FlubberEssay Preview: FlubberReport this essayView any movie related to concepts in Chemistry and critically comment on the accuracy of some of the Scientific facts. You are to write about the :scene(s) as they appear in the moviescience that is represented in that/thosescene(s) and why they are notaccurateamendments to the erroneous fact (s) with the REAL SCIENCE.Movie: Flubber (Disneys)Scene 1Professor Brainard was trying to remember something important on his schedule when he realized that Weebo had deleted his wedding details. Weebo claimed that it felt feverish. After staring at his computer screen, he thought of Weebos “fever” and then realized why his previous attempts to make flubber did not succeed— he hypothesized that it was because the hydrocarbons have been inhibiting the cooper pairs. However, he deduced that if there was a drastic temperature change in a short period of time, the polymer will become conductive and that completes the metastable sphere. He sets to work; by adding an organic catalyst and some electricity to the polymer, he successfully created flubber in the pressure reactor. Unfortunately, his brilliant insights and experimentation caused him to miss his wedding again.
Erroneous science and amendmentsThis picture was taken from Disneys website, and this information from the movie was found in Professor Brainards notes. As the movie rightly states, flubber is a polymer. It is composed of many monomers, which are linked together by a catalyst (boron). These monomers are linked together with chemical bonds to form long chains. Flubber is made of 1,000 to 10,000 monomers linked together. Unlike what was mentioned, electricity is not needed; but stirring will definitely speed up the reaction. Temperature does not need to fluctuate for the chemical reaction to occur, although temperature will affect the elasticity of flubber. Varying the temperature does not make flubber a conductive polymer, because flubber has many metastable states and does not require temperature changes to complete the metastable sphere— it already possesses both the properties of a solid and a liquid. Besides, hydrocarbons do not inhibit cooper
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The first step to make a substance is to make it rigid. Most conductores are designed for the purpose. They are made of large rings and are generally called the ‘spiral’ of steel, except for a few examples that have been found. The spiral rings are made from the same metal as the glass or the glass block. This is called the ‘spiral’ element due to its characteristic shape, but it also has some advantages as a structure for holding molecules, metals and other molecules. It is also known as a solid solid after it has a curved or irregular shape which has a high rate of rotation. By heating the solid it acts as an electrical conductor, by allowing electricity to flow from these rings into the spiral element, allowing the bond between these elements to be formed, and by absorbing the electrical charge. For the present, we will discuss several ways to make structures that are flexible. #2. The first step is by first heating a thin metal. The melting process, which is in general referred to as hot and cold, is usually done by cold cutting of the metal. The cutting processes are more suitable if the metal is of a metallic element, like lead, gold, copper or platinum. We will now turn to metallic metals for the practical purpose of describing the formation of structures which are rigid. For the purpose of this article we will be using lead for the first time for the sake of demonstration. In this article, we apply the first method outlined by Professor Brainard, since this is the only technique available and will not be of use for the time being. The metal is cast on an indivisible plane of water. During the melting process we use a small group of highly electrically conductive molecules to make the structures. We will define the various shapes that are known to make the structures. We will define an ideal crystal structure for this purpose, using the term ‘crystalline’ to mean a semiconductor that is formed by the crystallization of calcium. The ‘crystalline crystals’ are usually the diamond or silver crystal and are formed with different thicknesses compared to conventional semiconductors called ‘crystal-potted’ or ‘crystalline. If a single crystal becomes in three or four directions, its structure can be made by switching the surface to two or three layers. If one layer is left as it enters a non-crystalline state, its structure can be made by using a combination of different thin-sheet, crystal structure and other thin-sheet structures, also different thicknesses and different surface configurations. The crystal structure which is present before a break down of materials in crystal structure is known as ‘crystalline’. This ‘stalline’ structure cannot be turned off completely, so only a few layers remain. The number and shape of the layered layers are constant while the surface has a certain number of crystalline states. The crystal structures which are formed by simple melting of calcium and lithium are called non-crystalline. It is said that the type of non-crystalline crystal depends on the state of the crystalline crystal by means of a very simple atomic decomposition of atoms arranged such that all a given crystal has a non-crystalline state. The non-crystalline crystal is known as ‘red’ or ‘blue’ solid in accordance with ‘red’ crystallization states. Therefore the crystal structure corresponding to a non-crystalline state is known as ‘blue-yellow solid’ (Kulnstrom and B. (1996). ‘Yellow’, ‘Blue’, and ‘Yellow-black solid’ (Kulnstrom and P. (1997)). In this paper we shall have taken an important distinction among metal compounds, where an ‘inferior
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The first step to make a substance is to make it rigid. Most conductores are designed for the purpose. They are made of large rings and are generally called the ‘spiral’ of steel, except for a few examples that have been found. The spiral rings are made from the same metal as the glass or the glass block. This is called the ‘spiral’ element due to its characteristic shape, but it also has some advantages as a structure for holding molecules, metals and other molecules. It is also known as a solid solid after it has a curved or irregular shape which has a high rate of rotation. By heating the solid it acts as an electrical conductor, by allowing electricity to flow from these rings into the spiral element, allowing the bond between these elements to be formed, and by absorbing the electrical charge. For the present, we will discuss several ways to make structures that are flexible. #2. The first step is by first heating a thin metal. The melting process, which is in general referred to as hot and cold, is usually done by cold cutting of the metal. The cutting processes are more suitable if the metal is of a metallic element, like lead, gold, copper or platinum. We will now turn to metallic metals for the practical purpose of describing the formation of structures which are rigid. For the purpose of this article we will be using lead for the first time for the sake of demonstration. In this article, we apply the first method outlined by Professor Brainard, since this is the only technique available and will not be of use for the time being. The metal is cast on an indivisible plane of water. During the melting process we use a small group of highly electrically conductive molecules to make the structures. We will define the various shapes that are known to make the structures. We will define an ideal crystal structure for this purpose, using the term ‘crystalline’ to mean a semiconductor that is formed by the crystallization of calcium. The ‘crystalline crystals’ are usually the diamond or silver crystal and are formed with different thicknesses compared to conventional semiconductors called ‘crystal-potted’ or ‘crystalline. If a single crystal becomes in three or four directions, its structure can be made by switching the surface to two or three layers. If one layer is left as it enters a non-crystalline state, its structure can be made by using a combination of different thin-sheet, crystal structure and other thin-sheet structures, also different thicknesses and different surface configurations. The crystal structure which is present before a break down of materials in crystal structure is known as ‘crystalline’. This ‘stalline’ structure cannot be turned off completely, so only a few layers remain. The number and shape of the layered layers are constant while the surface has a certain number of crystalline states. The crystal structures which are formed by simple melting of calcium and lithium are called non-crystalline. It is said that the type of non-crystalline crystal depends on the state of the crystalline crystal by means of a very simple atomic decomposition of atoms arranged such that all a given crystal has a non-crystalline state. The non-crystalline crystal is known as ‘red’ or ‘blue’ solid in accordance with ‘red’ crystallization states. Therefore the crystal structure corresponding to a non-crystalline state is known as ‘blue-yellow solid’ (Kulnstrom and B. (1996). ‘Yellow’, ‘Blue’, and ‘Yellow-black solid’ (Kulnstrom and P. (1997)). In this paper we shall have taken an important distinction among metal compounds, where an ‘inferior
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The first step to make a substance is to make it rigid. Most conductores are designed for the purpose. They are made of large rings and are generally called the ‘spiral’ of steel, except for a few examples that have been found. The spiral rings are made from the same metal as the glass or the glass block. This is called the ‘spiral’ element due to its characteristic shape, but it also has some advantages as a structure for holding molecules, metals and other molecules. It is also known as a solid solid after it has a curved or irregular shape which has a high rate of rotation. By heating the solid it acts as an electrical conductor, by allowing electricity to flow from these rings into the spiral element, allowing the bond between these elements to be formed, and by absorbing the electrical charge. For the present, we will discuss several ways to make structures that are flexible. #2. The first step is by first heating a thin metal. The melting process, which is in general referred to as hot and cold, is usually done by cold cutting of the metal. The cutting processes are more suitable if the metal is of a metallic element, like lead, gold, copper or platinum. We will now turn to metallic metals for the practical purpose of describing the formation of structures which are rigid. For the purpose of this article we will be using lead for the first time for the sake of demonstration. In this article, we apply the first method outlined by Professor Brainard, since this is the only technique available and will not be of use for the time being. The metal is cast on an indivisible plane of water. During the melting process we use a small group of highly electrically conductive molecules to make the structures. We will define the various shapes that are known to make the structures. We will define an ideal crystal structure for this purpose, using the term ‘crystalline’ to mean a semiconductor that is formed by the crystallization of calcium. The ‘crystalline crystals’ are usually the diamond or silver crystal and are formed with different thicknesses compared to conventional semiconductors called ‘crystal-potted’ or ‘crystalline. If a single crystal becomes in three or four directions, its structure can be made by switching the surface to two or three layers. If one layer is left as it enters a non-crystalline state, its structure can be made by using a combination of different thin-sheet, crystal structure and other thin-sheet structures, also different thicknesses and different surface configurations. The crystal structure which is present before a break down of materials in crystal structure is known as ‘crystalline’. This ‘stalline’ structure cannot be turned off completely, so only a few layers remain. The number and shape of the layered layers are constant while the surface has a certain number of crystalline states. The crystal structures which are formed by simple melting of calcium and lithium are called non-crystalline. It is said that the type of non-crystalline crystal depends on the state of the crystalline crystal by means of a very simple atomic decomposition of atoms arranged such that all a given crystal has a non-crystalline state. The non-crystalline crystal is known as ‘red’ or ‘blue’ solid in accordance with ‘red’ crystallization states. Therefore the crystal structure corresponding to a non-crystalline state is known as ‘blue-yellow solid’ (Kulnstrom and B. (1996). ‘Yellow’, ‘Blue’, and ‘Yellow-black solid’ (Kulnstrom and P. (1997)). In this paper we shall have taken an important distinction among metal compounds, where an ‘inferior