Quantum Resonance Magnetic Analyzer Software 4.7.0 Download
Janet Denzel
Since now, few data are available on the mechanism of interaction between QMR and cells. Dal Maschio and colleagues [22] provided the description of the behavior of muscle fibers exposed to QMR, where the changes of membrane potential and the variations of free calcium concentration strictly followed the time course of electrical field application and removal. Moreover, the effectiveness of molecular quantum resonance in reducing edema after total knee arthroplasty in a clinical trial has been reported [23].
In quantum mechanics, magnetic resonance is a resonant effect that can appear when a magnetic dipole is exposed to a static magnetic field and perturbed with another, oscillating electromagnetic field. Due to the static field, the dipole can assume a number of discrete energy eigenstates, depending on the value of its angular momentum (azimuthal) quantum number. The oscillating field can then make the dipole transit between its energy states with a certain probability and at a certain rate. The overall transition probability will depend on the field's frequency and the rate will depend on its amplitude. When the frequency of that field leads to the maximum possible transition probability between two states, a magnetic resonance has been achieved. In that case, the energy of the photons composing the oscillating field matches the energy difference between said states. If the dipole is tickled with a field oscillating far from resonance, it is unlikely to transition. That is analogous to other resonant effects, such as with the forced harmonic oscillator. The periodic transition between the different states is called Rabi cycle and the rate at which that happens is called Rabi frequency. The Rabi frequency should not be confused with the field's own frequency. Since many atomic nuclei species can behave as a magnetic dipole, this resonance technique is the basis of nuclear magnetic resonance, including nuclear magnetic resonance imaging and nuclear magnetic resonance spectroscopy.
The phenomenon of magnetic resonance is rooted in the existence of spin angular momentum of a quantum system and its specific orientation with respect to an applied magnetic field. Both cases have no explanation in the classical approach and can be understood only by using quantum mechanics. Some people claim[who?] that purely quantum phenomena are those that cannot be explained by the classical approach. For example, phenomena in the microscopic domain that can to some extent be described by classical analogy are not really quantum phenomena. Since the basic elements of magnetic resonance have no classical origin, although analogy can be made with Classical Larmor precession, MR should be treated as a quantum phenomenon.
Non-Invasive Scanning: QRMA employs non-invasive scanning probes that emit low-energy electromagnetic waves. These waves interact with the body's electromagnetic fields, generating resonance responses.
Resonance Responses: As the emitted electromagnetic waves interact with the body's tissues and organs, they induce resonance responses. Each organ and system within the body produces a unique electromagnetic pattern.
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