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Nuclei Class 12 Physics Notes

NUCLEI

SOME IMPORTANT FACTS ABOUT ATOMIC MASS, SIZE AND COMPOSITION OF NUCLEUS

• Proton was discovered by Goldstein
• Atomic mass unit
  1.a.m.u = 1/12th of mass of C-12 isotope,
  1 a.m.u = 1.660565 × 10–27 kg
• Mass of a proton, mp = 1.0073 a.m.u = 1.6726 × 10–27 kg
• Chadwick’s experiment
  Neutrons were detected.
  
• Mass of neutron, mn = 1.00866 a.m.u = 1.6749 × 10–27 kg
• Mass of electron = 9.1 ×10–31 kg
• Mass number, A = total number of nucleons (neutrons + protons present in the nucleus of an atom)
• Atomic number, Z = number of protons = number of electrons
• Types of nuclei :
• Isotopes : The atoms of the element which have the same atomic number but different atomic mass numbers. e.g.,  1H1, 1H2, 1H3 ; 8O16, 8O17, 8O18
• Isobars : The atoms of differents element which have the same atomic mass number but different atomic numbers. e.g., 6C14, 7N14, 18Ar40, 20Ca40 etc.
• Isotones : The nuclides which contain the same number of neutrons e.g., 2H23, 2He24, 2Be59, 5Be510  etc.
• Isomers : having same mass number, same atomic number but different radioactive properties.
• Rest mass of nucleus is less than sum of rest masses of constituent nucleons, the difference is called mass defect.
• Size of the nucleus : Radius of nucleus, R = R0 A1/ 3 where R0 = 1.1 × 10–15 m.
• Nuclear density of all elements ~ 1017 kg m–3.

MASS ENERGY AND NUCLEAR BINDING ENERGY

BINDING ENERGY

Total

Binding energy per nucleon

    

1. A nuclide is a specific nucleus of an atom characterised as ZXA  where A = mass number and Z = atomic number.
2. Binding energy per nucleon is nearly 8.4 MeV for nuclei in the range of mass number 40 to 120.
3. Binding energy is highest in Fe56.( 8.8 MeV)
4. Binding energy curve predicts :
1. Fission : Breaking up of a heavy nucleus (A > 200) into two nuclei of approximately equal size,  and release of energy.
2. Fusion : Lighter nuclei ( A < 20) combine together to form heavier nucleus and release of energy.
3. BE/ A varies by less than 10% above A = 10 suggests that each nucleon interacts with its neighbouring nucleon only.
4. For A > 56, BE/A decreases because of the destabilising effect of long-range coulombic force.

NUCLEAR FORCE

CHARACTERISTICS OF NUCLEAR FORCE

1. It is a short range force effective only in range 10–15 m
2. It is charge independent. It acts between proton-proton, proton-neutron and neutron – neutron.
3. It is not a central force.
4. It is spin dependent.
5. It is 1038 times stronger than gravitational force and 102 times stronger than electric force.
6. The main cause of nuclear force is the exchange of π− mesons between nucleus

, ,

RADIOACTIVITY

• α-rays (i.e., Helium nuclei or α – particles)
• β-rays (i.e., electron or positron or β – particles)
• γ-rays (photons or gamma radiations)

• chemical combination
• changing physical environment other than nuclear bombardment

FEATURES OF RADIOACTIVITY

• It is a statistical process.
• When a nucleus undergoes alpha or beta decay, its atomic number and  mass number changes (in β-decay only atomic number changes) & it transforms into a new element.
• (α-particle), it means that by emission of alpha particle (α-particle), it loses 2 units of charge and 4 units of mass.
• (positron). It means that by emission of beta particle (β+-particle), nucleus loses one unit of charge. It is surprising to note that a nucleus does not contain β+ then how is it emitted. Reason : During a β+ particle(i.e., positron) decay, a protron converts into a neutron

 (neutrino).

 (antineutrino)

• When a nucleus emits a gamma ray, neither the mass nor the charge of the nucleus changes

i.e.,

PROPERTIES OF α, β & γ-RAYS

• It is a positively charged particle & contains a charge of 3.2 × 10–19 coulomb (exactly double the charge of electron).
• The mass of α-particles is 6.645 × 10–27kg (It is equal to mass of a helium nucleus). Actually α-particle is nucleus of helium, hence it is called doubly ionised helium.
• They (α-particles) get deflected in both electric & magnetic fields.
• The velocity of α-particle is very less than the velocity of light i.e., , where c is velocity of light.
• The range of α-particle in air depends on radioactive substance.
• The ionisation power of α-particle is higher than both β (100 times of β & 10,000 times of γ) and γ particle.
• The penetrating power of α particle is lowest (in comparison to β & γ particles). It is 1/100 times of β-particles & 1/10,000 times of γ-rays.
• The α-particles can produce fluorescence in barium platinocyanide and zinc sulphide.
• They show little effect on photographic plate.
• They show heating effect on stopping.

• The beta particles (i.e., β– or β+) may be positive & negative particle & contain of charge. Actually β– is electron & β+ is positron.
• They get deflected in both electric & magnetic field.
• The velocity of β-particle varies between 0.01c to .99c, where c is velocity of light.
• The mass of β particle is relativistic, because its velocity is comparable to velocity of light
• They have both ionisation & penetration power. Ionisation power less than α-particle and penetration power more than α-particle.
• They produce fluorescence on barium platinocyanide & zinc sulphide.

• They are electromagnetic waves as x-rays.
• They are not deflected in electric & magnetic field, it means that they are chargeless.
• The velocity of γ-particle is equal to velocity of light.
• The ionisation power of gamma rays is less than β & α rays but penetration power more than β and α-rays.
• The γ-particles are emitted from the nucleus, while X-rays are obtained, when electron goes from one state to another in an atom.    
• When γ-rays photon strikes nucleus in a substance, then it gives rise to a phenomenon of pair production i.e.,

The minimum energy of γ-rays required for this phenomena is 1.02 MeV, because the rest mass energy of particle is 0.51 MeV.

RUTHERFORD AND SODDY LAW FOR RADIOACTIVE DECAY

If N is the number of nuclei at any time t & at t + dt time, it decrease to N-dN then the rate of decay of these nuclei is (negative sign comes because N decreases as t increases). So according to Rutherford & Sodi,

or ...(1)

where

⇒  

HALF-LIFE OF A RADIOACTIVE SUBSTANCE

Let at = T1/2
then by eq. (2)

or  

Also for n half-lives

⇒ where m0 is mass of radioactive substance at t = 0 and m is mass at t = t.

MEAN LIFE OF A RADIOACTIVE SUBSTANCE

It is given as :

The equivalent and τ for two nuclei A and B,

RADIOACTIVE SERIES

(Half life )

(Half life )

(Half life )

(Half life )

RADIOACTIVE EQUILIBRIUM

NA λA = NB λB = ............ or = ............

CARBON DATING

 

1. Specific activity is the activity of 1 gram of material.
2. Geiger Muller Counter is used for detecting α and β particles.
3. Cloud chamber is used for detecting radioactive radiations and for determining their paths, range and energy.
4. Baryon number
   B = 1, for a neutron and a proton.
5. Lepton number (L)
   L = 1 for electron, and neutrino

6. Radioactive isotope
1. Iodine-131 For detecting the activity of thyroid gland
2. Chromium-51 To locate the exact position of haemorrhage
3. Phosphorus-32 In agriculture
4. C–14 Carbon dating, Photosynthesis in plants
5. Co60 Cancer treatment
6. Na24 For circulation of blood

NUCLEAR REACTION

1. Charge conservation
2. Conservation of linear momentum
3. Conservation of angular momentum
4. Conservation of energy (Rest mass energy + K.E.)

Standard way  

NUCLEAR FISSION (BY OTTO HAHN AND STRASSMANN)

• Nuclear fuel : U233, U235, Pu239 etc.
• Moderator : Graphite, heavy water (D2O). To slow down the neutrons (or slow down the nuclear reaction).
• Control rods : (Cadmium, boron). To absorb excess neutrons. It controls the chain reaction.
• Coolant : (water etc). To remove the heat produced in the core to heat exchanger for production of electricity.

Critical mass :  It is the minimum amount of fissionable material required to carry out fission reaction. It is 10 kg for

Reproduction factor K

for uncontrolled reaction

NUCLEAR FUSION