Friday, August 23, 2024

3D Printed Optical Pressure Sensor!



Discover the groundbreaking capabilities of a polymer Fabry-Perot interferometer-based microcavity in this comprehensive overview video. We'll introduce you to this innovative non-contact optical pressure sensor, exploring its sophisticated design featuring a hollow cavity and unique pressure-sensing mechanism. Learn about the impressive performance metrics such as sensitivity and stability that make this sensor a game-changer. Finally, we'll delve into its promising applications in the biomedical and aerospace industries. Don't forget to like and share this video to spread knowledge about this cutting-edge technology!

#OpticalPressureSensor #FabryPerotInterferometer #BiomedicalTechnology #AerospaceInnovation #SensorTechnology #Microcavity #NonContactSensor #ScienceFather #scifax #ScienceDad #proffessor #students #ResearchScholar #awardwinner #scientist #PhD #acedemic More Details: Title: International Research Awards on High Energy Physics and Computational Science by ScienceFather. Website: physics.sciencefather.com Visit Our Award Nomination : https://hep-conferences.sciencefather.com/award-nomination/?ecategory=Awards&rcategory=Awardee Contact us : Physicsinquiry@sciencefather.com Get Connected Here: ================== Facebook : https://www.facebook.com/profile.php?id=100089114473152 Instagram : https://www.instagram.com/victoriaanisa1/ Twitter : https://twitter.com/Psciencefather Pinterest : https://in.pinterest.com/victoriaanisa1/ Blog : https://physicscience23.blogspot.com/ tumblr : https://www.tumblr.com/blog/high-energy-physics

Wednesday, August 21, 2024

China achieves new progress in building High Energy Photon Source

 


Major progress has been made in the construction of the High Energy Photon Source (HEPS), the first high-energy synchrotron radiation light source in China, with the electron beams with currents reaching 12 mA stored in the HEPS storage ring. The Institute of High Energy Physics (IHEP) under the Chinese Academy of Sciences, the main HEPS developer, announced the new achievement in Beijing's suburban Huairou District on Monday. As one of the country's key scientific and technological infrastructure projects, HEPS is expected to become one of the brightest fourth-generation synchrotron radiation facilities worldwide and will serve as a research platform for material science, chemical engineering, biomedicine and other fields. The construction of the HEPS project began on June 29, 2019. The facility is composed of several parts, including accelerators, beamlines, end stations and support facilities. A synchrotron radiation light source is a source of electromagnetic radiation usually produced by a storage ring. To generate extremely bright light, electrons will be accelerated to near the speed of light in several stages and forced to travel in a closed path. The electron storage ring, with a circumference of 1,360.4 meters, is the main component of the HEPS accelerator complex. The HEPS storage ring is one of the largest synchrotron light source accelerators in the world and the largest in China. Its primary function is to store high-energy, high-quality electron beams and generate high-performance synchrotron radiation, according to Pan Weimin, the HEPS project director. The commissioning of the storage ring was launched on July 23. A total of 1,776 magnets, over 2,500 power supplies and 578 electron beam position monitors have been installed on the storage ring, with over 100,000 control signals. "Any small hardware error could affect the trajectory of the electron beam, which is undoubtedly a huge challenge for the commissioning of the storage ring," said Pan. Commissioning of the HEPS storage ring will continue in the next few months, with the aim of achieving higher beam currents with a sufficiently long beam lifetime for vacuum conditioning and beamline commissioning, said Jiao Yi, deputy head of the HEPS accelerator division. The HEPS project is expected to be ready for operation by the end of 2025. Once completed, HEPS will be able to emit light that is one trillion times brighter than the sun, and will be open to users in fields such as aerospace, energy, environment, life science and pharmaceuticals, according to IHEP.


More Details: Title: International Research Awards on High Energy Physics and Computational Science by ScienceFather. Website: physics.sciencefather.com Visit Our Award Nomination : https://x-i.me/hepnom Contact us : Physicsinquiry@sciencefather.com


Get Connected Here: ==================
Instagram : https://x-i.me/Vn71
Twitter      : https://x-i.me/unl4
Pinterest   : https://x-i.me/y7HN
tumblr       : https://x-i.me/Z7js





Saturday, August 17, 2024

Large Hadron Collider pipe brings search for elusive magnetic monopole closer than ever

 



New research using a decommissioned section of the beam pipe from the Large Hadron Collider (LHC) at CERN has brought scientists closer than ever before to test whether magnetic monopoles exist.

Scientists from the University of Nottingham, in collaboration with an international team, have revealed the most stringent constraints yet on the existence of magnetic monopoles, pushing the boundaries of what is known about these elusive particles. Their research has been published in Physical Review Letters. In particle physics, a magnetic monopole is a hypothetical elementary particle that is an isolated magnet with only one magnetic pole (a north pole without a south pole or vice versa). Oliver Gould, Dorothy Hodgkin Fellow at the School of Physics and Astronomy at the University of Nottingham is the lead theorist for the study. He said, "Could there be particles with only a single magnetic pole, either north or south? This intriguing possibility, championed by renowned physicists Pierre Curie, Paul Dirac, and Joseph Polchinski, has remained one of the most captivating mysteries in theoretical physics. Confirming their existence would be transformative for physics, yet to date experimental searches have come up empty handed." The team focused their search on a decommissioned section of the beam pipe from the LHC at CERN, the European Organization for Nuclear Research. Conducted by physicists from the Monopole and Exotics Detector at the LHC (MoEDAL) experiment, the study examined a beryllium beam pipe section that had been located at the particle collision point for the Compact Muon Solenoid (CMS) experiment. This pipe had endured radiation from billions of ultra-high-energy ion collisions occurring just centimeters away.




More Details: Title: International Research Awards on High Energy Physics and Computational Science by ScienceFather. Website: physics.sciencefather.com Visit Our Award Nomination : https://x-i.me/hepnom Contact us : Physicsinquiry@sciencefather.com


Get Connected Here: ==================
Instagram : https://x-i.me/Vn71
Twitter      : https://x-i.me/unl4
Pinterest   : https://x-i.me/y7HN
tumblr       : https://x-i.me/Z7js