How the nature of this uncharacterized light source would vary from what was programed into the remote sensor as temperature of the reactor increased.
should read How the nature of this uncharacterized light source would vary from what was programed into the remote sensor is undetermined as the temperature of the reactor is increased up beyond 1400C. On Tue, Oct 21, 2014 at 10:58 AM, Axil Axil <[email protected]> wrote: > There is a boatload of assumptions that the 6 professors would naturally > make about the nature of the E-Cat in a black box type test. One of them is > that the heat produced by the reactor would come in the form of blackbody > radiation. This critical assumption should have been verified by spectual > analysis of the nature of this light to insure that the light was the type > of light that one would naturally expect in a black box test. When one is > testing a technology that is completely undefined, if the light emitted > from the reactor was some undetermined mixture of light produced from both > a coherent and incoherent source, such a situation would add an > undetermined error factor into both the calibration of the remote > temperature sensors against a true blackbody light source and the remote > temperature sensor. > How the nature of this uncharacterized light source would vary from what > was programed into the remote sensor as temperature of the reactor > increased. Since the remote temperature sensor is the primary data > collection instrument used in this test, and it has not been cross checked > through the use of any other temperature sensing mechanism, then all the > data collected by that sensor is placed under suspicion as inaccurate. > > On Tue, Oct 21, 2014 at 2:56 AM, Axil Axil <[email protected]> wrote: > >> Black-body radiation has a characteristic, continuous frequency spectrum >> that depends only on the body's temperature, called the Planck spectrum >> or Planck's law. The spectrum is peaked at a characteristic frequency that >> shifts to higher frequencies with increasing temperature, and at room >> temperature most of the emission is in the infrared region of the >> electromagnetic spectrum. As the temperature increases past about 500 >> degrees Celsius, black bodies start to emit significant amounts of visible >> light. Viewed in the dark, the first faint glow appears as a "ghostly" >> grey. With rising temperature, the glow becomes visible even when there is >> some background surrounding light: first as a dull red, then yellow, and >> eventually a "dazzling bluish-white" as the temperature rises. >> >> This appearance is caused by a distribution of all wavelengths of light >> more or less based on temperature in blackbody radiation. >> >> In laser radiation, only a single frequency appears. Light from a >> infrared laser cannot be seen. >> >> The Rossi reactor may be acting like an infrared laser since few visible >> wavelengths are seen at 1400C, >> > >
