Question CYCLIC UNIVERSE

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marcin

You're a madman I've come to the right place, then
Jul 18, 2024
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Cyclic events can be explained by understanding quantum mechanics and properties of Transient Condensates. To explain contraction and expansion of both matter and energy.
Since there are no space and time to be expanded and contracted, right? Since the radiation energy doesn't need space and time to exist and to propagate. Since there are no such things as a wavelength and oscillation period, right? Since this radiation energy does not depend directly on the wavelength and the frequency, that is the inverse of period. There is also no need for space and time at all to separate all the matter, right? It just exists withouth them, but it's miracuolosly separated and distinguishable.
 
Since there are no space and time to be expanded and contracted, right? Since the radiation energy doesn't need space and time to exist and to propagate. Since there are no such things as a wavelength and oscillation period, right? Since this radiation energy does not depend directly on the wavelength and the frequency, that is the inverse of period. There is also no need for space and time at all to separate all the matter, right? It just exists withouth them, but it's miracuolosly separated and distinguishable.
What are you trying to say?
 
Cyclic events are most important toe explain the workings of an infinite time line in space.

[Submitted on 6 Aug 2024]

Revealing the Berry phase under the tunneling barrier​

Lior Faeyrman, Eduardo B. Molinero, Roni Weiss, Vladimir Narovlansky, Omer Kneller, Talya Arusi-Parpar, Barry D. Bruner, Binghai Yan, Misha Ivanov, Olga Smirnova, Alvaro Jimenez-Galan, Riccardo Piccoli, Rui E.F. Silva, Nirit Dudovich, Ayelet J. Uzan-Narovlansky
In quantum mechanics, a quantum wavepacket may acquire a geometrical phase as it evolves along a cyclic trajectory in parameter space. In condensed matter systems, the Berry phase plays a crucial role in fundamental phenomena such as the Hall effect, orbital magnetism, and polarization. Resolving the quantum nature of these processes commonly requires sensitive quantum techniques, as tunneling, being the dominant mechanism in STM microscopy and tunneling transport devices. In this study, we integrate these two phenomena - geometrical phases and tunneling - and observe a complex-valued Berry phase via strong field light matter interactions in condensed matter systems. By manipulating the tunneling barrier, with attoseconds precision, we measure the imaginary Berry phase accumulated as the electron tunnels during a fraction of the optical cycle. Our work opens new theoretical and experimental directions in geometrical phases physics and their realization in condensed matter systems, expanding solid state strong field light metrology to study topological quantum phenomena.
 
When scientists talk about the early universe, I start questioning the paper.
Assuming there is an early universe without foundational evidence is picking at straws. But! saying that the paper is worth reading.
Hey! I could be wrong with my opinion.

[Submitted on 28 Feb 2025 (v1), last revised 11 Mar 2025 (this version, v2)]

The THESAN-ZOOM project: Burst, quench, repeat -- unveiling the evolution of high-redshift galaxies along the star-forming main sequence​

William McClymont, Sandro Tacchella, Aaron Smith, Rahul Kannan, Ewald Puchwein, Josh Borrow, Enrico Garaldi, Laura Keating, Mark Vogelsberger, Oliver Zier, Xuejian Shen, Filip Popovic, Charlotte Simmonds
Characterizing the evolution of the star-forming main sequence (SFMS) at high redshift is crucial to contextualize the observed extreme properties of galaxies in the early Universe. We present an analysis of the SFMS and its scatter in the THESAN-ZOOM simulations, where we find a redshift evolution of the SFMS normalization scaling as ∝(1+z)2.64±0.03, significantly stronger than is typically inferred from observations. We can reproduce the flatter observed evolution by filtering out weakly star-forming galaxies, implying that current observational fits are biased due to a missing population of lulling galaxies or overestimated star-formation rates. We also explore star-formation variability using the scatter of galaxies around the SFMS (σMS). At the population level, the scatter around the SFMS increases with cosmic time, driven by the increased importance of long-term environmental effects in regulating star formation at later times. To study short-term star-formation variability, or ''burstiness'', we isolate the scatter on timescales shorter than 50 Myr. The short-term scatter is larger at higher redshift, indicating that star formation is indeed more bursty in the early Universe. We identify two starburst modes: (i) externally driven, where rapid large-scale inflows trigger and fuel prolonged, extreme star formation episodes, and (ii) internally driven, where cyclical ejection and re-accretion of the interstellar medium in low-mass galaxies drive bursts, even under relatively steady large-scale inflow. Both modes occur at all redshifts, but the increased burstiness of galaxies at higher redshift is due to the increasing prevalence of the more extreme external mode of star formation.
 
OK, we have many papers that have talked about previous AEONs.


[Submitted on 31 Mar 2025]

The Physics of Conformal Cyclic Cosmology​

Krzysztof A. Meissner, Roger Penrose
According to conformal cyclic cosmology (CCC), the currently conventional description of the entire history of the universe (but without an initial inflationary phase) provides but one cosmic aeon of an unending sequence of such aeons, where the future conformal infinity of each aeon joins essentially smoothly to the conformally stretched big bang of the next, across a spacelike 3-surface, referred to as a crossover 3-surface. Whereas in previous accounts of CCC a detailed description of the physics of crossover had been somewhat problematic, a novel idea is introduced here to show how crossover takes place naturally during a temporal period of the universe that is dominated by gravitational waves referred to here as a gravitational wave epoch (GWE). Accordingly, the geometry at the crossover surface is conformally smooth, except at a discrete set of points, referred to as Hawking points, each representing the final Hawking evaporation of the dominant black hole of a galactic cluster in the earlier aeon. It is shown here (using 2-spinor and twistor techniques) that there is a mass-energy conservation law that holds across the crossover surface, showing that the rise of temperature within such Hawking spots should be effectively determined by the total mass of the pre-crossover galactic cluster involved. This rise of temperature on the CMB map within Hawking spots is found to be in quantitative agreement with the masses of the largest galactic clusters observed in our own aeon what suggests that the physics in the previous aeon was, at least in the gravitational sector, similar to ours. A second observational feature, the actual angular diameter of the Hawking spots seen in our CMB, which is about twice what should have been expected, is associated to the presence of GWE just after the crossover and before the start of the usual cosmological epochs.
 

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