10 Albert Einstein Quotes To Inspire Students
7 Physicists Who Were Also Great Musicians
Brian May:
Albert Einstein:
Max Planck:
Brian Cox:
Richard Feynman:
Satyendra Nath Bose:
Werner Heisenberg:
Heisenberg could read sheet music when only 4 years old, so it is said that he was a prodigy. Heisenberg’s parents wanted him to become a concert pianist - however - his love of physics outgrew his love of music. Heisenberg's work in physics irked Einstein to such an extent that he commented, “God does not play dice with the Universe”.
Who Proposed The Idea of Black Hole?
When will black hole form
Birth of black hole
Cut to present
10 differences between astrology and astronomy
1. Every newspaper in the world has a daily column on astrology. How many papers carry even a weekly column on astronomy? – this is a major, disappointing difference between the two fields, as pointed out by Carl Sagan.
2. Astronomy is a practical science built upon technical skills such as in observation, mathematics and computer programming. Astrology does not demand such complicated knowledge.
3. If you delete all of human history, astronomy will come up again in exactly the same manner since it is based upon facts and figures. Whereas, astrology is a product of the human imagination and will acquire different shapes and forms.
4. There is a Nobel Prize for astronomers who make great advances to our understanding of the universe – astronomy being a branch of physics. In astrology, there is no such honor.
5. According to astrology, the position of a planet such as Saturn can trigger a life changing influence on an individual located on some corner of the Earth. Astronomy denies this claim.
6. After decades of research, astronomy has reached to the conclusion that life on earth is made from elements that were forged in the core of dying stars – a poetically beautiful truth. Astrology could not have reached to this sophisticated result.
7. Historians say that astrology is 2,500 years old. On the contrary, astronomy is vastly older. The first human beings depended on astronomical events for various activities, such as in agriculture and navigation. This developed into questions like, "What's out there?" and into inventions like the telescope.
8. Hence, astronomy is a natural tendency (aka curiosity) whereas astrology is derived, from observations and results in astronomy. Astrology is something that people turn to thinking it would have answers to life's problems.
9. Astronomy is a healthy activity for kids to get involved in. Astrophotography is one way to get started. Whereas, a sincere belief in astrology puts children inside boxes and they grow up asking dumb questions like, "What's your star sign?" to measure compatibility.
10. Reading astrology may be comforting to some people, but at only a superficial level. On the contrary, astronomy appeals to the very core of a person and may inspire them to paint a timeless piece like the "starry night".
Five Quotes By Freeman Dyson On Religion
5. Over periods of 10,000 years the distinctions between Western and Eastern and African cultures lose all meaning. Over a time span of 100,000 years we are all Africans. And over a time span of 300 million years we are all amphibians, waddling uncertainly out of dried-up ponds onto the alien and hostile land.
5 Science Quotes By Robert Oppenheimer
Robert Oppenheimer was an American physicist who is often called the father of the atomic bomb. Despite making significant contributions to the fields of quantum mechanics and astrophysics, Oppenheimer is famously remembered for his role in the Manhattan project.
From an early age, Oppenheimer was interested in arts and sciences. He wrote poetry and enjoyed solving physics problems. In a letter to his bother, dated 14 October 1929 Oppenheimer admitted: "It is occasionally true, that I need physics more than friends."
Oppenheimer is also known as a defender and promoter of science in the post war world. He toured Europe and Asia, giving lectures on the history of science, the role of science in society and the nature of the universe.
Regarding his part in the Los Alamos laboratory, Oppenheimer said: "You cannot stop such a thing if you are a scientist. It is good to find out how the world works. It is good to turn over to mankind the greatest possible power to control the world, and to deal with it according to its lights and its values."
At the same time, Oppenheimer was aware of the increasing political misuse of scientific discoveries, which is why, he joined Albert Einstein and Bertrand Russell in establishing the World Academy of Art and Science. It was started to discuss the major concerns of humanity.
Following are five quotes by J. Robert Oppenheimer on science:
1. Science is not everything, but science is very beautiful. (last published words, 1966)
2. There is no place for dogma in science. The scientist is free, and must be free to ask any question, to doubt any assertion, to seek for any evidence, to correct any errors. (1949)
3. Science is the basis for radically new technological developments. Most people, when they think of science as a good thing, when they think of it as worthy of encouragement, have in mind that the conditions of their life have been altered just by such technology, of which they may be reluctant to be deprived. (1948)
4. It is a profound and necessary truth that the deep things in science are not found because they are useful; they are found because it was possible to find them.
5. Science starts with a preconception, with common sense. It moves on to observation, is marked by the discovery of paradox, and is then concerned with the correction of preconception. It moves then to further observation and for more refined experiment. (1958)
Oppenheimer was a polymath who obtained a PhD degree aged only 23, under the guidance of physicist Max Born. He served as the director of the Institute for Advanced Study in Princeton, where Einstein was a resident scholar.
Under his directorship, Oppenheimer brought together the most brilliant minds of his time such as Bohr, Fermi, Dirac, Bethe and Feynman. In 1963, Oppenheimer was recognized by the president of United States with Enrico Fermi award.
A biographical film by Christopher Nolan is scheduled to be released this year, starring actor Cillian Murphy as Robert Oppenheimer. It is based on the book, American Prometheus: The Triumph and Tragedy of J. Robert Oppenheimer.
Who Was Alexander Friedmann?
Not only that, Friedmann also gave lectures on aeronautics for pilots and flew aircraft during the first world war. His students included such distinguished scientists as George Gamow and Vladimir Fock.
Early years
Friedmann received a bachelor's degree in 1910 and quickly joined Saint Petersburg Mining Institute as a lecturer.
Training
His love of the pure sciences encouraged Friedmann to exchange letters, while fighting the war, with mathematician Vladimir Steklov – a friend from college days, in order to stay updated on new activities in the world of physics.
A new theory
In June of 1922, Friedmann introduced his own idea that the entire universe’s curvature could be a function of time.
Revolt
Summing up
Friedmann received many honors after death, including a crater on the Moon which is named after him. Also, a prestigious Friedmann Prize is awarded once every three years to a single scientist for outstanding work done in cosmology.
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Five Quotes By Stephen Hawking On Religion
5 Niels Bohr Quotes On Quantum Mechanics
Niels Bohr was a Danish physicist who made pioneering contributions to understanding atomic structure and quantum theory, for which Bohr was recognized with a Nobel Prize in 1922. Bohr was an active participant in the new quantum theory revolution that shook the foundations of classical physics.
Einstein, who was not ready to accept Heisenberg's uncertainty principle, as one of the cornerstones of modern physics, commented: God does not play dice with the universe. Bohr made peace with the uncertainty principle by developing the principle of complementarity.
According to complementarity, particles have certain pairs of interdependent properties that cannot all be observed or measured simultaneously. For example: position and momentum make such a pair.
Bohr regarded complementarity as an essential feature of quantum mechanics. It is said that Bohr replied to Einstein, who preferred the determinism of classical physics over the probabilistic new quantum physics: (1) "Stop telling God what to do."
In 1920, Bohr met Heisenberg for the first time. Bohr said, (2) What is it that we humans depend on? We depend on our words... Our task is to communicate experience and ideas to others. But when it comes to atoms, language can be used only as in poetry. The poet, too, is not nearly so concerned with describing facts as with creating images and establishing mental connections.
Some physicists depended on mathematical analysis to make sense of the quantum world. However, Bohr was not satisfied. (3) Even the mathematical framework helps nothing, I (Bohr) would first like to understand how Nature avoids the contradictions. (1927)
Bohr said further: Our experience in recent years has brought light to the insufficiency of our simple mechanical conceptions and, as a consequence, has shaken the foundation on which the customary interpretation of observation was based.
We can still use the objectifying language of classical physics to make statements about observable facts. But we can say nothing about the atoms themselves.
In the 1927 Solvay conference, Bohr and Einstein went head-to-head on the metaphysical and philosophical implications of quantum mechanics. Two legends, one defending the new-age probabilistic physics and another fighting for classical determinism. At the end, it was Bohr who emerged victorious and successfully established the probabilistic character of quantum measurement.
Niels Bohr wrote in 1934: (4) Isolated material particles are abstractions, their properties being definable and observable only through their interaction with other systems. Everything we call real is made of things that cannot be regarded as real.
In a 1952 conversation with Heisenberg and Pauli in Copenhagen, Bohr quipped: (5) "Those who are not shocked when they first come across quantum theory cannot possibly have understood it." This was most likely a reference to Einstein, who not only contributed to the new theory but also immediately taken aback by its bizarre results.
Richard Feynman Explains The Circle of Life
Nobel prize winning American scientist, Richard Feynman, was fascinated by simple things. From rubber band to fire, Feynman was delighted to explain the physics of day to day items in easy and poetic language. Here, Feynman described the life cycle of a tree as an example to illustrate that life comes full circle.
Where does the structure of the tree come from? To find out, we must start at the beginning. It is understood that seed sown in the ground will develop shoot of the plant, as it reaches out for the sunlight. At the same time, a root spreads deep in the soil searching for water.
Capillary action helps bring water up into the roots when the soil has higher concentration of water than the root cells. It is like putting a wick in oil lamp. But capillary action can only pull water up a small distance, when the plant is small.
In a mature tree, liquid water flows into the woody stem and then into green leaves where photosynthesis will occur. How does it work against the effects of gravity? The answer is cohesive forces that help to move water to the furthest leaf.
In the green leaves, some part of the water is used for photosynthesis. The other part, due to heat from sunlight, escapes into the atmosphere as water in gaseous form. In fact, if you wrap a plastic bag around a leaf, you can actually see vapor condense inside the bag.
Since molecules of water in the root and stem stick tightly to one another because of cohesion, the vapors which escape from the leaves, kind of pull the remaining water, as a single unit, upward behind them. This process is called transpiration.
Going back to, where does the structure of the tree come from? Feynman comments: it is generally thought that plants grow out of the ground. However, apart from water and vital nutrients, the ground does not contribute in the building up of the tree.
Mass of the tree is primarily carbon and where does that come from? The atmosphere, but not in pure form, it comes as carbon dioxide. (In its lifetime, a tree soaks up tons of carbon dioxide from the air, which is why it is advised to plant more trees).
The absorbed carbon dioxide is reduced to pure carbon when acted upon by the sunlight. Trees utilize these carbon molecules to construct their body tissues, for example in the stem. The useless oxygen molecules, on the other hand, are spit back into the air.
Thus, a combination of water, air and light as they come from the ground, atmosphere and sun respectively, mediate the flowering and growth of the tree.
There is a beautiful end to the story. The tree is used as a fuel for combustion. When pieces of wood are rubbed, for example, heat is built up by friction and that leads to reunification of carbon molecules in the tree with oxygen molecules in the air, generating a "tremendous catastrophe" as Feynman puts it, fire.
If you think about it, this light and heat of the fire is the light and heat of the sun, that went in! Feynman says: it is kind of a "stored sun", that is coming out when you burn a log. Isn't it wonderful how nature manages to come back in a full circle?