Section 11

Question 1

What is the stellar birth line?

Answer 1

The line in the HR diagram which young pre-main sequence stars have become visible

(the birth line for massive stars coincides with main sequence)

Question 2

Before a protostar can join main sequence, what needs to happen?

Answer 2

It has to begin hydrogen burning and needs to contract further by radiating away the released grav energy

Question 3

What is the timescale for contraction?

Answer 3

Kelvin-Helmholtz timescale: ratio of gravitational energy to luminosity

Question 4

What is assumed if luminosity is taken to be proportional to M^4 ?

Answer 4

Constant radius
Constant gravity

Question 5

What can be deduced when comparing Kelvin-Helmholtz timescale with free fall time?

Answer 5

t_k-h &laquo_space; t_ff

freefall timescale has shallower relationship with mass compared to KH timescale

Massive stars arrive on main sequence while still embedded in their molecular cloud

Question 6

How do the timescales of higher mass stars vary with smaller mass stars?

Answer 6

smaller ratio of timescales
shorter KH timescale compared to free fall timescale so massive stars can’t be seen in initial phases (contraction time is shorter than that for low mass stars)

Question 7

How is a low mass star formed?

Answer 7

cloud -> collapse -> hydrostatic core -> contraction -> star

free fall time: cloud -> collapse

KH timescale: hydrostatic core -> contraction -> star

Question 8

How is a high mass star formed?

Answer 8

cloud -> collapse -> collapse -> collapse… -> hydrostatic core -> contraction -> star

Question 9

Why can’t high mass stars be seen until they are formed?

Answer 9

Pre-main sequence phase is deeply embedded in cloud

Still accreting when they reach main sequence

(upper right region of HR digram is empty)

Question 10

How are massive stars identified?

Answer 10

Luminous IR sources
HII regions

Question 11

What is the main characteristic of massive stars?

Answer 11

they have enough energy to ionise their surroundings (UV wavelengths), seen as HII regions

Question 12

What do energetic photons do in the HII region?

Answer 12

Energetic photons dissociate H_2 and ionise atomic hydrogen

Question 13

How is atomic hydrogen recreated?

Answer 13

Via process of RECOMBINATION with an electron

Question 14

What is a star with a fixed output in UV radiation limited to?

Answer 14

Only being able to ionise limited regions in the surrounding cloud

Question 15

What is the Stromgren sphere?

Answer 15

The surrounding medium of a massive star which is uniform and ionises the surrounding region, producing a HII region

Question 16

What does the central massive star do?

Answer 16

Photo-ionises hydrogen atoms in the surroundings which results in a HII region

Question 17

What happens in the ionised gas surrounding massive star?

Answer 17

Free electrons can recombine with protons to form neutral hydrogen

Question 18

Which rates are balanced in the Stromgren sphere?

Answer 18

The photo-ionisation rate will be balanced by recombination rate

Question 19

Why is it possible to calculate the size of the Stromgren sphere?

Answer 19

There is a finite number of ionising photons from the star

Question 20

What determines the size of the HII region?

Answer 20

Stellar temperature and luminosity
density of medium

Question 21

Why is the number density of electrons with HII region not equal to number density of H atoms externally?

Answer 21

Ionisation spreads quickly to the Stromgren radius and the original cloud density is not able to change appreciably

Question 22

From Stromgren radius, what can be deduced about increasing the number density?

Answer 22

Stromgren radius decreases as increase in number density means faster recombination so HII region decreases in size)

Less material is ionised

Question 23

What shows a sharp increase in the number of ionising photons?

Answer 23

Spectral type of stars

Question 24

Which sizes of stars can ionise their surrounding gas?

Answer 24

M > 10 M_o
T > 30,000 K

Emits radio continuum (free-free radiation)

Question 25

How can the HII region be observed?

Answer 25

At radio wavelengths via free-free emission of radiation from ionised gas (eventually visible in optical)

Question 26

What happens at the Stromgren radius and why?

Answer 26

The ionisation fraction drops sharply

due to the PRESSURE DIFFERENCE between regions caused by:

ionised hydrogen has twice as many particles

Temperature drop (from 10,000 K to 10K)

Question 27

What will the overpressure of the Stromgren radius cause?

Answer 27

The ionisation front to expand due to overpressure at the speed of sound (10km/s)

Question 28

What is the HII region for an O6 star?

Answer 28

very sharp - edged
radius of 0.4 pc
T = 30,000 K

Question 29

What holds the Stromgren sphere?

Answer 29

Ionisation balance

volumetric ionisation rate = recombination rate (p+ + e-)

Question 30

What are the main phases of the molecular cloud period of stars?

Answer 30

Infrared dark cloud (IRDC)

hot core

massive young stellar object (MYSO)

hyper and ultra compact HII regions

compact then classical HII region

Question 31

What are infrared dark clouds?

Answer 31

clouds that exhibit significant mid-infrared opacity (with extreme properties such as cold temp (<20K)

Question 32

What wavelengths are MYSOS bright at?

Answer 32

mid and near infrared wavelengths

L > 10^4 L_o

(possess HII regions at radio wavelengths)

Question 33

Why do MYSOs not have a HII region?

Answer 33

jets and outflows formed: they are still accreting so might be similar to low mass stars

Question 34

In which wavelength are UCHII regions visible?

Answer 34

in the far-IR they are the most luminous objects in Galaxy

Question 35

What needs to be considered to evaluate if massive stars are expected to form at all?

Answer 35

Mass accretion rate

Luminosity as a function of mass

Question 36

What is the main problem with massive star formation?

Answer 36

Radiation pressure on dust considered a severe hinderance on accretion
(problem may be fixed by accretion through a disk)

Question 37

What are the three theories on massive star formation?

Answer 37

isolated cores

strong clustering

stellar collisions and mergers, dense systems

(the formation of massive stars requires additional processes)

Question 38

What shows that massive stars cannot form?

Answer 38

Comparing the rate of change of momentum of in-falling material with the force due to radiation