Difference between revisions of "Physics"
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+ | <strong>Physics</strong> is a branch of [[science]] that studies the properties of matter, energy, and many more. Physics is considered to be the most fundamental of all the sciences, and is also the oldest. | ||
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== Overview == | == Overview == | ||
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Physics before the 19th century is called <strong>Classical Physics</strong>. Physics after the 19th century is know as <strong>Modern Physics</strong>. | Physics before the 19th century is called <strong>Classical Physics</strong>. Physics after the 19th century is know as <strong>Modern Physics</strong>. | ||
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Classical Physics can be split even further into its own branches: | Classical Physics can be split even further into its own branches: | ||
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* [[Thermodynamics]] | * [[Thermodynamics]] | ||
* [[Electromagnetism]] | * [[Electromagnetism]] | ||
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Modern Physics is also a group of different subjects in physics: | Modern Physics is also a group of different subjects in physics: | ||
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== History of Physics == | == History of Physics == | ||
− | The history of physics is | + | The history of physics is long and exciting. Physics started with the first scientist, [[Thales]] of Miletus, who was the first to try to systematically explain the world using theories and hypotheses instead of using gods and magic. |
− | + | [[Archimedes]] also made a big breakthrough in physics when he devised the concept of [[buoyancy]]. This discovery was in the third century BC and not much innovation was made thereafter for many centuries. | |
− | + | ||
− | However, Galileo Galilei, an Italian scientist, first advocated for the study of physics. He was the one who tried to preach | + | However, Galileo Galilei, an Italian scientist, first advocated for the systematic study of physics. He was the one who tried to preach his scientific thoughts about how the Earth orbited the Sun, opposing the ideas of the Catholic establishment, and became the first patron of physics. |
− | This was then further developed by Sir Isaac Newton, an English scientist | + | |
− | Since then, physics has never looked back! | + | This was then further developed by [[Isaac Newton|Sir Isaac Newton]], an English scientist, who devised the modern study of physics by discovering many laws. Since then, physics has never looked back! |
== Notable Figures == | == Notable Figures == | ||
===Isaac Newton=== | ===Isaac Newton=== | ||
+ | {{main|Isaac Newton}} | ||
Isaac Newton was born on January 4, 1643, in Lincolnshire, England. Newton was born very shortly after the death of his father. He did very well at his local school and later attended Trinity College. | Isaac Newton was born on January 4, 1643, in Lincolnshire, England. Newton was born very shortly after the death of his father. He did very well at his local school and later attended Trinity College. | ||
− | What is | + | What is now considered Newton's most famous achievement is the formal statement of three basic, almost trivial laws of motion: |
#If the net force on any amount of matter is [[Zero]], then the object's velocity will not change if viewing from a constant reference point. | #If the net force on any amount of matter is [[Zero]], then the object's velocity will not change if viewing from a constant reference point. | ||
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===Albert Einstein=== | ===Albert Einstein=== | ||
{{main|Albert Einstein}} | {{main|Albert Einstein}} | ||
− | '''Albert Einstein''' was a scientist | + | '''Albert Einstein''' was a scientist and mathematician. He was born in Ulm, Germany on March 14, 1879. He died on April 18, 1955. He is most noted for his work on relativity and many call him a theoretical physicist. Some of his most famous works are <math>E=MC^{2}</math>, [[General Relativity]], [[Special Relativity]], and his [[Brownian Motion#Theory of Brownian Motion|Theory of Brownian Motion]]. |
{{main|Relativity}} | {{main|Relativity}} | ||
'''Relativity''' is a branch of modern science that has two parts: special relativity and general relativity. Both were formed by Albert Einstein. | '''Relativity''' is a branch of modern science that has two parts: special relativity and general relativity. Both were formed by Albert Einstein. | ||
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* The rate of change of momentum of a body with respect to time is directly proportional to the force acting on it. | * The rate of change of momentum of a body with respect to time is directly proportional to the force acting on it. | ||
* Every action has an equal and opposite reaction. | * Every action has an equal and opposite reaction. | ||
− | [[Mass]] is one of the two most basic intrinsic properties of a body. It is a measure of its [[inertia]]. [[Momentum]] is defined as the [[product]] of the mass and [[velocity]] of a body. [[Force]] is something that changes or tends to change the momentum of a body, | + | [[Mass]] is one of the two most basic intrinsic properties of a body. It is a measure of its [[inertia]]. [[Momentum]] is defined as the [[product]] of the mass and [[velocity]] of a body. [[Force]] is something that changes or tends to change the momentum of a body, (informally, a "push or pull"). |
Mechanical [[work]] is defined by the relation <math>W =\int^{x_f}_{x_i} F\,dx</math> where <math>W</math> is work done, <math>F</math> is force, <math>x</math> is displacement, and subscripts <math>i</math> and <math>f</math> denote the initial and final states respectively. Similarly, mechanical [[power]] is defined as <math>P =\int^{v_f}_{v_i} F\,dv</math> where <math>P</math> is power delivered and <math>v</math> is velocity. [[Energy]] is the other basic intrinsic property of a body. Mechanical energy is simply the capacity of a body to do mechanical work. | Mechanical [[work]] is defined by the relation <math>W =\int^{x_f}_{x_i} F\,dx</math> where <math>W</math> is work done, <math>F</math> is force, <math>x</math> is displacement, and subscripts <math>i</math> and <math>f</math> denote the initial and final states respectively. Similarly, mechanical [[power]] is defined as <math>P =\int^{v_f}_{v_i} F\,dv</math> where <math>P</math> is power delivered and <math>v</math> is velocity. [[Energy]] is the other basic intrinsic property of a body. Mechanical energy is simply the capacity of a body to do mechanical work. | ||
Among the various properties of matter are elasticity, surface tension, and viscosity. The most important one is [[gravity]]. Gravity is indeed considered one of the most mysterious things not only in physics but in [[science]] as a whole. | Among the various properties of matter are elasticity, surface tension, and viscosity. The most important one is [[gravity]]. Gravity is indeed considered one of the most mysterious things not only in physics but in [[science]] as a whole. | ||
+ | |||
+ | Newton's laws can also be used to study the behavior of continuous substances. This has, for example, led to the development of [[fluid mechanics]], which, despite being almost entirely summarized by the [[Navier-Stokes Equation|Navier-Stokes equations]] or its variants, has many open questions about, for example, whether fluids continue to be well-behaved after arbitrary amounts of time. | ||
+ | |||
== Statistical Mechanics == | == Statistical Mechanics == | ||
{{main|Statistical Mechanics}} | {{main|Statistical Mechanics}} | ||
− | Mechanics that use statistics to draw conclusions. | + | Statistical Mechanics is mechanics that use statistics to draw conclusions. |
== Acoustics == | == Acoustics == | ||
{{main|Acoustics}} | {{main|Acoustics}} | ||
− | Acoustics is | + | Acoustics is the study of [[sound]]. Sound waves are mechanical waves - they travel by actual vibrations in some material medium. Acoustics concerns itself with mechanical [[wave]]s in general. Phenomena such as forced [[vibration]]s, [[resonance]], damped vibrations and the [[Doppler effect]] come under this branch of physics. |
== Optics == | == Optics == | ||
{{main|Optics}} | {{main|Optics}} | ||
− | + | Optics is the study of vision and light. [[Light]] waves are electromagnetic waves - they consist of mutually perpendicular electric fields and [[magnetic field]]s, and can travel through a vacuum. Optics is the study of electromagnetic waves in general. So it covers all waves in the [[electromagnetic spectrum]] given below: | |
* [[Gamma rays]] | * [[Gamma rays]] | ||
* [[X-Rays]] | * [[X-Rays]] | ||
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== Thermodynamics == | == Thermodynamics == | ||
{{main|Thermodynamics}} | {{main|Thermodynamics}} | ||
− | Thermodynamics | + | Thermodynamics is the study of [[heat]] transfer. Anything in physics related to heat is classified as thermodynamics. |
There are three laws of thermodynamics: | There are three laws of thermodynamics: | ||
* The First Law of Thermodynamics is a form of conservation of energy: The change in internal energy of a system is equal to the sum of the energy transferred to the system by heat and the work done on the system. | * The First Law of Thermodynamics is a form of conservation of energy: The change in internal energy of a system is equal to the sum of the energy transferred to the system by heat and the work done on the system. | ||
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== Electromagnetism == | == Electromagnetism == | ||
{{main|Electromagnetism}} | {{main|Electromagnetism}} | ||
− | Electromagnetism is the combined study of [[electricity]] and [[magnetism]], and the most important addition to classical physics after [[ Isaac Newton]]'s work. The concept of electromagnetism has wide applications in everyday devices such as computers, televisions, linear particle accelerators, and more. Electromagnetism operates on the fact that when electricity is run through a conductor, it produces a magnetic field | + | Electromagnetism is the combined study of [[electricity]] and [[magnetism]], and the most important addition to classical physics after [[Isaac Newton]]'s work. The concept of electromagnetism has wide applications in everyday devices such as modern computers, televisions, linear particle accelerators, and more. Electromagnetism operates on the fact that when electricity is run through a conductor, it produces a magnetic field |
== See also == | == See also == |
Latest revision as of 06:29, 29 September 2021
Physics is a branch of science that studies the properties of matter, energy, and many more. Physics is considered to be the most fundamental of all the sciences, and is also the oldest.
Contents
Overview
Physics before the 19th century is called Classical Physics. Physics after the 19th century is know as Modern Physics.
Classical Physics can be split even further into its own branches:
Modern Physics is also a group of different subjects in physics:
- Relativity
- Quantum Mechanics
- Nuclear Physics
- Condensed Matter Physics
- Particle Physics
- Astrophysics
- Cosmology
History of Physics
The history of physics is long and exciting. Physics started with the first scientist, Thales of Miletus, who was the first to try to systematically explain the world using theories and hypotheses instead of using gods and magic. Archimedes also made a big breakthrough in physics when he devised the concept of buoyancy. This discovery was in the third century BC and not much innovation was made thereafter for many centuries.
However, Galileo Galilei, an Italian scientist, first advocated for the systematic study of physics. He was the one who tried to preach his scientific thoughts about how the Earth orbited the Sun, opposing the ideas of the Catholic establishment, and became the first patron of physics.
This was then further developed by Sir Isaac Newton, an English scientist, who devised the modern study of physics by discovering many laws. Since then, physics has never looked back!
Notable Figures
Isaac Newton
- Main article: Isaac Newton
Isaac Newton was born on January 4, 1643, in Lincolnshire, England. Newton was born very shortly after the death of his father. He did very well at his local school and later attended Trinity College.
What is now considered Newton's most famous achievement is the formal statement of three basic, almost trivial laws of motion:
- If the net force on any amount of matter is Zero, then the object's velocity will not change if viewing from a constant reference point.
- If an object has mass and acceleration , then the force which acted upon it is equivalent to . This is stated formally as .
- Every action has an equal and opposite reaction. Formally, if an amount of matter places a force on the matter with the same mass , then will put an equivalent force in the opposite direction.
Albert Einstein
- Main article: Albert Einstein
Albert Einstein was a scientist and mathematician. He was born in Ulm, Germany on March 14, 1879. He died on April 18, 1955. He is most noted for his work on relativity and many call him a theoretical physicist. Some of his most famous works are , General Relativity, Special Relativity, and his Theory of Brownian Motion.
- Main article: Relativity
Relativity is a branch of modern science that has two parts: special relativity and general relativity. Both were formed by Albert Einstein.
Classical Mechanics
- Main article: Classical Mechanics
Mechanics is the study of movement. Kinematics, mechanical forces, work, power, energy, and matter are all part of mechanics.
Kinematics is the study of (relative) motion - displacement, velocity, acceleration etc. The two relations at the heart of kinematics are: and where is displacement at time , is velocity, is acceleration, and is time. Uniform rectilinear motion, projectile motion, uniform circular motion, and simple harmonic motion are some of the types of problems studied in kinematics.
The rules of physics are almost fully summarized by the three famous laws of motion formulated by Isaac Newton:
- A body continues to be in its state of uniform rectilinear motion until it is disturbed by an external force. This property is known as inertia.
- The rate of change of momentum of a body with respect to time is directly proportional to the force acting on it.
- Every action has an equal and opposite reaction.
Mass is one of the two most basic intrinsic properties of a body. It is a measure of its inertia. Momentum is defined as the product of the mass and velocity of a body. Force is something that changes or tends to change the momentum of a body, (informally, a "push or pull").
Mechanical work is defined by the relation where is work done, is force, is displacement, and subscripts and denote the initial and final states respectively. Similarly, mechanical power is defined as where is power delivered and is velocity. Energy is the other basic intrinsic property of a body. Mechanical energy is simply the capacity of a body to do mechanical work.
Among the various properties of matter are elasticity, surface tension, and viscosity. The most important one is gravity. Gravity is indeed considered one of the most mysterious things not only in physics but in science as a whole.
Newton's laws can also be used to study the behavior of continuous substances. This has, for example, led to the development of fluid mechanics, which, despite being almost entirely summarized by the Navier-Stokes equations or its variants, has many open questions about, for example, whether fluids continue to be well-behaved after arbitrary amounts of time.
Statistical Mechanics
- Main article: Statistical Mechanics
Statistical Mechanics is mechanics that use statistics to draw conclusions.
Acoustics
- Main article: Acoustics
Acoustics is the study of sound. Sound waves are mechanical waves - they travel by actual vibrations in some material medium. Acoustics concerns itself with mechanical waves in general. Phenomena such as forced vibrations, resonance, damped vibrations and the Doppler effect come under this branch of physics.
Optics
- Main article: Optics
Optics is the study of vision and light. Light waves are electromagnetic waves - they consist of mutually perpendicular electric fields and magnetic fields, and can travel through a vacuum. Optics is the study of electromagnetic waves in general. So it covers all waves in the electromagnetic spectrum given below:
One of the most controversial questions in optics is whether light is a wave or a ray. Accordingly, there are two branches of optics, but only ray optics belongs to classical physics. Wave optics are a topic of modern physics. In ray, optics covers topics such as reflection and refraction and the dispersion of white light into its constituent colors.
Thermodynamics
- Main article: Thermodynamics
Thermodynamics is the study of heat transfer. Anything in physics related to heat is classified as thermodynamics. There are three laws of thermodynamics:
- The First Law of Thermodynamics is a form of conservation of energy: The change in internal energy of a system is equal to the sum of the energy transferred to the system by heat and the work done on the system.
- The Second Law of Thermodynamics states that the efficiency of heat engines must always be < 1.
- The Third Law of Thermodynamics states that the temperature of a system cannot reach absolute zero (0 K); as the system approaches absolute zero, entropy approaches a constant.
Electromagnetism
- Main article: Electromagnetism
Electromagnetism is the combined study of electricity and magnetism, and the most important addition to classical physics after Isaac Newton's work. The concept of electromagnetism has wide applications in everyday devices such as modern computers, televisions, linear particle accelerators, and more. Electromagnetism operates on the fact that when electricity is run through a conductor, it produces a magnetic field
See also
- Physics books
- Physics competitions
- Physics scholarships
- Physics summer programs
- Gamma rays
- X-Rays
- Ultraviolet rays
- Visible light
- Infrared Rays
- Microwaves
- Radio waves
- Electricity
- magnetism
- Classical Mechanics
- Statistical Mechanics
- Acoustics
- Optics
- Thermodynamics
- Electromagnetism
- Relativity
- Quantum Mechanics
- Nuclear Physics
- Condensed Matter Physics
- Particle Physics
- Astrophysics
- Cosmology