Lecture-04 Big-Bang Nucleosysthesis

Lecture-04Big-Bang Nucleosysthesis Ping He ITP.CAS.CN 2006.03.04 http://power.itp.ac.cn/~hep/cosmology.htm

Basic Ideas of Nucleosynthesis • H, He, Li, … Light-elements are produced by big-bang nucleosysthesis (BBN); • Heavy metals (<Fe) are created in stars; • Super-heavy metals (>Fe) are generated in SNs.

4.0 Preliminaries In nuclear physics For pre-exponential factors:

4.1 Nuclear Statistical Equilibrium (NSE) When thermal equilibrium, for nuclear species A, the number density is

Moreover, chemical equilibrium Eq-3.1 also applies to n, p, hence we have

Definition of binding energy of the nuclear species A(Z) Substituting Eq-3.3 into 3.1, the abundance of A is: Table-1

Define total nucleon density: 丰度：质量百分比 So Eq-3.5 becomes: nB=nN Baryon-to-photon ratio So in NSE, the mass fraction of species A,

If Chemical equilibrium 4.2 Initial Conditions (T>>1MeV, t<<1sec) Key points: neutron-to-proton ratio The balance of neutron and proton is maintained by the weak interactions:

So, we have: Based upon charge neutrality, we have: Similarly:

The equilibrium n/p ratio: T → high n/p → 1

In terms of neutron lifetime Rates for interactions between neutrons and protons, for example

Since Lifetime of neutron So half-life of neutron: In fact:

So, we have: where In high- and low-Temperature limits:

By comparing to the expansion rate, , we have: Thus when T>0.8MeV, n/p -> equilibrium value, from (Eq-3.12), T->high, n/p ->1 At T>1MeV, rates of nuclear reactions for building up the light elements are also high -->NSE

Consider the following light elements: n, p, D-2, He-3, He-4, C-12, in NSE, the mass fractions are:

From Eq-3.7, when Table-2

4.3.1 step 1 ( t= sec, T=10MeV) 4.3 Production of the Light Elements: 1-2-3 The weak rates are much larger than the expansion rate H, so (n/p)=(n/p)eq~1, and light elements are also in NSE. From Eq-3.20 to Eq-3.25

The weak interactions that interconvert n and p freeze out ( ) 4.3.2 step 2 ( t= 1sec, T=TF=1MeV) • Not really constant due to residual weak interactions. • The deviation of n/p from its equilibrium value becomes significant by the time nucleosynthesis begins. (See Fig.4.1) • At this time, the light nuclei are still in NSE.

due to occasional weak interactions 4.3.3 step 3 ( t= 1 to 3 minutes, T=0.3 to 0.1 MeV) Major nuclear reactions:

that is, there are 109-1010 photons around one nucleon. Deuterium bottleneck: NSE So when T=0.1MeV, t=3min, not enough high-energy photons (E>2.2MeV) to disassociate D-2. is very low, due to The light-element bottleneck a). low abundances for D-2, He-3, and H-3, their NSE values:

b). Coulomb-barrier suppression: : thermally-averaged cross section times relative velocity. Bottleneck is broken If abundances of D-2, He-3, H-3  1 at TNUC=0.1MeV

, is predicted by: Li-7: An abundance of the order • H/p and He-4 are in dominative amounts; • Nuclei of A=5 and 8 are unstable, and with high Coulomb-barrier suppression, BBN is stopped at He-4, so that no heavier elements produced. Substantial amounts of both D-2 and He-3 are left: So:

So, T should not be too high, i.e., T<0.1MeV, t=3min otherwise, photon disassociation However, T should not be too low, i.e., T>0.02MeV, t~1hr otherwise, kinetic energy not high enough to penetrate Coulomb potential.

4.4 Primordial Abundances: Predictions What affect primordial nucleosynthesis?

Primordial He-4 abundance An accurate analytic fit for primordial mass fraction of He-4 Li-7 production process-I Li-7 production process-II

4.5 Primordial Abundances: Observations Hard task Primordial nucleosynthesis: 3min1hr Age of the universe: 13.8 billion years The difficulty of measurement: contaminants from astrophysical processes, such as stellar production and destruction. Specifically: 4.5.1 measurement of D a) via the UV absorption studies of the local interstellar medium (ISM) in the solar system. (DCO, DHO) Atmosphere of Jupiter : Consistent with

Primordial NSE value of D/H < 10^(-13), only when “the deuterium bottleneck” is broken , deuteron can be accumulated in great amount. See Fig-4.4, constrain h: b) high-z QSO absorption line Since deuteron is weakly-bound  easy to be destroyed In a star, more dense, so in NSE  D/H < 10^(-13)

4.5.2 measurement of He-3 a) measure of oldest meteorites: b) measure of solar wind: Notice that in a star, the processes for He-3 more complicated: hotter interiors: He-3 is destroyed cooler outer layers: He-3 is preserved low mass star : new He-3 from hydrogen burning Also provides constraint to h

4.5.3 measurement of He-4 He-4 can also be synthesis in stars • Hence, • low Z  low Y • Primordial abundance

Predicted He-4 abundance Present observations suggest that:

4.5.4 measurement of Li-7 Lithium abundances versus metallicity (from a compilation of stellar observations by V.V. Smith.)

Problem?

4.6 Primordial Nucleosynthesis as a Probe a) non-baryonic form of matter From the concordance of D, He-3, He-4, Li-7 abundances, we derive Dark matter From dynamical determinations

present observation b) Number of light neutrino flavors or cold components

4.7 Final Words • Primordial nucleosynthesis: agreement between theory and observation indicating the standard cosmology is valid back to 10-2sec, or T=10MeV; • Works as a probe for cosmology (WB), and particle physics (Nv), etc; • More precise observations for D, He-3, He-4, Li-7 are of great importance.

References • E.W. Kolb & M.S. Turner, The Early Universe, Addison-Wesley Publishing Company, 1993 • L. Bergstrom & A. Goobar, Cosmology and Particle Astrophysics, Springer, 2004 • M.S. Longair, Galaxy Formation, Springer, 1998 • 俞允强，热大爆炸宇宙学，北京大学出版社，2001 • 范祖辉，Course Notes on Physical Cosmology, See this site.

Lecture-04 Big-Bang Nucleosysthesis

Lecture-04 Big-Bang Nucleosysthesis

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