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How Far Can Ki-energy Reach?--A Hypothetical Mechanism for the Generation and Transmission of Ki-energy.

Ohnishi ST, Ohnishi T - Evid Based Complement Alternat Med (2007)

Bottom Line: 'Ki-energy', which can be enhanced through the practice of Nishino Breathing Method, was reported to have beneficial health effects.Using a linear variable interference filter, we found that Ki-energy may have a peak around 1000 nm.All of these results suggest that (i) Ki-energy can be guided as a directional 'beam' with a small divergence angle; (ii) the beam can be reflected by a mirror and (iii) Ki-energy may have a specific wavelength.

View Article: PubMed Central - PubMed

Affiliation: Philadelphia Biomedical Research Institute, Suite 250, 100 Ross Road, King of Prussia, PA 19406-0227, USA. stohnishi@aol.com.

ABSTRACT
'Ki-energy', which can be enhanced through the practice of Nishino Breathing Method, was reported to have beneficial health effects. Although Ki-energy can play an important role in complementary and alternative medicine (CAM), as yet it is unknown how Ki-energy is generated, transmitted through air and received by another individual. We previously proposed that Ki-energy may include near-infrared radiation, and that the wavelength was between 800 and 2700 nm. Since Ki-energy is reflected by a mirror, we believe that the 'Ki-beam' has a small divergence angle. It can also be guided in a desired direction. The acrylic mirror reflection experiment suggests that the wavelength may be between 800 and 1600 nm. Using a linear variable interference filter, we found that Ki-energy may have a peak around 1000 nm. We have also observed that 'sensitive' practitioners responded to Ki sent from a distance of 100 m. All of these results suggest that (i) Ki-energy can be guided as a directional 'beam' with a small divergence angle; (ii) the beam can be reflected by a mirror and (iii) Ki-energy may have a specific wavelength. Since these properties are characteristics of the laser radiation, we propose a quantum physics-based mechanism of 'Light Amplification by the Stimulated Emission of Radiation' (i.e. LASER) for the generation of Ki-energy. Volunteers responded to Ki even with a blindfold. This suggests that the skin must be detecting Ki-energy. We propose that the detector at the skin level may also have the stimulated emission mechanism, which amplifies the weak incident infrared radiation.

No MeSH data available.


Related in: MedlinePlus

Transmittance spectra of glass (6.5 mm thick; red line) and acrylic (9 mm thick; blue line) plates in the near-infrared region.
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Figure 4: Transmittance spectra of glass (6.5 mm thick; red line) and acrylic (9 mm thick; blue line) plates in the near-infrared region.

Mentions: Since Ki-energy passes through the mirror materials (glass or acrylic) when it is reflected, it is important to know how much is absorbed by these materials. For that purpose, we obtained transparent glass (6.5 mm thick) and acrylic (9 mm thick) plates. The thickness of these plates was very close to the actual path length of the Ki-beam in the mirrors. The transmittance spectra of these plates in the near-infrared region (Fig. 4) were measured with a Bruker infrared spectrophotometer (ISP-66v/S by Dr K.S. Reddy at the Dept. of Biochemistry/Biophysics, University of Pennsylvania School of Medicine).Figure 4.


How Far Can Ki-energy Reach?--A Hypothetical Mechanism for the Generation and Transmission of Ki-energy.

Ohnishi ST, Ohnishi T - Evid Based Complement Alternat Med (2007)

Transmittance spectra of glass (6.5 mm thick; red line) and acrylic (9 mm thick; blue line) plates in the near-infrared region.
© Copyright Policy - creative-commons
Related In: Results  -  Collection

License
Show All Figures
getmorefigures.php?uid=PMC2722212&req=5

Figure 4: Transmittance spectra of glass (6.5 mm thick; red line) and acrylic (9 mm thick; blue line) plates in the near-infrared region.
Mentions: Since Ki-energy passes through the mirror materials (glass or acrylic) when it is reflected, it is important to know how much is absorbed by these materials. For that purpose, we obtained transparent glass (6.5 mm thick) and acrylic (9 mm thick) plates. The thickness of these plates was very close to the actual path length of the Ki-beam in the mirrors. The transmittance spectra of these plates in the near-infrared region (Fig. 4) were measured with a Bruker infrared spectrophotometer (ISP-66v/S by Dr K.S. Reddy at the Dept. of Biochemistry/Biophysics, University of Pennsylvania School of Medicine).Figure 4.

Bottom Line: 'Ki-energy', which can be enhanced through the practice of Nishino Breathing Method, was reported to have beneficial health effects.Using a linear variable interference filter, we found that Ki-energy may have a peak around 1000 nm.All of these results suggest that (i) Ki-energy can be guided as a directional 'beam' with a small divergence angle; (ii) the beam can be reflected by a mirror and (iii) Ki-energy may have a specific wavelength.

View Article: PubMed Central - PubMed

Affiliation: Philadelphia Biomedical Research Institute, Suite 250, 100 Ross Road, King of Prussia, PA 19406-0227, USA. stohnishi@aol.com.

ABSTRACT
'Ki-energy', which can be enhanced through the practice of Nishino Breathing Method, was reported to have beneficial health effects. Although Ki-energy can play an important role in complementary and alternative medicine (CAM), as yet it is unknown how Ki-energy is generated, transmitted through air and received by another individual. We previously proposed that Ki-energy may include near-infrared radiation, and that the wavelength was between 800 and 2700 nm. Since Ki-energy is reflected by a mirror, we believe that the 'Ki-beam' has a small divergence angle. It can also be guided in a desired direction. The acrylic mirror reflection experiment suggests that the wavelength may be between 800 and 1600 nm. Using a linear variable interference filter, we found that Ki-energy may have a peak around 1000 nm. We have also observed that 'sensitive' practitioners responded to Ki sent from a distance of 100 m. All of these results suggest that (i) Ki-energy can be guided as a directional 'beam' with a small divergence angle; (ii) the beam can be reflected by a mirror and (iii) Ki-energy may have a specific wavelength. Since these properties are characteristics of the laser radiation, we propose a quantum physics-based mechanism of 'Light Amplification by the Stimulated Emission of Radiation' (i.e. LASER) for the generation of Ki-energy. Volunteers responded to Ki even with a blindfold. This suggests that the skin must be detecting Ki-energy. We propose that the detector at the skin level may also have the stimulated emission mechanism, which amplifies the weak incident infrared radiation.

No MeSH data available.


Related in: MedlinePlus