Medical technologies like PET (positron emission tomography) rely on the physics of elementary particles to visualize and track the behavior of positrons emitted by radioactive tracers in the body. Other examples include proton therapy for cancer treatment, which uses proton particles to target tumors with precision, and PET-MRI scanners that combine PET imaging with magnetic resonance imaging for better diagnostic capabilities.
... Well, for once a CRT TV tube is a direct result of elementary particle physics research. I would not mention the 'side effects' such as creation of the Internet. Myriad of medical and security applications are in existence by now. Particle physics is (arguably) the most fundamental branch of natural science thus it impacts many aspects of our lives albeit seemingly indirectly.
One highly recommended particle physics textbook for beginners is "Introduction to Elementary Particles" by David Griffiths.
Physics is related to health science because it helps us understand the underlying principles of the human body and medical technologies. Concepts like mechanics, electricity, and optics are fundamental to fields like biomechanics, medical imaging, and prosthetics. Understanding physics allows for the development of new medical technologies and treatments to improve healthcare outcomes.
A medical physicist uses the principles of physics to conduct research in medical-related fields such as radiation therapy, imaging technologies, and medical devices. They collaborate with medical professionals to improve diagnostics and treatments using physics concepts and technology.
Spontaneous symmetry breaking is important in particle physics because it helps explain how elementary particles acquire mass. It occurs when the symmetry of a system is broken, leading to the creation of mass-giving particles like the Higgs boson. This process is crucial for understanding the fundamental forces and interactions in the universe.
Yes, the muon is a subatomic elementary particle. The subatomic label is not really needed; all elementary particles are subatomic.
W. Galbraith has written: 'How elementary are elementary particles?' -- subject(s): Addresses, essays, lectures, Particles (Nuclear physics)
... Well, for once a CRT TV tube is a direct result of elementary particle physics research. I would not mention the 'side effects' such as creation of the Internet. Myriad of medical and security applications are in existence by now. Particle physics is (arguably) the most fundamental branch of natural science thus it impacts many aspects of our lives albeit seemingly indirectly.
Christopher G. Tully has written: 'Elementary particle physics in a nutshell' -- subject(s): Particles (Nuclear physics)
One highly recommended particle physics textbook for beginners is "Introduction to Elementary Particles" by David Griffiths.
Physics is related to health science because it helps us understand the underlying principles of the human body and medical technologies. Concepts like mechanics, electricity, and optics are fundamental to fields like biomechanics, medical imaging, and prosthetics. Understanding physics allows for the development of new medical technologies and treatments to improve healthcare outcomes.
Douglas Hayhoe has written: 'Elementary particles and the standard model' -- subject(s): Outlines, syllabi, Outlines, syllabi, etc, Particles (Nuclear physics), Physics, Standard model (Nuclear physics), Study and teaching (Secondary)
A medical physicist uses the principles of physics to conduct research in medical-related fields such as radiation therapy, imaging technologies, and medical devices. They collaborate with medical professionals to improve diagnostics and treatments using physics concepts and technology.
subatomic particleIn physics or chemistry, subatomic particles are the small particles composing nucleons and atoms. There are two types of subatomic particles: elementary particles, which are not made of other particles, and composite particles.
John David Jackson has written: 'Electrodynamique classique' 'The physics of elementary particles' -- subject(s): Particles 'Klassische Elektrodynamik'
Spontaneous symmetry breaking is important in particle physics because it helps explain how elementary particles acquire mass. It occurs when the symmetry of a system is broken, leading to the creation of mass-giving particles like the Higgs boson. This process is crucial for understanding the fundamental forces and interactions in the universe.
Murray Gell-Mann is best known for his work in theoretical physics, especially in the development of the quark model to describe the structure of hadrons. He was awarded the Nobel Prize in Physics in 1969 for his contributions to the theory of elementary particles.