by johnm33 » Wed Feb 22, 2023 10:28 pm
I think we can also speculate that Brown Dwarf stars
In some sense I think of all stars being either in or out of the powerful magnetohydrodynamic charge flux of the galaxy's bloch wall. So like light bulbs they can be off or on. My own peculiar take, though others have suggested it, is that stars are 'born' mostly at the galactic core and are released to slowly move away from the core, and spend most of their time in the arm to which they're 'native. In this way all the stars 'orbit' at a similar speed, but in fact move away according to their charge potential much like ions in the suns heliospheric current sheet. Those stars which spend little time in reciept of energy evolve slowly as a consequence of spending little time close to the galactic equatorial plane. I suspect the sun is native to M54 which would explain, almost perfectly it's orientation to that plane, as a consequence it has encountered a number of stars/brown dwarfs and may have been captured by the charge field of the M.W. it has certainly usurped their [4 as giants] place in the energy stream for now.
I prefer Charles Chandlers model of what takes place in the heart of stars, where iron precipitates out and settles into the depths, then since so many heavy metals are also created they form a layer directly above the iron, this because although the pressure continues to grow the gravitational peak is perhaps close to 1/3 of the way out from the center, by mass. Once the iron core has formed it seems that electrical/radiative forces create heavy metals within the iron and co-create protons/hydrogen ions in the process. These hyrogen ions are trapped in the matrix of the crystaline iron and are held in place by both the P/T's and the powerful charge feild surrounding the iron. Some no doubt escape in the matrix of the heavy metals as they are, over time, squeezed to the surrounding layer.
When two stars meet the most developed will draw in all the charge of both, this will alter the balance of power more in the core of the lesser and excess hydrogen ions will escape leeding to an explosive shattering of the iron core, which may emerge as several pieces some will be lost some may coalesce and others may find an orbital slot to inhabit. The largest pieces may retain a substantial amount of the upper layers of it's native sun and may even form planets. If they do it may be that they retain some of the hydrogen ions within their new iron core, and if they find an orbit then the acceleration into the orbit may be enough to cool down the heavy metals and the iron core after which in a slow process the interaction of it's 'new' sun and the core may continue to produce more hydrogen ions and these may be released at some future time when a new 'star' is captured and orbital slots change. This time instead of an explosive event a whole cascade of hydrogen chemistry begins to occur with any number of hydrogen based solvents being created in situe as supercritical liquids, one of which will be H2O.
[quote]I think we can also speculate that Brown Dwarf stars [/quote]
In some sense I think of all stars being either in or out of the powerful magnetohydrodynamic charge flux of the galaxy's bloch wall. So like light bulbs they can be off or on. My own peculiar take, though others have suggested it, is that stars are 'born' mostly at the galactic core and are released to slowly move away from the core, and spend most of their time in the arm to which they're 'native. In this way all the stars 'orbit' at a similar speed, but in fact move away according to their charge potential much like ions in the suns heliospheric current sheet. Those stars which spend little time in reciept of energy evolve slowly as a consequence of spending little time close to the galactic equatorial plane. I suspect the sun is native to M54 which would explain, almost perfectly it's orientation to that plane, as a consequence it has encountered a number of stars/brown dwarfs and may have been captured by the charge field of the M.W. it has certainly usurped their [4 as giants] place in the energy stream for now.
I prefer Charles Chandlers model of what takes place in the heart of stars, where iron precipitates out and settles into the depths, then since so many heavy metals are also created they form a layer directly above the iron, this because although the pressure continues to grow the gravitational peak is perhaps close to 1/3 of the way out from the center, by mass. Once the iron core has formed it seems that electrical/radiative forces create heavy metals within the iron and co-create protons/hydrogen ions in the process. These hyrogen ions are trapped in the matrix of the crystaline iron and are held in place by both the P/T's and the powerful charge feild surrounding the iron. Some no doubt escape in the matrix of the heavy metals as they are, over time, squeezed to the surrounding layer.
When two stars meet the most developed will draw in all the charge of both, this will alter the balance of power more in the core of the lesser and excess hydrogen ions will escape leeding to an explosive shattering of the iron core, which may emerge as several pieces some will be lost some may coalesce and others may find an orbital slot to inhabit. The largest pieces may retain a substantial amount of the upper layers of it's native sun and may even form planets. If they do it may be that they retain some of the hydrogen ions within their new iron core, and if they find an orbit then the acceleration into the orbit may be enough to cool down the heavy metals and the iron core after which in a slow process the interaction of it's 'new' sun and the core may continue to produce more hydrogen ions and these may be released at some future time when a new 'star' is captured and orbital slots change. This time instead of an explosive event a whole cascade of hydrogen chemistry begins to occur with any number of hydrogen based solvents being created in situe as supercritical liquids, one of which will be H2O.