Lecture 1 - Cosmological Questions (9/10/98)

Next Lecture - Copernican Revolution

ASTR11
Reading:

Chapter 1-1, 3-1 (ZG4)

The Earth as seen from the Galileo spacecraft. (Courtesy NASA)

	Key Question:	How do we ask and answer questions about our Universe?
	Key Principle:	Physical and Mathematical Models
	Key Problem:	How big is the Universe?
	Key Quote:	Its big, really big.

Investigations:

The Big Questions
- What is the goal of Astronomy?
- What role do quantitative physical models play in science?
- In what sense is mathematics the "language of the Universe"?
- Just how good do models need to be to be useful?
- How do we evaluate the relative merits of "competing" models?
- What is the proper way to use mathematical formulae in this course?
- What good is precision without accuracy?
- When are order of magnitude estimates appropriate?
- What is "twiddle math"?
- How big is the Universe?
- How old is the Universe?
- How do we know that we know what we know?
Charting the Universe
- How many powers of ten are there from the human scale to the scale of the Universe?
- How many powers of ten are there from the human scale to the subatomic quantum scale?
- What is the relation between distance and time?
- What is a light year?
- What is an astronomical unit?
- How long does it take for sunlight to reach us?
Cycles in the Sky
- How did ancient civilizations view the heavens?
- What is the daily motion of the stars?
- What are the apparent daily, monthly and yearly motions of the Sun, Moon, and planets?
- What is the relation between the daily motion of the Sun and that of the stars?
- What cycles do the solar day and sidereal day refer to?
- What cycle does the month represent?
- What does the year signify?
- How far apart do eclipse cycles occur?
- What is the cycle of precession of the north celestial pole?

Goals of this course:

Understand how we came to our current paradigm for the Universe
Construct our own model for the Universe
Build intuition about astrophysical equations
See how new technology and observational facilities push astronomy forward
Discover our place in the larger picture of the Universe
Learn how physics, engineering, mathematics, chemistry, geology and biology all interact in astronomy

Two Minute Relativity Drill:

The speed of light in vaccuum, c, 186,282 miles per second, or 299,792.5 kilometers per second, the ultimate speed limit, the light barrier. For us "twiddle mathematicians", 3 x 10^8 m/s. Call it what you will, what is it? When we look out in the Universe, the farther away something is, the farther back in time we see it. It takes light time to reach us and report on its origin. Is there a deeper meaning to this?>

Actually, just try and graph space versus time without a way of relating changes in distance to changes in time - the conversion factor must have units of velocity. Lets call it "c", for "conversion factor". Thus, in calculus terms

dx = c dt

or, since changing the sign of the "delta x" dx doesn't change the sign of "delta t" dt, we can just as well deal with the squares of these quantities

dx² = c² dt²

This little differential equation ('cause the little dx and dt are differential quantities, just as dx/dt is a derivative) is know as the metric, and is the basis of Einstein's Theory of Relativity! In three spatial dimensions x, y, z, time t, we can define a "proper distance" ds such that

ds² = c² dt² - ( dx² + dy² + dz² )

which for the path light takes, it is easy to see necessarily that ds^2 = 0!

When you see a first-order derivative such as

v = dx/dt

you should picture a straight line graph with slope v. (Remember elementary calculus?) The important thing is to actually visualize this, and think of a ball rolling down that line with constant velocity, for example. What about second derivatives? Think of a graph with a curve, like a parabola at its vertex. The rate of curvature is given by the second derivative

R = d²x/dt²

where you can also think of R as a radius of curvature. Hey, a circle of radius R has constant radius of curvature, with second derivative R. In three dimensions a sphere, etc.

Hey wait a sec, didn't we learn in first semester Physics that the acceleration is the second derivative

a = dv/dt = d²x/dt².

Does that mean that if we have a spacetime curvature with radius R, that this gives an acceleration a? Einstein's Theory of Relativity says "yes", and so the mass of the Earth curves spacetime at the radius of 9.8 meters per second per second at its surface! Neat, huh?

Note, we are not going to be doing anything with this in the class (or on homeworks or tests), but I thought it would be illustrative to show how a simple line of questioning, and careful consideration of the meanings of mathemetical representations, can lead to deep and important discoveries about the Universe. This is only a cartoon picture of relativity, for example, but it has a good deal of merit to it.

Note that you should be comfortable with simple derivatives, powers of ten and scientific notation, and the notions of velocity and acceleration.

If you missed the first lecture:

No worries. I mostly talked about the stuff in the course guide, and some of the topics listed above. Oh, and I showed some cool laserdisk pictures too. You can find photocopies of my lecture notes on reserve in the Physics, Math & Astronomy Library, 3rd Floor, North Wing, DRL.

Next Lecture:

We start our main work, first looking over the history of Astronomy from the Greeks to Galileo, then looking at how the Sun, Moon, Planets and Stars move on the sky, and how we build models to explain those motions. And we see how those clever Greeks figured out the size of the Earth, and other pretty advanced things!

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smyers@nrao.edu Steven T. Myers