Nanotechnology

Nano means one billionth. So 2 nanometers is equivalent to 0.000000002 meter.

Nanotechnology is the study and design of systems at the nanometer scale where individual molecules and atoms are arranged into precise structures using material science fabrication techniques. Nanotechnology can be used to produce molecular antennas where molecules act as receivers and transmitters of high frequency electromagnetic energy.

Examples of Nanotechnology applications using molecular antennas powered by the sun include:

Spray-On Solar-Power Cells - plastic paint containing quantum dots absorbs the sun's infrared energy and converts it to electricity.

Diads - molecular diodes on solar cells replicate a part of the photosynthesis process by converting light photons to electricity.

Solar (Photovoltaic) Cells - nanocrystalline dye-sensitized solar cells that use an organic dye to absorb incoming light to produce excited electrons.

Just as the sun emits infrared radiation, so does the human body. LifeWave patches are manufactured with natural organic materials that exhibit optical (chiral), liquid crystal, and semiconductor properties. By using a nanotechnology production process called solution-based self-assembly, these optically active and electrically conductive materials when placed in IceWave patches form small nanosized molecular structures that function as molecular antennas.

These passive molecular antennas are activated by the oscillating electromagnetic field of the body to generate electromagnetic signals that are resonant frequencies for certain protein structures contained within your cells' membrane receptors. These frequencies are generated by induction (a well-known physics principle):

?Any object has a certain natural or resonant frequency? when two objects have similar natural frequencies, they can interact without touching, their vibrations can become coupled or entrained.? (Oschman, James L. Energy Medicine: The Scientific Basis. London: Harcourt Publishers, 2000.)

Enzymes and proteins are known semiconductors. They are basically organic electronic devices. The affected protein structures are known to operate by a communication system called signal induction (usually a chemical signal which can also be a frequency signal). The activation of these receptors results in coupling and amplication of the signal in a process known as signal transduction.

By starting and supporting this chain of events, IceWave patches activate metabolic reactions within your body by applying the appropriate frequency code and waveform through their molecular antennas. As soon as the patches interact with your body, a set of biologically active signals are generated within your body. In a sense, IceWave patches are programmed like computer chip software. They use bio-quantum formulas to produce different sized antennas to deliver targeted biological messages to your body.