Quantum Magnetometers
-- Taking Advantage of Atomic Effects
Quantum magnetometers
are widely used in mineral exploration, hydrocarbon exploration;
archeology; environmental and engineering; unexploded ordnance detection
(UXO / EOD); and monitoring (magnetic observatory, volcanology,
earthquake hazard) applications.
GEM's quantum
magnetometer technical paper describes the types of quantum magnetometers,
their operating principles, and some of the guidelines for using
these geophysical instrumentation systems in real-world surveying
environments.
For brevity,
only a portion of this paper is included here. This page gives a
brief summary of each of the three main types of quantum magnetometers.
The complete paper includes the following topics:
- Magnetometers
- A Brief Description
- Quantum Magnetometers
- Standard
Proton Precession Magnetometers
- Overhauser
Magnetometers
- Optically
Pumped Alkali Vapor Magnetometers
- Sensitivity
- Bandwidth
- Recommended
Applications
- For More
Information
To download
this document (842 kB),
Brief Review of Quantum Magnetometers
by Dr. Ivan Hrvoic
click
here.
Proton Precession
Magnetometers
A standard proton
precession magnetometer uses hydrogen atoms to generate precession
signals. Liquids such as kerosene and methonol are used because
they offer very high densities of hydrogen and are not dangerous
to handle.
A polarizing
DC current is passed through a coil that is wound around the sample.
In a magnetometer, such as the GSM-19T, this creates a high-intensity
magnetic field of over 100 Gauss.
Protons in this
field are polarized to a stronger net magnetization corresponding
to the thermal equilibrium of stronger magnetic flux density.
When the auxiliary
flux is released, the "polarized" protons precess to re-align
themselves with the "normal" magnetic flux density. The
frequency of the precession relates directly to the magnetic field
strength.
Overhauser Magnetometers
The Overhauser
Effect is a nuclear method that takes advantage of a "quirk"
of physics that affects the hydrogen atom. This effect occurs when
a special liquid (containing electrons) is combined with hydrogen
and then exposed to a radio frequency (RF) magnetic field (i.e.
generated from a radio frequency source).
RF fields are
ideal for this type of application because they are transparent
to the Earth's DC magnetic field and the RF frequency is well out
of the bandwidth of the precession signal (i.e. does not contribute
noise to the measuring system).
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The unbound
electrons in the special liquid (normally a mixture of free radicals)
transfer their excited state (i.e. energy) to the hydrogen nuclei
(protons). This transfer of energy alters the spin state populations
of the protons and polarizes the liquid - just like in a proton
magnetometer - but with much less power and to greater extent.
The proportionality
of the precession frequency and the magnetic flux density is linear
and can be described through a simple equation.
Optically Pumped
Magnetometers
Optically pumped
magnetometers use gaseous alkali metals from the first column of
the periodic table, such as cesium and potassium (or He 4 in metastable
state). That means that the cell containing the metal must be continuously
heated to approximately 45 degrees C. These magnetometers operate
on virtually the same principle (illustrated in part, by the figure
below).
First, a glass
cell containing the gaseous alkali metal is exposed (or pumped)
by light of a very specific wavelength - an effect called light
polarization. The frequency shift of light is specifically selected
and circularly polarized for each element to shift electrons from
level 2 to the excited state 3.
Electrons at
level 3 are not stable, and these electrons spontaneously decay
to both energy levels 1 and 2. Eventually, the level 1 is fully
populated (i.e. level 2 is depleted). When this happens, the absorption
of polarizing light stops and the vapour cell becomes more transparent.
This is when
RF depolarization comes into play. RF power corresponding to the
energy difference between levels 1 and 2 is applied to the cell
to move electrons from level 1 back to level 2 (and the cell becomes
opaque again). The frequency of the RF field required to populate
level 2 varies with the ambient magnetic field and is called the
Larmor frequency.
The effect of
polarization and depolarization is that the light intensity becomes
modulated by the RF frequency. By detecting light modulation and
measuring the frequency, we can obtain a value of the magnetic field.
Access the Complete
Paper
The complete
paper provides a complete overview of quantum magnetometers of interest
to both those who are new and experienced with the basic principles
and applications.
In addition,
a comprehensive comparison of cesium and potassium optically-magnetometers
is provided - giving insight into some of the scientific basis on
which more users are adopting potassium methods for high sensitivity
ground and airborne work.
To download this
document,
Advantages of Potassium
Magnetometers
click
here.
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