Elementary Particles and Particle Physics Theory: Difference between revisions
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Particle | Particle physics is a field of study concerned with the most fundamental constituents of matter and the forces governing their interactions. By probing the structure of subatomic particles, this field aims to uncover the laws of the universe at the most elementary level. The Standard Model of particle physics has been the dominant theory for describing three of the four fundamental forces—electromagnetic, weak, and strong—and the particles that interact through them. While successful, it is incomplete, leaving out gravity and unsolved mysteries such as dark matter and dark energy. Particle physics continues to evolve, with theoretical advancements like string theory and loop quantum gravity offering new insights into the nature of the universe. | ||
==History== | |||
The history of particle physics spans over a century, from the earliest discoveries of subatomic particles to the establishment of the Standard Model and the exploration of physics beyond it. This section traces the key events and discoveries that have shaped the field, focusing on the development of quantum theory, the discovery of the fundamental particles, and the search for a unified theory of all forces. | |||
===Early Discoveries and the Birth of Quantum Mechanics=== | |||
The story of particle physics began with the discovery of the electron by J.J. Thomson in 1897. Thomson's experiments with cathode rays revealed that atoms contained negatively charged particles, which were much smaller than the atoms themselves. This discovery challenged the idea that atoms were indivisible and set the stage for the exploration of subatomic particles. | |||
The development of quantum mechanics in the early 20th century was a pivotal moment in the history of particle physics. The wave-particle duality of light, as proposed by Albert Einstein in 1905, and Werner Heisenberg's uncertainty principle in 1927, laid the groundwork for understanding the behavior of particles at the atomic and subatomic scales. Niels Bohr, Erwin Schrödinger, and Paul Dirac contributed further to the development of quantum theory, which would later become crucial for explaining the interactions between particles. | |||
In the 1920s and 1930s, the theory of quantum mechanics was expanded to include the idea that particles, including electrons, could be described as wavefunctions governed by Schrödinger's equation. This new understanding led to the exploration of quantum field theory (QFT), which treats particles as excitations in underlying fields. | |||
===The Discovery of the Nucleus and the Neutron=== | |||
In the early 20th century, Ernest Rutherford's groundbreaking experiments in 1911 led to the discovery of the atomic nucleus. Rutherford's work showed that atoms consisted of a dense, positively charged nucleus at the center, surrounded by a cloud of negatively charged electrons. This finding marked the beginning of a new understanding of atomic structure. | |||
In 1932, James Chadwick discovered the neutron, a neutral particle in the atomic nucleus that, together with the proton, accounted for most of the atom's mass. This discovery was crucial for understanding the structure of atomic nuclei and laid the foundation for the development of nuclear physics. | |||
===The Quark Model and the Development of the Standard Model=== | |||
In the 1960s, particle physicists began to discover that protons and neutrons were not elementary particles but were themselves composed of smaller, more fundamental particles. The quark model, independently proposed by Murray Gell-Mann and George Zweig, identified quarks as the building blocks of protons, neutrons, and other hadrons. Quarks come in six "flavors": up, down, charm, strange, top, and bottom, and each flavor carries a fractional electric charge. | |||
The discovery of quarks was a significant step toward the formulation of the Standard Model, but it was not until the 1970s that the Standard Model became a coherent framework. Quantum Chromodynamics (QCD), developed in the 1970s, describes the strong force that holds quarks together inside hadrons. According to QCD, quarks interact via the exchange of gluons, the force carriers of the strong interaction. | |||
The electroweak theory, developed by Sheldon Glashow, Abdus Salam, and Steven Weinberg, unified the electromagnetic and weak nuclear forces into a single framework. The electromagnetic force is mediated by photons, while the weak nuclear force, responsible for processes like beta decay, is mediated by the W and Z bosons. In 1979, Glashow, Salam, and Weinberg were awarded the Nobel Prize in Physics for their contributions to this unification. | |||
By the late 1970s, the Standard Model had successfully described three of the four fundamental forces—electromagnetic, weak, and strong—and their associated particles. The missing piece was the Higgs boson, the particle associated with the Higgs field, which gives mass to elementary particles. | |||
===Experimental Confirmation and the Discovery of the Higgs Boson=== | |||
The 1980s and 1990s saw the development of high-energy particle accelerators, such as the Large Electron-Positron Collider (LEP) at CERN, which allowed physicists to probe deeper into the subatomic world. The discovery of the top quark in 1995 at Fermilab confirmed the existence of all six quark flavors predicted by the Standard Model. | |||
In 2012, after decades of searching, the Higgs boson was discovered at CERN's Large Hadron Collider (LHC). The discovery provided experimental confirmation of the Higgs mechanism, which explains how particles acquire mass. The Higgs boson was detected through its decay products, marking a monumental achievement in particle physics and further solidifying the Standard Model as the leading theory of particle interactions. | |||
===Open Questions and the Search for New Physics=== | |||
Despite its successes, the Standard Model is not a complete theory. One of the major challenges it faces is the inclusion of gravity. The Standard Model describes three of the four fundamental forces, but it does not account for the gravitational force, which is described by general relativity. Efforts to unify gravity with the other three forces have led to the development of quantum gravity theories. | |||
One prominent candidate for unifying all the forces is string theory, which proposes that the fundamental particles are not point-like, but rather tiny, vibrating strings. String theory predicts the existence of additional spatial dimensions beyond the familiar three dimensions of space and one of time. It also introduces the concept of supersymmetry, which posits that each particle has a supersymmetric partner. | |||
Another approach to unifying the forces is loop quantum gravity (LQG), which attempts to quantize space-time itself. LQG does not rely on additional dimensions or supersymmetry, but instead proposes that space-time is granular, consisting of discrete loops at the smallest scales. | |||
The Standard Model also leaves unanswered questions about the nature of dark matter and dark energy, which make up the majority of the universe's mass and energy. Dark matter interacts with regular matter through gravity, but it does not emit, absorb, or reflect light, making it invisible to current detection methods. Dark energy, on the other hand, is thought to be responsible for the accelerated expansion of the universe. Neither dark matter nor dark energy is included in the Standard Model, and their discovery remains one of the most significant challenges in modern physics. | |||
==The Standard Model== | |||
The Standard Model (SM) of particle physics is the current best theory describing the fundamental particles of nature and their interactions. It provides a framework for understanding the electromagnetic, weak, and strong nuclear forces, which govern the behavior of matter on the smallest scales. Developed over several decades, the Standard Model has been highly successful in explaining numerous phenomena, offering precise predictions that have been experimentally verified in particle accelerators. However, it is not a complete theory. It leaves several questions unanswered, particularly regarding gravity and the nature of dark matter. This essay will explore the fundamental postulates of the Standard Model, examine its experimental successes and failures, and discuss its theoretical shortcomings. | |||
===Fundamental Postulates of the Standard Model=== | |||
The Standard Model describes the universe using two main categories of particles: fermions (matter particles) and bosons (force carriers). The theory is built on the foundation of quantum field theory (QFT), where fields permeate space and particles correspond to excitations of these fields. | |||
====The Quantum Field Theory Framework==== | |||
In the Standard Model, particles are described as excitations of underlying quantum fields. For example, an electron is an excitation of the electron field, while a photon is an excitation of the electromagnetic field. The interaction between particles is mediated by gauge bosons, which are the force carriers of the fundamental forces. The interactions between these particles and fields are governed by the principles of quantum mechanics, which are formulated using Lagrangians. In the case of the Standard Model, the Lagrangian includes terms for the electromagnetic force (mediated by the photon <math> \gamma </math> ), the weak force (mediated by the ''W'' and ''Z'' bosons), and the strong force (mediated by the gluons <math> \gamma </math>). The Higgs field, which gives particles mass, also plays a crucial role in the theory. | |||
====Gauge Symmetries and Force Mediators==== | |||
One of the key components of the Standard Model is the concept of gauge symmetries, which are mathematical symmetries that correspond to the forces in nature. These symmetries define how particles interact with each other through the exchange of force-mediating particles (gauge bosons). The Standard Model uses SU(3) × SU(2) × U(1) gauge symmetry, where: | |||
SU(3) corresponds to the strong interaction (Quantum Chromodynamics, or QCD), mediated by gluons. | |||
SU(2) corresponds to the weak interaction, mediated by the ''W<sup>−</sup>'', and ''Z<sup>0</sup>'' bosons. | |||
U(1) corresponds to the electromagnetic interaction, mediated by the photon <math>\gamma</math>. | |||
This framework allows for the description of how particles interact under these forces, and the Higgs field, through spontaneous symmetry breaking, gives mass to particles. | |||
===Experimental Successes of the Standard Model=== | |||
The Standard Model has been extraordinarily successful in predicting and explaining experimental results. Its predictions have been tested in numerous particle experiments, and it has consistently matched observations to a high degree of precision. | |||
====The Discovery of the Higgs Boson==== | |||
One of the most significant experimental successes of the Standard Model was the discovery of the Higgs boson in 2012 by the Large Hadron Collider (LHC) at CERN. The Higgs boson is a fundamental particle associated with the Higgs field, which is responsible for giving other particles their mass. The detection of the Higgs boson confirmed the Higgs mechanism and validated a central part of the Standard Model. | |||
====Precise Measurements of the Electromagnetic and Weak Interactions==== | |||
The predictions of the Standard Model regarding the electromagnetic and weak interactions have been experimentally verified to remarkable precision. For example, the magnetic moment of the electron has been measured with high accuracy, and the observed value is in perfect agreement with the Standard Model prediction. | |||
The muon g-2 experiment has similarly provided precision measurements that match Standard Model expectations. These successes reinforce the reliability of the theory in describing particle interactions. | |||
====The Structure of Hadrons==== | |||
The discovery of the quark model in the 1960s and subsequent experiments at particle accelerators provided overwhelming evidence for the existence of quarks. The properties of hadrons, such as protons and neutrons, can be described by quarks bound together by the strong force, as predicted by the Standard Model. | |||
===Experimental Failures of the Standard Model=== | |||
Despite its successes, the Standard Model has also encountered some experimental challenges. These anomalies suggest the possibility of new physics beyond the Standard Model. | |||
== | ====The Neutrino Masses==== | ||
In the Standard Model, neutrinos are massless particles. However, experiments such as neutrino oscillation have shown that neutrinos have a small but nonzero mass. This discovery contradicts the Standard Model's predictions and suggests that there is physics beyond the Standard Model, potentially involving new particles or interactions. | |||
====The Matter-Antimatter Asymmetry==== | |||
The Standard Model does not fully explain the observed asymmetry between matter and antimatter in the universe. According to the theory, the Big Bang should have produced equal amounts of matter and antimatter. However, the universe today is dominated by matter, and the exact cause of this asymmetry remains unknown. | |||
===Theoretical Shortcomings of the Standard Model=== | |||
While the Standard Model has been experimentally successful, it faces several significant theoretical shortcomings. | |||
====Inclusion of Gravity==== | |||
The most significant limitation of the Standard Model is its inability to incorporate gravity, the fourth fundamental force. Gravity is described by Einstein's general theory of relativity, which is incompatible with quantum mechanics. The Standard Model does not offer a quantum description of gravity, and no satisfactory theory of quantum gravity has yet been developed. The search for a Theory of Everything (TOE) that unifies all four fundamental forces remains one of the biggest challenges in theoretical physics. | |||
====The Hierarchy Problem==== | |||
The Standard Model cannot explain why the mass of the Higgs boson is so small compared to the scale of other fundamental forces. This is known as the hierarchy problem. Quantum corrections to the Higgs mass are expected to generate a much larger mass, yet the observed Higgs mass is much smaller. This discrepancy suggests that there must be some unknown physics at high energies that stabilizes the Higgs mass. | |||
====Dark Matter and Dark Energy==== | |||
The Standard Model does not provide an explanation for the existence of dark matter or dark energy, which together account for approximately 95% of the universe's mass-energy content. Dark matter interacts gravitationally with visible matter but does not emit or interact with electromagnetic radiation. Dark energy is thought to be responsible for the accelerated expansion of the universe, but it remains mysterious and unaccounted for in the Standard Model. | |||
==Elementary Particles== | ==Elementary Particles== | ||
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The Higgs Boson, first theorized in the 1960's along with the higgs field (a field to exist everywhere in the universe at once), was confirmed recently to exist through research conducted at the Large Hadron Collider. Termed "the God particle", the higgs boson has no spin and is extremely short-lived before decaying. This particle still is under the spotlight in particle physics, as much is theorized about the higgs boson to complete the standard model and particle physics theory, but yet to be confirmed. The higgs boson is known as a scalar boson because it is theorized to be the particle that gives other particles mass via the higgs field. This is a process that a lot of research is looking into today. | The Higgs Boson, first theorized in the 1960's along with the higgs field (a field to exist everywhere in the universe at once), was confirmed recently to exist through research conducted at the Large Hadron Collider. Termed "the God particle", the higgs boson has no spin and is extremely short-lived before decaying. This particle still is under the spotlight in particle physics, as much is theorized about the higgs boson to complete the standard model and particle physics theory, but yet to be confirmed. The higgs boson is known as a scalar boson because it is theorized to be the particle that gives other particles mass via the higgs field. This is a process that a lot of research is looking into today. | ||
== | ==Beyond the Standard Model== | ||
===String Theory=== | |||
String theory posits that the fundamental constituents of matter are not point particles, as described in the Standard Model, but rather one-dimensional "strings" that vibrate at different frequencies. These vibrations determine the properties of the particles. String theory offers a potential way to reconcile quantum mechanics with gravity, as it provides a framework where gravity can be described alongside the other three fundamental forces. The theory also predicts the existence of additional dimensions beyond the familiar three spatial dimensions and one-time dimension, which are compactified and hidden from view at the subatomic scale. | |||
String theory also introduces the concept of supersymmetry, which predicts a partner particle for every known particle. For example, the electron would have a partner known as the selectron, and the photon would have a partner called the photino. Though no supersymmetric particles have been discovered yet, the search continues in particle accelerators. | |||
=== | ===Loop Quantum Gravity=== | ||
Loop quantum gravity (LQG) is another approach to understanding quantum gravity. Unlike string theory, LQG does not propose extra dimensions or supersymmetry. Instead, it focuses on quantizing space-time itself. According to LQG, space-time is composed of discrete, quantized loops at the smallest scales. These loops form a spin network that describes the structure of space-time at the Planck scale. LQG aims to merge quantum mechanics and general relativity, providing a quantum theory of gravity without the need for additional dimensions. | |||
== See also == | |||
https://en.wikipedia.org/wiki/Particle_physics | |||
https://en.wikipedia.org/wiki/Standard_Model | |||
https://www.physicsbook.gatech.edu/String_Theory | |||
https://www.physicsbook.gatech.edu/Einstein%27s_Theory_of_General_Relativity | |||
==References== | ==References== | ||
Line 93: | Line 177: | ||
http://hyperphysics.phy-astr.gsu.edu/hbase/particles/lepton.html | http://hyperphysics.phy-astr.gsu.edu/hbase/particles/lepton.html | ||
Kragh, Helge (1999), Quantum Generations: A History of Physics in the Twentieth Century, Princeton: Princeton University Press. | |||
https://home.cern/science/physics/standard-model |
Latest revision as of 04:28, 4 December 2024
Claimed by Troy Stephens Fall 2024
Particle physics is a field of study concerned with the most fundamental constituents of matter and the forces governing their interactions. By probing the structure of subatomic particles, this field aims to uncover the laws of the universe at the most elementary level. The Standard Model of particle physics has been the dominant theory for describing three of the four fundamental forces—electromagnetic, weak, and strong—and the particles that interact through them. While successful, it is incomplete, leaving out gravity and unsolved mysteries such as dark matter and dark energy. Particle physics continues to evolve, with theoretical advancements like string theory and loop quantum gravity offering new insights into the nature of the universe.
History
The history of particle physics spans over a century, from the earliest discoveries of subatomic particles to the establishment of the Standard Model and the exploration of physics beyond it. This section traces the key events and discoveries that have shaped the field, focusing on the development of quantum theory, the discovery of the fundamental particles, and the search for a unified theory of all forces.
Early Discoveries and the Birth of Quantum Mechanics
The story of particle physics began with the discovery of the electron by J.J. Thomson in 1897. Thomson's experiments with cathode rays revealed that atoms contained negatively charged particles, which were much smaller than the atoms themselves. This discovery challenged the idea that atoms were indivisible and set the stage for the exploration of subatomic particles.
The development of quantum mechanics in the early 20th century was a pivotal moment in the history of particle physics. The wave-particle duality of light, as proposed by Albert Einstein in 1905, and Werner Heisenberg's uncertainty principle in 1927, laid the groundwork for understanding the behavior of particles at the atomic and subatomic scales. Niels Bohr, Erwin Schrödinger, and Paul Dirac contributed further to the development of quantum theory, which would later become crucial for explaining the interactions between particles.
In the 1920s and 1930s, the theory of quantum mechanics was expanded to include the idea that particles, including electrons, could be described as wavefunctions governed by Schrödinger's equation. This new understanding led to the exploration of quantum field theory (QFT), which treats particles as excitations in underlying fields.
The Discovery of the Nucleus and the Neutron
In the early 20th century, Ernest Rutherford's groundbreaking experiments in 1911 led to the discovery of the atomic nucleus. Rutherford's work showed that atoms consisted of a dense, positively charged nucleus at the center, surrounded by a cloud of negatively charged electrons. This finding marked the beginning of a new understanding of atomic structure.
In 1932, James Chadwick discovered the neutron, a neutral particle in the atomic nucleus that, together with the proton, accounted for most of the atom's mass. This discovery was crucial for understanding the structure of atomic nuclei and laid the foundation for the development of nuclear physics.
The Quark Model and the Development of the Standard Model
In the 1960s, particle physicists began to discover that protons and neutrons were not elementary particles but were themselves composed of smaller, more fundamental particles. The quark model, independently proposed by Murray Gell-Mann and George Zweig, identified quarks as the building blocks of protons, neutrons, and other hadrons. Quarks come in six "flavors": up, down, charm, strange, top, and bottom, and each flavor carries a fractional electric charge.
The discovery of quarks was a significant step toward the formulation of the Standard Model, but it was not until the 1970s that the Standard Model became a coherent framework. Quantum Chromodynamics (QCD), developed in the 1970s, describes the strong force that holds quarks together inside hadrons. According to QCD, quarks interact via the exchange of gluons, the force carriers of the strong interaction.
The electroweak theory, developed by Sheldon Glashow, Abdus Salam, and Steven Weinberg, unified the electromagnetic and weak nuclear forces into a single framework. The electromagnetic force is mediated by photons, while the weak nuclear force, responsible for processes like beta decay, is mediated by the W and Z bosons. In 1979, Glashow, Salam, and Weinberg were awarded the Nobel Prize in Physics for their contributions to this unification.
By the late 1970s, the Standard Model had successfully described three of the four fundamental forces—electromagnetic, weak, and strong—and their associated particles. The missing piece was the Higgs boson, the particle associated with the Higgs field, which gives mass to elementary particles.
Experimental Confirmation and the Discovery of the Higgs Boson
The 1980s and 1990s saw the development of high-energy particle accelerators, such as the Large Electron-Positron Collider (LEP) at CERN, which allowed physicists to probe deeper into the subatomic world. The discovery of the top quark in 1995 at Fermilab confirmed the existence of all six quark flavors predicted by the Standard Model.
In 2012, after decades of searching, the Higgs boson was discovered at CERN's Large Hadron Collider (LHC). The discovery provided experimental confirmation of the Higgs mechanism, which explains how particles acquire mass. The Higgs boson was detected through its decay products, marking a monumental achievement in particle physics and further solidifying the Standard Model as the leading theory of particle interactions.
Open Questions and the Search for New Physics
Despite its successes, the Standard Model is not a complete theory. One of the major challenges it faces is the inclusion of gravity. The Standard Model describes three of the four fundamental forces, but it does not account for the gravitational force, which is described by general relativity. Efforts to unify gravity with the other three forces have led to the development of quantum gravity theories.
One prominent candidate for unifying all the forces is string theory, which proposes that the fundamental particles are not point-like, but rather tiny, vibrating strings. String theory predicts the existence of additional spatial dimensions beyond the familiar three dimensions of space and one of time. It also introduces the concept of supersymmetry, which posits that each particle has a supersymmetric partner.
Another approach to unifying the forces is loop quantum gravity (LQG), which attempts to quantize space-time itself. LQG does not rely on additional dimensions or supersymmetry, but instead proposes that space-time is granular, consisting of discrete loops at the smallest scales.
The Standard Model also leaves unanswered questions about the nature of dark matter and dark energy, which make up the majority of the universe's mass and energy. Dark matter interacts with regular matter through gravity, but it does not emit, absorb, or reflect light, making it invisible to current detection methods. Dark energy, on the other hand, is thought to be responsible for the accelerated expansion of the universe. Neither dark matter nor dark energy is included in the Standard Model, and their discovery remains one of the most significant challenges in modern physics.
The Standard Model
The Standard Model (SM) of particle physics is the current best theory describing the fundamental particles of nature and their interactions. It provides a framework for understanding the electromagnetic, weak, and strong nuclear forces, which govern the behavior of matter on the smallest scales. Developed over several decades, the Standard Model has been highly successful in explaining numerous phenomena, offering precise predictions that have been experimentally verified in particle accelerators. However, it is not a complete theory. It leaves several questions unanswered, particularly regarding gravity and the nature of dark matter. This essay will explore the fundamental postulates of the Standard Model, examine its experimental successes and failures, and discuss its theoretical shortcomings.
Fundamental Postulates of the Standard Model
The Standard Model describes the universe using two main categories of particles: fermions (matter particles) and bosons (force carriers). The theory is built on the foundation of quantum field theory (QFT), where fields permeate space and particles correspond to excitations of these fields.
The Quantum Field Theory Framework
In the Standard Model, particles are described as excitations of underlying quantum fields. For example, an electron is an excitation of the electron field, while a photon is an excitation of the electromagnetic field. The interaction between particles is mediated by gauge bosons, which are the force carriers of the fundamental forces. The interactions between these particles and fields are governed by the principles of quantum mechanics, which are formulated using Lagrangians. In the case of the Standard Model, the Lagrangian includes terms for the electromagnetic force (mediated by the photon [math]\displaystyle{ \gamma }[/math] ), the weak force (mediated by the W and Z bosons), and the strong force (mediated by the gluons [math]\displaystyle{ \gamma }[/math]). The Higgs field, which gives particles mass, also plays a crucial role in the theory.
Gauge Symmetries and Force Mediators
One of the key components of the Standard Model is the concept of gauge symmetries, which are mathematical symmetries that correspond to the forces in nature. These symmetries define how particles interact with each other through the exchange of force-mediating particles (gauge bosons). The Standard Model uses SU(3) × SU(2) × U(1) gauge symmetry, where:
SU(3) corresponds to the strong interaction (Quantum Chromodynamics, or QCD), mediated by gluons. SU(2) corresponds to the weak interaction, mediated by the W−, and Z0 bosons. U(1) corresponds to the electromagnetic interaction, mediated by the photon [math]\displaystyle{ \gamma }[/math]. This framework allows for the description of how particles interact under these forces, and the Higgs field, through spontaneous symmetry breaking, gives mass to particles.
Experimental Successes of the Standard Model
The Standard Model has been extraordinarily successful in predicting and explaining experimental results. Its predictions have been tested in numerous particle experiments, and it has consistently matched observations to a high degree of precision.
The Discovery of the Higgs Boson
One of the most significant experimental successes of the Standard Model was the discovery of the Higgs boson in 2012 by the Large Hadron Collider (LHC) at CERN. The Higgs boson is a fundamental particle associated with the Higgs field, which is responsible for giving other particles their mass. The detection of the Higgs boson confirmed the Higgs mechanism and validated a central part of the Standard Model.
Precise Measurements of the Electromagnetic and Weak Interactions
The predictions of the Standard Model regarding the electromagnetic and weak interactions have been experimentally verified to remarkable precision. For example, the magnetic moment of the electron has been measured with high accuracy, and the observed value is in perfect agreement with the Standard Model prediction.
The muon g-2 experiment has similarly provided precision measurements that match Standard Model expectations. These successes reinforce the reliability of the theory in describing particle interactions.
The Structure of Hadrons
The discovery of the quark model in the 1960s and subsequent experiments at particle accelerators provided overwhelming evidence for the existence of quarks. The properties of hadrons, such as protons and neutrons, can be described by quarks bound together by the strong force, as predicted by the Standard Model.
Experimental Failures of the Standard Model
Despite its successes, the Standard Model has also encountered some experimental challenges. These anomalies suggest the possibility of new physics beyond the Standard Model.
The Neutrino Masses
In the Standard Model, neutrinos are massless particles. However, experiments such as neutrino oscillation have shown that neutrinos have a small but nonzero mass. This discovery contradicts the Standard Model's predictions and suggests that there is physics beyond the Standard Model, potentially involving new particles or interactions.
The Matter-Antimatter Asymmetry
The Standard Model does not fully explain the observed asymmetry between matter and antimatter in the universe. According to the theory, the Big Bang should have produced equal amounts of matter and antimatter. However, the universe today is dominated by matter, and the exact cause of this asymmetry remains unknown.
Theoretical Shortcomings of the Standard Model
While the Standard Model has been experimentally successful, it faces several significant theoretical shortcomings.
Inclusion of Gravity
The most significant limitation of the Standard Model is its inability to incorporate gravity, the fourth fundamental force. Gravity is described by Einstein's general theory of relativity, which is incompatible with quantum mechanics. The Standard Model does not offer a quantum description of gravity, and no satisfactory theory of quantum gravity has yet been developed. The search for a Theory of Everything (TOE) that unifies all four fundamental forces remains one of the biggest challenges in theoretical physics.
The Hierarchy Problem
The Standard Model cannot explain why the mass of the Higgs boson is so small compared to the scale of other fundamental forces. This is known as the hierarchy problem. Quantum corrections to the Higgs mass are expected to generate a much larger mass, yet the observed Higgs mass is much smaller. This discrepancy suggests that there must be some unknown physics at high energies that stabilizes the Higgs mass.
Dark Matter and Dark Energy
The Standard Model does not provide an explanation for the existence of dark matter or dark energy, which together account for approximately 95% of the universe's mass-energy content. Dark matter interacts gravitationally with visible matter but does not emit or interact with electromagnetic radiation. Dark energy is thought to be responsible for the accelerated expansion of the universe, but it remains mysterious and unaccounted for in the Standard Model.
Elementary Particles
Elementary particles can first be grouped into fermions, particles with mass composing matter and antimatter, and gauge bosons, force carrier particles with no mass. In addition to these two groups, there lies the Higgs Boson in a category of its own, classified as a as a scalar boson.
Fermions: Particles of Matter and Antimatter
Fermions are all fundamental particles that compose matter or antimatter, and therefore have mass. All matter is composed of quarks and leptons, which share a spin of +1/2 in common. Antimatter is composed purely of antiquarks and antileptons.
Matter
Quarks
There are six types of quarks: Up, Down, Charm, Strange, Top, Bottom. All six quarks have a spin of +1/2. Up, charm, and top quarks have a charge of +2/3, while down, strange, and bottom quarks have a charge of -1/3.
Leptons
Leptons are particles with spins of 1/2. Leptons can be broken down into two major classes: charged leptons and neutral leptons. The electron, muon, and tau are the charged electrons, all with a charge of -1. Each of these have a respective neutral lepton, which are termed neutrinos. The speed at which neutrinos travel is hotly contested because it's extremely important and extremely difficult to measure. Many scientists believe neutrinos travel at the speed of light, which would pose a challenge to the idea that only massless particles can travel at the maximum speed of the universe which is the speed of light.
Antimatter
As matter is composed of quarks and leptons, antimatter is composed of antiquarks and antileptons. The antiparticle counterparts of quarks and leptons are mostly identical in property magnitudes but opposite in sign.
Antiquarks
For the six flavors of quarks, there exist antiquarks. Antiquarks have the same magnitude in properties as their quark counterparts, but flipped signs. The charges of each antiquark is the negative of its counterpart's charge.
Antileptons
For every charged lepton flavor there is a corresponding antilepton flavor, so there exist the anti electron, commonly known as the positron, the antimuon, and the antitau. There is still uncertainty however as to whether or not neutrinos have antiparticles. The electron antineutrino, muon antineutrino, and tau antineutrino, are all theorized, but some particle physicists argue that neutrinos may be their own antiparticles. There is yet much research to be done on neutrinos to further understand them.
Gauge Bosons: Carriers of Fundamental Forces
There are four fundamental forces: electromagnetic force, gravity, strong force, and weak force. Each of these are hypothesized to have a massless carrier particle. These particles are classified together as Gauge Bosons. Although these do not hold mass, they do hold energy(seeing as they carry force) and therefore mass can be calculated by mass-energy equivalence, which is an exceptionally important idea because it enables scientists to perform a variety of calculations on these particles.
Photon: Carrier of Electromagentic Force
The photon is the guage boson responsible for mediating the electromagentic force. Electromagnetism and the photon are the most well understood force and respective carrier. The photon's mediation of the electromagnetic force can best be explained by the photoelectric effect.
Gluons: Carrier of Strong Force
Gluons mediate the strong force, which is the force between quarks. The attraction between quarks, strong force, is what allows quarks to come together to form hadrons, which can be classified into baryons(combinations of three quarks) and mesons(combinations of a quark and an antiquark). The most well-known baryons are protons and neutrons which form the atomic nucleus. Gluons and the strong force are reponsible for both the attraction between neutrons and protons, and the attraction between quarks that allow neutrons and protons to form. There are altogether eight variations, or colors, of the gluon.
W and Z Bosons: Carrier of Weak Force
There exist three gauge bosons that mediate the weak force between W and Z Bosons: W+, W−, and Z0. The weak force, or weak nuclear force, is the interaction responsible for the radioactive decay of subatomic particles, which plays a crucial role in nuclear fission. The two W bosons are responsible for the absorption and emission of neutrinos in nuclear decay, while the Z boson is responsible for the transfer of momentum, spin, and energy when the neutrinos scatter after decay.
Graviton: (Hypothesized) Carrier of Gravitational Force
Gravitons are the hypothesized particle to carry the fundamental force of gravity. Yet to be discovered, they are expected to have a spin of 2, no mass, have light-particle duality, and travel at the speed of light.
Scalar Bosons: The Higgs Boson
The Higgs Boson, first theorized in the 1960's along with the higgs field (a field to exist everywhere in the universe at once), was confirmed recently to exist through research conducted at the Large Hadron Collider. Termed "the God particle", the higgs boson has no spin and is extremely short-lived before decaying. This particle still is under the spotlight in particle physics, as much is theorized about the higgs boson to complete the standard model and particle physics theory, but yet to be confirmed. The higgs boson is known as a scalar boson because it is theorized to be the particle that gives other particles mass via the higgs field. This is a process that a lot of research is looking into today.
Beyond the Standard Model
String Theory
String theory posits that the fundamental constituents of matter are not point particles, as described in the Standard Model, but rather one-dimensional "strings" that vibrate at different frequencies. These vibrations determine the properties of the particles. String theory offers a potential way to reconcile quantum mechanics with gravity, as it provides a framework where gravity can be described alongside the other three fundamental forces. The theory also predicts the existence of additional dimensions beyond the familiar three spatial dimensions and one-time dimension, which are compactified and hidden from view at the subatomic scale.
String theory also introduces the concept of supersymmetry, which predicts a partner particle for every known particle. For example, the electron would have a partner known as the selectron, and the photon would have a partner called the photino. Though no supersymmetric particles have been discovered yet, the search continues in particle accelerators.
Loop Quantum Gravity
Loop quantum gravity (LQG) is another approach to understanding quantum gravity. Unlike string theory, LQG does not propose extra dimensions or supersymmetry. Instead, it focuses on quantizing space-time itself. According to LQG, space-time is composed of discrete, quantized loops at the smallest scales. These loops form a spin network that describes the structure of space-time at the Planck scale. LQG aims to merge quantum mechanics and general relativity, providing a quantum theory of gravity without the need for additional dimensions.
See also
https://en.wikipedia.org/wiki/Particle_physics
https://en.wikipedia.org/wiki/Standard_Model
https://www.physicsbook.gatech.edu/String_Theory
https://www.physicsbook.gatech.edu/Einstein%27s_Theory_of_General_Relativity
References
http://www.livescience.com/34045-higgs-particle-mass.html
http://www.particleadventure.org/other/history/
http://www.particleadventure.org/
http://home.cern/about/physics/z-boson
http://hyperphysics.phy-astr.gsu.edu/hbase/particles/lepton.html
Kragh, Helge (1999), Quantum Generations: A History of Physics in the Twentieth Century, Princeton: Princeton University Press.