What is the energy of an atom in a magnetic trap as a function of position?

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In summary, the energy of an atom in a magnetic trap varies with position due to the spatially dependent magnetic field. Atoms experience different potential energies based on their alignment with the magnetic field, leading to a potential well where the energy minima correspond to stable trapping regions. The energy landscape influences the atom's behavior and dynamics within the trap, which is crucial for applications in quantum mechanics and atomic physics.
  • #1
Malamala
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Hello! I am a bit confused about trapping using magnetic traps. In a simplified version, assuming we have 2 anti-Helmholtz coils, the magnetic field in between them (assume that the trapping regions is much smaller than the radius of a coil, as well as much smaller than the distance between the coils) along the axial direction is given by:

$$B_z = az$$
where ##a## depends on the geometry. Now the energy of an atom in the trap, with spin ##S## (assume it is 1/2) is given by:

$$E = -g\mu_BS_zB_z = -ag\mu_BS_zz \equiv \alpha zS_z$$
Now I understand that there are high and low field seeking states. But I am not sure how does it work. Say we are in a state with ##S_z = +1/2##. Then the energy is given by ##E = \alpha/2 \times z##, which means that the atom won't be stable around 0, but will try to move away in a negative direction (assuming ##\alpha > 0##). Similarly, for ##S_z=-1/2## the atom will move in the positive direction. In either case, there doesn't seem to be a value of ##z## for which the atoms will have a minimum of energy, which means that they won't get trapped. What am I doing wrong? Thank you!
 
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This magnetic field doesn't exist in Nature, since ##\vec{\nabla} \cdot \vec{B} \neq 0##.

It's rather much more worthwhile studying the Penning trap. Which for obvious reasons is sometimes called an "artificial atom" or "geonium", and you can get very far with analytical solutions.

L. S. Brown and G. Gabrielse, Geonium Theory: Physics of a
Single Electron or Ion in a Penning Trap, Rev. Mod. Phys. 58,
233 (1986), https://doi.org/10.1103/RevModPhys.58.233
 
  • #3
Malamala said:
Hello! I am a bit confused about trapping using magnetic traps. In a simplified version, assuming we have 2 anti-Helmholtz coils, the magnetic field in between them (assume that the trapping regions is much smaller than the radius of a coil, as well as much smaller than the distance between the coils) along the axial direction is given by:

$$B_z = az$$
where ##a## depends on the geometry.
That's incorrect. While the magnitude of the magnetic field of a quadrupole trap is approximately linear near the center of the trap, its goes as ##B = B' (x^2 + y^2 + 4z^2)^{1/2}##. It is minimum at the center of the trap an increases in all directions.

vanhees71 said:
It's rather much more worthwhile studying the Penning trap.
But that would be changing the subject. The OP is about traps for neutral atoms, not for charged particles.
 
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  • #4
vanhees71 said:
This magnetic field doesn't exist in Nature, since ##\vec{\nabla} \cdot \vec{B} \neq 0##.

It's rather much more worthwhile studying the Penning trap. Which for obvious reasons is sometimes called an "artificial atom" or "geonium", and you can get very far with analytical solutions.

L. S. Brown and G. Gabrielse, Geonium Theory: Physics of a
Single Electron or Ion in a Penning Trap, Rev. Mod. Phys. 58,
233 (1986), https://doi.org/10.1103/RevModPhys.58.233
I am not sure I understand what you mean. People use magnetic traps to trap neutral atoms. I know about Penning traps, but these are used for charged particles. Also what you mean by it doesn't exists in Nature? I just used Maxwell's equations to derive that and did a Taylor expansion around ##z=0##. You mean I made a mistake in the derivation?
 
  • #5
DrClaude said:
That's incorrect. While the magnitude of the magnetic field of a quadrupole trap is approximately linear near the center of the trap, its goes as ##B = B' (x^2 + y^2 + 4z^2)^{1/2}##. It is minimum at the center of the trap an increases in all directions.But that would be changing the subject. The OP is about traps for neutral atoms, not for charged particles.
Thanks for this. But that formula is for the magnitude of the field and I agree with it. However, for the energy, don't we need the vectorial form of B, in order to take the dot product with the magnetic dipole moment? My question is basically what is the energy as a function of ##z## (assuming ##x=y=0##).
 
  • #6
Malamala said:
I am not sure I understand what you mean. People use magnetic traps to trap neutral atoms. I know about Penning traps, but these are used for charged particles. Also what you mean by it doesn't exists in Nature? I just used Maxwell's equations to derive that and did a Taylor expansion around ##z=0##. You mean I made a mistake in the derivation?
I thought, you just want to have an example for traps. Of course, you can't use a Penning trap for trapping neutral atoms. For that you use indeed magnetic traps, but of course you can only use magnetic fields that exist in Nature, i.e., they must obey Maxwell's equations, i.e., it must obey Gauss's Law for the magnetic field, ##\vec{\nabla} \cdot \vec{B}=0##. Here's a review

https://doi.org/10.1103/RevModPhys.79.235
 
  • #7
Malamala said:
Thanks for this. But that formula is for the magnitude of the field and I agree with it. However, for the energy, don't we need the vectorial form of B, in order to take the dot product with the magnetic dipole moment? My question is basically what is the energy as a function of ##z## (assuming ##x=y=0##).
The field changes direction as you cross the origin,
$$
\mathbf{B} = B' (x,y,-2z)
$$
See https://commons.wikimedia.org/wiki/File:VFPt_anti-helmholtz_coil.svg
 
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FAQ: What is the energy of an atom in a magnetic trap as a function of position?

What is the basic concept of the energy of an atom in a magnetic trap?

The energy of an atom in a magnetic trap is determined by its interaction with the magnetic field. The magnetic field creates a potential energy landscape where the atom can be trapped and manipulated. The energy depends on the magnetic moment of the atom and the strength and gradient of the magnetic field at the atom's position.

How does the position of the atom affect its energy in a magnetic trap?

The position of the atom affects its energy because the magnetic field strength varies with position. As the atom moves within the trap, it experiences different magnetic field strengths, leading to changes in its potential energy. Typically, the energy is lower at the center of the trap where the magnetic field is stronger and increases as the atom moves away from the center.

What mathematical expression describes the energy of an atom in a magnetic trap?

The energy \( E \) of an atom in a magnetic trap can be expressed as \( E = -\mu \cdot B \), where \( \mu \) is the magnetic moment of the atom and \( B \) is the magnetic field strength at the atom's position. For a magnetic quadrupole trap, the field strength \( B \) can be a function of position coordinates, such as \( B(x, y, z) \).

What role does the magnetic moment of the atom play in determining its energy in the trap?

The magnetic moment \( \mu \) of the atom plays a crucial role in determining its energy in the trap. It represents the strength and orientation of the atom's magnetic dipole. The interaction between the magnetic moment and the magnetic field determines the potential energy of the atom. Atoms with larger magnetic moments will experience stronger interactions with the magnetic field, leading to more significant changes in energy with position.

How can the energy of an atom in a magnetic trap be experimentally measured?

The energy of an atom in a magnetic trap can be measured using techniques such as radiofrequency spectroscopy, where transitions between different energy levels are induced and detected. Additionally, imaging techniques can be used to observe the position and motion of the atoms within the trap, allowing for indirect determination of their energy based on the known magnetic field distribution.

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