Which is true about the total energy at point S?
(1 point)
Responses
At point S, the total energy is three times the total energy of the system, as kinetic energy was increased.
At point S, the total energy is three times the total energy of the system, as kinetic energy was increased.
At point S, the total energy is double the total energy of the system, as new energy is created as the potential energy increases.
At point S, the total energy is double the total energy of the system, as new energy is created as the potential energy increases.
At point S, the total energy is equal to the total energy of the system because energy kinetic energy has been transformed to potential energy.
At point S, the total energy is equal to the total energy of the system because energy kinetic energy has been transformed to potential energy.
At point S, the total energy is half of the system’s total energy, as kinetic energy was destroyed.
25 answers
At point S, the total energy is equal to the total energy of the system because energy kinetic energy has been transformed to potential energy.
The universe’s total amount of energy does not ever change, but the amount of this energy that is available to do work varies tremendously. What statement best explains the changes in available energy?(1 point)
Responses
Energy constantly changes from one form to another.
Energy constantly changes from one form to another.
Energy transfer always occurs through heat.
Energy transfer always occurs through heat.
The only way to create energy is through nuclear reactions.
The only way to create energy is through nuclear reactions.
100% of energy is always converted with perfect efficiency.
Responses
Energy constantly changes from one form to another.
Energy constantly changes from one form to another.
Energy transfer always occurs through heat.
Energy transfer always occurs through heat.
The only way to create energy is through nuclear reactions.
The only way to create energy is through nuclear reactions.
100% of energy is always converted with perfect efficiency.
Energy constantly changes from one form to another.
When a match is struck, what forms of energy does the burning match give off?(1 point)
Responses
Solar energy and nuclear energy
Solar energy and nuclear energy
Light energy and thermal energy
Light energy and thermal energy
Nuclear energy and light energy
Nuclear energy and light energy
Thermal energy and solar energy
Responses
Solar energy and nuclear energy
Solar energy and nuclear energy
Light energy and thermal energy
Light energy and thermal energy
Nuclear energy and light energy
Nuclear energy and light energy
Thermal energy and solar energy
Light energy and thermal energy
A light is connected to a battery as shown below.
What type of energy transfer occurs?
(1 point)
Responses
Electrical energy to mechanical energy
Electrical energy to mechanical energy
Chemical energy to electrical energy
Chemical energy to electrical energy
Chemical energy to mechanical energy
Chemical energy to mechanical energy
Mechanical energy to electrical energy
What type of energy transfer occurs?
(1 point)
Responses
Electrical energy to mechanical energy
Electrical energy to mechanical energy
Chemical energy to electrical energy
Chemical energy to electrical energy
Chemical energy to mechanical energy
Chemical energy to mechanical energy
Mechanical energy to electrical energy
Chemical energy to electrical energy
When an electric fan is plugged into a wall outlet, the fan blades spin as a result. What energy transformation occurred?(1 point)
Responses
Mechanical energy is created, but electrical energy is destroyed.
Mechanical energy is created, but electrical energy is destroyed.
Electrical energy is created, but mechanical energy is destroyed.
Electrical energy is created, but mechanical energy is destroyed.
Mechanical to electrical
Mechanical to electrical
Electrical to mechanical
Responses
Mechanical energy is created, but electrical energy is destroyed.
Mechanical energy is created, but electrical energy is destroyed.
Electrical energy is created, but mechanical energy is destroyed.
Electrical energy is created, but mechanical energy is destroyed.
Mechanical to electrical
Mechanical to electrical
Electrical to mechanical
Electrical to mechanical
A simple circuit is wired with a battery, a switch, and a bell.
When the switch is turned on, what energy transformations will occur?
(1 point)
Responses
The switch’s electrical energy transforms to sound energy, which the wire transfers to the bell.
The switch’s electrical energy transforms to sound energy, which the wire transfers to the bell.
The battery’s chemical energy transforms to sound energy, which the wire transfers to the bell.
The battery’s chemical energy transforms to sound energy, which the wire transfers to the bell.
The battery’s chemical energy transforms to electrical energy, which the bell then transforms to sound energy.
The battery’s chemical energy transforms to electrical energy, which the bell then transforms to sound energy.
The switch transforms electrical energy to chemical energy, which the bell then transforms to sound energy.
When the switch is turned on, what energy transformations will occur?
(1 point)
Responses
The switch’s electrical energy transforms to sound energy, which the wire transfers to the bell.
The switch’s electrical energy transforms to sound energy, which the wire transfers to the bell.
The battery’s chemical energy transforms to sound energy, which the wire transfers to the bell.
The battery’s chemical energy transforms to sound energy, which the wire transfers to the bell.
The battery’s chemical energy transforms to electrical energy, which the bell then transforms to sound energy.
The battery’s chemical energy transforms to electrical energy, which the bell then transforms to sound energy.
The switch transforms electrical energy to chemical energy, which the bell then transforms to sound energy.
The battery’s chemical energy transforms to electrical energy, which the bell then transforms to sound energy.
Which type of energy transfer can take place without matter present?(1 point)
Responses
Radiation
Radiation
Conduction
Conduction
Convection
Convection
Insulation
Responses
Radiation
Radiation
Conduction
Conduction
Convection
Convection
Insulation
Radiation
The picture below shows two flasks, one with hot water and one with room temperature water, which are connected by a conductive metal bar.
In which direction does the thermal energy between the flasks flow?
(1 point)
Responses
Thermal energy flows from the flask with room temperature water to the flask with hot water.
Thermal energy flows from the flask with room temperature water to the flask with hot water.
Thermal energy flows from the flask with hot water to the flask with room temperature water.
Thermal energy flows from the flask with hot water to the flask with room temperature water.
Thermal energy flows equally between the two flasks.
Thermal energy flows equally between the two flasks.
Thermal energy does not flow between the two flasks.
Thermal energy does not flow between the two flasks.
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In which direction does the thermal energy between the flasks flow?
(1 point)
Responses
Thermal energy flows from the flask with room temperature water to the flask with hot water.
Thermal energy flows from the flask with room temperature water to the flask with hot water.
Thermal energy flows from the flask with hot water to the flask with room temperature water.
Thermal energy flows from the flask with hot water to the flask with room temperature water.
Thermal energy flows equally between the two flasks.
Thermal energy flows equally between the two flasks.
Thermal energy does not flow between the two flasks.
Thermal energy does not flow between the two flasks.
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Thermal energy flows from the flask with hot water to the flask with room temperature water.
Lucy is making a cup of hot chocolate. She puts the chocolate and hot water into a cup, and stirs the mixture.
A few minutes later, she notices the cup and the spoon have gotten hot. What made Lucy’s cup and spoon get hot?
(1 point)
Responses
Heat was transferred through convection to the cup and spoon when the hot water molecules radiated into the cooler molecules of the hot chocolate mix and transferred heat.
Heat was transferred through convection to the cup and spoon when the hot water molecules radiated into the cooler molecules of the hot chocolate mix and transferred heat.
Heat was transferred through convection to the cup and spoon when the hot water molecules moved through the cooler molecules in the surrounding air and transferred heat.
Heat was transferred through convection to the cup and spoon when the hot water molecules moved through the cooler molecules in the surrounding air and transferred heat.
Heat was transferred through conduction to the cup and spoon when the hot water molecules flowed in currents through the cooler molecules of the hot chocolate mix and transferred heat.
Heat was transferred through conduction to the cup and spoon when the hot water molecules flowed in currents through the cooler molecules of the hot chocolate mix and transferred heat.
Heat was transferred through conduction to the cup and spoon when the hot water molecules collided frequently with the cooler molecules in the cup and spoon and transferred heat.
Heat was transferred through conduction to the cup and spoon when the hot water molecules collided frequently with the cooler molecules in the cup and spoon and transferred heat.
A few minutes later, she notices the cup and the spoon have gotten hot. What made Lucy’s cup and spoon get hot?
(1 point)
Responses
Heat was transferred through convection to the cup and spoon when the hot water molecules radiated into the cooler molecules of the hot chocolate mix and transferred heat.
Heat was transferred through convection to the cup and spoon when the hot water molecules radiated into the cooler molecules of the hot chocolate mix and transferred heat.
Heat was transferred through convection to the cup and spoon when the hot water molecules moved through the cooler molecules in the surrounding air and transferred heat.
Heat was transferred through convection to the cup and spoon when the hot water molecules moved through the cooler molecules in the surrounding air and transferred heat.
Heat was transferred through conduction to the cup and spoon when the hot water molecules flowed in currents through the cooler molecules of the hot chocolate mix and transferred heat.
Heat was transferred through conduction to the cup and spoon when the hot water molecules flowed in currents through the cooler molecules of the hot chocolate mix and transferred heat.
Heat was transferred through conduction to the cup and spoon when the hot water molecules collided frequently with the cooler molecules in the cup and spoon and transferred heat.
Heat was transferred through conduction to the cup and spoon when the hot water molecules collided frequently with the cooler molecules in the cup and spoon and transferred heat.
Heat was transferred through conduction to the cup and spoon when the hot water molecules collided frequently with the cooler molecules in the cup and spoon and transferred heat.
The picture below shows two rooms at different temperatures.
Which statement describes what will happen as the door opens between the two rooms?
(1 point)
Responses
The temperature in each room will remain unchanged.
The temperature in each room will remain unchanged.
The temperature in both rooms will become equal over time.
The temperature in both rooms will become equal over time.
The colder room will warm up to 80°F.
The colder room will warm up to 80°F.
The warmer room will cool down to 50°F.
Which statement describes what will happen as the door opens between the two rooms?
(1 point)
Responses
The temperature in each room will remain unchanged.
The temperature in each room will remain unchanged.
The temperature in both rooms will become equal over time.
The temperature in both rooms will become equal over time.
The colder room will warm up to 80°F.
The colder room will warm up to 80°F.
The warmer room will cool down to 50°F.
The temperature in both rooms will become equal over time.
An ice cube is placed on a metal block that is at a room temperature of 30oC. Which statement describes the transfer of heat between the ice cube and metal block?(1 point)
Responses
Heat is transferred from the air to the ice cube, and the ice melts.
Heat is transferred from the air to the ice cube, and the ice melts.
Heat is transferred from the air and metal to the ice cube, and the ice melts.
Heat is transferred from the air and metal to the ice cube, and the ice melts.
Heat is transferred from the ice cube to the metal block, and the ice melts.
Heat is transferred from the ice cube to the metal block, and the ice melts.
Heat is transferred from the ice cube to the air, and the ice melts.
Responses
Heat is transferred from the air to the ice cube, and the ice melts.
Heat is transferred from the air to the ice cube, and the ice melts.
Heat is transferred from the air and metal to the ice cube, and the ice melts.
Heat is transferred from the air and metal to the ice cube, and the ice melts.
Heat is transferred from the ice cube to the metal block, and the ice melts.
Heat is transferred from the ice cube to the metal block, and the ice melts.
Heat is transferred from the ice cube to the air, and the ice melts.
Heat is transferred from the air and metal to the ice cube, and the ice melts.
Heated gases will rise to the top of its container. Why does this occur?(1 point)
Responses
Heated gases will increase in kinetic energy and decrease in density.
Heated gases will increase in kinetic energy and decrease in density.
Heated gases will decrease in kinetic energy and increase in density.
Heated gases will decrease in kinetic energy and increase in density.
Heated gases will increase in kinetic energy and increase in density.
Heated gases will increase in kinetic energy and increase in density.
Heated gases will decrease in kinetic energy and decrease in density.
Responses
Heated gases will increase in kinetic energy and decrease in density.
Heated gases will increase in kinetic energy and decrease in density.
Heated gases will decrease in kinetic energy and increase in density.
Heated gases will decrease in kinetic energy and increase in density.
Heated gases will increase in kinetic energy and increase in density.
Heated gases will increase in kinetic energy and increase in density.
Heated gases will decrease in kinetic energy and decrease in density.
Heated gases will increase in kinetic energy and decrease in density.
A woman runs as shown.
What main energy conversion occurs?
(1 point)
Responses
Thermal energy changes into mechanical energy because heat provides energy for motion.
Thermal energy changes into mechanical energy because heat provides energy for motion.
Mechanical energy changes into chemical energy as the kinetic energy from motion creates reactions in the surrounding air.
Mechanical energy changes into chemical energy as the kinetic energy from motion creates reactions in the surrounding air.
Chemical energy changes into mechanical energy because energy from digestion of food provides energy for the runner’s motion.
Chemical energy changes into mechanical energy because energy from digestion of food provides energy for the runner’s motion.
Mechanical energy changes into thermal energy because the energy from motion creates heat in the air around the runner.
Mechanical energy changes into thermal energy because the energy from motion creates heat in the air around the runner.
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What main energy conversion occurs?
(1 point)
Responses
Thermal energy changes into mechanical energy because heat provides energy for motion.
Thermal energy changes into mechanical energy because heat provides energy for motion.
Mechanical energy changes into chemical energy as the kinetic energy from motion creates reactions in the surrounding air.
Mechanical energy changes into chemical energy as the kinetic energy from motion creates reactions in the surrounding air.
Chemical energy changes into mechanical energy because energy from digestion of food provides energy for the runner’s motion.
Chemical energy changes into mechanical energy because energy from digestion of food provides energy for the runner’s motion.
Mechanical energy changes into thermal energy because the energy from motion creates heat in the air around the runner.
Mechanical energy changes into thermal energy because the energy from motion creates heat in the air around the runner.
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Chemical energy changes into mechanical energy because energy from digestion of food provides energy for the runner’s motion.
1 answer