I have never felt at ease with this answer. There is an arbitrary large number of partons in a hadrons, provided one looks close enough. So I always thought "three scatering centers" is oversimplfying. But maybe you'd call this nitpicking.mathman said:Shooting high speed electrons at protons led to the observation that there are three scattering centers in the protons.
ghery said:Hi:
I have heard that It was found at SLAC that the nucleons are made of 3 quarks, how did they found that if quarks can not be isolated?, and by the way, how do you detect those quarks if they can not be found free in nature?
Regards
humanino said:There is an arbitrary large number of partons in a hadrons, provided one looks close enough. So I always thought "three scatering centers" is oversimplfying. But maybe you'd call this nitpicking.
Quarks are fundamental particles that make up protons and neutrons, which are in turn the building blocks of atoms. They are the smallest known particles and cannot be divided into smaller components.
Quarks were first proposed by physicists Murray Gell-Mann and George Zweig in the 1960s to explain the behavior of subatomic particles. Their existence was later confirmed through experiments at particle accelerators, such as the Stanford Linear Accelerator Center.
Quarks cannot be observed directly, as they are confined within particles. Instead, scientists use particle accelerators to study the interactions of particles and look for evidence of quarks. They also use mathematical models and simulations to study the behavior of particles at the subatomic level.
Quarks cannot be isolated in the traditional sense, as they are always bound together in groups. However, scientists can study the properties and behavior of individual quarks by studying their interactions with other particles. This is done through experiments at particle accelerators, as well as through theoretical and computational models.
Quarks are crucial to our understanding of the fundamental forces and building blocks of the universe. By studying quarks, scientists can gain insights into the behavior of matter at the smallest scale and how the universe was formed. Additionally, research on quarks has practical applications, such as improving our understanding of nuclear energy and developing new technologies.