Conversion of mass to energy

In summary, the bound system of an electron and proton behaves as though it has less mass than the individual particles due to the release of energy in the form of a photon. This can be explained by the decrease in potential energy between the particles as they come together, which results in a decrease in the overall mass of the system. The equation E=mc^2 is used to calculate the binding energy of the system.
  • #1
K8181
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I have a fundamental question. I am reading this modern physics book, and it says that an electron and a proton that are released and come together into a bound state release a photon. Fine. But the explanation given is that the sum of the individual masses of the proton and electron is greater than the mass of the bound system, and that the extra rest mass was converted to energy in the release of the photon. I am confused because it seems that an equally good explanation is that the electron and proton have a potential energy when they are apart, and it is this energy that is released as a photon. Here there would be no conversion of mass into energy needed to save conservation of energy. Does the bound system behave as though it has less mass than the constituent particles, or is the second explanation just as good? Please help. :confused:
 
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  • #2
Start with the electron and proton infinitely far apart. Call this 0 potential energy. Now let them fall together under their electrostatic attraction. They feel an attractive force, and the energy of the final configuration is less than it was at infinity--i.e., work must be done to pull them apart, i.e., you must add energy to the system to make them both "free" again. Now, whether the electron and proton spit out a photon to get rid of this energy, or whether the energy is removed in some other way, there is less interaction energy between them when they are bound into an atom than when they were at infinity. The rest mass is the same in both cases, just the rest mass of the electron and the rest mass of the proton. But when they are bound, their potential energy is less. Since energy has mass (E=mc^2), the mass of the bound system is m_proton + m_electron - E_binding/c^2. To find the binding energy, integrate the coulomb force between the particles from infinity to the electronic radius of the atom.

-Beth
 

What is the conversion of mass to energy?

The conversion of mass to energy is a fundamental concept in physics, which states that mass and energy are interchangeable. This concept is described by Einstein's famous equation: E = mc^2. This means that a small amount of mass can be converted into a large amount of energy, and vice versa.

How does the conversion of mass to energy work?

The conversion of mass to energy occurs through nuclear reactions. These reactions involve the splitting or combining of atomic nuclei, which releases or absorbs energy. This energy is in the form of radiation, such as gamma rays and heat.

What is an example of mass being converted into energy?

A well-known example of mass being converted into energy is in nuclear power plants. In these plants, radioactive materials, such as uranium, undergo nuclear reactions, which convert a small amount of mass into a large amount of energy. This energy is then used to generate electricity.

What is the significance of mass to energy conversion in our daily lives?

The conversion of mass to energy has significant implications in our daily lives. It is the principle behind nuclear power, which provides a significant portion of the world's electricity. It is also the basis for nuclear weapons and has played a crucial role in space exploration, as it allows for the immense amounts of energy needed for rocket propulsion.

Is the conversion of mass to energy reversible?

According to the laws of physics, the conversion of mass to energy is reversible. This means that energy can be converted back into mass, although the process requires the same amount of energy that was initially released. However, due to the high energy requirements, this type of conversion is not yet practical or feasible for human use.

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