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OverviewThis book offers a comprehensive exploration of the phenomenology surrounding high-energy particle interactions. When particles possess kinetic energy surpassing their rest energy, remarkable phenomena occur. Colliding particles at such high energies can lead to the creation of entirely new particles, illuminating the intricate workings of the universe. Through vivid explanations, this book elucidates the intricate processes that unfold during particle collisions. From proton collisions yielding pions and kaons to electron-positron collisions producing muons, each collision unveils a tapestry of particle interactions. Central to these interactions is the exchange of photons, which come in various forms. Among them are electromagnetic (EM) photons, akin to the light photons that bind electrons to protons within atoms. Then, there are the heavy bosons responsible for beta decay, crucial mediators of weak interactions that govern the decay of particles such as muons and pions. Additionally, there exist photons that bind quarks within protons and neutrons, facilitating the strong force that holds atomic nuclei together. In 'High Energy Physics: A Level and Transition Approach,' we embark on a journey through the diverse array of particles and photons that orchestrate these interactions, shedding light on the fundamental forces shaping the fabric of our universe. Full Product DetailsAuthor: Navin KhanejaPublisher: Springer International Publishing AG Imprint: Springer International Publishing AG Edition: 2025 ed. ISBN: 9783031756443ISBN 10: 3031756444 Pages: 132 Publication Date: 06 January 2025 Audience: Professional and scholarly , Professional & Vocational Format: Hardback Publisher's Status: Forthcoming Availability: Not yet available This item is yet to be released. You can pre-order this item and we will dispatch it to you upon its release. Table of ContentsReviewsAuthor InformationNavin Khaneja holds a B.Tech. in Electrical Engineering from IIT Kanpur (1994), an M.A. and M.Sc. in Mathematics and Electrical Engineering from Washington University in St. Louis (1997), and a Ph.D. in Applied Mathematics from Harvard University in 2000. Distinguished by prestigious accolades including the NSF Career Award, The Sloan Fellowship, and the Bessel Prize of the Humboldt Foundation, his scholarly pursuits traverse the domains of control theory and NMR spectroscopy. With a prolific output, he has authored nearly 90 journal papers, contributing significantly to the advancement of his fields of expertise. Tab Content 6Author Website:Countries AvailableAll regions |