Physics world
Tuesday, August 9, 2011
Wednesday, August 3, 2011
TRAVELOGUE
.
These lights are lights source or the source of light. other source of light can be incandescent light and the sun.
What you see in the picture is a plane mirror. Plane mirrors are mirrors with flat surface that produce images that are erect, have the same size, have the same distance, and virtual. |
Mirror used in cosmetic purposes is a concave mirror to act as a magnifier of your face for better applying of the make up, lipstick and other cosmetic products. |
mirror used in the cars' side view mirror is a convex mirror. It gives a wider and clearer view outside. |
As you can see, the pair of scissors is reflected in the mirror. since plane mirror is used, it has the same distance, same size and it is virtual. |
The ball pen appears to be broken, due to refraction of light as it is dipped into the water
The human eye is a wonderful instrument, relying on refraction and lenses to form images. There are also many similarities between the human eye and a camera. |
OPTICAL ILLUSION |
when a curved mirror like this is struck by light and in front of an object, the image formed is real and projected unto a screen sound is produced from vibrations mediums make. one example is the medium strings, when strings are struck, vibrations are created and travels in air then through our ears. that's why we hear music. irregular vibrations create noise The wavelength of the blue light scatters better than the rest , predominates over the other colors in the light spectrum, and makes the sky appear blue to us. water is a transparent medium which means light can travel through it. here we can see whats in the water as light is incident upon an object, colors of the spectrum are either reflected and/or absorbed. this flower reflects the color pink and green and that's what our eyes see When a beam of light shines onto something, that thing will cast a dark image of itself onto the ground or another surface. This image is called shadow. |
Friday, July 29, 2011
Physics Trivia
*Laser is an abbreviation of Light Amplification by Stimulated Emission of Radiation.
*The Dead Sea is so dense with salt, you can easily float on it without drowning.
*Albert Einstein pointed out that the faster you move, the heavier you get
*Lake Baikal in Russia contains more water than all the North American Great Lakes combined.
*The world's densest wood, the Black Ironwood (Olea laurifolia), does not float on water and therefore sinks.
*The mass of our entire atmosphere is estimated to be some 5.5 quadrillion tons (55 followed by 14 zeros).
*Because of differences in gravity, a 100kg (220 pound) person would only weigh 38kg (84 pounds) on Mars
*The amount of water beneath our ground soil is 50 times as much as all the water in the rivers and lakes combined.
*The bark of the redwood tree is fireproof.
*Electric eels can stun both predators and prey with electric shocks of around 500 volts.
*American Benjamin Franklin carried out extensive electricity research in the 18th century, inventing the lightning rod among his many discoveries. Lightning rods protect buildings in the event of lightning by conducting lightning strikes through a grounded wire.
*Back in the 1880’s there was even a ‘war of currents’ between Thomas Edison (who helped invent DC) and Nikola Tesla (who helped invent AC). Both wanted their system to be used with AC eventually winning out due to the fact that it is safer and can be used over longer distances.
*Uranus is the only planet in our solar system that rolls on its side like a barrel, while Venus is the only planet that spins in the opposite direction to Earth.
*While formula one racing drivers may feel around 5 g’s under heavy braking, they can experience over 100 g’s if a crash causes them to decelerate extremely quickly over a very short distance.
*The human body can handle increased g-forces as seen in activities such as dragster races, airplane acrobatics and space training. The highest known acceleration voluntarily experienced by a human is 46.2 g by g-force pioneer John Stapp.
*Other animals can see parts of the spectrum that humans can’t. For example, a large number of insects can see ultraviolet (UV) light.
*Our ears vibrate in a similar way to the original source of the vibration, allowing us to hear many different sounds.
*The loud noise you create by cracking a whip occurs because the tip is moving so fast it breaks the speed of sound!
*UV light can be used to show things the human eye can’t see, coming in handy for forensic scientists.
*Although music can be hard to define, it is often described as a pleasing or meaningful arrangement of sounds.
*Water can work against gravity, moving up narrow tubes in a process called capillary action.
*Traveling in space makes you 2.5-5 cm taller
*A spacecraft that was crashed into the moon last year threw up debris that included not only water but also higher-than-expected amounts of silver.
*The Dead Sea is so dense with salt, you can easily float on it without drowning.
*Albert Einstein pointed out that the faster you move, the heavier you get
*Lake Baikal in Russia contains more water than all the North American Great Lakes combined.
*The world's densest wood, the Black Ironwood (Olea laurifolia), does not float on water and therefore sinks.
*The mass of our entire atmosphere is estimated to be some 5.5 quadrillion tons (55 followed by 14 zeros).
*Because of differences in gravity, a 100kg (220 pound) person would only weigh 38kg (84 pounds) on Mars
*The amount of water beneath our ground soil is 50 times as much as all the water in the rivers and lakes combined.
*The bark of the redwood tree is fireproof.
*Electric eels can stun both predators and prey with electric shocks of around 500 volts.
*American Benjamin Franklin carried out extensive electricity research in the 18th century, inventing the lightning rod among his many discoveries. Lightning rods protect buildings in the event of lightning by conducting lightning strikes through a grounded wire.
*Back in the 1880’s there was even a ‘war of currents’ between Thomas Edison (who helped invent DC) and Nikola Tesla (who helped invent AC). Both wanted their system to be used with AC eventually winning out due to the fact that it is safer and can be used over longer distances.
*Uranus is the only planet in our solar system that rolls on its side like a barrel, while Venus is the only planet that spins in the opposite direction to Earth.
*While formula one racing drivers may feel around 5 g’s under heavy braking, they can experience over 100 g’s if a crash causes them to decelerate extremely quickly over a very short distance.
*The human body can handle increased g-forces as seen in activities such as dragster races, airplane acrobatics and space training. The highest known acceleration voluntarily experienced by a human is 46.2 g by g-force pioneer John Stapp.
*Other animals can see parts of the spectrum that humans can’t. For example, a large number of insects can see ultraviolet (UV) light.
*Our ears vibrate in a similar way to the original source of the vibration, allowing us to hear many different sounds.
*The loud noise you create by cracking a whip occurs because the tip is moving so fast it breaks the speed of sound!
*UV light can be used to show things the human eye can’t see, coming in handy for forensic scientists.
*Although music can be hard to define, it is often described as a pleasing or meaningful arrangement of sounds.
*Water can work against gravity, moving up narrow tubes in a process called capillary action.
*Traveling in space makes you 2.5-5 cm taller
*A spacecraft that was crashed into the moon last year threw up debris that included not only water but also higher-than-expected amounts of silver.
Friday, July 22, 2011
Famous Physicists
*he was born prematurely about 11-15 weeks early.
*he was considered by many to be the father of modern physics
*he invented calculus, and with calculus in hand, people could now create mathematical models of changing systems
*his three laws of motion and his law of gravitation, however, are still one of the first things that all physics students learn, and are the basis behind a lot of physics that is done today.
*he became a mathematics professor at the age of 26
* he was a religious person and he has written a lot about Biblical hermeneutics.
*he completed his graduation in the year 1665 and the generalized binomial theorem was discovered by him in the same year.
*delivered lectures on the subject of optics from the year 1670-1672. In the mean time, he studied refraction of light and demonstrated the decomposition of white light in a color spectrum.
*he was named after his father who died three months before he was born.
*he likes to draw, his room was even colored on the ceilings and walls.
*He went to Trinity College at Cambridge University with the intention of becoming a Church of England minister.
OPTICS:
Newton used prisms to show that sunlight was made up of all all the colors of the rainbow. This proved that the ancient Greeks’ ideas about light were wrong. In Newton’s time, astronomy was severely hampered because lenses in telescopes broke some of the light into unwanted colors, causing a somewhat unclear view. Although not the first to consider using a curved mirror instead of a lens, Newton was the first to successfully construct a telescope using this principle—a principle still used today in many telescopes.
André-Marie Ampère
*The French physicist and mathematician
*He is mainly credited for laying down the basis of electrodynamics (now known as electromagnetism).
*His name endures in everyday life in the ampere, the unit for measuring electric current.
* His father, Jean-Jacques Ampère, was an affluent businessman and local government official.
* His father gave him Latin lessons and encouraged him to pursue his passion for mathematics.
*He took his first regular job in 1799 as a modestly paid mathematics teacher, which gave him the financial security to marry and be a father of his first child, Jean-Jacques, the next year.
*In 1802, he was appointed a professor of physics and chemistry at the École Centrale in Bourg-en-Bresse.
Foundation of Electrodynamics
*His Father was a prominent citizen of Greenock, and was at various times chief magistrate and treasurer of the town.
*The quadrants lying about his father's carpenter's shop led him to the study of optics and astronomy; his ill health induced him to pry into the secrets of physiology; and his solitary walks through the country attracted him to the study of botany and history.
*While carrying on the business of a mathematical-instrument maker, he received an order to build an organ; and, though without an ear for music, he undertook the study of harmonics, and successfully constructed the instrument.
*He was one of the first people to observe sunspots, which helped develop the predictions that would help identify the annual patterns.
Robert Hooke
*British natural philosopher, architect and polymath
*perhaps the most neglected natural philosophers of all time despite the significant role he played in the scientific revolution
*His father was the minister of the Church of England.
*At the age of thirteen young Hooke was able to enter Westminster School, and from there went to Oxford, where some of the finest scientists in England were working at the time.
* He was appointed as a chemical assistant to Dr Thomas Willis and later met the natural philosopher Robert Boyle, and gained a position as his assistant from about 1655 to 1662.
Hooke’s law
~ law of elasticity discovered by the English scientist Robert Hooke in 1660, which states that, for relatively small deformations of an object, the displacement or size of the deformation is directly proportional to the deforming force or load. Under these conditions the object returns to its original shape and size upon removal of the load. Elastic behaviour of solids according to Hooke’s law can be explained by the fact that small displacements of their constituent molecules, atoms, or ions from normal positions is also proportional to the force that causes the displacement.
*He went to Trinity College at Cambridge University with the intention of becoming a Church of England minister.
OPTICS:
Newton used prisms to show that sunlight was made up of all all the colors of the rainbow. This proved that the ancient Greeks’ ideas about light were wrong. In Newton’s time, astronomy was severely hampered because lenses in telescopes broke some of the light into unwanted colors, causing a somewhat unclear view. Although not the first to consider using a curved mirror instead of a lens, Newton was the first to successfully construct a telescope using this principle—a principle still used today in many telescopes.
When Cambridge University reopened in 1667, Isaac Newton returned to do a Masters Degree, while teaching and doing research.
André-Marie Ampère
*The French physicist and mathematician
*He is mainly credited for laying down the basis of electrodynamics (now known as electromagnetism).
*His name endures in everyday life in the ampere, the unit for measuring electric current.
* His father, Jean-Jacques Ampère, was an affluent businessman and local government official.
* His father gave him Latin lessons and encouraged him to pursue his passion for mathematics.
*He took his first regular job in 1799 as a modestly paid mathematics teacher, which gave him the financial security to marry and be a father of his first child, Jean-Jacques, the next year.
*In 1802, he was appointed a professor of physics and chemistry at the École Centrale in Bourg-en-Bresse.
Foundation of Electrodynamics
On September 11, 1820, Ampere heard of Oersted's discovery that a magnetic needle is acted on by a current. A week later, he presented a full paper to the Academy about his own findings. He demonstrated that parallel wires carrying currents either attract or repel each other depending whether currents are in the same or in opposite directions. This laid the groundwork for the science of
electrodynamics or electromagnetism.
James Watt
*The quadrants lying about his father's carpenter's shop led him to the study of optics and astronomy; his ill health induced him to pry into the secrets of physiology; and his solitary walks through the country attracted him to the study of botany and history.
*While carrying on the business of a mathematical-instrument maker, he received an order to build an organ; and, though without an ear for music, he undertook the study of harmonics, and successfully constructed the instrument.
*He was born in Greenock, Scotland, in 1736
*At the age of nineteen, he was sent to Glasgow to learn the trade of a mathematical-instrument maker.
*He was engaged in the improvement of harbors and in the deepening of the Forth, Clyde and other rivers in Scotland.
*In 1755, he had been granted a patent by Parliament that prevented anybody else from making a steam-engine like the one he had developed.
*His grandfather, Thomas Watt, was a well known
mathematician and local schoolmaster
* was born in Pisa Italy
*the first of six children of Vincenzo Galilei, a famous composer, and Giulia Ammannati. Four of their six children survived infancy, and the youngest Michelangelo also became a noted composer.
*Although he seriously considered the priesthood as a young man, he enrolled for a medical degree at the University of Pisa at his father's urging. He did not complete this degree, but instead studied mathematics.*the first of six children of Vincenzo Galilei, a famous composer, and Giulia Ammannati. Four of their six children survived infancy, and the youngest Michelangelo also became a noted composer.
*Discovered the phases of Venus, the four satellites of Jupiter Io, Europa, Callisto, and Ganymede.
*He taught geometry, mechanics and astronomy at the University of Padua from 1592 to 1610.*He was one of the first people to observe sunspots, which helped develop the predictions that would help identify the annual patterns.
*According to his notes, he observed the planet Neptune in 1612, but did not recognize it as a planet. He thought it was simply another dim star.
*His formulation of (circular) inertia, the law of falling bodies, and parabolic trajectories marked the beginning of a fundamental change in the study of motion.
*In the fall of 1609, he began observing the heavens with instruments that magnified up to 20 times.
*He became blind at the age of 72. His blindness has often been attributed to damage done to his eyes by telescopic observations he made .The truth is he was blinded by a combination of cataracts and glaucoma. Galileo died at Arcetri in 1642, the year Isaac Newton was born leaving behind his resourceful creations.
*He became blind at the age of 72. His blindness has often been attributed to damage done to his eyes by telescopic observations he made .The truth is he was blinded by a combination of cataracts and glaucoma. Galileo died at Arcetri in 1642, the year Isaac Newton was born leaving behind his resourceful creations.
Heinrich Hertz
* a German physicist
*He was born in 1857 and died of blood poisoning in 1894 at the age of 37
*He applied Maxwell's theories to the production and reception of radio waves. In recognition of his work, the unit of frequency of a radio wave -- one cycle per second -- is named the Hertz.
*He was born in 1857 and died of blood poisoning in 1894 at the age of 37
*He applied Maxwell's theories to the production and reception of radio waves. In recognition of his work, the unit of frequency of a radio wave -- one cycle per second -- is named the Hertz.
* In 1888, in a corner of his physics classroom at the Karlsruhe Polytechnic in Berlin, he generated electric waves by means of the oscillatory discharge of a condenser through a loop provided with a spark gap, and then detecting them with a similar type of circuit. Hertz's condenser was a pair of metal rods, placed end to end with a small gap for a spark between them. When these rods were given charges of opposite signs, strong enough to spark, the current would oscillate back and forth across the gap and along the rods. With this oscillator, Hertz solved two problems: 1) timing Maxwell's waves (he had demonstrated, in the concrete, what Maxwell had only theorized: that the velocity of radio waves was equal to the velocity of light), and 2) how to make the electric and magnetic fields detach themselves from wires and go free as Maxwell's waves.
* Discovered radio waves and photoelectric effect.
Robert Hooke
*British natural philosopher, architect and polymath
*perhaps the most neglected natural philosophers of all time despite the significant role he played in the scientific revolution
*His father was the minister of the Church of England.
*At the age of thirteen young Hooke was able to enter Westminster School, and from there went to Oxford, where some of the finest scientists in England were working at the time.
* He was appointed as a chemical assistant to Dr Thomas Willis and later met the natural philosopher Robert Boyle, and gained a position as his assistant from about 1655 to 1662.
Hooke’s law
~ law of elasticity discovered by the English scientist Robert Hooke in 1660, which states that, for relatively small deformations of an object, the displacement or size of the deformation is directly proportional to the deforming force or load. Under these conditions the object returns to its original shape and size upon removal of the load. Elastic behaviour of solids according to Hooke’s law can be explained by the fact that small displacements of their constituent molecules, atoms, or ions from normal positions is also proportional to the force that causes the displacement.
Christian Huygens
-- a Dutch physicist, mathematician, astronomer, and inventor who was the leading proponent of the wave theory of light.
-- He also made important contributions to mechanics, stating that in a collision between bodies, neither loses nor gains "motion'' (his term for momentum).
-- In 1654, his attention was directed to the improvement of the telescope. Together with his brother, Christian Huygens devised a new and better way of grinding and polishing lenses. As a result of these improvements, Huygens was able during 1655 and 1656 to resolve numerous astronomical questions of the day including the fact that Saturn's rings were made of rocks and the presence of Titan.
-- In 1656, Huygens invented the first pendulum clock, as described in his 1658 article "Horologium". The time-pieces previously in use had been balance-clocks, Chris Huygens' pendulum clock was regulated by a mechanism with a "natural" period of oscillation and had an error of less than 1 minute a day, the first time such accuracy had been achieved. His later refinements reduced his clock's errors to less than 10 seconds a day.
James Prescott Joule
*He was born at Salford, near Manchester, England, on December 24, 1818.
*He was the second of five children born to a wealthy brewery owner.
*He initially was educated at home, before being tutored, at the age of sixteen, by the eminent Manchester scientist John Dalton.
*When their father became ill, James and his brother took over running the brewery.
*In 1839, he began a series of experiments involving mechanical work, electricity and heat.
*He was influenced by the thinking of Franz Aepinus and tried to explain the phenomena of electricity and magnetism in terms of atoms surrounded by a "calorific ether in a state of vibration".
*He died at home in Sale and is buried in Brooklands cemetery there.
Joule's major contributions to physics were in proving that energy can neither be created or destroyed, finding the mechanical equivalent of heat, and discovering Joule's law. The idea of conservation of energy was proved by Joule in a series of experiments. In his early years Joule proved that heat produced in a small electromagnet built by him was from electrical energy which was in turn generated by mechanical energy which powered the dynamo. From this experiment Joule concluded that the heat produced in the electromagnet was energy which came directly from the human effort that went into the machine.
In an effort to quantify mechanical work, Joule used a brass paddle wheel which was turned by falling weights, which possessed potential energy because of their position. As they fell, they lost their potential energy, which in turn provided kinetic energy to the wheel. As the paddle wheel turned, it stirred the water in a copper tub. By noting that there was a rise in the temperature of the water every time a weight fell, and by relating the rise to the falling weights, Joule was able to claim that the mechanical energy from the falling weights was being converted to heat energy in the water. He proved that the quantity of heat capable of increasing the temperature of a pound of water by 1 degree Fahrenheit requires the expenditure of a mechanical energy represented by the fall of 772 pounds through the space of one foot. Joule showed through his research, that work can be converted to heat with a fixed conversion ratio of one to the other and vice versa. His principle of Conservation of Energy became the first law of Thermodynamics, a field of physics that Joule is often referred to as the chief founder of.
James Prescott Joule
*He was born at Salford, near Manchester, England, on December 24, 1818.
*He was the second of five children born to a wealthy brewery owner.
*He initially was educated at home, before being tutored, at the age of sixteen, by the eminent Manchester scientist John Dalton.
*When their father became ill, James and his brother took over running the brewery.
*In 1839, he began a series of experiments involving mechanical work, electricity and heat.
*He was influenced by the thinking of Franz Aepinus and tried to explain the phenomena of electricity and magnetism in terms of atoms surrounded by a "calorific ether in a state of vibration".
*He died at home in Sale and is buried in Brooklands cemetery there.
Joule's major contributions to physics were in proving that energy can neither be created or destroyed, finding the mechanical equivalent of heat, and discovering Joule's law. The idea of conservation of energy was proved by Joule in a series of experiments. In his early years Joule proved that heat produced in a small electromagnet built by him was from electrical energy which was in turn generated by mechanical energy which powered the dynamo. From this experiment Joule concluded that the heat produced in the electromagnet was energy which came directly from the human effort that went into the machine.
Monday, July 18, 2011
Definition of Physics
1.(used with a sing. verb) The science of matter and energy and of interactions between the two, grouped in traditional fields such as acoustics, optics, mechanics, thermodynamics, and electromagnetism, as well as in modern extensions including atomic and nuclear physics, cryogenics, solid-state physics, particle physics, and plasma physics.
2.used with a pl. verb) Physical properties, interactions, processes, or laws: the physics of supersonic flight.
3.(used with a sing. verb) Archaic The study of the natural or material world and phenomena; natural philosophy.
4.The scientific study of matter, energy, space, and time, and of the relations between them.
5.The behavior of a given physical system, especially as understood by a physical theory.
2.used with a pl. verb) Physical properties, interactions, processes, or laws: the physics of supersonic flight.
3.(used with a sing. verb) Archaic The study of the natural or material world and phenomena; natural philosophy.
4.The scientific study of matter, energy, space, and time, and of the relations between them.
5.The behavior of a given physical system, especially as understood by a physical theory.
Subscribe to:
Posts (Atom)