Page 23 The Reactor & Other Images

Page Two - VIDEO Understanding the Data Page Three - VIDEO Fusion Exp 1R Page Twelve - VIDEO of EXP-BN-4 Page Thirteen - Wavelengths & Fusion Exp XX Page Fourteen - How Spectral Lines are Produced & Exp 1C Page Fifteen - Fusion VIDEO Exp 2C Page Sixteen - Fusion VIDEO Exp 3C Page Seventeen - Fusion VIDEO Exp 1R Page Eighteen - Fusion VIDEO Exp 2R Page Nineteen - Fusion VIDEO Exp RW1 Page Twenty - Fusion VIDEO Exp RW2 Welcome To Fusionpeery Homepage Page 27 EXP-46, P1, VTPR & BN 1&2 Page Six - VIDEO of Fusion's Dilemma in Today's World Page 23 The Reactor & Other Images Page 25 "N" Fusion Series Continued Page 29 EXP-BN Fusions Continued Page 21 Book Site Info Page 24 "N" Series Fusions Page 26 "A" Fusion Series Low H Page 28 EXP-BN High H Concentration Fusions Page 31 Fusion Exp Composite Images Page 32 Fusion Exp Composite Images Page Ten - Who Gains? Page Eleven - Who Looses? Photo 2 Photo 4

Images in Greater Resolution

A Prototype Common Hydrogen Fusion Reactor is now being designed. The main pressure containment vessal is a small cylinder with hemispherical ends standing a total of 41 cm in height and having a diameter of 18 cm. The internal reaction chamber is made from a ceramic material which is all at the ambient internal pressure of the containment vessal. No images of the reactor are being released at this time. 4 February 2010. NRP. 

How the spectral video photography is implemented to capture the line spectrums during a dynamic Hydrogen Fusion Reaction in which Helium is formed.

Here is the comparative line spectra of Hydrogen, Helium, and Lithium. At the bottom is the full rainbow visual spectrum as can be seen with the human eye.

Sample Photo 3

Here is shown in diagramatic form how each line of Hydrogen's spectrum is generated by means of electrons moving between excited states (higher orbits) and then giving up there energy as radiation at an exact frequency and wavelength when they return to a lower energy orbit, which is the cause of their individual spectral lines. The intensity of any spectral line is solely dependent of how frequently an electron is repeatedly excited to the same higher energy orbit and falls back to some lower orbit.

Above is displayed the individual spectral lines that result from the excitation of pure Helium gas contained within a standard Helium lamp. Below that spectrum is the spectum captured from the hot gas that has been produced by the fusion of Hydrogen to form Helium and heavier nuclei. This reaction is so hot as to vaporize some of the metal parts of the SDME Reactor, this hot vaporized metal produces it own unique spectrum which is superimposed onto the fusion spectrum. Note the spectral line directly below the helium lamp line at 667.815 nm is actualy a spectral line of lithium at 670.776 nm and Li at 670.791 nm the photographic grating images are only accurate within about 3 nanometers. The spectral line directly below the He lamp line at 587.562 is a spectral line of Sodium at 588.995 nm, Both the Lithium and Sodium are heavier nuclei generated during the common Hydrogen fusion process

See: the Acurate Spectrometer Spectral Data on the last pages of this site.

The spectral lines captured here are within themselves an absolute guarantee that Helium was the chemical element that produced this spectrum.