Stories with Tag high energy physics

• Symmetry between up and down quarks is more broken than expected

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  Posted: 2025-03-29 10:12:03

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  New research from the LHCb experiment at CERN reveals a greater than anticipated difference in how often the charm meson decays into a kaon and either a pion or a muon pair, depending on whether an up or down quark is involved. This asymmetry, which signifies a violation of charge-parity (CP) symmetry, is four times larger than the Standard Model of particle physics predicts. While not yet statistically definitive enough to claim a discovery, this substantial deviation hints at potential new physics beyond the Standard Model, possibly involving unknown particles or forces influencing these decays. Further data analysis is crucial to confirm these findings and explore the implications for our understanding of fundamental interactions.

  A recent study published in Nature challenges a fundamental assumption in particle physics regarding the symmetry between up and down quarks. The Standard Model of particle physics, the prevailing theory describing fundamental forces and particles, posits a near-perfect symmetry between the up and down quarks, the two lightest quarks that constitute protons and neutrons, the building blocks of atomic nuclei. This symmetry, known as isospin symmetry, suggests that the strong force, which governs quark interactions, treats up and down quarks identically, aside from their differing electric charges and slightly different masses. The mass difference, traditionally considered a minor perturbation, is attributed to the electromagnetic interaction and the Higgs field.

  This new research, utilizing lattice quantum chromodynamics (LQCD) calculations performed on supercomputers, delves deeper into the origins of this mass difference. LQCD is a non-perturbative approach to quantum chromodynamics (QCD), the theory of the strong interaction, allowing scientists to simulate quark interactions on a discretized spacetime lattice. These highly computationally intensive simulations provide insights into the complexities of QCD that are otherwise analytically intractable. The study's findings reveal that the mass difference between the up and down quarks is not solely a consequence of electromagnetic and Higgs interactions, as previously thought. Instead, a substantial portion, approximately 30%, stems directly from the strong force itself.

  This unexpected contribution of the strong force to the quark mass difference indicates a more significant breaking of isospin symmetry than predicted by the Standard Model. The research suggests that the strong force interacts differently with up and down quarks, leading to a larger mass disparity than anticipated. This discovery has profound implications for our understanding of the fundamental workings of the universe. It subtly shifts our picture of how the strong force shapes the properties of matter, highlighting a previously underappreciated asymmetry at the heart of nuclear physics. The findings may necessitate refinements to the Standard Model or even pave the way for new physics beyond the current theoretical framework.

  Furthermore, the research underscores the crucial role of advanced computational techniques, such as LQCD, in probing the intricacies of fundamental interactions. These sophisticated simulations provide a powerful tool for exploring non-perturbative regimes of QCD, offering insights into the dynamics of quarks and gluons that are inaccessible through traditional analytical methods. The ability to simulate these complex interactions with increasing precision allows physicists to scrutinize the Standard Model's predictions and potentially uncover discrepancies that point towards new physics. This discovery, with its implications for isospin symmetry breaking, emphasizes the continued importance of investing in and developing advanced computational resources for fundamental research.

  • particle physics
  • quantum chromodynamics
  • QCD
  • standard model
  • quarks
  • up quark
  • down quark
  • isospin symmetry
  • symmetry breaking
  • nuclear physics
  • subatomic particles
  • physics
  • theoretical physics
  • high energy physics

  Summary of Comments ( 3 )
  https://news.ycombinator.com/item?id=43514246

  Verbose tl;dr

  HN commenters discuss potential implications of the discovery that the up/down quark mass difference is larger than previously thought. Some express excitement about the potential to refine the Standard Model and gain a deeper understanding of fundamental physics. Others are skeptical, pointing out the preliminary nature of the findings and questioning the significance of a small shift in already-known asymmetry. Several commenters delve into the technical details of lattice QCD calculations and the challenges involved in precisely determining quark masses. There's also discussion of the relationship between quark masses and the strong CP problem, with some suggesting this discovery might offer new avenues for exploration in that area.

  The Hacker News post titled "Symmetry between up and down quarks is more broken than expected," linking to a Phys.org article about the same topic, has generated a modest number of comments, mostly focusing on clarifying aspects of the scientific finding and its implications.

  One commenter points out the importance of distinguishing between the bare quark masses and the constituent quark masses. They explain that the bare masses, which are the focus of the research, are significantly smaller than the constituent masses typically quoted in educational materials. The commenter emphasizes that the constituent mass includes the effects of gluon fields and other QCD interactions, leading to the much larger values usually associated with protons and neutrons. This clarification helps contextualize the small difference in up and down quark masses discussed in the article.

  Another comment delves into the nature of the strong force and its contribution to the mass of hadrons. It explains that the Higgs mechanism only accounts for a small fraction of the mass of hadrons like protons and neutrons, with the majority arising from the strong force interactions within these particles. This reinforces the idea that the slight difference in bare quark masses has a relatively small impact on the overall mass difference between protons and neutrons.

  A further comment thread delves into the concept of isospin symmetry, which is an approximate symmetry assuming the up and down quarks have the same mass. The discussion clarifies that while isospin symmetry is broken, it's still a useful concept in nuclear physics. The broken symmetry leads to observable differences in the properties of related particles, like the neutron and proton.

  Finally, a commenter raises the intriguing question of why the universe exhibits this asymmetry between up and down quarks. While acknowledging that the "why" question is often difficult in physics, they speculate about potential connections to deeper, yet-unknown principles. This comment highlights the broader implications of the research and the ongoing quest to understand the fundamental workings of the universe.

  In summary, the comments section offers valuable insights into the nuances of quark masses, the strong force, and the concept of isospin symmetry, all within the context of the reported research. While not extensive, the discussion provides helpful clarifications and raises thought-provoking questions about the fundamental nature of particle physics.

• Gravitational Effects of Small Primordial Black Hole Passing Through Human Body

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  Posted: 2025-02-19 14:21:03

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  The paper explores the theoretical biological effects of a primordial black hole (PBH) with a tiny mass (around 10^15 grams) passing through a human body. While such an event is improbable, the authors calculate the gravitational forces exerted by the PBH as it traverses different tissues. They find that these forces, though exceeding Earth's gravity by many orders of magnitude for a brief period, are unlikely to cause significant macroscopic damage due to the extremely short interaction time. However, the study suggests potential disruptions at the cellular level, specifically stretching of DNA molecules, which might lead to mutations or other biological consequences. The overall conclusion is that while mechanically disruptive effects are likely minimal, biological impacts from the induced strains warrant further investigation.

  The preprint titled "Gravitational Effects of a Small Primordial Black Hole Passing Through a Human Body" explores the hypothetical scenario of a primordial black hole (PBH), specifically one with a minuscule mass comparable to a small asteroid (around 10^17 kg), traversing a human body. The authors meticulously analyze the potential biological consequences of such an encounter, focusing predominantly on the gravitational influence of this relatively low-mass black hole.

  Contrary to popular depictions of black holes violently consuming all matter in their vicinity, the study emphasizes that the primary interaction with the human body would not be accretion, or the sucking in of matter. Instead, the dominant effect would stem from the tidal forces exerted by the PBH's gravitational field. These tidal forces, arising from the difference in gravitational pull across the dimensions of the human body, would be the primary mechanism of interaction.

  The paper details a comprehensive calculation of these tidal forces, considering the varying densities and distributions of tissues within the human body. It meticulously considers the relative motion between the PBH and the body, assuming a range of plausible velocities for such an object. Furthermore, the analysis investigates the temporal evolution of these forces as the PBH approaches, passes through, and recedes from the body.

  The authors quantify the magnitude of these tidal forces and compare them to the known mechanical strengths and tolerances of various biological tissues. They discuss the potential for cellular deformation, tissue disruption, and even potential nerve stimulation that could arise from these forces. However, the analysis concludes that, for a PBH of the specified mass and at realistic encounter velocities, the induced tidal forces are likely to be significantly smaller than the forces experienced by the human body during routine activities or even minor impacts. Consequently, the paper suggests that, while detectable in principle, the biological effects of such a transit would likely be negligible and potentially even imperceptible.

  The authors underscore the importance of distinguishing these subtle gravitational effects from the more dramatic consequences associated with larger black holes, where accretion and energy release would be the dominant processes. This nuanced perspective provides a valuable contribution to the understanding of the potential interaction between hypothetical primordial black holes and biological systems, highlighting that not all black hole encounters would necessarily be catastrophic.

  • astrophysics
  • Black Holes
  • primordial black holes
  • gravitational effects
  • human body
  • theoretical physics
  • high energy physics
  • particle physics
  • cosmology

  Summary of Comments ( 59 )
  https://news.ycombinator.com/item?id=43102425

  Verbose tl;dr

  Several Hacker News commenters expressed skepticism about the practicality of detecting the effects described in the paper, especially given the rarity of primordial black holes and the subtle nature of the gravitational influence. Some questioned the assumptions made in the calculations, like the density and velocity of the black holes. Others pointed out that other everyday gravitational forces, like those from nearby objects or even the moon, would likely dwarf the effect of a tiny black hole passing through the body. A few commenters engaged in humorous speculation about potential (and unlikely) biological impacts, while others debated the overall significance of the research. Several users also discussed the plausibility of primordial black holes as dark matter candidates.

  The Hacker News post titled "Gravitational Effects of Small Primordial Black Hole Passing Through Human Body" (https://news.ycombinator.com/item?id=43102425) has a modest number of comments, sparking a discussion around the plausibility and effects of such an event.

  Several commenters focus on the extremely low probability of this event actually occurring. One commenter points out the vastness of space and the tiny size of a human, making a collision incredibly unlikely. Another echoes this sentiment, emphasizing the rarity of primordial black holes themselves, combined with the low chances of intersection with a human.

  The discussion then delves into the potential consequences if such an improbable event were to occur. One commenter, referencing the paper's calculations, highlights that a small primordial black hole (PBH) passing through the body would likely cause negligible damage, contrary to what might be assumed. They explain that the gravitational force exerted would be incredibly localized and brief, leading to a minor displacement of tissues rather than any catastrophic damage. This comment sparks a small thread discussing the inverse square law and how the rapid transit of the PBH minimizes its overall effect.

  Another commenter questions the assumption of a straight trajectory through the body. They propose that the PBH might interact with the Earth's gravitational field, potentially leading to a more complex path, like an orbit. This raises further questions about the duration and overall effect of the PBH's interaction with a human in such a scenario, which goes unanswered in the thread.

  One commenter injects a touch of humor by wondering if such a transit would be detectable as a sudden, unexplained weight loss.

  Finally, a commenter circles back to the probability aspect, highlighting the greater risks posed by everyday occurrences compared to the astronomically low chances of a PBH encounter. They mention that worrying about such an event is akin to worrying about being struck by lightning while simultaneously winning the lottery – a colorful analogy emphasizing the extreme improbability.

  In essence, the comments section explores the implications of the paper's findings with a mix of scientific curiosity and healthy skepticism, acknowledging the extremely low probability of the event while exploring the theoretical consequences. The discussion remains grounded in the paper's focus on small PBHs and their relatively minor impact on the human body, should such an improbable encounter occur.

• A bestiary of exotic hadrons

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  Posted: 2024-12-20 15:29:59

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  The article "A bestiary of exotic hadrons" explores the burgeoning field of exotic hadron discoveries. Beyond the conventional meson and baryon structures, physicists are increasingly finding particles with more complex quark configurations, such as tetraquarks and pentaquarks. These discoveries, facilitated by experiments like LHCb, are challenging existing quark models and prompting the development of new theoretical frameworks to explain these exotic particles' structures, properties, and their roles within the broader landscape of quantum chromodynamics. The article highlights specific examples of newly observed exotic hadrons and discusses the ongoing debates surrounding their interpretations, emphasizing the vibrant and evolving nature of hadron spectroscopy.

  The article "A Bestiary of Exotic Hadrons" from CERN Courier explores the burgeoning field of hadron spectroscopy, detailing the exciting discoveries and ongoing investigations into particles beyond the conventional quark model. For decades, our understanding of hadrons was limited to mesons, composed of a quark and an antiquark, and baryons, made up of three quarks. However, the advent of increasingly sophisticated experimental facilities, such as the LHCb at CERN and Belle II at KEK, has unveiled a plethora of new particles that defy this simple categorization. These "exotic hadrons" present compelling evidence for more complex internal structures, challenging our established theories and opening new frontiers in quantum chromodynamics (QCD).

  The article meticulously outlines several classes of these exotic hadrons. Tetraquarks, comprised of two quarks and two antiquarks, are discussed in detail, with specific examples like the X(3872), discovered in 2003, highlighted for its unusual properties and the ongoing debate surrounding its true nature. The article explains how the X(3872)'s mass, close to the combined mass of a D and a D* meson, suggests it could be a loosely bound "molecule" of these two particles, a configuration drastically different from a tightly bound tetraquark. Similarly, the Z(4430), confirmed as a tetraquark in 2014, is presented as another pivotal discovery solidifying the existence of this exotic configuration.

  Pentaquarks, composed of four quarks and an antiquark, are another focus of the article. Discovered by LHCb in 2015, these particles, such as the P_c(4380) and P_c(4450), represent another significant leap in our understanding of hadronic matter. The article elucidates how these pentaquarks could be tightly bound five-quark states or, alternatively, loosely bound "molecular" states of a baryon and a meson. This duality in possible interpretations underscores the complexity of these systems and the need for further experimental and theoretical investigation.

  The article emphasizes the crucial role of high-energy experiments in unraveling the mysteries of these exotic hadrons. The immense datasets generated by facilities like LHCb and Belle II provide the statistical power necessary to observe these rare particles and study their properties with precision. This, combined with advances in theoretical modeling and lattice QCD calculations, allows physicists to probe the intricate dynamics of the strong force and refine their understanding of quark confinement, the phenomenon that binds quarks within hadrons.

  The article concludes by highlighting the dynamic nature of this research area, with ongoing experiments poised to uncover even more exotic hadrons and provide further insights into their internal structure and formation mechanisms. The exploration of these exotic particles promises not only to deepen our comprehension of the strong force but also to potentially reveal unforeseen connections to other fundamental aspects of particle physics, potentially even shedding light on the very nature of matter itself.

  • particle physics
  • hadrons
  • exotic hadrons
  • quantum chromodynamics
  • QCD
  • quark model
  • tetraquarks
  • pentaquarks
  • subatomic particles
  • CERN
  • high energy physics
  • nuclear physics
  • physics
  • Science
  • strong interaction
  • standard model
  • quantum mechanics
  • theoretical physics
  • experimental physics
  • high-energy physics

  Summary of Comments ( 61 )
  https://news.ycombinator.com/item?id=42471927

  Verbose tl;dr

  HN commenters generally express fascination with the complexity and strangeness of exotic hadrons. Some discuss the challenges in detecting and classifying these particles, highlighting the statistical nature of the process and the difficulty in distinguishing true signals from background noise. A few commenters dive deeper into the theoretical aspects, mentioning QCD, quark confinement, and the potential for future discoveries. Others draw parallels to other scientific fields like biology, marveling at the "zoo" of particles and the constant evolution of our understanding. Several express appreciation for the clear and accessible writing of the CERN Courier article, making the complex topic understandable to a wider audience. One commenter questions the practical applications of this research, prompting a discussion about the fundamental nature of scientific inquiry and its unpredictable long-term benefits.

  The Hacker News post titled "A bestiary of exotic hadrons," linking to a CERN Courier article about the same topic, has generated several comments discussing various aspects of particle physics, the nature of scientific discovery, and the challenges of understanding fundamental particles.

  One commenter highlights the rapid pace of discovery in this field, noting how the once-exotic tetraquarks and pentaquarks are now becoming commonplace, leading to a need for more nuanced classification schemes beyond simply counting quarks. They express excitement about what future discoveries might hold and how our understanding of the strong force might evolve.

  Another commenter delves into the complexities of quantum chromodynamics (QCD), explaining that the constituent quark model, while useful, doesn't fully capture the reality of these particles. They emphasize that these exotic hadrons aren't simply collections of individual quarks bound together, but rather complex emergent phenomena arising from the underlying gluon fields and sea quarks. This commenter also touches upon the computational challenges of simulating QCD, mentioning lattice QCD and its limitations.

  A different user focuses on the naming conventions used for these particles, finding the current system to be somewhat arbitrary and lacking a clear organizational principle. They suggest a more systematic approach based on the underlying quantum properties of the particles rather than just their quark composition.

  Another comment thread discusses the philosophical implications of these discoveries, questioning what it means to truly "understand" these particles. One commenter argues that simply knowing their quark content doesn't constitute understanding, and that a deeper comprehension of the underlying dynamics and interactions is crucial.

  There's also some discussion about the experimental techniques used to detect these particles, with one commenter asking about the specific methods used by the LHCb experiment mentioned in the article. Another commenter briefly explains the concept of reconstructing particles from their decay products.

  Finally, a few commenters express general enthusiasm for the article and the field of particle physics, appreciating the clear explanation of a complex topic. They highlight the fascinating nature of these discoveries and the ongoing quest to unravel the mysteries of the universe.