Jump to content

Albert2024

Members
  • Posts

    29
  • Joined

  • Last visited

  • Days Won

    2

Everything posted by Albert2024

  1. The paper just used Meissner effect that implies breaking U(1) symmetry. When one uses this, only SU(3) remain intact. The Meissner effect happens for ordinary materials at 70 K or even higher. The average temperature of CMB is much lower. It is only 2.7 K.
  2. Look at the table in the paper that outlines the temperature scales at which symmetry breaking occurs. As far as I understand from reading the paper, the universe began in the radiation-dominant era, where all particles were massless due to the extremely high temperatures (around 10^16 GeV and 10^29 K). At this stage, all symmetries (SU(3) × SU(2) × U(1)) were unbroken, and the universe was dominated by radiation energy. As the universe expanded and cooled, it reached the electroweak symmetry breaking scale (around 100 GeV, or approximately 10^15 K), where the electroweak symmetry broke, leading to the creation of mass. This marked the beginning of the matter-dominant era, where mass formed and matter became the dominant energy source. As the universe continued cooling, it transitioned into the dark energy-dominant era, where dark energy drives the accelerated expansion of the universe. In the current era, with an energy scale around 10^-3 eV and a temperature of 2.7 K, only SU(3) remains unbroken, while the experimental Meissner effect has broken U(1) at low temperatures. The authors argue that SU(3) is stabilized by the third law of thermodynamics, preventing further symmetry breaking. The third law of thermodynamics states that it is impossible to reach zero Kelvin by any finite number of physical cooling steps, implying that there is always a remnant volume that never vanishes, unlike what would happen according to ideal gas theory at absolute zero. This remnant volume appear to be the proton volume, and that may explain why proton has never been observed to decay. The reference to absolute zero is significant, as it emphasizes that at these extremely low temperatures, SU(3) remains unbroken, stabilizing the vacuum energy and providing a solution to the cosmological constant problem. The cosmological constant discrepancy, as noted by Weinberg, arises because quantum field theory (QFT) predicts a vacuum energy proportional to the fourth power of the Planck energy, resulting in an enormous value of 10^76 GeV, while the observed vacuum energy density is about 10^-47 GeV—a difference of 10^123 orders of magnitude. The mathematical approach of the paper is key to resolving this discrepancy. The author redefined the Lagrangian of QCD by dividing it by the 10^123 atoms of SU(3) that are realized to exist in the universe. This redefinition stems from the insight that there are approximately 10^123 atoms of vacuum energy based on the volume of the universe divided by the proton volume. When computing the vacuum energy density from this modified Lagrangian, the result matches the observed value precisely, solving the cosmological constant problem. I recommend reviewing the table in the paper for a clearer understanding of these phases and how they relate energy and temperature scales to symmetry-breaking events in the universe If you read the paper, it is solidly based on the experimental Meissner effect, which shows that U(1) symmetry is experimentally broken at low temperatures, leaving SU(3) as the remaining symmetry close to absolute zero. The paper’s entire premise relies on this experimentally verified Meissner effect. Additionally, I have read another paper by the same author, where they demonstrated that dark energy represents a superconducting state of matter. This paper was published in JCAP, a highly prestigious journal. https://iopscience.iop.org/article/10.1088/1475-7516/2024/08/012
  3. Section II and Section III in the paper show all the math details Section II and Section III in the paper show all the math details
  4. A recent idea offers a new perspective on one of the biggest mysteries in physics: the nature of dark energy. This proposal suggests that dark energy—the mysterious force driving the universe's expansion—could resemble a superconducting state of matter, composed of roughly 10^123 small "units" called SU(3) atoms, which stabilize the vacuum energy. The approach relies on well-established physical principles, such as the Meissner effect (seen in superconductors) and the third law of thermodynamics. According to this idea, at extremely low temperatures, the Meissner effect breaks U(1) symmetry while leaving SU(3) symmetry intact. To calculate the number of these SU(3) atoms in the universe, one could divide the volume of the observable universe by the volume of a proton, arriving at approximately 10^123 atoms. This number aligns precisely with quantum field theory (QFT) predictions for vacuum energy density, potentially resolving the long-standing discrepancy between theoretical calculations and observed values. What makes this idea compelling is its simplicity—it requires no exotic extensions or fine-tuning, sticking to established physics. It also proposes that the third law of thermodynamics keeps these SU(3) units stable at very low temperatures, ensuring that the vacuum energy remains consistent. This experimentally grounded and straightforward approach makes it worth considering: could this be the answer we've been searching for, or are there significant challenges that still need addressing? For those interested, you can read the paper here: https://inspirehep.net/literature/2778290.
×
×
  • Create New...

Important Information

We have placed cookies on your device to help make this website better. You can adjust your cookie settings, otherwise we'll assume you're okay to continue.