Midterm Exam #2 Tuesday, March 23 Closed book Will cover Lecture 8 (Special Relativity) through Lecture 14 (Star Formation) only If a topic is in the book, but was not covered in class, it will not be on the exam! Some combination of multiple choice, short answer, short calculation Equations, constants will all be given Standard calculators allowed Cell phones, PDAs, computers not allowed
Outline - March 16, 2010 Recap: Interstellar Medium Recap: How are stars made? Stages of star birth Protostars, protostellar disks, protostellar jets
Interstellar Medium (ISM) Material between the stars (specifically in our own Galaxy) Most of space is a better vacuum than can be made in a laboratory! About 1/5 as much mass in the ISM as in stars in our Galaxy Some regions of space contain clouds gas (some clouds are hot: > 10,000 K, some clouds are very cold: 10 K-30 K) Chemical composition of ISM: 70% H, 28% He, 2% other elements (by mass)
Why should you care about the ISM? Stars had to come from somewhere (the Big Bang didn’t make stars) When stars die, their guts have to go somewhere If those “somewheres” weren’t the same place, we wouldn’t be here! (a topic for after Spring Break)
Association Between Cold Clouds and Stars “Heir ist wahrhaftig ein Loch im Himmel” Wm. Herschel Image taken in optical / visible light
Cold clouds are transparent in the infrared and radio Milky Way: Optical Cold clouds obscure our view at visible wavelengths, but infrared and radio light penetrates the clouds. Milky Way: Infrared Milky Way: Radio
Molecular Clouds Stellar Nurseries Very, very cold (10K to 30K) Typical density is 300 molecules per cubic centimeter (vastly less than the density of air at sea level, but vastly more than the density of the ISM on average in our Galaxy) Gas is primarily H 2 molecules, but you can’t detect them directly! (Note: Helium does not form molecules because it is chemically inert.) Most common “tracer” molecule is CO (carbon monoxide) About 1% of the mass in molecular clouds is in “dust”
“Dust” in the ISM Not dust bunnies, more like the microscopic particles in smoke Size of dust grains is smaller than bacteria (typical size is 1 micron = m) Dust grains made mostly of some combination of carbon, silicon, oxygen, and iron Dust blocks wavelengths of light that are smaller than the size of the grains ( < m) Dust easily blocks UV and visible light, but IR and radio light can (usually) pass right through Horsehead Nebula (in Orion), optical image
Cloud Structure: Gravitational Equilibrium A stable cloud has a balance of two forces: INWARD: Gravity OUTWARD: Pressure No net force => No motion
What do we mean by “pressure” in a cloud? Why does a balloon maintain its shape? What happens to a balloon if you blow it up at room temperature, then put it in the freezer for a couple of hours? This is what is known as “thermal” pressure (the common pressure for gasses) Easiest place for gravity to “win” over pressure is in a cloud of gas that is very cold (= low pressure)
Collapsing Clouds This cold, dark cloud is collapsing and forming cores that will eventually become stars This is a cloud where gravity has won the tug-of-war!
Most Stars are Born Inside Clusters Pleiades Star Cluster Most molecular clouds contain MUCH more mass than would make a single star Most molecular clouds are very LUMPY (not smooth) Likely scenario is that many lumps (which are more dense than the average) contract to form stars at about the same time Single star formation is possible but probably very rare (because you need an unusually dense, yet low- mass cloud)
Star Formation Basic stages: * Cloud collapses * Protostar forms * Disk forms * Planets form
Cloud Collapse
Collapse to Protostar If you compress a gas, it will heat up. Center of a collapsing cloud becomes denser and hotter. The energy is gravitational. Half the gravitational energy goes into heating the collapsing clout, the other half escapes as light. The central object is called a “protostar”, and they are very bright! (Because they have very large radii.) Protostars are hard to see because they are being formed in very dusty regions of space. Protostar
Protostars vs. Stars Main difference between a protostar and a genuine star: Stars generate power by nuclear fusion, protostars generate power by gravitational collapse. Note: For the most part, stars are stable (neither expanding nor contracting). Protostars are all contracting. When does the contraction end? When the core becomes hot enough and dense enough to start nuclear fusion reactions.
Some Protostars NGC 6334IRDC 43
Disk Formation
Conservation Laws The following quantities are conserved: 1. Total Energy 2. Linear Momentum 3. Angular momentum The total amount of these quantities never changes
Angular Momentum, L m v r For an object of mass m orbiting with velocity v and distance from rotation axis r, the angular momentum L is L = mvr
Spin-up If the radius of the orbit decreases, and angular momentum is conserved, the velocity must increase. L i = mv i r i L f = mv f r f L i = L f v f = v i (r i /r f ) riri rfrf vivi vfvf
Disk Formation To conserve angular momentum, an object moving perpendicular to the rotation axis must increase speed, and eventually stop because it has a finite energy. L = mvr r r changes here
Disk Formation r L=mvr To conserve angular momentum, an object moving parallel to the rotation axis need not change speed, and is free to move to the equatorial plane. r doesn’t change here
Disk Formation
Do disks around stars exist? YES HST Image of Beta Pictoris: note star itself has been blocked out
More Disks around Protostars
Scale bar shows 1,000 AU
HH-34
HH-30 (image & model) Jets are perpendicular to the disk = rotation plays a role in their formation. Most likely link of rotation and outflowing gas are magnetic field lines. We’ll see this again when we talk about “active galaxies”.
Planet Formation It shouldn’t be that hard….
Portion of Orion Nebula showing “Proplyds” = Protoplanetary Disks
Proplyds are ~99% gas, ~1% dust
Beta Pictoris will have many planets around in the future?