Luminosity Equation
(σT^4) x (4piR^2)
Wein’s Displacement Law
λ(max) = b/T
Doppler effect
Δλ/λ = v(source)/c
Parallax
p (arc seconds) = 1/d (parsecs)
Parsec to lighyears
pc = ly x 0.3066
Rydberg equation
ṽ = R(1/(n1)^2 - 1/(n2)^2)
Law of gravity
F = - Gm1m2/R^2
Gravitational energy
E = - Gm1m2/R
3 elements of the Big Bang theory
Big bang nucleosynthesis
Cosmic microwave background radiation
Expansion/inflation
Proof of big bang elements
BBN: abundance/distribution of the elements
CMBR: “uniform” and described via blackbody radiation
Expansion: red shift - light from galaxies shifted to longer wavelengths so getting further away
Factors that add/remove intensity from photon flux (5)
Stimulated adsorption Stimulated emission Spontaneous emission Elastic scattering (Rayleigh) Inelastic scattering (Raman)
Issues with molecular astronomy affects of spectra (4)
Line broadening: lifetime and pressure broadening
Line of sight
Doppler: shift and broadening
Resolution
Why is it difficult to detect H2?
No dipole moment, can only measure electronic part (no IR). Can detect CO (has dipole moment); assume where CO is H2 is also there
How do stars form?
Some particles held together via gravity. Mass becomes larger, then when it gets to a certain mass (Jean’s mass) it collapses in on itself. As cloud contracts it heats up, interacting and releasing photons which are released and which are not reabsorbed causing energy loss (temperature decreases) resulting in further contraction
What is a proto-start?
Early star - region closest to the star is free of dust due to radiation destroying everything. Further out less intense radiation, dust remains forming proto-planetary disk
Low mass star M < M(sun)
- stops at He burning
- core contracts
- shell expands
- star turns into white dwarf into black dwarf (carbon cinder)
High mass star M > 20 M(sun)
- alpha capture
- Carbon, oxygen burning
- Elements up to 40Ca
- silicon burning ultimately gives iron
- even elements more abundant
- after O and Si burning collapse into neutron star
- (super) nova –> heavy elements
Issues with molecules in space (6)
- abundances
- densities
- temperature
- dissipation
- cosmic rays
- shock waves
Molecular view of the universe (6)
- detection of molecules
- determination of abundances
- physical conditions
- optical extinction
- chemical network
- kinetics
Define ISM
region between stars - outside heliosphere
What are the four different environments in the ISM?
- diffuse clouds
- dense clouds
- circumstellar disk
- photon-dominated region
Describe a diffuse cloud
- n = 1 - 100 cm-3
- T = 100 K
- temperature too high for molecules to stick so bare grains
- radiation from stars easily penetrates so not many molecules
- get H2 and CO due to self-shielding
Describe a dense cloud
- n = 10^6 cm-3
- T = 10 K
- Ices
- star formation
- lower T means radiation can’t penetrate so less heating
- shielded from radiation means more molecules present
- densities are high so bright in IR
- can collapse under own mass (Jean’s mass)
Describe a circumstellar disk
- depends of age/radiation field - further away from star temperature drops - get closer to molecular cloud e.g. molecules and ices
- full of ices and dust - light scattering
