The Sun is powered by nuclear fusion. In each chain reaction, four hydrogen nuclei fuse together to become a single helium nucleus. The total combined mass of the individual hydrogen nuclei before the reaction is greater than the mass of the helium nucleus. The mass lost as a result of this chain reaction is turned into energy according to Einstein’s famous equation, E = mc² (Chapter 39). Consider the first part of the chain reaction in which two hydrogen nuclei (each a single proton) fuse. Figure P8.56A shows the potential energy curve of a two-proton system. The energy in this graph is given in keV, where “eV” is the abbreviation for the unit electron-volt and 1 eV = 1.6 × 10−19 J. When the protons are more than about 2 fm (2 × 10−15 m) apart, the potential energy is positive. When the protons are close together, the potential energy is negative, and the protons are fused. Figure P8.56B shows a close-up of the potential energy curve when the protons are far apart.

1. a. What is the minimum mechanical energy required for the two protons to fuse? Give your answer in keV.
2. b. The mechanical energy of an average two-proton system in the Sun is around 2 keV. What is the minimum distance between the protons in such a system?
3. c. Explain why it seems impossible for fusion to take place in the Sun. Note: Of course, fusion must take place in the Sun. Although it seems impossible according to classical mechanics, quantum mechanics (Part VI) makes fusion possible. According to quantum mechanics, the seemingly impossible is merely improbable, and even events with a low probability of occurrence may still happen. Because there are so many protons in the Sun, there is a good chance that at any moment many of them will fuse.

Most of the Sun’s energy comes from the proton-proton chain inwhich four hydrogen nuclei (i.e., protons)
fuse into one helium nucleus.
(a) Calculate how much mass is “lost” in one proton-proton chainreaction.
(b) How much energy is produced in one proton-proton chainreaction? In other words, find a change in
the rest mass energy before and after the reaction.
(c) The total power output of the Sun is 3.85×10²⁶W. Ifall of it comes from the proton-proton chains,
how many kilograms of mass is being converted into energy in theSun in one second?

A relatively new method of treating cancers is to bombard the tumorwith protons (The nuclei of hydrogen). The idea is that the protonswill eject electrons from the molecules of the cell, and thenelectrostatic forces (discussed in physics 1202W) will then pullthe molecule apart. If this happens in the cell DNA, the cell willbe sterile and thus will not reproduce but will disappear after itsnatural lifetime.

Electrons are however bound to their individual atoms, which meanthat relative to the world they have negative potential energy. Itis therefore necessary to transfer energy to them in order torelease them.

Consider the most favorable case. A proton collides head on with anelectron, so that after the collision, they both leave in the samedirection as the proton was incident.. The collision is elastic,i.e. no loss of energy, and the average binding (potential) energyof the electrons in the tumor cells is -5 electron volts.

What is the minimum energy of the incoming proton which will ejectan average electron? If instead of it being an elastic collision,the electron sticks to the proton to form a hydrogen atom, whatthen would be the minimum energy of the incoming proton?

( 1 electron volt = 6 x 10-18 Joules.

Mass of a proton 1..6 x 10- 27 Kg,

Mass of an electron 9.1 x 10-31 Kg).

A relatively new method of treating cancers is to bombard the tumorwith protons (The nuclei of hydrogen). The idea is that the protonswill eject electrons from the molecules of the cell, and thenelectrostatic forces (discussed in physics 1202W) will then pullthe molecule apart. If this happens in the cell DNA, the cell willbe sterile and thus will not reproduce but will disappear after itsnatural lifetime.

Electrons are however bound to their individual atoms, which meanthat relative to the world they have negative potential energy. Itis therefore necessary to transfer energy to them in order torelease them.

Consider the most favorable case. A proton collides head on with anelectron, so that after the collision, they both leave in the samedirection as the proton was incident.. The collision is elastic,i.e. no loss of energy, and the average binding (potential) energyof the electrons in the tumor cells is -5 electron volts.

What is the minimum energy of the incoming proton which will ejectan average electron? If instead of it being an elastic collision,the electron sticks to the proton to form a hydrogen atom, whatthen would be the minimum energy of the incoming proton?

( 1 electron volt = 6 x 10-18 Joules.

Mass of a proton 1..6 x 10- 27 Kg,

Mass of an electron 9.1 x 10-31 Kg).