Unraveling the Mystery of Neutral Atoms and Electric Fields

In summary, the conversation discusses the effects of electric fields on neutral atoms. It is explained that a neutral atom does not have a net charge, so it neither creates nor is affected by electric fields in the same way as charged particles. However, electric fields can still affect an atom's internal structure, such as its energy levels. The concept is further explored using classical and quantum mechanics.
  • #1
MHD93
93
0
Hi

People all know that a neutral atom has no net charge.

Well, does that mean that it neither creates an electric field nor is affected by any electric field?

I wonder whether it's correct or not, because the distance between a test charge outside this atom is closer to its electrons relative to its protons.

Thanks
 
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  • #2
Mohammad_93 said:
Hi

People all know that a neutral atom has no net charge.

Well, does that mean that it neither creates an electric field nor is affected by any electric field?

I wonder whether it's correct or not, because the distance between a test charge outside this atom is closer to its electrons relative to its protons.

Thanks

There are two aspects to answering your question. The first is classical, and the second is quantum mechanical, or if you prefer, chemistry.

1. Tackle this using classical E&M. Put a charge Q at an origin. Now, on a spherical shell at a radius R, put an amount of charge -Q that is spherically symmetric about the origin.

Using Gauss's Law, what is the E field at a field point r>R?

2. An electric field doesn't affect an atom in ways that it changes its path or anything similar to a charged particle. However, it can change it internal "structure", such as its energy levels. The Stark effect is one clear example. At some point, with sufficiently high E field one can also induce an electric dipole by shifting the orbital geometry with respect to the nucleus, etc. So yes, an electric field can affect a neutral atom, but not in the same way you may have in mind.

Zz.
 

Related to Unraveling the Mystery of Neutral Atoms and Electric Fields

1. What are neutral atoms and how are they different from charged atoms?

Neutral atoms are atoms that have an equal number of protons and electrons, resulting in a net charge of zero. This means that the positive charge of the protons is balanced out by the negative charge of the electrons. Charged atoms, on the other hand, have an unequal number of protons and electrons, resulting in a net positive or negative charge.

2. How do electric fields interact with neutral atoms?

Electric fields are created by the presence of charged particles and exert a force on other charged particles. However, neutral atoms do not have a net charge and therefore do not interact directly with electric fields. Instead, the electrons within the atom may be affected by the electric field, causing the atom to become polarized.

3. What is the significance of studying neutral atoms and electric fields?

Understanding the interactions between neutral atoms and electric fields is crucial in many fields of science, including physics, chemistry, and engineering. It helps us understand the behavior of matter and how it responds to different forces, which can have practical applications in technology and further our understanding of the natural world.

4. How do scientists unravel the mystery of neutral atoms and electric fields?

Scientists use a variety of experimental techniques and theoretical models to study the behavior of neutral atoms in the presence of electric fields. This often involves manipulating and measuring the properties of atoms using specialized equipment and conducting experiments in controlled environments.

5. What are some potential applications of understanding neutral atoms and electric fields?

The knowledge gained from studying neutral atoms and electric fields has many practical applications, such as in developing new technologies like sensors and electronic devices. It also plays a crucial role in fields like material science, where understanding how materials interact with electric fields is essential for designing new materials with specific properties.

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