Diapositiva 1

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Livio Giuliani1,2, Settimio Grimaldi5,3,
Antonella Lisi 9, Enrico DEmilia 4 The
replicability of the Zhadin effect and
perspectives of application in diagnostics and
therapy 1 ICEMS Scientific Secretariat 2
Director of ISPESL Department of Venice 3
CNR-INMM, Rome 4 ISPESL
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But first, lets start with a little
history..
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We reproduced the Liboff-Zhadin effect in an
A-magnetic room with strictly controlled
parameters
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A-magnetic room
Power supply units
Solenoid chamber 3 meters long - 30 cm wide
Zhadin cell is placed in the center of the
solenoid
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The Zhadin cell
Magnetic detector
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Glutaminic acid
Zhadin effect
Baseline current
Applied without magnetic field
4.17Hz 48uT Bo 48nT B
Experimental parameters
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An attempt to study if, at the Zhadin ions
cyclotron frequency, molecules can generate an
intrinsic magnetic field
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• Procedures
• Samples are placed into an A-magnetic flask
  surrounded by two external electrodes and placed
  in a magnetic transductor.
• The magnetic transductor is placed in the center
  of the main solenoid where the frequency
  resonance is generated

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The solenoid for sample magnetic Field
detection is in the center of the main solenoid
Sample
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Function generator
Pico Ammeter
Controller unit (humidity, atmosphere)
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Signal applied
Threshold noise
Threshold noise, time-delayed
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Glutamimic acid at room temperature
Without magnetic field
Magnetic field generated by Zhadin effect at
4.99 Hz
Time delayed magnetic Field detection
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Glutaminic acid at -80C
Without magnetic field
Magnetic field due to Zhadin effect at 2.87 Hz
Scan end
Synchronized magnetic Field detection
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Conclusion 1- at ion frequency resonance,
molecules trapped into coherence
domain produce an intrinsic
magnetic field (impulse) 2-if this
intrinsic magnetic field should be of some
interest in the Liboff-Zhadin theory is
still to be investigated