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  If I threw a $1\mathrm{.}0$ kg text book up into the air with a speed of $5\mathrm{.}0$ km$/$s$,$ what maximum height would it reach? The mass of the Earth is $5\mathrm{.}98$ x $10^24$ kg and its radius is $6\mathrm{.}3810^6$ m$.$My mass is about $86$ kg$.$ If I$\text{'}$m at rest on the surface of the Earth, what is my Binding Energy?If I climbed Mount Everest $($easy $-$ it is only $8848$ m high$)$ and stood still at the top, what would happen to my Binding Energy? Do the math, and then select the BEST SINGLE response below to complete the following: "During the climb $...$It wouldn't changeIt would decreaseIt would increaseIt would decrease by a very small amountIt would increase by a very small amountThe Moon has a mass of $7\mathrm{.}34$ x $10^22$ kg and a radius of $1\mathrm{.}74$ x $10^6$ m according to your textbook. What is the escape velocity for ANY object that is at rest on the surface of the Moon?What is the Gravitational Potential Energy of a $2000$ kg satellite on the surface of the Earth?What is the TOTAL energy of the same satellite when it is in ORBIT at an altitude $($or height$)$ of $550$ km above the Earth?How much Work must be done to put the satellite into this orbit? Another way of saying this: How much MORE energy does it need to get from the Earth to this orbit?What speed would the object need to have, at the surface of the Earth, to end up in orbit $550$ km above the Earth? That is$,$ how fast would the satellite need to be 'thrown' from Earth's surface to end up in the orbit we've described?Try it in one step! Et$1=$ Eto $-$ in order for the satellite to get into orbit it needs to have the same total energy at the surface of the earth, Et$1,$ as it does in orbit, Eto. Plug in the correct values and solve for v$1,$ the speed at the surface of the Earth. Do you get about $8200$ m$/$s$?$If I threw a $1\mathrm{.}0$ kg text book up into the air with a speed of $5\mathrm{.}0$ km$/$s$,$ what maximum height would it reach? The mass of the Earth is $5\mathrm{.}98$ x $10^24$ kg and its radius is $6\mathrm{.}3810^6$ m$.$My mass is about $86$ kg$.$ If I$\text{'}$m at rest on the surface of the Earth, what is my Binding Energy?If I climbed Mount Everest $($easy $-$ it is only $8848$ m high$)$ and stood still at the top, what would happen to my Binding Energy? Do the math, and then select the BEST SINGLE response below to complete the following: "During the climb $...$It wouldn't changeIt would decreaseIt would increaseIt would decrease by a very small amountIt would increase by a very small amountThe Moon has a mass of $7\mathrm{.}34$ x $10^22$ kg and a radius of $1\mathrm{.}74$ x $10^6$ m according to your textbook. What is the escape velocity for ANY object that is at rest on the surface of the Moon?What is the Gravitational Potential Energy of a $2000$ kg satellite on the surface of the Earth?What is the TOTAL energy of the same satellite when it is in ORBIT at an altitude $($or height$)$ of $550$ km above the Earth?How much Work must be done to put the satellite into this orbit? Another way of saying this: How much MORE energy does it need to get from the Earth to this orbit?What speed would the object need to have, at the surface of the Earth, to end up in orbit $550$ km above the Earth? That is$,$ how fast would the satellite need to be 'thrown' from Earth's surface to end up in the orbit we've described?Try it in one step! Et$1=$ Eto $-$ in order for the satellite to get into orbit it needs to have the same total energy at the surface of the earth, Et$1,$ as it does in orbit, Eto. Plug in the correct values and solve for v$1,$ the speed at the surface of the Earth. Do you get about $8200$ m$/$s$?$If I threw a $1\mathrm{.}0$ kg text book up into the air with a speed of $5\mathrm{.}0$ km$/$s$,$ what maximum height would it reach? The mass of the Earth is $5\mathrm{.}98$ x $10^24$ kg and its radius is $6\mathrm{.}3810^6$ m$.$My mass is about $86$ kg$.$ If I$\text{'}$m at rest on the surface of the Earth, what is my Binding Energy?If I climbed Mount Everest $($easy $-$ it is only $8848$ m high$)$ and stood still at the top, what would happen to my Binding Energy? Do the math, and then select the BEST SINGLE response below to complete the following: "During the climb $...$It wouldn't changeIt would decreaseIt would increaseIt would decrease by a very small amountIt would increase by a very small amountThe Moon has a mass of $7\mathrm{.}34$ x $10^22$ kg and a radius of $1\mathrm{.}74$ x $10^6$ m according to your textbook. What is the escape velocity for ANY object that is at rest on the surface of the Moon?What is the Gravitational Potential Energy of a $2000$ kg satellite on the surface of the Earth?What is the TOTAL energy of the same satellite when it is in ORBIT at an altitude $($or height$)$ of $550$ km above the Earth?How much Work must be done to put the satellite into this orbit? Another way of saying this: How much MORE energy does it need to get from the Earth to this orbit?What speed would the object need to have, at the surface of the Earth, to end up in orbit $550$ km above the Earth? That is$,$ how fast would the satellite need to be 'thrown' from Earth's surface to end up in the orbit we've described?Try it in one step! Et$1=$ Eto $-$ in order for the satellite to get into orbit it needs to have the same total energy at the surface of the earth, Et$1,$ as it does in orbit, Eto. Plug in the correct values and solve for v$1,$ the speed at the surface of the Earth. Do you get about $8200$ m$/$s$?$the air with a speed of $5\mathrm{.}0$ km$/$s$,$ what maximum height would it reach? The mass of the Earth is $5\mathrm{.}98$ x $10^24$ kg and its radius is $6\mathrm{.}3810^6$ m$.$My mass is about $86$ kg$.$ If I$\text{'}$m at rest on the surface of the Earth, what is my Binding Energy?If I climbed Mount Everest $($easy $-$ it is only $8848$ m high$)$ and stood still at the top, what would happen to my Binding Energy? Do the math, and then select the BEST SINGLE response below to complete the following: "During the climb $...$It wouldn't changeIt would decreaseIt would increaseIt would decrease by a very small amountIt would increase by a very small amountThe Moon has a mass of $7\mathrm{.}34$ x $10^22$ kg and a radius of $1\mathrm{.}74$ x $10^6$ m according to your textbook. What is the escape velocity for ANY object that is at rest on the surface of the Moon?What is the Gravitational Potential Energy of a $2000$ kg satellite on the surface of the Earth?What is the TOTAL energy of the same satellite when it is in ORBIT at an altitude $($or height$)$ of $550$ km above the Earth?How much Work must be done to put the satellite into this orbit? Another way of saying this: How much MORE energy does it need to get from the Earth to this orbit?What speed would the object need to have, at the surface of the Earth, to end up in orbit $550$ km above the Earth? That is$,$ how fast would the satellite need to be 'thrown' from Earth's surface to end up in the orbit we've described?Try it in one step! Et$1=$ Eto $-$ in order for the satellite to get into orbit it needs to have the same total energy at the surface of the earth, Et$1,$ as it does in orbit, Eto. Plug in the correct values and solve for v$1,$ the speed at the surface of the Earth. Do you get about $8200$ m$/$s$?$
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