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In Episode 37, I ask the question "Are we in the middle of a Time War?" I ask the question because, for those who wish to contain God or control God, they must first control time. Is there any evidence of time travel? What about the Bermuda Triangle? There have been dozens of reports of people gaining and losing time when traveling through the Bermuda Triangle. Is the fabled Foundation of Youth another time well where the earth distorts time? How about time slips? In 1901, two Englishwomen, Anne Moberly and Eleanor Jourdain swore they saw Marie Antoinette drawing in a sketchbook in her Garden during their vacation in France. If ancient man was as smart as I have claimed, he/she would have used these natural time distortions as part of the quantum drive that powered the planetary computer that built. Yes, I argue that as a Type I civilization, ancient man converted the planet into a computer (see previous episodes). Unfortunately, I believe current has learned ancient man's secrets and are seeking to use it to control God. Current attempts at time control include the Nazi Bell (Die Glocke), the Philadelphia Experiment (The USS Eldridge), DARPA's Project Pegasus, and CERN's Large Hadron Collider. If any of these attempts at Time Travel are real we should be seeing evidence of timeline disruption. Would a shoe print in a rock in Fisher Canyon, NV that is estimated to be 5 million years old be enough evidence of timeline disruption? Would the discovery of the Methuselah Star, a star estimated to be 2 billion years older than our universe, be more evidence of timeline disruption? If you buy what I am preaching, then you will accept that there are occultist scientists and billionaires who want to control God. Think I have lost my mind yet? Come with me and take a walk into the paranormal. Follow us on Facebook at https://www.facebook.com/hebeheberadio/ and Twitter at @EventHo14339589, and Instagram @EventHorizon. Give me your feedback and leave a comment.If you like Event Horizon, and if you are also a political junkie, you might just like my podcast, "The Mark Peterson Show." Please check it out on Spreaker https://www.spreaker.com/show/the_mark_peterson_show You might also like my new podcast, "Movie Reviews from the Edge." Check it out at https://www.spreaker.com/show/movie-reviews-from-the-edge
Todd Adams is a professor of physics at Florida State University, and a member of the High Energy Physics Group that is working on the Compact Muon Solenoid (CMS) experiment at the European Organization for Nuclear Research (CERN) in Switzerland. He joins the show to discuss the details of this fascinating work, such as the following: How gravitational lensing allows for the estimation of the mass of unseen objects, and how this is used to investigate dark matter In what ways the standard model of particle physics fails to address critical questions and observations in physics What WIMPs (weakly interacting massive particles) are and why Adams is hoping to produce them in the proton-proton collisions taking place in the Large Hadron Collider The Large Hadron Collider is the “world's largest scientific experiment,” says Adams. It is a particle accelerator that was built underground in Geneva, Switzerland, and is about 17 miles in circumference. It accelerates protons in a circle at a speed close to that of light, with the purpose of observing what happens when protons collide. These collisions are the highest energy collisions ever created in a lab. As many people know from the famous equation E= MC2, energy can be converted to mass, which is the goal at the Hadron Collider; the creation and study of new particles from these high-energy collisions. Adams explains the details of the CMS experiment, which uses a detector five stories in height and 12,000 tons in weight that's designed to detect the particles produced by the high-energy collision of protons. Once the particles have been identified, the goal is to reconstruct precisely what happened at the time of the collision. So, what's the ultimate purpose of these experiments? Adams explains that the standard model of particle physics does an excellent job of explaining most of what we see in the world, but it leaves some compelling questions and observations unanswered, namely what's called “dark matter.” One theory to explain dark matter is the presence of a particle that doesn't interact like normal matter in that it does not interact with light, with the exception of the gravitational effects of light. Adams also discusses why it becomes harder to accelerate a particle to higher velocities as the particle approaches the speed of light, how protons are brought to such high speeds, the importance of the search for weakly interacting massive particles (WIMPs), the significance of the Higgs boson, the uncertainty principle from quantum physics, and so much more. Learn more at http://www.hep.fsu.edu/~tadams/ and https://cms.cern/.
Our universe is bizarre. Why is most of the cosmos composed of mysterious dark matter? Why is the Higgs boson so strange? Why do atoms exist? The hottest-and-latest in physics suggests that the biggest puzzles of science could be elegantly solved if our universe were one of a possibly infinite number of universes. But is this a testable scientific idea, or eternally speculative? How do we talk about what's outside our universe? Join Dr. James Beacham, of CERN's Large Hadron Collider, as he explores the edges of knowledge -- including CERN's plans for a colossal Future Circular Collider -- and how the future of science, technology, and innovation will be much wilder than we can imagine.
Bitgenstein’s Table, the Crypto Philosophy Podcast: Exploring the Future of Blockchain
This week, we discuss kidnappings & gunpoint attacks demanding cryptocurrency. We often say that cryptocurrency is unseizable. But in one sense, it’s more seizable than dollars in your account: Kidnappers’ crypto accounts, unlike bank accounts, are unfreezable and are themselves unseizable – making stolen funds completely unrecoverable. What can we do to be safe from ransom and wrench attacks? *** Next week I have an exciting guest interview with Manuel Martin, who worked at CERN's Large Hadron Collider for many years and is now teaming up with other experts to fix many problems with the scientific publishing industry. *** Original theme song, as usual, by Joseph Dickinson (audiojungle.net/user/jdmusic). Besides one nocturne (in C minor) by Polish composer Frederic Chopin, all other piano songs – Prelude for the Left Hand Alone, Nocturne for the Left Hand Alone, and Etude in C sharp minor – are by Russian composer Alexander Scriabin. --- Support this podcast: https://anchor.fm/bitgenstein/support
Ordinary atoms that make up the visible universe, from the smallest molecules to planets and stars, constitute only 5% of all matter and energy in the cosmos. The remaining 95% is invisible, and comprises two mysterious components commonly dubbed dark matter and dark energy. In this talk Professor Manfred Lindner (Director at the Max Planck Institute for Nuclear Physics and a professor at the faculty for physics and astronomy of Heidelberg University, Germany) reviews what we currently know about the 'dark side' of the universe, and discuss the state-of-the-art of the ongoing hunt for the dark matter being pursued in underground laboratories, using satellites in space, and at CERN's Large Hadron Collider. More info:http://sydney.edu.au/sydney_ideas/lectures/2016/professor_manfred_lindner.shtml
Almost 50 years after it was first proposed, evidence for the elusive Higgs boson finally emerged. But how can you detect a particle that only exists for a tiny fraction of a second? Jonathan Butterworth takes us through the experiments at CERN's Large Hadron Collider. | Read along while listening at our Medium: bit.ly/1N4bqZN | Narrated by Vidish Athavale | Music by Kai Engel | Jonathan is a Professor of Physics at UCL, head of the Department of Physics & Astronomy, and a member of the ATLAS experiment at CERN's Large Hadron Collider. He writes regularly for The Guardian and has recently published 'Smashing Physics', a book on his experiences of the discovery of the Higgs boson, that was shortlisted for the 2015 Royal Society Winton Prize for Science Books.
Owen Sheers' career as a poet began aged 10, when he won a competition at Abergavenny Show for a poem in which he found a rhyme for "orange" - a mountain in the Brecon Beacons called the Blorenge. He says: "I won 50p and thought, 'there's money in this poetry game'. I've since been proved wrong." He persisted with the poetry, publishing his first volume fresh out of university, and rapidly becoming one of Britain's most successful poets, as well as writing prolifically for theatre, television and radio and enjoying great success as a novelist - his latest book I Saw a Man was published earlier this year. Owen Sheers is a writer who likes to get away from his desk, and he tells Michael about his delight at being Artist in Residence at the Welsh Rugby Union, and about his collaboration with composer Mark Bowden, which took him to Cern's Large Hadron Collider in Switzerland. He has chosen music from Haydn's Creation, one of Bach's Celllo Suites (which features in his first novel), music by Keith Jarrett and a favourite Welsh folk song. Producer: Jane Greenwood A Loftus Production for BBC Radio 3.
The discovery of the Higgs boson was the culmination of the largest experiment ever run, the ATLAS and CMS experiments at CERN's Large Hadron Collider. But what is a Higgs boson? How was it found? And what will the LHC do next?
Presented by Prof. Geoff Taylor on 2nd December 2011The Large Hadron Collider is operating beautifully well. Data from the highest energy particle collisions produced in the laboratory is being amassed at rates never before achieved. The big experiments, including the ATLAS experiment, on which Australian scientists collaborate, are operating extraordinarily well considering their complexity. The level of sophistication of analyses achieved with such a short period of operation has surprised the scientific world. Searches for the Higgs boson, Supersymmetry and other exotic phenomena are well underway. This presentation will give the status of these searches in the LHC/ATLAS program.The new ARC Centre of Excellence for Particle Physics at the Terascale ("CoEPP") brings together Australian experimentalist and theorists from Melbourne, Adelaide, Sydney and Monash. It will provide the resources and the focus to fully participate in the LHC program. A description of the CoEPP and its key goals will be covered in the presentation.
Presented by Prof. Geoff Taylor on 2nd December 2011The Large Hadron Collider is operating beautifully well. Data from the highest energy particle collisions produced in the laboratory is being amassed at rates never before achieved. The big experiments, including the ATLAS experiment, on which Australian scientists collaborate, are operating extraordinarily well considering their complexity. The level of sophistication of analyses achieved with such a short period of operation has surprised the scientific world. Searches for the Higgs boson, Supersymmetry and other exotic phenomena are well underway. This presentation will give the status of these searches in the LHC/ATLAS program.The new ARC Centre of Excellence for Particle Physics at the Terascale ("CoEPP") brings together Australian experimentalist and theorists from Melbourne, Adelaide, Sydney and Monash. It will provide the resources and the focus to fully participate in the LHC program. A description of the CoEPP and its key goals will be covered in the presentation.
In this episode we discuss the intriguing results hot off the press from Cern's Large Hadron Collider with particle physicist Professor Jonathan Butterworth. Have we found the Higgs particle, yet? And if we had, what would that mean for the future of particle physics?