Forces in Motion
Available worksheet, PE, KE, and ME.
First Law of Energy (Thermodynamics) All energy is either kinetic or potential. Copyright © 2010 Ryan P. Murphy
First Law of Energy (thermodynamics) All energy is either kinetic or potential. Copyright © 2010 Ryan P. Murphy
First Law of energy (thermodynamics) All energy is either kinetic or potential. Copyright © 2010 Ryan P. Murphy
First Law of Energy (thermodynamics) All energy is either kinetic or potential. Copyright © 2010 Ryan P. Murphy
First Law of Energy (thermodynamics) All energy is either kinetic or potential. Copyright © 2010 Ryan P. Murphy
Potential Energy: (PE) The energy stored by an object as a result of its position. Copyright © 2010 Ryan P. Murphy
Potential Enegy (PE) Kinetic Energy (KE)
Potential Enegy (PE) Kinetic Energy (KE)
Potential Enegy (PE) Kinetic Energy (KE)
Kinetic Energy is the energy of motion. Potential Energy is the energy of position. Objects that are elevated have a high potential energy. Kinetic Energy is the energy of motion. Copyright © 2010 Ryan P. Murphy
Kinetic Energy is the energy of motion. Potential Energy is the energy of position. Objects that are elevated have a high potential energy. Kinetic Energy is the energy of motion. Copyright © 2010 Ryan P. Murphy
Kinetic Energy is the energy of motion. Potential Energy is the energy of position. Objects that are elevated have a high potential energy. Kinetic Energy is the energy of motion. Copyright © 2010 Ryan P. Murphy
Available worksheet, PE, KE, and ME.
Activity! Please write and plan on sharing a sentence about PE and KE about the animation below. Copyright © 2010 Ryan P. Murphy
Activity! Please write and plan on sharing a sentence about PE and KE about the animation below. Copyright © 2010 Ryan P. Murphy
The monkey has potential energy because of its position in the tree The monkey has potential energy because of its position in the tree. When she lets go her potential energy is transferred into the energy of motion (KE). and Copyright © 2010 Ryan P. Murphy
The monkey has potential energy because of its position in the tree The monkey has potential energy because of its position in the tree. When he lets go his potential energy is transferred into the energy of motion (KE). Copyright © 2010 Ryan P. Murphy
Potential Energy Potential
Kinetic Energy
Potential Energy Kinetic Energy
Potential Energy Potential Energy Kinetic Energy
Potential Energy Kinetic Energy Potential Energy Kinetic Energy
Copyright © 2010 Ryan P. Murphy
Kinetic Copyright © 2010 Ryan P. Murphy
Kinetic Potential Copyright © 2010 Ryan P. Murphy
Kinetic Potential Potential Copyright © 2010 Ryan P. Murphy
Kinetic Potential Kinetic Potential Copyright © 2010 Ryan P. Murphy
Video Link! (Optional) Energy changes, Potential and Kinetic Energy. http://www.youtube.com/watch?v=Jnj8mc04r9E
Activity! PE – KE Skateboarder Simulator Search Phet Skate Board Demo. Download program (Free) http://phet.colorado.edu/en/simulation/energy-skate-park Copyright © 2010 Ryan P. Murphy
PE = mgh Copyright © 2010 Ryan P. Murphy
PE = mgh PE = Energy (in Joules) Copyright © 2010 Ryan P. Murphy
PE = mgh PE = Energy (in Joules) m = mass (in kilograms) Copyright © 2010 Ryan P. Murphy
g = gravitational acceleration of the earth (9.8 m/s²) PE = mgh PE = Energy (in Joules) m = mass (in kilograms) g = gravitational acceleration of the earth (9.8 m/s²) Copyright © 2010 Ryan P. Murphy
g = gravitational acceleration of the earth (9.8 m/s²) PE = mgh PE = Energy (in Joules) m = mass (in kilograms) g = gravitational acceleration of the earth (9.8 m/s²) h = height above Earth's surface (in meters) Copyright © 2010 Ryan P. Murphy
g = gravitational acceleration of the earth (9.8 m/s²) PE = mgh PE = Energy (in Joules) m = mass (in kilograms) g = gravitational acceleration of the earth (9.8 m/s²) h = height above Earth's surface (in meters) Learn more about Potential Energy at… http://www.physicsclassroom.com/class/energy/u5l1b.cfm Copyright © 2010 Ryan P. Murphy
Available worksheet, PE, KE, and ME.
Find the PE in Joules? PE=mgh Calculate the potential energy for a 2 kg basketball dropping from a height of 3.5 meters with a velocity of 9.8 m / sec². Find the PE in Joules? PE=mgh Copyright © 2010 Ryan P. Murphy
Find the PE in Joules? PE=mgh Calculate the potential energy for a 2 kg basketball dropping from a height of 3.5 meters with a velocity of 9.8 m / s². Find the PE in Joules? PE=mgh Copyright © 2010 Ryan P. Murphy
Find the PE in Joules? PE=mgh Calculate the potential energy for a 2 kg basketball dropping from a height of 3.5 meters with a velocity of 9.8 m / s². Find the PE in Joules? PE=mgh Copyright © 2010 Ryan P. Murphy
PE = mgh m = 2 kg g = 9.8 m/sec2 h = 3.5 m Copyright © 2010 Ryan P. Murphy
PE = mgh m = 2 kg g = 9.8 m/sec2 h = 3.5 m Copyright © 2010 Ryan P. Murphy
PE = mgh m = 2 kg g = 9.8 m/s² h = 3.5 m Copyright © 2010 Ryan P. Murphy
PE = mgh m = 2 kg g = 9.8 m/s² h = 3.5 m Copyright © 2010 Ryan P. Murphy
PE = mgh m = 2 kg g = 9.8 m/s² h = 3.5 m PE = (2 kg ) (9.8 m/s²) (3.5 m) Copyright © 2010 Ryan P. Murphy
PE = mgh m = 2 kg g = 9.8 m/s² h = 3.5 m PE = (2 kg ) (9.8 m/s²) (3.5 m) PE = Copyright © 2010 Ryan P. Murphy
PE = mgh m = 2 kg g = 9.8 m/s² h = 3.5 m PE = (2 kg ) (9.8 m/s²) (3.5 m) PE = 68.6 Joules Copyright © 2010 Ryan P. Murphy
Available worksheet, PE, KE, and ME.
Calculate the potential energy of a shot put dropping from a height of 6 meters weighing 5.44 kg with a velocity of 9.8 m/s². Find the PE in Joules? Copyright © 2010 Ryan P. Murphy
Calculate the potential energy of a shot put dropping from a height of 6 meters weighing 5.44 kg with a velocity of 9.8 m/s². Find the PE in Joules? Copyright © 2010 Ryan P. Murphy
Find the PE in Joules? PE=mgh Calculate the potential energy of a shot put dropping from a height of 6 meters weighing 5.44 kg with a velocity of 9.8 m/s². Find the PE in Joules? PE=mgh Copyright © 2010 Ryan P. Murphy
PE = mgh m = 5.44 kg g = 9.8 m/s² h = 6 m Copyright © 2010 Ryan P. Murphy
PE = mgh m = 5.44 kg g = 9.8 m/s² h = 6 m PE = (5.44kg) (9.8m/s²) (6m) Copyright © 2010 Ryan P. Murphy
Answer: PE = 319.87 Joules. Copyright © 2010 Ryan P. Murphy
Available worksheet, PE, KE, and ME.
Calculate the potential energy for a 2500 kg satellite orbiting at an altitude of 50,000 meters above the surface of the earth if it is traveling with a velocity of 9.8 m/s². Find PE in Joules? Assume we are using the earth gravity constant.
Calculate the potential energy for a 2500 kg satellite orbiting at an altitude of 50,000 meters above the surface of the earth if it is traveling with a velocity of 9.8 m/s². Find PE in Joules? Assume we are using the earth gravity constant.
Calculate the potential energy for a 2500 kg satellite orbiting at an altitude of 50,000 meters above the surface of the earth if it is traveling with a velocity of 9.8 m/s². Find PE in Joules? PE=mgh Assume we are using the earth gravity constant.
Calculate the potential energy for a 2500 kg satellite orbiting at an altitude of 50,000 meters above the surface of the earth if it is traveling with a velocity of 9.8 m/s². Find PE in Joules? PE=mgh Assume we are using the earth gravity constant.
PE = mgh m = 2500 kg g = 9.8 m/s² h = 50,000m Copyright © 2010 Ryan P. Murphy
PE = mgh m = 2500 kg g = 9.8 m/s² h = 50,000m Copyright © 2010 Ryan P. Murphy
PE = mgh m = 2500 kg g = 9.8 m/s² h = 50,000m PE = (2500 kg) (9.8 m/s²) (50,000 m) Copyright © 2010 Ryan P. Murphy
PE = mgh m = 2500 kg g = 9.8 m/s² h = 50,000m PE = (2500 kg) (9.8 m/s²) (50,000 m) PE = ? Copyright © 2010 Ryan P. Murphy
Or PE = 1,225,000,000 Joules Copyright © 2010 Ryan P. Murphy
Can you put it into scientific notation? Or PE = 1,225,000,000 Joules Can you put it into scientific notation? Copyright © 2010 Ryan P. Murphy
Can you put it into scientific notation? Or PE = 1,225,000,000 Joules Can you put it into scientific notation? 9 Copyright © 2010 Ryan P. Murphy
PE = 1.225 x 109 Joules Or PE = 1,225,000,000 Joules Can you put it into scientific notation? 9 PE = 1.225 x 109 Joules Copyright © 2010 Ryan P. Murphy
Kinetic energy Copyright © 2010 Ryan P. Murphy
The energy that matter has because of its motion and mass. Kinetic energy The energy that matter has because of its motion and mass. Copyright © 2010 Ryan P. Murphy
The energy that matter has because of its motion and mass. Kinetic energy The energy that matter has because of its motion and mass. Where m = mass of object (kg). Copyright © 2010 Ryan P. Murphy
The energy that matter has because of its motion and mass. Kinetic energy The energy that matter has because of its motion and mass. Where m = mass of object (kg). v = speed of object. Copyright © 2010 Ryan P. Murphy
The energy that matter has because of its motion and mass. Kinetic energy The energy that matter has because of its motion and mass. Where m = mass of object (kg). v = speed of object. KE = Energy in Joules. Copyright © 2010 Ryan P. Murphy
The energy that matter has because of its motion and mass. Kinetic energy The energy that matter has because of its motion and mass. Where m = mass of object (kg). v = speed of object. KE = Energy in Joules. This equation shows that the kinetic energy of an object is proportional to the square of its speed. For a twofold increase in speed, the kinetic energy will increase by a factor of four. Copyright © 2010 Ryan P. Murphy
The energy that matter has because of its motion and mass. Kinetic energy The energy that matter has because of its motion and mass. Where m = mass of object (kg). v = speed of object. KE = Energy in Joules. This equation shows that the kinetic energy of an object is proportional to the square of its speed. For a twofold increase in velocity, the kinetic energy will increase by a factor of four. Copyright © 2010 Ryan P. Murphy
Kinetic energy - Copyright © 2010 Ryan P. Murphy
Copyright © 2010 Ryan P. Murphy
Kinetic Energy Copyright © 2010 Ryan P. Murphy
Kinetic Energy Copyright © 2010 Ryan P. Murphy
Amount of KE depends on both the objects mass and its velocity / (speed). Copyright © 2010 Ryan P. Murphy
Amount of KE depends on both the objects mass and its velocity / (speed). Copyright © 2010 Ryan P. Murphy
Amount of KE depends on both the objects mass and its velocity / (speed). Copyright © 2010 Ryan P. Murphy
Amount of KE depends on both the objects mass and its velocity / (speed). Copyright © 2010 Ryan P. Murphy
Amount of KE depends on both the objects mass and its velocity / (speed). Copyright © 2010 Ryan P. Murphy
Available worksheet, PE, KE, and ME.
What is the kinetic energy of a 10 kilogram cannon ball traveling at 50 meters per second? m = 10 kg v = 50 m/s Copyright © 2010 Ryan P. Murphy
What is the kinetic energy of a 10 kilogram cannon ball traveling at 50 meters per second? m = 10 kg v = 50 m/s Copyright © 2010 Ryan P. Murphy
What is the kinetic energy of a 10 kilogram cannon ball traveling at 50 meters per second? m = 10 kg v = 50 m/s Copyright © 2010 Ryan P. Murphy
Don’t forget your order of operations. Copyright © 2010 Ryan P. Murphy
Don’t forget your order of operations. PEMDAS Copyright © 2010 Ryan P. Murphy
Don’t forget your order of operations. PEMDAS For KE, you must do exponents (E) before multiplying (M). Copyright © 2010 Ryan P. Murphy
Don’t forget your order of operations. PEMDAS For KE, you must do exponents (E) before multiplying (M). Copyright © 2010 Ryan P. Murphy
Don’t forget your order of operations. PEMDAS For KE, you must do exponents (E) before multiplying (M). Copyright © 2010 Ryan P. Murphy
KE = 0.5 times 10 kg times (50) ² Joules Copyright © 2010 Ryan P. Murphy
KE = 0.5 times 10 kg times (50) ² Joules Copyright © 2010 Ryan P. Murphy
KE = 0.5 times 10 kg times (50) ² Joules Copyright © 2010 Ryan P. Murphy
KE = 0.5 times 10 kg times (50) ² Joules Copyright © 2010 Ryan P. Murphy
KE = 0.5 times 10 kg times (50) ² Joules KE = 5 kg times 2,500 Joules Copyright © 2010 Ryan P. Murphy
KE = 0.5 times 10 kg times (50) ² Joules KE = 5 kg times 2,500 Joules KE = Copyright © 2010 Ryan P. Murphy
KE = 0.5 times 10 kg times (50) ² Joules KE = 5 kg times 2,500 Joules KE = 12,500 Joules Copyright © 2010 Ryan P. Murphy
KE = 0.5 times 10 kg times (50) ² Joules KE = 5 kg times 2,500 Joules KE = 12,500 Joules Copyright © 2010 Ryan P. Murphy
Available worksheet, PE, KE, and ME.
What is the kinetic energy of a What is the kinetic energy of a .142 kilogram baseball traveling at 45 meters per second? m = .142 kg v = 45 m/s Copyright © 2010 Ryan P. Murphy
What is the kinetic energy of a What is the kinetic energy of a .142 kilogram baseball traveling at 45 meters per second? m = .142 kg v = 45 m/s Copyright © 2010 Ryan P. Murphy
What is the kinetic energy of a What is the kinetic energy of a .142 kilogram baseball traveling at 45 meters per second? m = .142 kg v = 45 m/s Copyright © 2010 Ryan P. Murphy
KE = 0.5 times .142 kg times (45) ² Joules Copyright © 2010 Ryan P. Murphy
PEMDAS KE = 0.5 times .142 kg times (45) ² Joules Copyright © 2010 Ryan P. Murphy
KE = 0.5 times .142 kg times (45) ² Joules Copyright © 2010 Ryan P. Murphy
KE = 0.5 times .142 kg times (45) ² Joules KE = .071 kg times 2,025 Joules Copyright © 2010 Ryan P. Murphy
KE = 0.5 times .142 kg times (45) ² Joules KE = .071 kg times 2,025 Joules KE = Copyright © 2010 Ryan P. Murphy
KE = 0.5 times .142 kg times (45) ² Joules KE = .071 kg times 2,025 Joules KE = 143.775 Joules Copyright © 2010 Ryan P. Murphy
KE = 0.5 times .142 kg times (45) ² Joules KE = .071 kg times 2,025 Joules KE = 143.775 Joules Copyright © 2010 Ryan P. Murphy
Mechanical Energy (ME): Energy due to position and motion. - Copyright © 2010 Ryan P. Murphy
Mechanical Energy (ME): Energy due to position and motion. Sum of potential and kinetic energies, includes heat and friction. PE + KE = ME Copyright © 2010 Ryan P. Murphy
Available worksheet, PE, KE, and ME.
A ski jumper moving down the hill had a Potential Energy of 6,500 Joules, and a Kinetic Energy of 10,500 Joules. What is her Mechanical Energy?
A ski jumper moving down the hill had a Potential Energy of 6,500 Joules, and a Kinetic Energy of 10,500 Joules. What is her Mechanical Energy?
A ski jumper moving down the hill had a Potential Energy of 6,500 Joules, and a Kinetic Energy of 10,500 Joules. What is her Mechanical Energy?
A ski jumper moving down the hill had a Potential Energy of 6,500 Joules, and a Kinetic Energy of 10,500 Joules. What is her Mechanical Energy? ME = PE + KE
A ski jumper moving down the hill had a Potential Energy of 6,500 Joules, and a Kinetic Energy of 10,500 Joules. What is her Mechanical Energy? ME = PE + KE ME = 6,500 J + 10,500 J
A ski jumper moving down the hill had a Potential Energy of 6,500 Joules, and a Kinetic Energy of 10,500 Joules. What is her Mechanical Energy? ME = PE + KE ME = 6,500 J + 10,500 J ME =
A ski jumper moving down the hill had a Potential Energy of 6,500 Joules, and a Kinetic Energy of 10,500 Joules. What is her Mechanical Energy? ME = PE + KE ME = 6,500 J + 10,500 J ME = 17,000 Joules.
Please calculate the potential energy of a pole-vaulter at the top of their vault. The run into the vault was 8.3 m/s and they weighed 77 kilograms. (Assume all energy in the vault was transformed into potential energy to make this question easier.) Potential
Please calculate the potential energy of a pole-vaulter at the top of their vault. The run into the vault was 8.3 m/s and they weighed 77 kilograms. KE= ½ m * V² (Assume all energy in the vault was transformed into potential energy to make this question easier.) Potential
Please calculate the potential energy of a pole-vaulter at the top of their vault. The run into the vault was 8.3 m/s and they weighed 77 kilograms. KE= ½ m * V2 (Assume all energy in the vault was transformed into potential energy to make this question easier.) Potential “The homework isn’t color coded.”
Please calculate the potential energy of a pole-vaulter at the top of their vault. The run into the vault was 8.3 m/s and they weighed 77 kilograms. KE= ½ m * V2 (Assume all energy in the vault was transformed into potential energy to make this question easier.) Potential “The homework isn’t color coded.”
Please calculate the potential energy of a pole-vaulter at the top of their vault. The run into the vault was 8.3 m/s and they weighed 77 kilograms. KE= ½ m * V² (Assume all energy in the vault was transformed into potential energy to make this question easier.) Potential
Please calculate the potential energy of a pole-vaulter at the top of their vault. The run into the vault was 8.3 m/s and they weighed 77 kilograms. KE= ½ m * V² (Assume all energy in the vault was transformed into potential energy to make this question easier.) Potential KE = ½ m * V² KE =
Please calculate the potential energy of a pole-vaulter at the top of their vault. The run into the vault was 8.3 m/s and they weighed 77 kilograms. KE= ½ m * V² (Assume all energy in the vault was transformed into potential energy to make this question easier.) Potential KE = ½ m * V² KE = .5* 77 kg * 8.3 m/s KE =
Please calculate the potential energy of a pole-vaulter at the top of their vault. The run into the vault was 8.3 m/s and they weighed 77 kilograms. KE= ½ m * V² (Assume all energy in the vault was transformed into potential energy to make this question easier.) Potential KE = ½ m * V² KE = .5* 77 kg * 8.3 m/s KE = .5* 77 kg * 68.89 m/s KE =
Please calculate the potential energy of a pole-vaulter at the top of their vault. The run into the vault was 8.3 m/s and they weighed 77 kilograms. KE= ½ m * V² (Assume all energy in the vault was transformed into potential energy to make this question easier.) Potential KE = ½ m * V² KE = .5* 77 kg * 8.3 m/s KE = .5* 77 kg * 68.89 m/s KE = 2652.2 Joules
Please calculate the potential energy of a pole-vaulter at the top of their vault. Their height was 3 meters and they weighed 77 kilograms. PE= mgh (Assume all energy in the vault was transformed into potential energy to make this question easier.) Potential
Please calculate the potential energy of a pole-vaulter at the top of their vault. Their height was 3 meters and they weighed 77 kilograms. PE= mgh (Assume all energy in the vault was transformed into potential energy to make this question easier.) Potential
Please calculate the potential energy of a pole-vaulter at the top of their vault. Their height was 3 meters and they weighed 77 kilograms. PE= mgh (Assume all energy in the vault was transformed into potential energy to make this question easier.) Potential
Please calculate the potential energy of a pole-vaulter at the top of their vault. Their height was 3 meters and they weighed 77 kilograms. PE= mgh (Assume all energy in the vault was transformed into potential energy to make this question easier.) Potential
Please calculate the potential energy of a pole-vaulter at the top of their vault. Their height was 3 meters and they weighed 77 kilograms. PE= mgh (Assume all energy in the vault was transformed into potential energy to make this question easier.) Potential
Please calculate the potential energy of a pole-vaulter at the top of their vault. Their height was 3 meters and they weighed 77 kilograms. PE= mgh (9.8 m/s²) (Assume all energy in the vault was transformed into potential energy to make this question easier.) Potential
Please calculate the potential energy of a pole-vaulter at the top of their vault. Their height was 3 meters and they weighed 77 kilograms. PE= mgh (9.8 m/s²) (Assume all energy in the vault was transformed into potential energy to make this question easier.) Potential
“Organize your work please.” Please calculate the potential energy of a pole-vaulter at the top of their vault. Their height was 3 meters and they weighed 77 kilograms. PE= mgh (9.8 m/s²) (Assume all energy in the vault was transformed into potential energy to make this question easier.) Potential “Organize your work please.”
Please calculate the potential energy of a pole-vaulter at the top of their vault. Their height was 3 meters and they weighed 77 kilograms. PE= mgh (9.8 m/s²) (Assume all energy in the vault was transformed into potential energy to make this question easier.) Potential PE= mgh
Please calculate the potential energy of a pole-vaulter at the top of their vault. Their height was 3 meters and they weighed 77 kilograms. PE= mgh (9.8 m/s²) (Assume all energy in the vault was transformed into potential energy to make this question easier.) Potential PE= mgh PE = 77 kg* 9.8 m/s² * 3 m
Please calculate the potential energy of a pole-vaulter at the top of their vault. Their height was 3 meters and they weighed 77 kilograms. PE= mgh (9.8 m/s²) (Assume all energy in the vault was transformed into potential energy to make this question easier.) Potential PE= mgh PE = 77 kg* 9.8 m/s² * 3 m PE = 2263.8 Joules
Please calculate the potential energy of a pole-vaulter at the top of their vault. Their height was 3 meters and they weighed 77 kilograms. PE= mgh (9.8 m/s²) (Assume all energy in the vault was transformed into potential energy to make this question easier.) Potential PE= mgh PE = 77 kg* 9.8 m/s² * 3 m PE = 2263.8 Joules
Please calculate the potential energy of a pole-vaulter at the top of their vault. Their height was 3 meters and they weighed 77 kilograms. PE= mgh (9.8 m/s²) (Assume all energy in the vault was transformed into potential energy to make this question easier.) Potential PE= mgh PE = 77 kg* 9.8 m/s² * 3 m PE = 2263.8 Joules KE = 2652.2 Joules
Please calculate the potential energy of a pole-vaulter at the top of their vault. Their height was 3 meters and they weighed 77 kilograms. PE= mgh (9.8 m/s²) (Assume all energy in the vault was transformed into potential energy to make this question easier.) Potential PE= mgh PE = 77 kg* 9.8 m/s² * 3 m PE = 2263.8 Joules KE = 2652.2 Joules -388.4 Joules for heat, sound, and other losses.
Please calculate the potential energy of a pole-vaulter at the top of their vault. Their height was 3 meters and they weighed 77 kilograms. PE= mgh (9.8 m/s²) (Assume all energy in the vault was transformed into potential energy to make this question easier.) Potential PE= mgh PE = 77 kg* 9.8 m/s² * 3 m PE = 2263.8 Joules KE = 2652.2 Joules -388.4 Joules for heat, sound, and other losses.
Color Key Areas with high potential energy and kinetic energy. Activity! Please make a roller coaster on a page in your science journal. Color Key Areas with high potential energy and kinetic energy. Copyright © 2010 Ryan P. Murphy
Color Key Areas with high potential energy and kinetic energy. Activity! Please make a roller coaster on a page in your science journal. Color Key Areas with high potential energy and kinetic energy. Copyright © 2010 Ryan P. Murphy
Color Key Areas with high potential energy and kinetic energy. Activity! Please make a roller coaster on a page in your science journal. Color Key Areas with high potential energy and kinetic energy. Copyright © 2010 Ryan P. Murphy
Centripetal Force: A force that makes a body follow a curved path. Copyright © 2010 Ryan P. Murphy
Matter wants to travel in a straight line Centripetal Force: A force that makes a body follow a curved path. Matter wants to travel in a straight line Copyright © 2010 Ryan P. Murphy
Video! Centripetal Force http://www.youtube.com/watch?v=XWCBk9Vl-rc
Gravity from the mass of the sun keeps the earth from heading out into space. Copyright © 2010 Ryan P. Murphy
What would happen if the Gravity from the mass of the sun keeps the earth from heading out into space. What would happen if the sun disappeared? Copyright © 2010 Ryan P. Murphy
What would happen if the Gravity from the mass of the sun keeps the earth from heading out into space. What would happen if the sun disappeared? Lets find out on the next slide. Copyright © 2010 Ryan P. Murphy
The World of the Hammer Throw. Centripetal and Centrifugal Force http://www.youtube.com/watch?v=tB00eDfTNhs
Activity (Optional) Funky foam tube roller coaster. Use ½ inch foam pipe insulation cut in half, duct tape to connect the tubes and anchor, cup to catch at end, and marbles. Know your KE and PE
Create a one page visual of a roller coaster with drawings. Name your coaster. Create a not to scale visual that will be achievable with the materials provided by teacher. Class will vote to choose a model and build the coaster. Calculate the PE and KE. Find the mass of the marble. Measure the height of the coaster. Calculate the velocity. Distance / meters divided by seconds and direction
Create a one page visual of a roller coaster with drawings. Name your coaster. Create a not to scale visual that will be achievable with the materials provided by teacher. Class will vote to choose a model and then build the coaster. Calculate the PE and KE. Find the mass of the marble. Measure the height of the coaster. Calculate the velocity. Distance / meters divided by seconds and direction
Academic Link! (Optional) http://www.youtube.com/watch?v=BSWl_Zj-CZs
F=MA, PE, KE and more ramp activity. Available Sheet
Activity! Kinetic and Potential Energy + Newton’s Laws F=MA. Copyright © 2010 Ryan P. Murphy
High Medium Low Find blocks / books to create three heights Activity! Kinetic and Potential Energy + Newton’s Laws F=MA. High Medium Low Find blocks / books to create three heights Copyright © 2010 Ryan P. Murphy
Parked Car Three Washers Please create this spreadsheet in your journal. Truck (D Battery) Car (AA Batter) – Cup (Parked Car) Ramp Height Parked car One Washer Parked Car Two Washer Parked Car Three Washers Lowest (Distance of Parked Car) AA –Car_________ D – Truck________ Middle AA –Car___________ D – Truck__________ Highest Make Prediction after data collection, Copyright © 2010 Ryan P. Murphy
Meter Stick to measure distance cup “parked car” travels after hit. Set-up of the activity. The height can change by placing the rectangular block on its various sides. Ramp start line 5cm gap Plastic Cup D Washers 1-3 Height AA Meter Stick to measure distance cup “parked car” travels after hit. Copyright © 2010 Ryan P. Murphy
Repeat with Truck / D Battery. Conduct trials with small car (AA Battery) with one and three washers and the three different heights, measuring the distance the parked car traveled after hit in cm. Repeat with Truck / D Battery. Do not do medium height as we will predict later. Copyright © 2010 Ryan P. Murphy
F=MA, PE, KE and more ramp activity. Available Sheet
Predict after data collection F=MA, PE, KE and more ramp activity. Available Sheet Predict after data collection
Based on your data, make a prediction for the distance the parked car should travel for both the small car (AA) and truck (D) on your spreadsheets for medium height with two washers. Copyright © 2010 Ryan P. Murphy
Based on your data, make a prediction for the distance the parked car should travel for both the small car (AA) and truck (D) on your spreadsheets for medium height with two washers. Run some trials afterward to see if your prediction is correct. Copyright © 2010 Ryan P. Murphy
Car
Car
Car
Car
Car
Car Increase in Friction / Mass to move.
Truck
Truck
Truck
Truck
Truck
Truck Increase in Friction / Mass to move.
F=MA, PE, KE and more ramp activity. Available Sheet
F=MA, PE, KE and more ramp activity. Available Sheet
How did the height of the ramp affect the movement of the parked car? Use potential energy and kinetic energy in your response. Measure the height of the ramp, mass of the batteries, and determine the Potential Energy. PE=mgh Copyright © 2010 Ryan P. Murphy
How did the resistance to force (washers) affect the movement of the parked car? Copyright © 2010 Ryan P. Murphy
How did the height of the ramp affect the movement of the parked car? Copyright © 2010 Ryan P. Murphy
How did the height of the ramp affect the movement of the parked car? Increasing the height of the ramp increased the batteries potential energy. Copyright © 2010 Ryan P. Murphy
How did the height of the ramp affect the movement of the parked car? Increasing the height of the ramp increased the batteries potential energy. This increase of potential energy created an increase in kinetic energy / (Acceleration) which caused the parked car to move further (force). Copyright © 2010 Ryan P. Murphy
How did the resistance to force (washers) affect the movement of the parked car? Copyright © 2010 Ryan P. Murphy
How did the resistance to force (washers) affect the movement of the parked car? The more mass added to the parked car (washers) decreased the distance it traveled after being struck. Copyright © 2010 Ryan P. Murphy
PE = mgh KE = ½ mass * velocity2 Find the Mechanical Energy of the large D battery hitting the parked car from the highest position. PE = mgh KE = ½ mass * velocity2 D Battery mass = 148 g (.148kg) Height = 6 cm (.06m) Gravity = 9.8 m/sec Velocity 3 m/sec
PE = mgh KE = ½ mass * velocity² Find the Mechanical Energy of the large D battery hitting the parked car from the highest position. PE = mgh KE = ½ mass * velocity² D Battery mass = 148 g (.148kg) Height = 6 cm (.06m) Gravity = 9.8 m/sec Velocity 3 m/sec
PE = mgh KE = ½ mass * velocity² Find the Mechanical Energy of the large D battery hitting the parked car from the highest position. PE = mgh KE = ½ mass * velocity² D Battery mass = 148 g (.148kg) Height = 6 cm (.06m) Gravity = 9.8 m/s² Velocity 3 m/s
PE = mgh KE = ½ mass * velocity² Find the Mechanical Energy of the large D battery hitting the parked car from the highest position. PE = mgh KE = ½ mass * velocity² D Battery mass = 148 g (.148kg) Height = 6 cm (.06m) Gravity = 9.8 m/s² Velocity 3 m/s Organize your work! PE= mgh PE = ____ * ___ * ____ PE = Joules
PE = mgh KE = ½ mass * velocity² Find the Mechanical Energy of the large D battery hitting the parked car from the highest position. PE = mgh KE = ½ mass * velocity² D Battery mass = 148 g (.148kg) Height = 6 cm (.06m) Gravity = 9.8 m/s² Velocity 3 m/s
PE = mgh KE = ½ mass * velocity² Find the Mechanical Energy of the large D battery hitting the parked car from the highest position. PE = mgh KE = ½ mass * velocity² D Battery mass = 148 g (.148kg) Height = 6 cm (.06m) Gravity = 9.8 m/s² Velocity 3 m/s Answer in Joules
PE = mgh KE = ½ mass * velocity² Find the Mechanical Energy of the large D battery hitting the parked car from the highest position. PE = mgh KE = ½ mass * velocity² D Battery mass = 148 g (.148kg) Height = 6 cm (.06m) Gravity = 9.8 m/s² Velocity 3 m/s Answer in Joules
PE = mgh KE = ½ mass * velocity² Find the Mechanical Energy of the large D battery hitting the parked car from the highest position. PE = mgh KE = ½ mass * velocity² D Battery mass = 148 g (.148kg) Height = 6 cm (.06m) Gravity = 9.8 m/s² Velocity 3 m/s Answer in Joules
PE = mgh KE = ½ mass * velocity² Find the Mechanical Energy of the large D battery hitting the parked car from the highest position. PE = mgh KE = ½ mass * velocity² D Battery mass = 148 g (.148kg) Height = 6 cm (.06m) Gravity = 9.8 m/s² Velocity 3 m/s Answer in Joules
PE = mgh KE = ½ mass * velocity² Find the Mechanical Energy of the large D battery hitting the parked car from the highest position. PE = mgh KE = ½ mass * velocity² D Battery mass = 148 g (.148kg) Height = 6 cm (.06m) Gravity = 9.8 m/s² Velocity 3 m/s Answer in Joules
PE = mgh KE = ½ mass * velocity² Find the Mechanical Energy of the large D battery hitting the parked car from the highest position. PE = mgh KE = ½ mass * velocity² D Battery mass = 148 g (.148kg) Height = 6 cm (.06m) Gravity = 9.8 m/s² Velocity 3 m/s Answer in Joules Organize your work! PE= mgh PE = ____ * ___ * ____ PE = Joules
PE = mgh KE = ½ mass * velocity² Find the Mechanical Energy of the large D battery hitting the parked car from the highest position. PE = mgh KE = ½ mass * velocity² D Battery mass = 148 g (.148kg) Height = 6 cm (.06m) Gravity = 9.8 m/s² Velocity 3 m/s Answer in Joules PE=mgh
PE = mgh KE = ½ mass * velocity² Find the Mechanical Energy of the large D battery hitting the parked car from the highest position. PE = mgh KE = ½ mass * velocity² D Battery mass = 148 g (.148kg) Height = 6 cm (.06m) Gravity = 9.8 m/s² Velocity 3 m/s Answer in Joules PE=mgh PE= .148kg * 9.8 m/s² * .06m
PE = mgh KE = ½ mass * velocity² Find the Mechanical Energy of the large D battery hitting the parked car from the highest position. PE = mgh KE = ½ mass * velocity² D Battery mass = 148 g (.148kg) Height = 6 cm (.06m) Gravity = 9.8 m/s² Velocity 3 m/s Answer in Joules PE=mgh PE= .148kg * 9.8 m/s² * .06m
PE = mgh KE = ½ mass * velocity² Find the Mechanical Energy of the large D battery hitting the parked car from the highest position. PE = mgh KE = ½ mass * velocity² D Battery mass = 148 g (.148kg) Height = 6 cm (.06m) Gravity = 9.8 m/s² Velocity 3 m/s Answer in Joules PE=mgh PE= .148kg * 9.8 m/s² * .06m PE = .087 Joules
PE = mgh KE = ½ mass * velocity² PE = .087 Joules Find the Mechanical Energy of the large D battery hitting the parked car from the highest position. PE = mgh KE = ½ mass * velocity² PE = .087 Joules D Battery mass = 148 g (.148kg) Height = 6 cm (.06m) Gravity = 9.8 m/s² Velocity 3 m/s Answer in Joules
PE = mgh KE = ½ mass * velocity² PE = .087 Joules Find the Mechanical Energy of the large D battery hitting the parked car from the highest position. PE = mgh KE = ½ mass * velocity² PE = .087 Joules D Battery mass = 148 g (.148kg) Height = 6 cm (.06m) Gravity = 9.8 m/s² Velocity 3 m/s Answer in Joules KE=1/2 m * velocity²
PE = mgh KE = ½ mass * velocity² PE = .087 Joules Find the Mechanical Energy of the large D battery hitting the parked car from the highest position. PE = mgh KE = ½ mass * velocity² PE = .087 Joules D Battery mass = 148 g (.148kg) Height = 6 cm (.06m) Gravity = 9.8 m/s² Velocity 3 m/s Answer in Joules KE=1/2 m * velocity²
PE = mgh KE = ½ mass * velocity² PE = .087 Joules Find the Mechanical Energy of the large D battery hitting the parked car from the highest position. PE = mgh KE = ½ mass * velocity² PE = .087 Joules D Battery mass = 148 g (.148kg) Height = 6 cm (.06m) Gravity = 9.8 m/s² Velocity 3 m/s Answer in Joules KE=1/2 m * velocity² KE=.5 * .148 * 3 m/s²
PE = mgh KE = ½ mass * velocity² PE = .087 Joules Find the Mechanical Energy of the large D battery hitting the parked car from the highest position. PE = mgh KE = ½ mass * velocity² PE = .087 Joules D Battery mass = 148 g (.148kg) Height = 6 cm (.06m) Gravity = 9.8 m/s² Velocity 3 m/s Answer in Joules KE=1/2 m * velocity² KE=.5 * .148 * 3 m/s² KE=.5 * .148 * 9 m/s²
PE = mgh KE = ½ mass * velocity² PE = .087 Joules Find the Mechanical Energy of the large D battery hitting the parked car from the highest position. PE = mgh KE = ½ mass * velocity² PE = .087 Joules D Battery mass = 148 g (.148kg) Height = 6 cm (.06m) Gravity = 9.8 m/s² Velocity 3 m/s Answer in Joules KE=1/2 m * velocity² KE=.5 * .148 * 3 m/s² KE=.5 * .148 * 9 m/s² KE = .666 Joules
PE = mgh KE = ½ mass * velocity² PE = .087 Joules KE = .666 Joules Find the Mechanical Energy of the large D battery hitting the parked car from the highest position. PE = mgh KE = ½ mass * velocity² PE = .087 Joules KE = .666 Joules D Battery mass = 148 g (.148kg) Height = 6 cm (.06m) Gravity = 9.8 m/s² Velocity 3 m/s Answer in Joules KE=1/2 m * velocity² KE=.5 * .148 * 3 m/s² KE=.5 * .148 * 9 m/s² KE = .666 Joules
Find the Mechanical Energy of the large D battery hitting the parked car from the highest position. PE = mgh KE = ½ mass * velocity² PE = .087 Joules KE = .666 Joules D Battery mass = 148 g (.148kg) Height = 6 cm (.06m) Gravity = 9.8 m/s² Velocity 3 m/s Answer in Joules + KE=1/2 m * velocity² KE=.5 * .148 * 3 m/s² KE=.5 * .148 * 9 m/s² KE = .666 Joules
Find the Mechanical Energy of the large D battery hitting the parked car from the highest position. PE = mgh KE = ½ mass * velocity² PE = .087 Joules KE = .666 Joules D Battery mass = 148 g (.148kg) Height = 6 cm (.06m) Gravity = 9.8 m/s² Velocity 3 m/s Answer in Joules + KE=1/2 m * velocity² KE=.5 * .148 * 3 m/s² KE=.5 * .148 * 9 m/s² KE = .666 Joules Mechanical Energy (ME) =
Find the Mechanical Energy of the large D battery hitting the parked car from the highest position. PE = mgh KE = ½ mass * velocity² PE = .087 Joules KE = .666 Joules D Battery mass = 148 g (.148kg) Height = 6 cm (.06m) Gravity = 9.8 m/s² Velocity 3 m/s Answer in Joules + KE=1/2 m * velocity² KE=.5 * .148 * 3 m/s² KE=.5 * .148 * 9 m/s² KE = .666 Joules Mechanical Energy (ME) = .753 Joules
Question on homework: Describe three ways potential energy of position as well as potential chemical energy are combined with kinetic energy to generate kinetic electrical energy. Copyright © 2010 Ryan P. Murphy
Question on homework: Describe three ways potential energy of position as well as potential chemical energy are combined with kinetic energy to generate kinetic electrical energy. Copyright © 2010 Ryan P. Murphy
Hydropower : Potential energy turned into kinetic energy of motion turned into kinetic electrical energy. Copyright © 2010 Ryan P. Murphy
Hydropower : Potential energy turned into kinetic energy of motion turned into kinetic electrical energy. Copyright © 2010 Ryan P. Murphy
Hydropower gave rise to early industry. One of our earliest ways to harness energy. Copyright © 2010 Ryan P. Murphy
Hydropower gave rise to early industry. One of our earliest ways to harness energy. Potential Energy Copyright © 2010 Ryan P. Murphy
Hydropower gave rise to early industry. One of our earliest ways to harness energy. Potential Energy Transfer to Kinetic Energy Copyright © 2010 Ryan P. Murphy
In Dinowrig, Wales. Water is pumped from the lower lake to the upper lake when electricity is low in demand.
During times high electrical demand, the stored potential energy flows downhill to generate electricity (Kinetic).
Loss of energy however as it requires more energy than produced. During times high electrical demand, the stored potential energy flows downhill to generate electricity (Kinetic). Loss of energy however as it requires more energy than produced.
Loss of energy however as it requires more energy than produced. During times high electrical demand, the stored potential energy flows downhill to generate electricity (Kinetic). Loss of energy however as it requires more energy than produced. Energy goes from useful to non-useful
Kinetic energy to kinetic electrical energy Copyright © 2010 Ryan P. Murphy
Gravity turns potential energy in tides, into kinetic energy (flowing tides) into kinetic electrical energy. Copyright © 2010 Ryan P. Murphy
Geothermal Copyright © 2010 Ryan P. Murphy
Geothermal -Kinetic energy heat, turns water into steam, water rises and runs a turbine to generate electrical energy. Copyright © 2010 Ryan P. Murphy
Geothermal -Kinetic energy heat, turns water into steam, water rises and runs a turbine to generate electrical energy. Copyright © 2010 Ryan P. Murphy
Geothermal -Kinetic energy heat, turns water into steam, water rises and runs a turbine to generate kinetic electrical energy. Copyright © 2010 Ryan P. Murphy
Steam / Coal and wood burning electric plant
Nuclear energy – Nuclear reactions generate kinetic electrical energy using water, steam, and a turbine.
When you lift an object, chemical energy (a form of potential energy) stored in the chemicals obtained from your digested food is converted into the mechanical energy (kinetic) used to move your arm and the object upward and into heat given off by your body. Copyright © 2010 Ryan P. Murphy
When you lift an object, chemical energy (a form of potential energy) stored in the chemicals obtained from your digested food is converted into the mechanical energy (kinetic). Which is then used to move your body. Heat is produced Copyright © 2010 Ryan P. Murphy
When you lift an object, chemical energy (a form of potential energy) stored in the chemicals obtained from your digested food is converted into the mechanical energy (kinetic). Which is then used to move your body. Heat is produced Copyright © 2010 Ryan P. Murphy
When you lift an object, chemical energy (a form of potential energy) stored in the chemicals obtained from your digested food is converted into the mechanical energy (kinetic). Which is then used to move your body. Heat is produced Copyright © 2010 Ryan P. Murphy
When you lift an object, chemical energy (a form of potential energy) stored in the chemicals obtained from your digested food is converted into the mechanical energy (kinetic). Which is then used to move your body. Heat is released. Copyright © 2010 Ryan P. Murphy