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Why are the results of Rutherford's gold foil experiment more consistent with a nuclear model of the atom than with the chocolate chip cookie dough model?
This may start you on the path. It is a simple explanation I developed for a 5th-grade lesson on how scientists use similes. At the time Rutherford was working, scientists had discovered that there were two parts of an atom: protons and electrons. They also knew that protons were much bigger than electrons. A scientist named Thomsen said he thought atoms were like chocolate chip cookies. The protons were like cookie dough, and electrons were mixed in like Chocolate Chips. Rutherford decided to test this idea. He said that if atoms were like Chocolate Chip Cookies, you could make a wall of atoms - like you could built a wall of chocolate chip cookies -- and shine a beam like a light through them, and the beam wouldn't get through. So he tried in an experiment. He didn't use chocolate chip cookies. Instead he used a really thin sheet of gold, made to be as close to one atom thick as he could. But he found out that when he shone the beam at the gold sheet, most of it went straight through the gold and came out the other side. So atoms could not be like chocolate chip cookies. In fact, atoms seemed mostly to be empty space. So Mr. Rutherford tried to imagine what an atom would look like if it were mostly empty space. He thought of another simile. What if atoms were like the solar system? The sun is much bigger than the planets, like protons are much bigger than neutrons. What if atoms were like really tiny solar systems, with electrons orbiting around a clump of protons in the middle? This explanation would match the results of his experiment. Many years later, other experiments have shown similar results. So now, instead of thinking of atoms as chocolate chip cookies, we think of them as tiny solar systems. This answer can be demonstrated by building a wall of cookies with toothpicks. Shine a flashlight, and light will only come through the cracks. However, in Rutherford's experiment, most of the beam (I believe he used gamma rays) went through and hit the reactive film behind the gold. Now imagine a mobile with "suns" made of ping-pong balls and "planets" made of jelly beans set on toothpicks. (I'm not a millionaire. I have to work with the materials I have.) When you shine a flashlight through the "solar systems" of the nuclear model, most of the light goes right through, as they did in Rutherford's experiment with gold. Based on his experiment, Rutherford decided that atoms are not thickly packed together like rows of cookies. Instead, like our solar system, atoms are mostly made up of empty space. Since we are made of atoms, and atoms are mostly empty space, why doesn't light shine through us? The answer is that we are a _lot_ of atoms think. While sun can shine around one leaf, a tree with many leaves arranged in offset layers blocks the light of the sun to create shade. In this example, the leaves are individual atoms, and the many leaves of the tree are like the many atoms in our bodies. This may start you on the path. It is a simple explanation I developed for a 5th-grade lesson on how scientists use similes. At the time Rutherford was working, scientists had discovered that there were two parts of an atom: protons and electrons. They also knew that protons were much bigger than electrons. A scientist named Thomsen said he thought atoms were like chocolate chip cookies. The protons were like cookie dough, and electrons were mixed in like chocolate chips. Rutherford decided to test this idea. He said that if atoms were like chocolate chip cookies, you could make a wall of atoms - like you could built a wall of chocolate chip cookies -- and shine a beam like a light through them, and the beam wouldn't get through. So he tried in an experiment. He didn't use chocolate chip cookies. Instead he used a really thin sheet of gold, made to be as close to one atom thick as he could. But he found out that when he shone the beam at the gold sheet, most of it went straight through the gold and came out the other side. So atoms could not be like chocolate chip cookies. In fact, atoms seemed mostly to be empty space. So Mr. Rutherford tried to imagine what an atom would look like if it were mostly empty space. He thought of another simile. What if atoms were like the solar system? The sun is much bigger than the planets, like protons are much bigger than neutrons. What if atoms were like really tiny solar systems, with electrons orbiting around a clump of protons in the middle? This explanation would match the results of his experiment. Many years later, other experiments have shown similar results. So now, instead of thinking of atoms as chocolate chip cookies, we think of them as tiny solar systems. This answer can be demonstrated by building a wall of cookies with toothpicks. Shine a flashlight, and light will only come through the cracks. However, in Rutherford's experiment, most of the beam (I believe he used gamma rays) went through and hit the reactive film behind the gold. Now imagine a mobile with "suns" made of ping-pong balls and "planets" made of jelly beans set on toothpicks. (I'm not a millionaire. I have to work with the materials I have.) When you shine a flashlight through the "solar systems" of the nuclear model, most of the light goes right through, as they did in Rutherford's experiment with gold. Based on his experiment, Rutherford decided that atoms are not thickly packed together like rows of cookies. Instead, like our solar system, atoms are mostly made up of empty space. Since we are made of atoms, and atoms are mostly empty space, why doesn't light shine through us? The answer is that we are a _lot_ of atoms think. While sun can shine around one leaf, a tree with many leaves arranged in offset layers blocks the light of the sun to create shade. In this example, the leaves are individual atoms, and the many leaves of the tree are like the many atoms in our bodies. Edited to add my information in case someone finds this useful.
What else can I help you with?
What did rutherfords gold foil experiment demonstrate?
Rutherford's gold foil experiment demonstrated the existence of the atomic nucleus and that it is densely packed in the center of the atom. This experiment led to the development of the nuclear model of the atom, which replaced the plum pudding model. It also showed that most of the atom is empty space.
Rutherfords gold foil experiment showed that the atomic nucleus is?
very small relative to size of whole atomextremely densehighly positively charged
Will you consider rutherfords gold foil experiment important?
Yes, Rutherford's gold foil experiment was important as it provided evidence that atoms have a small, dense nucleus at their center, leading to the development of the nuclear model of the atom. This experiment also contributed to our understanding of atomic structure and helped pave the way for further discoveries in the field of nuclear physics.
What did Ernest Rutherfords gold foil experiment demonstrate about an atom?
Ernest Rutherford's gold foil experiment demonstrated that atoms have a small, dense nucleus at their center that contains positively charged protons. This nucleus is surrounded by mostly empty space where negatively charged electrons are found orbiting. This experiment led to the development of the nuclear model of the atom.
What was rutherfords experiment?
he shot tiny alpha particles throug a piece of gold foil. -Apex
Who discovered the nuclear atom?
The nuclear atom was discovered by Ernest Rutherford. He did it with a gold foil experiment.
How did Rutherfords gold foil experiment tell scientists about the atomic structure?
Rutherford's gold foil experiment showed that atoms have a small, dense positively charged nucleus at their center, with most of the atom consisting of empty space. This led to the development of the nuclear model of the atom, where electrons orbit the nucleus. The experiment also suggested that the positive charge of the nucleus is concentrated in a small volume, explaining why most alpha particles passed through the foil undeflected.
What conclusion about the atom came from Ernest Rutherfords famous gold foil experiment?
The conclusions were that the nucleus in an atom must:- (1) Be positive as it repelled the positive alpha-particles (2) Have a high mass, as the deflections were massive (3) Be very small as only a few of the particles were deflected
How do use the words nuclear energy in a sentence?
there was nuclear energy in the science experiment
How did ernest rutherfords discovery help people?
Ernest Rutherford's discovery of the atomic nucleus in 1911 revolutionized our understanding of the structure of atoms, leading to the development of nuclear physics. This discovery paved the way for advancements in nuclear energy, medicine (e.g., radiation therapy), and technology (e.g., nuclear reactors). It continues to contribute to various fields, from energy production to scientific research.
What is the useful of counting statistics experiment in nuclear lab?
Counting statistics experiments in nuclear lab helps with science. This helps learn of numbers and measurements.
In Rutherfords gold foil experiment some of the aimed at gold atoms bounced back suggesting that a solid mass was at the center of the atom?
In Rutherford's gold foil experiment, some of the Alpha particles aimed at gold atoms bounced back, suggesting that a solid mass was at the center of the atom.They suggested that most of the mass of the atom is concentrated at the center and the center is positively charged.
