Baliunas:
To operate the whole facility is about a million dollars a year.
Question:
Where does your money come from?
Baliunas:
It's mostly private foundations and generous individuals, primarily
in Southern California. Occasionally we have some government grants
from the National Science Foundation or NASA to do some specific
project, but most of it's been private.
Question:
This reopening was very much a private venture.
Baliunas:
Yes, the idea was to keep Mount Wilson as an option in private
hands. The national observatories have, as their obligation, to
serve the wider [astronomical] community. That's terrific, but
it also means that servicing as many users as possible becomes
an important focus for them, which means short-term observing.
We prefer to serve important projects that can't get done at the
other sites. A long-term project--say, my project, which is 32
years in duration--is a different kind of project.
Question:
A lot of people have the idea that because of the capital equipment
costs, you can't do good astronomy without government support.
Baliunas:
I disagree with that. You can do good astronomy with government
support, but you don't need it. The Keck telescope [at Mauna Kea]
is an example of something that was privately funded. And in fact,
some politicization often comes with government support.
Question:
Can you give me an example?
Baliunas:
You have to write proposals to get telescope time [at the national
observatories]. You often have to write them a year in advance.
The subscription rate is a factor of several to one, overburdening
the time. Three-quarters of the proposals have to be thrown away.
So if you want to do something, you might have to submit a proposal
several years in a row. It might be four or five years before
you get it. The demand is so great that sometimes the tendency
is to divide up the time in some "equitable" way, so that means
you end up with two or three nights. You arrive and it's cloudy.
You have to start the process over again next year. So that's
something we wanted to try to provide to the community--another
avenue, where if you wanted 100 nights of telescope time, we'd
be in a position to be able to work that out.
Question:
I've heard a lot of scientists in different fields complain that
government funding is distorting science, distorting the peer
review process. What is your take on that?
Baliunas:
There is almost a crisis in the number of scientists and the amount
of funding available. There's been a population explosion in the
number of scientists practicing, and the amount of government
resources available has been not in that proportion. For example,
NASA's budget in the Apollo program days was a much higher percent
of GNP than it is today. A lot of astronomy funding has historically
been a fixed fraction of the NASA budget, so that means that as
a percentage of GNP, that number has gone down in real terms,
but there are more people competing for those dollars. So now
when you do proposals, you don't write an open proposal. You don't
say, "I have this great idea," and then write it down. You look
to see what targeted program your idea might fit into, and if
there's not a targeted program, you go try to lobby for one to
be made.
Question:
What is a targeted program?
Baliunas:
For example, discovering extrasolar planets is now something very
interesting, so NASA has an origins program encompassing that.
But before a specific program existed for extrasolar planet studies,
such research was difficult to fund. If you're doing something
that is radically different, it might not fit into one of the
bins. You have to bend your science into one of those bins, or
you have to work on getting a new bin accepted. Some of the targeted
areas are so overburdened that nine out of 10 proposals get rejected.
I've been on panel reviews where there were many excellent proposals,
but you have to make a decision and throw out 90 percent of them
because the budgets can't take them all.
Question:
You first came to Mount Wilson because your graduate school adviser
told all his students that you should do some observing at the
"mecca of modern astronomy." What makes Mount Wilson the mecca?
Baliunas:
Mount Wilson is where astronomy took its modern turn. Astronomy
used to be, in the 19th century, cataloging--a very personal,
artistic journey of looking at the sky. George Ellery Hale, who
founded the observatory, changed all that. He thought that there
was something to be learned from astronomy other than positions.
There was what powered the sun, the changes of the sun, how did
they influence the earth, how did life begin here, and what influence
does the space environment have on those larger issues? What are
the stars? How big is the universe? Where did it come from? Where
is it headed to? The idea of the evolution of the physical universe
was very important to Hale. He was influenced by Darwin's Origin
of Species. Hale was a brilliant scientist. He worked at Yerkes
Observatory in Chicago--he was born in Chicago, went to MIT. He
went back to Yerkes and built the largest telescope in the world
there at the end of the last century. That was the 40-inch Yerkes
Refractor Telescope. He found Chicago not to be the best environment
for doing astronomy, because of the high percentage of cloudy
nights. He went with a committee on a site-testing tour, and decided
that this mountaintop had images through testing telescopes that
were the finest of any site that they had ever seen. He decided
that this would be a good place to found the observatory. He packed
up the solar telescope and brought it out here in 1904. He took
a great risk because at that time he had very little commitment
of any funding. But his themes were always, "Make no small plans,
dream no small dreams" and "More light." His father was fairly
well-off and had given him a 60-inch mirror blank in 1896 as a
birthday present. He was again going to build the largest telescope
in the world, the 60-inch telescope. It took him 10 years to find
a site, and another four years to find the money--much of which
he borrowed from his friends, neighbors, and relatives--to finally
get the 60-inch telescope opened in 1908.
Question:
How much did that cost?
Baliunas:
I know there was a donation of $50,000 for the 100-inch mirror;
the 60-inch mirror was $2,000 in 1894 dollars.
Question:
Mount Wilson is at the top of a mountain and even today, it's
a bit of a haul up a winding, fairly narrow road. Certainly in
1908 or even 1917, it was worse. How did they build the observatory?
Baliunas:
The builders had this vision and just had to overcome terrible
conditions. There's a hiking trail that goes up from Sierra Madre--that
was the old toll road, a private road in those days--and everything
had to be brought up either in your backpack or by mule trains.
Everything had to be broken down into small bits and then built
in place on the mountain. You see the amount of massive concrete
and steel structures. They had to haul everything up, and it took
at least a good day to get up the mountain. Even though it was
a seven-mile trail, it was very steep. By 1910, there were primitive
trucks and the trail had to be widened by human labor, and then
things could be brought up that way.
Question:
Who built the observatory--the 100-inch telescope?
Baliunas:
They went to a steel company in Chicago, named Morava, for the
dome. They built and assembled the steel dome and structure in
Chicago, then took it apart and brought it up the mountain. The
concrete was put in place by the observatory staff--they had a
concrete plant up here. The whole telescope was designed by the
observatory staff. The mirror was cast in France, and it was ground
to its fine shape down in Pasadena by the observatory staff. The
telescope tube--the structure that holds the mirror and moves--was
built by the Fore River Shipyards in Massachusetts, which built
battleships. The telescope itself weighs 100 tons, the moving
part of it--the tube.
Question:
This was all done with private money?
Baliunas:
It was all private. By 1908, Hale had convinced a businessman
in Los Angeles, John Hooker, to pay for the casting of the 100-inch
telescope, and he got Andrew Carnegie to invest in the observatory.
This is his third time he built the largest telescope in the world,
and the fourth one is the 200-inch at Palomar Mountain.
Question:
You told a story about the Huntington Library in Pasadena that
indicated that Hale had a dim view of government control.
Baliunas:
He was talking to Henry Huntington, who had this fabulous collection
of rare books. Huntington was thinking about what to do with them
after his death, and he began thinking of a publicly owned--probably
city-owned--library where people could use them. Hale had a view
that once you entered the political process, it was a dangerous
thing. He suggested to Huntington that instead, why not have a
private library, for which they would raise the funds, to be run
by scholars who would ensure public access. And that's worked
very well to this day.
Question:
He was a little nervous about challenging Huntington--is that
because Huntington also supported the observatory?
Baliunas:
No, I think he just respected Huntington's desire to do what he
wanted with his own property. But Hale did say, "Realizing the
menace inherent in political control, I took my life in my hands
and wrote him a letter."
Question:
The 100-inch telescope here opened when?
Baliunas:
It opened in 1917. And this is where Edwin Hubble made his discoveries
of our place in the cosmos.
Question:
Who was Hubble?
Baliunas:
Edwin Hubble was an astronomer who came here in 1919 and made
modern cosmology. In 1900, no one knew what a galaxy was. It's
a term we all use, but it wasn't in use then. The Milky Way, which
was thought to be about a 100,000 light-years across, was all
there was of the universe. The universe was static, unchanging,
eternal--it had always been. And it was finite, something you
can grasp. A hundred thousand light years is not so bad for the
human mind to wrap around. Hubble came along, and by 1923 he was
interested in something called nebulae, the Latin word for clouds,
which were faint, pinwheel smudges that one would see through
the telescope. Hubble looked at the Andromeda nebula, which is
in the constellation Andromeda, and found a special kind of star.
The star changes in brightness rhythmically. By measuring the
period, you know the intrinsic brightness of that star. I use
this example: When one drives on the road at night and you see
the streetlights or the lights of an oncoming car, you automatically
think, "I know how bright a streetlight is when it's next to me,"
or how bright headlights are, so you make a mental calculation
as you look at how dim the lights are; you say, "OK, it's far
away," or "It's near." The word in astronomy is "standard candle,"
but I've always found that not to evoke the right image. It's
something whose intrinsic brightness you know and by looking at
its apparent brightness--because the intensity of light fades
with the square of the distance--you can easily calculate the
distance.
Hubble saw
how faint the star looked on the photo, and then he saw what its
real brightness was. So he knew how far away Andromeda was. It
is external to our galaxy. It is 2 million light-years away. So
now it's not just the Milky Way, but each one of his smudges is
a Milky Way, a hundred billion stars, and there's hundreds of
billions of these galaxies. So overnight in 1923, he changed the
scale of the universe, from being finite to something essentially
infinite.
Now by the
end of the 1920s he did something else, which is to discover that
the universe is not static. He looked at these galaxies again,
and he noticed that they had a speed of motion relative to us.
The farther away the galaxy is, the faster it's flying away from
us. He found the evidence for the expanding universe.
This is a
notion which is embedded in Einstein's theory of relativity, that
there was a beginning to space and time, some 15 billion years
ago. Hubble overturned everything. I call it the last step of
the Copernican revolution: The universe is not finite and static.
It's infinite and expanding, and what's worse, it had a beginning,
which means it's not eternal. And that all happened at the chair
here. The little wooden rickety chair.
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