THE PHOTON CLOCK
by Eugene A. Ellis (April 2022)
Nick Percival, in his “Time in Physics” conclusion video indicates that time focuses on process, or more specifically...process length. This “surprise ending” in his CNPS 3/26/22 talk has merit when using ionization as the process and viewing the spectrum as the keeper of time.
The process begins with elemental atoms exhibiting photon energy (in eV units). All celestial bodies are composed of a small number of (abundance) elements of differing amounts. Earth has 8 elements representing 98.8% of its mass, the moon has 6 elements representing 99% of mass, and the sun has 5 elements representing 99.57% of mass. All celestial bodies decay (age) at a specific unchanging rate that is determined by their abundance amounts (percentages).
The ageing rate at each place also generates a time of occurrence of each element’s ionization potential (IP) listed in NBS-34 with the IP Limit as the ageing starting point. When ageing, all the abundance elements would decay together around the same time and at the same level, thereby causing an ambient energy level for each place.
Einstein indicated that...time passes differently in different places depending on how those places are moving with respect to one another. The photon ageing rate of earth (1 eV / 1.6 my), moon (1 eV / 2.03 my), and sun (1 eV / 8.29 my) affirms that time passes differently in different places. However, how the places move with respect to one another involves changes in rate of growth, which was an unknown unknown in Einstein’s time and it wasn’t until 2011 that Physics World published... Radioactive decay accounts for half of Earth’s heat.
An analysis of the 1970 NBS-34 (Table 1) reveals that the elements grow at certain times and heat at other times. Support for this energy conversion duality is sourced in the amount of heat contained below earth’s crust and/or the amount of heat necessary to melt the 32.1% iron that settled mostly in the core. Further analysis of the first 30 elements (Slide 5) reveals the total heating time of the elements (from Z = 3 to Z = 30) progressively increases and always exceeds the total growing time. Yet, to its detriment, the physics of particles and motion disregards this significant heating aspect (entropy@ Slide 19) and its relationship with growth.
Changing growth rates equate with when and how fast or slow mass accumulates at a place while the unchanging ageing rate is immersed in the spectrum. A spectrum that functions as photon clock that ticks the ageing rate of each place.
by Eugene A. Ellis (April 2022)
Nick Percival, in his “Time in Physics” conclusion video indicates that time focuses on process, or more specifically...process length. This “surprise ending” in his CNPS 3/26/22 talk has merit when using ionization as the process and viewing the spectrum as the keeper of time.
The process begins with elemental atoms exhibiting photon energy (in eV units). All celestial bodies are composed of a small number of (abundance) elements of differing amounts. Earth has 8 elements representing 98.8% of its mass, the moon has 6 elements representing 99% of mass, and the sun has 5 elements representing 99.57% of mass. All celestial bodies decay (age) at a specific unchanging rate that is determined by their abundance amounts (percentages).
The ageing rate at each place also generates a time of occurrence of each element’s ionization potential (IP) listed in NBS-34 with the IP Limit as the ageing starting point. When ageing, all the abundance elements would decay together around the same time and at the same level, thereby causing an ambient energy level for each place.
Einstein indicated that...time passes differently in different places depending on how those places are moving with respect to one another. The photon ageing rate of earth (1 eV / 1.6 my), moon (1 eV / 2.03 my), and sun (1 eV / 8.29 my) affirms that time passes differently in different places. However, how the places move with respect to one another involves changes in rate of growth, which was an unknown unknown in Einstein’s time and it wasn’t until 2011 that Physics World published... Radioactive decay accounts for half of Earth’s heat.
An analysis of the 1970 NBS-34 (Table 1) reveals that the elements grow at certain times and heat at other times. Support for this energy conversion duality is sourced in the amount of heat contained below earth’s crust and/or the amount of heat necessary to melt the 32.1% iron that settled mostly in the core. Further analysis of the first 30 elements (Slide 5) reveals the total heating time of the elements (from Z = 3 to Z = 30) progressively increases and always exceeds the total growing time. Yet, to its detriment, the physics of particles and motion disregards this significant heating aspect (entropy@ Slide 19) and its relationship with growth.
Changing growth rates equate with when and how fast or slow mass accumulates at a place while the unchanging ageing rate is immersed in the spectrum. A spectrum that functions as photon clock that ticks the ageing rate of each place.