People, I do not send my idea to scientific magazines, because I don't think they will accept my idea. I do want to post it here, because I believe in the mission of JREF.
But I honestly believe that I have a good alternative to explain the observed expansion of space.
Please give it a change.
The observed velocity-distance-relationship is due to an unobservable gravitational timestretch/distance relationship.
The observed velocity of recession of galaxies, proportional to their distance (Hubble) is an observation of expanding space, because of an invisible timestretch relative to our clocks due to a weaker and weaker gravitational attraction between these receding galaxies, further and further away from each other. The gravitational timedilation is becoming less weaker, when galaxies are further from each other, then when they are close to each other. We can call this ‘gravitational timestretch’ of imaginary clocks in the empty regions between them.
So, the observed velocity-distance relationship is also a field of gravity-distance relationship.
It’s crucial to mention that the empty region of space must be of remote galaxies, because locally, we always measure normal properties of time and normal properties of space. In our own referenceframe, all laws of physics are as usual. (relativity principle). The difference in timeflow is small.
We can say, that there is a stronger field of gravity between two remote galaxies closer to each other then between remote galaxies further away from each other.
Therefore, we know that the empty space between galaxies closer to each other have a slower timeflow then galaxies further away from eachother.
We are part of Earth, a solarsystem, a galaxy with a black hole in the centre of it, the Virgo cluster and the Local Group.
The gravity of these objects are slowing down our clocks, relative to clocks in the empty regions of space without matter. But to us, our time is ticking as usual, wherever we are. And our space doesn’t seem to be distorted.
conclusion
The observed space-distortion is due to the difference between clocks on Earth and the invisible clocks in empty space between remote galaxies because of the difference in gravitational timedistortion. If the timeflow between remote galaxies or stars is faster than our clock, we see a space-expansion, when the timeflow between remote galaxies or stars is slower than our clock, we see a spaceshrink. Locally, we do not observe such differences, because the difference in timeflow is too small and our idea of time in our own referenceframe is always the standard to observe space- and timedistortions elsewhere. We will always observe space- and timedistortions elsewhere.
Summary:
Observed space-expansion is due to a gravitational timestretch relative to our clock and observed space-shrink is due to a gravitational timedilation relative to our clock.
But when the difference in timeflow between clocks on Earth and clocks in the empty regions of space between remote galaxies is almost the same, we do not observe distortions of space.
Testable predictions?
When we leave our solarsystem and our galaxy, the influence of the gravitational timedilation of our galaxy on our clock will decrease. But according to us, our clock is still the standard for observations elsewhere. Our time and our idea of space is the norm for observations of distortions elsewhere, wherever we are. Which means: we observe a spaceshrink of the space between stars in our galaxies closer to the centre of our galaxy then further away from the centre. We observe a decreasing of ‘the expanding universe’ when we leave our galaxy.
When we are further and further away from our Local Group in the voids of space, and we look back, we will see galaxies coming back together. We will see ‘a shrinking universe’.
When we are closer to the black hole in the centre of our galaxy, we will observe ‘an increasing expansion of the universe’ because the difference in timeflow will increase. Our timeflow will always be the standard for observations of space- and timedistortions elsewhere, so the observed expansion rate will be higher when we are closer to the centre of the black hole.
The math
I only like to think about space and time and I was obsessed by the question of observations of time and space. But I invite you to find the mathematical equation, who will explain the relationship I described here in words with the proper well-defined terms.
Maarten Vergucht, Belgium.
Obsessive thinker about our observations of time and space.
But I honestly believe that I have a good alternative to explain the observed expansion of space.
Please give it a change.
The observed velocity-distance-relationship is due to an unobservable gravitational timestretch/distance relationship.
The observed velocity of recession of galaxies, proportional to their distance (Hubble) is an observation of expanding space, because of an invisible timestretch relative to our clocks due to a weaker and weaker gravitational attraction between these receding galaxies, further and further away from each other. The gravitational timedilation is becoming less weaker, when galaxies are further from each other, then when they are close to each other. We can call this ‘gravitational timestretch’ of imaginary clocks in the empty regions between them.
So, the observed velocity-distance relationship is also a field of gravity-distance relationship.
It’s crucial to mention that the empty region of space must be of remote galaxies, because locally, we always measure normal properties of time and normal properties of space. In our own referenceframe, all laws of physics are as usual. (relativity principle). The difference in timeflow is small.
We can say, that there is a stronger field of gravity between two remote galaxies closer to each other then between remote galaxies further away from each other.
Therefore, we know that the empty space between galaxies closer to each other have a slower timeflow then galaxies further away from eachother.
We are part of Earth, a solarsystem, a galaxy with a black hole in the centre of it, the Virgo cluster and the Local Group.
The gravity of these objects are slowing down our clocks, relative to clocks in the empty regions of space without matter. But to us, our time is ticking as usual, wherever we are. And our space doesn’t seem to be distorted.
conclusion
The observed space-distortion is due to the difference between clocks on Earth and the invisible clocks in empty space between remote galaxies because of the difference in gravitational timedistortion. If the timeflow between remote galaxies or stars is faster than our clock, we see a space-expansion, when the timeflow between remote galaxies or stars is slower than our clock, we see a spaceshrink. Locally, we do not observe such differences, because the difference in timeflow is too small and our idea of time in our own referenceframe is always the standard to observe space- and timedistortions elsewhere. We will always observe space- and timedistortions elsewhere.
Summary:
Observed space-expansion is due to a gravitational timestretch relative to our clock and observed space-shrink is due to a gravitational timedilation relative to our clock.
But when the difference in timeflow between clocks on Earth and clocks in the empty regions of space between remote galaxies is almost the same, we do not observe distortions of space.
Testable predictions?
When we leave our solarsystem and our galaxy, the influence of the gravitational timedilation of our galaxy on our clock will decrease. But according to us, our clock is still the standard for observations elsewhere. Our time and our idea of space is the norm for observations of distortions elsewhere, wherever we are. Which means: we observe a spaceshrink of the space between stars in our galaxies closer to the centre of our galaxy then further away from the centre. We observe a decreasing of ‘the expanding universe’ when we leave our galaxy.
When we are further and further away from our Local Group in the voids of space, and we look back, we will see galaxies coming back together. We will see ‘a shrinking universe’.
When we are closer to the black hole in the centre of our galaxy, we will observe ‘an increasing expansion of the universe’ because the difference in timeflow will increase. Our timeflow will always be the standard for observations of space- and timedistortions elsewhere, so the observed expansion rate will be higher when we are closer to the centre of the black hole.
The math
I only like to think about space and time and I was obsessed by the question of observations of time and space. But I invite you to find the mathematical equation, who will explain the relationship I described here in words with the proper well-defined terms.
Maarten Vergucht, Belgium.
Obsessive thinker about our observations of time and space.
via JREF Forum http://forums.randi.org/showthread.php?t=263855&goto=newpost
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