Difference between revisions of "Time"
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==Context== | ==Context== | ||
Time is, above all, a measurement of duration between [[Event]]s. | Time is, above all, a measurement of duration between [[Event]]s. | ||
− | * According to St. Thomas Aquinas, concerning temporal things, only present things exist. | + | * According to St. Thomas Aquinas, concerning temporal things, only present things exist.<ref>Andrew Brenner, ''Aquinas on Eternity, Tense, and Temporal Becoming'' https://cah.ucf.edu/fpr/article/aquinas-on-eternity-tense-and-temporal-becoming/</ref> |
==Time Travel== | ==Time Travel== |
Revision as of 14:47, 8 April 2024
Full Title or Meme
Is Time a fundamental part of reality? Or just a result of the evolution of reality? Or just a figment of our imagination?
Context
Time is, above all, a measurement of duration between Events.
- According to St. Thomas Aquinas, concerning temporal things, only present things exist.[1]
Time Travel
- Kurt Gödel, a brilliant mathematician, delved into the fascinating realm of time travel. His mathematical insights led to the conclusion that, **theoretically**, time travel is **physically possible**¹. Gödel's work is a testament to the profound interplay between mathematics and the fabric of reality.
In Gödel's universe of mathematical wonder, he demonstrated that given certain conditions, we could traverse time. Imagine stepping into a time machine, not to visit the past or future, but to explore all the myriad paths that existence could take. Gödel's theorem suggests that, with enough time and the right circumstances, we might indeed experience **all possible futures**.
It's a mind-bending concept—one that invites us to ponder the intricacies of causality, destiny, and the very nature of our reality. Gödel's legacy continues to inspire both mathematicians and dreamers alike, as we grapple with the tantalizing possibility of unlocking the secrets of time itself.
So, next time you peel a banana, consider that its length might just be a tiny fraction of the vast tapestry of time and possibility that Gödel's mathematics weaves.
Source: Conversation with Bing, 4/8/2024
(1) The mathematician who worked out how to time travel. https://www.newscientist.com/article/2425623-the-mathematician-who-worked-out-how-to-time-travel/. (2) Wiles's proof of Fermat's Last Theorem - Wikipedia. https://en.wikipedia.org/wiki/Wiles%27s_proof_of_Fermat%27s_Last_Theorem. (3) David Hilbert: Mathematical Problems - MacTutor History of Mathematics .... https://mathshistory.st-andrews.ac.uk/Extras/Hilbert_Problems_speech/.
Recurrence
In the context of dynamical systems, the Poincaré recurrence theorem states that certain systems will, after a sufficiently long but finite time, return to a state arbitrarily close to their initial state. (from Wikipedia)
The Poincaré recurrence time is the length of time elapsed until the recurrence. This time may vary greatly depending on the exact initial state and required degree of closeness. The result applies to isolated mechanical systems subject to some constraints, e.g., all particles must be bound to a finite volume. The theorem is commonly discussed in the context of ergodic theory, dynamical systems and statistical mechanics. Systems to which the Poincaré recurrence theorem applies are called conservative systems.
References
- ↑ Andrew Brenner, Aquinas on Eternity, Tense, and Temporal Becoming https://cah.ucf.edu/fpr/article/aquinas-on-eternity-tense-and-temporal-becoming/