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470 Cards in this Set
- Front
- Back
Nuclear Reactions depend on...
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The binding energy in the atomic nucleus.
|
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Nuclear Reactions depend on...
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The binding energy in the atomic nucleus.
|
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Define: Fusion
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2 light nuclei such as hydrogen combining into one
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Define: Fusion
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2 light nuclei such as hydrogen combining into one
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Define Fission
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Heavy nuclei release large amounts of energy.
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Nuclear Reactions depend on...
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The binding energy in the atomic nucleus.
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Radio active Decay: The nucleus will spontaneously decay into another element named...
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The daughter product
|
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Define Fission
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Heavy nuclei release large amounts of energy.
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Radioactive Decay: What is used to measure the isotopes decay rate?
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Half-life
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Define: Fusion
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2 light nuclei such as hydrogen combining into one
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Radio active Decay: The nucleus will spontaneously decay into another element named...
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The daughter product
|
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Nuclear Reactions depend on...
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The binding energy in the atomic nucleus.
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Define Fission
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Heavy nuclei release large amounts of energy.
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Radioactivity's uses (2)
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Monitoring and understanding the environment
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Radioactive Decay: What is used to measure the isotopes decay rate?
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Half-life
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Define: Fusion
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2 light nuclei such as hydrogen combining into one
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Collisions between (gas, fluid) molecules and their exchange of momentum control what? (3)
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Diffusion, heat flow, and other fluid dynamical properties.
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Radio active Decay: The nucleus will spontaneously decay into another element named...
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The daughter product
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Radioactivity's uses (2)
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Monitoring and understanding the environment
|
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Define Fission
|
Heavy nuclei release large amounts of energy.
|
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Radioactive Decay: What is used to measure the isotopes decay rate?
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Half-life
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Define: Elastic Collusions:
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KE is not lost through collusion.
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Collisions between (gas, fluid) molecules and their exchange of momentum control what? (3)
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Diffusion, heat flow, and other fluid dynamical properties.
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Radio active Decay: The nucleus will spontaneously decay into another element named...
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The daughter product
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Radioactivity's uses (2)
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Monitoring and understanding the environment
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Define: Inelastic Collisions
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KE is converted to another form of energy through collisions.
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Define: Elastic Collusions:
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KE is not lost through collusion.
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Name 1 application of the Gravitational Force equation.
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Landslides
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Radioactive Decay: What is used to measure the isotopes decay rate?
|
Half-life
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Define: Inelastic Collisions
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KE is converted to another form of energy through collisions.
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Collisions between (gas, fluid) molecules and their exchange of momentum control what? (3)
|
Diffusion, heat flow, and other fluid dynamical properties.
|
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Name 1 application of the Gravitational Force equation.
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Landslides
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Radioactivity's uses (2)
|
Monitoring and understanding the environment
|
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Define: Elastic Collusions:
|
KE is not lost through collusion.
|
|
Nuclear Reactions depend on...
|
The binding energy in the atomic nucleus.
|
|
Nuclear Reactions depend on...
|
The binding energy in the atomic nucleus.
|
|
Collisions between (gas, fluid) molecules and their exchange of momentum control what? (3)
|
Diffusion, heat flow, and other fluid dynamical properties.
|
|
Define: Fusion
|
2 light nuclei such as hydrogen combining into one
|
|
Define: Fusion
|
2 light nuclei such as hydrogen combining into one
|
|
Define: Elastic Collusions:
|
KE is not lost through collusion.
|
|
Define Fission
|
Heavy nuclei release large amounts of energy.
|
|
Define Fission
|
Heavy nuclei release large amounts of energy.
|
|
Define: Inelastic Collisions
|
KE is converted to another form of energy through collisions.
|
|
Radio active Decay: The nucleus will spontaneously decay into another element named...
|
The daughter product
|
|
Name 1 application of the Gravitational Force equation.
|
Landslides
|
|
Radioactive Decay: What is used to measure the isotopes decay rate?
|
Half-life
|
|
Radio active Decay: The nucleus will spontaneously decay into another element named...
|
The daughter product
|
|
Define: Inelastic Collisions
|
KE is converted to another form of energy through collisions.
|
|
Radioactive Decay: What is used to measure the isotopes decay rate?
|
Half-life
|
|
Radioactivity's uses (2)
|
Monitoring and understanding the environment
|
|
Name 1 application of the Gravitational Force equation.
|
Landslides
|
|
Collisions between (gas, fluid) molecules and their exchange of momentum control what? (3)
|
Diffusion, heat flow, and other fluid dynamical properties.
|
|
Radioactivity's uses (2)
|
Monitoring and understanding the environment
|
|
Collisions between (gas, fluid) molecules and their exchange of momentum control what? (3)
|
Diffusion, heat flow, and other fluid dynamical properties.
|
|
Define: Elastic Collusions:
|
KE is not lost through collusion.
|
|
Define: Elastic Collusions:
|
KE is not lost through collusion.
|
|
Define: Inelastic Collisions
|
KE is converted to another form of energy through collisions.
|
|
Define: Inelastic Collisions
|
KE is converted to another form of energy through collisions.
|
|
Name 1 application of the Gravitational Force equation.
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Landslides
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Name 1 application of the Gravitational Force equation.
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Landslides
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Landslides will occur when.... (forces)...
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Gravitational force down a slope is greater than the frictional forces that support the soil.
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What is one method of studying the interior of the Earth?
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Measuring deviations from g along the Earth's surface.
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Kepler's Laws can be used to determine....
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Orbits of Comets, planets and satellites.
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Low orbit satellites are useful for...
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Meteorological purposes
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Satellites that orbit at a higher altitude have...
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Smaller velocities
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Define: Terminal Velocity
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The max speed something can reach when it is falling (so it stops increasing in speed)
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Higher terminal velocity means...
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Particles settle more rapidly
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Name 1 application of terminal velocity
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In settling chambers
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Define: Coriolis Force
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An explanation why low pressure wind systems blow counterclockwise in the northern hemisphere and clockwise in the other.
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Rotational Dynamics and Angular Momenta provide understanding in (3)
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1. The relation between climate systems and the Earth's Rotation
2. Vortices in the wind and water 3. Pollution control technology |
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Vortices can be observed in:
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Swirling water, tornadoes, whirlpools, climatic features, turbulent flow.
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Define Vorticity:
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A measure of the rotation of a fluid about an axis.
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In a vortex the rotating fluid is drawn towards the....
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centre of rotation
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In a vortex, as the fluid is drawn to the centre of the vortex the vortex is, in effect....
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speeding up
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Maxwell equations are...
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not equations for mass point, but for a field in space and time.
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What is the difference between gravity and electromagnetic forces?
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Gravity is always attractive, electromagnetic forces can be attractive or repulsive due to electric charges being positive or negative.
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Electricity's Unit is...
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Coulombs
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Electric Current is defined as...
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A measure of how much charge is moving along a conductor
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Voltage is a measure of...
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The potential difference in electric potential energy between two points in a circuit.
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Name 3 examples of Ferromagnetic Materials:
|
Iron, Cobalt, Nickel
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Ferromagnetic hold a ________ magnetic field.
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Permenant
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Materials that contain Paraagnetism:
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Solids, Liquids, Gases
|
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Paramagnets cannot hold a magnetic field _________.
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Permanently
|
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Paramagnetic materials become magnetic when....
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They are exposed to an external magnetic field.
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The strength of the induced magnetization depends on... (2)
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The strength of the external field and the magnetic susceptibility of the material
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What happens at the Curie Temperature?
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A Ferromagnet loses its magnetization and becomes paramagnetic.
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Application of the Curie Temperature..?
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When a rock is Hot magma and it cools through the Curie point, picking up the Earth's magnetic field, producing remanent magnetization in the rock.
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Magnetic Field strength is measure in (units)...
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Telsa
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Earth's core is....
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liquid iron
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Define: Magnetic declination
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Deviation between magnetic north and true north
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Define: Magnetic Inclination
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Angle between a compass needle and the horizontal at any point.
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Measurement of the Earth's magnetic field can provide data on...
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subsurface structures which affect the magnetic field.
|
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Rocks have general magnetic fields with 2 components:
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1. Remanent magnetization (From when the rock was formed)
2. Induced magnetization (present day magnetic field of the Earth) |
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Electric currents create...
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Magnetism
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Changing/moving magnetic fields create....
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Electric currents
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What is an Electromagnet?
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A magnet created by a current in a coil of wire surrounding a metal core which concentrates the magnetic field.
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Name an example of electricity used by animals:
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Fish in the dark use light, electric signals to send messages around the body
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Define Polarization:
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The direction of oscillation of a transverse wave, "not polarized" means that direction changes frequently
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Name some forms of electromagnetic radiation
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Infrared, UV, Xrays, Gamma rays.
|
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Materials involved in Mechanical Waves...
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MATERIAL is involved. EX. Waves on strings, acoustic waves, water waves, shock waves...
|
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Define: Magnetic Inclination
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Angle between a compass needle and the horizontal at any point.
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Measurement of the Earth's magnetic field can provide data on...
|
subsurface structures which affect the magnetic field.
|
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Rocks have general magnetic fields with 2 components:
|
1. Remanent magnetization (From when the rock was formed)
2. Induced magnetization (present day magnetic field of the Earth) |
|
Electric currents create...
|
Magnetism
|
|
Changing/moving magnetic fields create....
|
Electric currents
|
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What is an Electromagnet?
|
A magnet created by a current in a coil of wire surrounding a metal core which concentrates the magnetic field.
|
|
Name an example of electricity used by animals:
|
Fish in the dark use light, electric signals to send messages around the body
|
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Define Polarization:
|
The direction of oscillation of a transverse wave, "not polarized" means that direction changes frequently
|
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Name some forms of electromagnetic radiation
|
Infrared, UV, Xrays, Gamma rays.
|
|
Materials involved in Mechanical Waves...
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MATERIAL is involved. EX. Waves on strings, acoustic waves, water waves, shock waves...
|
|
Define: Magnetic Inclination
|
Angle between a compass needle and the horizontal at any point.
|
|
Measurement of the Earth's magnetic field can provide data on...
|
subsurface structures which affect the magnetic field.
|
|
Rocks have general magnetic fields with 2 components:
|
1. Remanent magnetization (From when the rock was formed)
2. Induced magnetization (present day magnetic field of the Earth) |
|
Electric currents create...
|
Magnetism
|
|
Changing/moving magnetic fields create....
|
Electric currents
|
|
What is an Electromagnet?
|
A magnet created by a current in a coil of wire surrounding a metal core which concentrates the magnetic field.
|
|
Name an example of electricity used by animals:
|
Fish in the dark use light, electric signals to send messages around the body
|
|
Define Polarization:
|
The direction of oscillation of a transverse wave, "not polarized" means that direction changes frequently
|
|
Name some forms of electromagnetic radiation
|
Infrared, UV, Xrays, Gamma rays.
|
|
Materials involved in Mechanical Waves...
|
MATERIAL is involved. EX. Waves on strings, acoustic waves, water waves, shock waves...
|
|
Material in Electromagnetic waves
|
In empty space, don't need an "ether"
|
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Material in Gravitational waves
|
Space and time
|
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Probability waves are used in..
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Quantum Mechanics
|
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Define: Phase Velocity
|
The speed at which the phase of any one frequency component of the wave travels.
|
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Define: Group Velocity
|
The velocity with which the overall shape of the waves amplitudes propagates through space.
|
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Speed of a wave can depend on...
|
Medium in which the wave propagates
Wavelength Amplitude |
|
Seismic waves AKA
|
Shockwaves
|
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Seismic waves from Earthquakes can be used to...
|
locate the center of an earthquake
|
|
Reflection of waves examples (2)
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Waves of a wall, echoes from a cliff
|
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Refraction of waves:
|
the change in direction of wave due to a change in its speed.
|
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Define Wave Diffraction`
|
The wave phenomena when waves hit obstacles, bend around corners, spread behind slits
|
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Define Wave Diffraction`
|
The wave phenomena when waves hit obstacles, bend around corners, spread behind slits
|
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Define waves scattering:
|
Combination of reflection and diffraction
|
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Polarization can be found in electromagnetic waves and....
|
seismic waves
|
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Define waves scattering:
|
Combination of reflection and diffraction
|
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Polarization can be found in electromagnetic waves and....
|
seismic waves
|
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Define: Wave Dispersion
|
When a waves velocity depends on the waves frequency.
|
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Define: Wave Dispersion
|
When a waves velocity depends on the waves frequency.
|
|
First law of thermodynamics
|
Energy in a system is conserved if heat is taken into account and energy is conserved in any process involving a themodynamic system and its surroundings
|
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First law of thermodynamics
|
Energy in a system is conserved if heat is taken into account and energy is conserved in any process involving a themodynamic system and its surroundings
|
|
Define Specific Heat:
|
the increase in total heat per unt increase in temperature when a unit mass of gas is heated.
|
|
Define Specific Heat:
|
the increase in total heat per unt increase in temperature when a unit mass of gas is heated.
|
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Define Latent heat:
|
When heat supplied to a substance without temp. change involves a phase change.
|
|
Define Latent heat:
|
When heat supplied to a substance without temp. change involves a phase change.
|
|
Define Compressibility
|
How much a fluid can be compressed
|
|
Define Compressibility
|
How much a fluid can be compressed
|
|
Viscosity
|
A measure of how "treacle" a liquid is
|
|
Viscosity
|
A measure of how "treacle" a liquid is
|
|
Laminar Flow
|
Uniform and orderly as in groudwater or blood circulation
|
|
Laminar Flow
|
Uniform and orderly as in groudwater or blood circulation
|
|
Turbulent Flow
|
Many different speeds and directions at the same time.
|
|
Turbulent Flow
|
Many different speeds and directions at the same time.
|
|
Reynolds number
|
a number that indicates whether a fluid will be laminar or turbulent
|
|
High Reynolds Number =
|
Slow flow
|
|
Reynolds number
|
a number that indicates whether a fluid will be laminar or turbulent
|
|
High Reynolds Number =
|
Slow flow
|
|
Low Reynolds Number =
|
Fast flow
|
|
Low Reynolds Number =
|
Fast flow
|
|
Bernoulli's prinicple
|
When fluids flow faster, its pressure decreases, and due to gravity it also depends on the height.
|
|
Bernoulli's prinicple
|
When fluids flow faster, its pressure decreases, and due to gravity it also depends on the height.
|
|
Dispersion
|
The speed of pollutants in space and time around a source
|
|
Dispersion
|
The speed of pollutants in space and time around a source
|
|
Diffusion
|
Physical provess, based on the thermal motion of particles
|
|
Diffusion
|
Physical provess, based on the thermal motion of particles
|
|
Convection
|
Change brought about by changes in temperature affecting density and creating currents
|
|
Convection
|
Change brought about by changes in temperature affecting density and creating currents
|
|
Conduction
|
Movement of heat through a surface by exchange of thermal energy between neighboring atoms
|
|
Conduction
|
Movement of heat through a surface by exchange of thermal energy between neighboring atoms
|
|
Radiation
|
transfer of heat energy via elevtromagnetic waves
|
|
Radiation
|
transfer of heat energy via elevtromagnetic waves
|
|
Convection
|
the movement of liquids or gases brought about by changes in temp. affecting the density and creating currents
|
|
Kinetic Energy
|
Related to motion, wind, waves, or thermal in heat
|
|
Potential energy
|
chemical energy stored in biomass
|
|
Conventional energy
|
uses fossil fuels like coal, oil, natural gase, release CO2 that may have been absorbed millions of years ago
|
|
Renewable energy
|
sources are the sun, wind, waves, geothermal, gravitational
|
|
Binding energy
|
electric potential between charges
|
|
Heat
|
Kinetic energy of brownian motion of atoms and molecules
|
|
Geothemal energy
|
Earth's internal heat
|
|
2nd Law of thermodynamics
|
No process is possible whose sole result is the transfer of heat from a body of lower temperature to a body of higher temperature.
|
|
Heat engines
|
Devices that operate between 2 or more heat resivoirs and thereby produce mechanical work
|
|
converting Mechanical energy to electricity by
|
squeezing crystals
|
|
converting thermal energy to electricity by
|
2 metals at different temp t o measure temp. electricity
|
|
converting radiation to electricity by
|
light in photovoltaics
|
|
for Voltage = ( what resistance, what power? )
|
low resistance = high power
|
|
how much energy in Wind energy is lost through blade movement?
|
40%
|
|
solar collection:
|
a device where the incoming solar radiation is converted into heat in an efficient way.
|
|
respiration
|
the process by which all living things use energy
|
|
2 disadvantages of renewable energy sources
|
they are intermittent and unpredictable
|
|
Carbon dating uses a measurement of...
|
the proportion of carbon's radioactive isotope to calculate the age of ancient organic objects
|
|
Radiometric dating of rocks is based on measuring...
|
proportions of the parent and daughter material.
|
|
converting Mechanical energy to electricity by
|
squeezing crystals
|
|
converting thermal energy to electricity by
|
2 metals at different temp t o measure temp. electricity
|
|
converting radiation to electricity by
|
light in photovoltaics
|
|
for Voltage = ( what resistance, what power? )
|
low resistance = high power
|
|
how much energy in Wind energy is lost through blade movement?
|
40%
|
|
solar collection:
|
a device where the incoming solar radiation is converted into heat in an efficient way.
|
|
respiration
|
the process by which all living things use energy
|
|
converting Mechanical energy to electricity by
|
squeezing crystals
|
|
converting thermal energy to electricity by
|
2 metals at different temp t o measure temp. electricity
|
|
2 disadvantages of renewable energy sources
|
they are intermittent and unpredictable
|
|
converting radiation to electricity by
|
light in photovoltaics
|
|
Carbon dating uses a measurement of...
|
the proportion of carbon's radioactive isotope to calculate the age of ancient organic objects
|
|
for Voltage = ( what resistance, what power? )
|
low resistance = high power
|
|
Radiometric dating of rocks is based on measuring...
|
proportions of the parent and daughter material.
|
|
how much energy in Wind energy is lost through blade movement?
|
40%
|
|
solar collection:
|
a device where the incoming solar radiation is converted into heat in an efficient way.
|
|
respiration
|
the process by which all living things use energy
|
|
2 disadvantages of renewable energy sources
|
they are intermittent and unpredictable
|
|
Carbon dating uses a measurement of...
|
the proportion of carbon's radioactive isotope to calculate the age of ancient organic objects
|
|
converting Mechanical energy to electricity by
|
squeezing crystals
|
|
converting Mechanical energy to electricity by
|
squeezing crystals
|
|
converting Mechanical energy to electricity by
|
squeezing crystals
|
|
converting Mechanical energy to electricity by
|
squeezing crystals
|
|
Radiometric dating of rocks is based on measuring...
|
proportions of the parent and daughter material.
|
|
converting thermal energy to electricity by
|
2 metals at different temp t o measure temp. electricity
|
|
converting thermal energy to electricity by
|
2 metals at different temp t o measure temp. electricity
|
|
converting thermal energy to electricity by
|
2 metals at different temp t o measure temp. electricity
|
|
converting thermal energy to electricity by
|
2 metals at different temp t o measure temp. electricity
|
|
converting radiation to electricity by
|
light in photovoltaics
|
|
converting radiation to electricity by
|
light in photovoltaics
|
|
converting radiation to electricity by
|
light in photovoltaics
|
|
converting Mechanical energy to electricity by
|
squeezing crystals
|
|
converting Mechanical energy to electricity by
|
squeezing crystals
|
|
converting Mechanical energy to electricity by
|
squeezing crystals
|
|
converting Mechanical energy to electricity by
|
squeezing crystals
|
|
converting Mechanical energy to electricity by
|
squeezing crystals
|
|
converting thermal energy to electricity by
|
2 metals at different temp t o measure temp. electricity
|
|
converting thermal energy to electricity by
|
2 metals at different temp t o measure temp. electricity
|
|
converting radiation to electricity by
|
light in photovoltaics
|
|
converting thermal energy to electricity by
|
2 metals at different temp t o measure temp. electricity
|
|
for Voltage = ( what resistance, what power? )
|
low resistance = high power
|
|
converting Mechanical energy to electricity by
|
squeezing crystals
|
|
converting Mechanical energy to electricity by
|
squeezing crystals
|
|
for Voltage = ( what resistance, what power? )
|
low resistance = high power
|
|
converting thermal energy to electricity by
|
2 metals at different temp t o measure temp. electricity
|
|
converting thermal energy to electricity by
|
2 metals at different temp t o measure temp. electricity
|
|
converting radiation to electricity by
|
light in photovoltaics
|
|
converting thermal energy to electricity by
|
2 metals at different temp t o measure temp. electricity
|
|
converting radiation to electricity by
|
light in photovoltaics
|
|
converting radiation to electricity by
|
light in photovoltaics
|
|
for Voltage = ( what resistance, what power? )
|
low resistance = high power
|
|
for Voltage = ( what resistance, what power? )
|
low resistance = high power
|
|
how much energy in Wind energy is lost through blade movement?
|
40%
|
|
for Voltage = ( what resistance, what power? )
|
low resistance = high power
|
|
converting radiation to electricity by
|
light in photovoltaics
|
|
how much energy in Wind energy is lost through blade movement?
|
40%
|
|
for Voltage = ( what resistance, what power? )
|
low resistance = high power
|
|
converting radiation to electricity by
|
light in photovoltaics
|
|
how much energy in Wind energy is lost through blade movement?
|
40%
|
|
for Voltage = ( what resistance, what power? )
|
low resistance = high power
|
|
for Voltage = ( what resistance, what power? )
|
low resistance = high power
|
|
solar collection:
|
a device where the incoming solar radiation is converted into heat in an efficient way.
|
|
converting Mechanical energy to electricity by
|
squeezing crystals
|
|
converting Mechanical energy to electricity by
|
squeezing crystals
|
|
for Voltage = ( what resistance, what power? )
|
low resistance = high power
|
|
solar collection:
|
a device where the incoming solar radiation is converted into heat in an efficient way.
|
|
converting Mechanical energy to electricity by
|
squeezing crystals
|
|
converting Mechanical energy to electricity by
|
squeezing crystals
|
|
converting Mechanical energy to electricity by
|
squeezing crystals
|
|
converting Mechanical energy to electricity by
|
squeezing crystals
|
|
how much energy in Wind energy is lost through blade movement?
|
40%
|
|
how much energy in Wind energy is lost through blade movement?
|
40%
|
|
converting Mechanical energy to electricity by
|
squeezing crystals
|
|
converting Mechanical energy to electricity by
|
squeezing crystals
|
|
how much energy in Wind energy is lost through blade movement?
|
40%
|
|
converting Mechanical energy to electricity by
|
squeezing crystals
|
|
how much energy in Wind energy is lost through blade movement?
|
40%
|
|
converting thermal energy to electricity by
|
2 metals at different temp t o measure temp. electricity
|
|
converting thermal energy to electricity by
|
2 metals at different temp t o measure temp. electricity
|
|
converting thermal energy to electricity by
|
2 metals at different temp t o measure temp. electricity
|
|
converting thermal energy to electricity by
|
2 metals at different temp t o measure temp. electricity
|
|
converting thermal energy to electricity by
|
2 metals at different temp t o measure temp. electricity
|
|
converting Mechanical energy to electricity by
|
squeezing crystals
|
|
converting thermal energy to electricity by
|
2 metals at different temp t o measure temp. electricity
|
|
solar collection:
|
a device where the incoming solar radiation is converted into heat in an efficient way.
|
|
converting thermal energy to electricity by
|
2 metals at different temp t o measure temp. electricity
|
|
converting Mechanical energy to electricity by
|
squeezing crystals
|
|
converting radiation to electricity by
|
light in photovoltaics
|
|
converting Mechanical energy to electricity by
|
squeezing crystals
|
|
converting radiation to electricity by
|
light in photovoltaics
|
|
how much energy in Wind energy is lost through blade movement?
|
40%
|
|
for Voltage = ( what resistance, what power? )
|
low resistance = high power
|
|
respiration
|
the process by which all living things use energy
|
|
solar collection:
|
a device where the incoming solar radiation is converted into heat in an efficient way.
|
|
converting radiation to electricity by
|
light in photovoltaics
|
|
respiration
|
the process by which all living things use energy
|
|
solar collection:
|
a device where the incoming solar radiation is converted into heat in an efficient way.
|
|
converting radiation to electricity by
|
light in photovoltaics
|
|
converting radiation to electricity by
|
light in photovoltaics
|
|
converting thermal energy to electricity by
|
2 metals at different temp t o measure temp. electricity
|
|
respiration
|
the process by which all living things use energy
|
|
how much energy in Wind energy is lost through blade movement?
|
40%
|
|
converting thermal energy to electricity by
|
2 metals at different temp t o measure temp. electricity
|
|
converting radiation to electricity by
|
light in photovoltaics
|
|
converting Mechanical energy to electricity by
|
squeezing crystals
|
|
converting radiation to electricity by
|
light in photovoltaics
|
|
for Voltage = ( what resistance, what power? )
|
low resistance = high power
|
|
for Voltage = ( what resistance, what power? )
|
low resistance = high power
|
|
respiration
|
the process by which all living things use energy
|
|
converting radiation to electricity by
|
light in photovoltaics
|
|
2 disadvantages of renewable energy sources
|
they are intermittent and unpredictable
|
|
converting radiation to electricity by
|
light in photovoltaics
|
|
2 disadvantages of renewable energy sources
|
they are intermittent and unpredictable
|
|
converting Mechanical energy to electricity by
|
squeezing crystals
|
|
for Voltage = ( what resistance, what power? )
|
low resistance = high power
|
|
how much energy in Wind energy is lost through blade movement?
|
40%
|
|
how much energy in Wind energy is lost through blade movement?
|
40%
|
|
solar collection:
|
a device where the incoming solar radiation is converted into heat in an efficient way.
|
|
solar collection:
|
a device where the incoming solar radiation is converted into heat in an efficient way.
|
|
converting thermal energy to electricity by
|
2 metals at different temp t o measure temp. electricity
|
|
converting thermal energy to electricity by
|
2 metals at different temp t o measure temp. electricity
|
|
converting thermal energy to electricity by
|
2 metals at different temp t o measure temp. electricity
|
|
solar collection:
|
a device where the incoming solar radiation is converted into heat in an efficient way.
|
|
converting thermal energy to electricity by
|
2 metals at different temp t o measure temp. electricity
|
|
for Voltage = ( what resistance, what power? )
|
low resistance = high power
|
|
converting Mechanical energy to electricity by
|
squeezing crystals
|
|
how much energy in Wind energy is lost through blade movement?
|
40%
|
|
solar collection:
|
a device where the incoming solar radiation is converted into heat in an efficient way.
|
|
Carbon dating uses a measurement of...
|
the proportion of carbon's radioactive isotope to calculate the age of ancient organic objects
|
|
for Voltage = ( what resistance, what power? )
|
low resistance = high power
|
|
how much energy in Wind energy is lost through blade movement?
|
40%
|
|
solar collection:
|
a device where the incoming solar radiation is converted into heat in an efficient way.
|
|
solar collection:
|
a device where the incoming solar radiation is converted into heat in an efficient way.
|
|
respiration
|
the process by which all living things use energy
|
|
converting radiation to electricity by
|
light in photovoltaics
|
|
how much energy in Wind energy is lost through blade movement?
|
40%
|
|
respiration
|
the process by which all living things use energy
|
|
for Voltage = ( what resistance, what power? )
|
low resistance = high power
|
|
solar collection:
|
a device where the incoming solar radiation is converted into heat in an efficient way.
|
|
converting thermal energy to electricity by
|
2 metals at different temp t o measure temp. electricity
|
|
respiration
|
the process by which all living things use energy
|
|
converting radiation to electricity by
|
light in photovoltaics
|
|
respiration
|
the process by which all living things use energy
|
|
2 disadvantages of renewable energy sources
|
they are intermittent and unpredictable
|
|
for Voltage = ( what resistance, what power? )
|
low resistance = high power
|
|
Radiometric dating of rocks is based on measuring...
|
proportions of the parent and daughter material.
|
|
converting thermal energy to electricity by
|
2 metals at different temp t o measure temp. electricity
|
|
for Voltage = ( what resistance, what power? )
|
low resistance = high power
|
|
Carbon dating uses a measurement of...
|
the proportion of carbon's radioactive isotope to calculate the age of ancient organic objects
|
|
solar collection:
|
a device where the incoming solar radiation is converted into heat in an efficient way.
|
|
respiration
|
the process by which all living things use energy
|
|
2 disadvantages of renewable energy sources
|
they are intermittent and unpredictable
|
|
converting thermal energy to electricity by
|
2 metals at different temp t o measure temp. electricity
|
|
2 disadvantages of renewable energy sources
|
they are intermittent and unpredictable
|
|
converting radiation to electricity by
|
light in photovoltaics
|
|
for Voltage = ( what resistance, what power? )
|
low resistance = high power
|
|
how much energy in Wind energy is lost through blade movement?
|
40%
|
|
2 disadvantages of renewable energy sources
|
they are intermittent and unpredictable
|
|
2 disadvantages of renewable energy sources
|
they are intermittent and unpredictable
|
|
respiration
|
the process by which all living things use energy
|
|
for Voltage = ( what resistance, what power? )
|
low resistance = high power
|
|
2 disadvantages of renewable energy sources
|
they are intermittent and unpredictable
|
|
Carbon dating uses a measurement of...
|
the proportion of carbon's radioactive isotope to calculate the age of ancient organic objects
|
|
respiration
|
the process by which all living things use energy
|
|
converting radiation to electricity by
|
light in photovoltaics
|
|
how much energy in Wind energy is lost through blade movement?
|
40%
|
|
how much energy in Wind energy is lost through blade movement?
|
40%
|
|
converting radiation to electricity by
|
light in photovoltaics
|
|
respiration
|
the process by which all living things use energy
|
|
Radiometric dating of rocks is based on measuring...
|
proportions of the parent and daughter material.
|
|
for Voltage = ( what resistance, what power? )
|
low resistance = high power
|
|
solar collection:
|
a device where the incoming solar radiation is converted into heat in an efficient way.
|
|
how much energy in Wind energy is lost through blade movement?
|
40%
|
|
Carbon dating uses a measurement of...
|
the proportion of carbon's radioactive isotope to calculate the age of ancient organic objects
|
|
respiration
|
the process by which all living things use energy
|
|
Carbon dating uses a measurement of...
|
the proportion of carbon's radioactive isotope to calculate the age of ancient organic objects
|
|
Carbon dating uses a measurement of...
|
the proportion of carbon's radioactive isotope to calculate the age of ancient organic objects
|
|
2 disadvantages of renewable energy sources
|
they are intermittent and unpredictable
|
|
converting radiation to electricity by
|
light in photovoltaics
|
|
solar collection:
|
a device where the incoming solar radiation is converted into heat in an efficient way.
|
|
solar collection:
|
a device where the incoming solar radiation is converted into heat in an efficient way.
|
|
2 disadvantages of renewable energy sources
|
they are intermittent and unpredictable
|
|
solar collection:
|
a device where the incoming solar radiation is converted into heat in an efficient way.
|
|
how much energy in Wind energy is lost through blade movement?
|
40%
|
|
Radiometric dating of rocks is based on measuring...
|
proportions of the parent and daughter material.
|
|
2 disadvantages of renewable energy sources
|
they are intermittent and unpredictable
|
|
for Voltage = ( what resistance, what power? )
|
low resistance = high power
|
|
converting radiation to electricity by
|
light in photovoltaics
|
|
Carbon dating uses a measurement of...
|
the proportion of carbon's radioactive isotope to calculate the age of ancient organic objects
|
|
respiration
|
the process by which all living things use energy
|
|
respiration
|
the process by which all living things use energy
|
|
for Voltage = ( what resistance, what power? )
|
low resistance = high power
|
|
how much energy in Wind energy is lost through blade movement?
|
40%
|
|
how much energy in Wind energy is lost through blade movement?
|
40%
|
|
2 disadvantages of renewable energy sources
|
they are intermittent and unpredictable
|
|
Carbon dating uses a measurement of...
|
the proportion of carbon's radioactive isotope to calculate the age of ancient organic objects
|
|
2 disadvantages of renewable energy sources
|
they are intermittent and unpredictable
|
|
Radiometric dating of rocks is based on measuring...
|
proportions of the parent and daughter material.
|
|
how much energy in Wind energy is lost through blade movement?
|
40%
|
|
Radiometric dating of rocks is based on measuring...
|
proportions of the parent and daughter material.
|
|
how much energy in Wind energy is lost through blade movement?
|
40%
|
|
Radiometric dating of rocks is based on measuring...
|
proportions of the parent and daughter material.
|
|
solar collection:
|
a device where the incoming solar radiation is converted into heat in an efficient way.
|
|
Radiometric dating of rocks is based on measuring...
|
proportions of the parent and daughter material.
|
|
for Voltage = ( what resistance, what power? )
|
low resistance = high power
|
|
converting radiation to electricity by
|
light in photovoltaics
|
|
for Voltage = ( what resistance, what power? )
|
low resistance = high power
|
|
Carbon dating uses a measurement of...
|
the proportion of carbon's radioactive isotope to calculate the age of ancient organic objects
|
|
2 disadvantages of renewable energy sources
|
they are intermittent and unpredictable
|
|
Carbon dating uses a measurement of...
|
the proportion of carbon's radioactive isotope to calculate the age of ancient organic objects
|
|
Carbon dating uses a measurement of...
|
the proportion of carbon's radioactive isotope to calculate the age of ancient organic objects
|
|
solar collection:
|
a device where the incoming solar radiation is converted into heat in an efficient way.
|
|
Radiometric dating of rocks is based on measuring...
|
proportions of the parent and daughter material.
|
|
Carbon dating uses a measurement of...
|
the proportion of carbon's radioactive isotope to calculate the age of ancient organic objects
|
|
respiration
|
the process by which all living things use energy
|
|
solar collection:
|
a device where the incoming solar radiation is converted into heat in an efficient way.
|
|
respiration
|
the process by which all living things use energy
|
|
solar collection:
|
a device where the incoming solar radiation is converted into heat in an efficient way.
|
|
for Voltage = ( what resistance, what power? )
|
low resistance = high power
|
|
2 disadvantages of renewable energy sources
|
they are intermittent and unpredictable
|
|
solar collection:
|
a device where the incoming solar radiation is converted into heat in an efficient way.
|
|
how much energy in Wind energy is lost through blade movement?
|
40%
|
|
2 disadvantages of renewable energy sources
|
they are intermittent and unpredictable
|
|
Radiometric dating of rocks is based on measuring...
|
proportions of the parent and daughter material.
|
|
Radiometric dating of rocks is based on measuring...
|
proportions of the parent and daughter material.
|
|
Carbon dating uses a measurement of...
|
the proportion of carbon's radioactive isotope to calculate the age of ancient organic objects
|
|
respiration
|
the process by which all living things use energy
|
|
solar collection:
|
a device where the incoming solar radiation is converted into heat in an efficient way.
|
|
respiration
|
the process by which all living things use energy
|
|
how much energy in Wind energy is lost through blade movement?
|
40%
|
|
Radiometric dating of rocks is based on measuring...
|
proportions of the parent and daughter material.
|
|
respiration
|
the process by which all living things use energy
|
|
respiration
|
the process by which all living things use energy
|
|
Carbon dating uses a measurement of...
|
the proportion of carbon's radioactive isotope to calculate the age of ancient organic objects
|
|
Radiometric dating of rocks is based on measuring...
|
proportions of the parent and daughter material.
|
|
respiration
|
the process by which all living things use energy
|
|
Carbon dating uses a measurement of...
|
the proportion of carbon's radioactive isotope to calculate the age of ancient organic objects
|
|
2 disadvantages of renewable energy sources
|
they are intermittent and unpredictable
|
|
2 disadvantages of renewable energy sources
|
they are intermittent and unpredictable
|
|
Radiometric dating of rocks is based on measuring...
|
proportions of the parent and daughter material.
|
|
solar collection:
|
a device where the incoming solar radiation is converted into heat in an efficient way.
|
|
2 disadvantages of renewable energy sources
|
they are intermittent and unpredictable
|
|
respiration
|
the process by which all living things use energy
|
|
Radiometric dating of rocks is based on measuring...
|
proportions of the parent and daughter material.
|
|
respiration
|
the process by which all living things use energy
|
|
how much energy in Wind energy is lost through blade movement?
|
40%
|
|
2 disadvantages of renewable energy sources
|
they are intermittent and unpredictable
|
|
Radiometric dating of rocks is based on measuring...
|
proportions of the parent and daughter material.
|
|
2 disadvantages of renewable energy sources
|
they are intermittent and unpredictable
|
|
2 disadvantages of renewable energy sources
|
they are intermittent and unpredictable
|
|
Carbon dating uses a measurement of...
|
the proportion of carbon's radioactive isotope to calculate the age of ancient organic objects
|
|
solar collection:
|
a device where the incoming solar radiation is converted into heat in an efficient way.
|
|
2 disadvantages of renewable energy sources
|
they are intermittent and unpredictable
|
|
Carbon dating uses a measurement of...
|
the proportion of carbon's radioactive isotope to calculate the age of ancient organic objects
|
|
2 disadvantages of renewable energy sources
|
they are intermittent and unpredictable
|
|
Carbon dating uses a measurement of...
|
the proportion of carbon's radioactive isotope to calculate the age of ancient organic objects
|
|
Carbon dating uses a measurement of...
|
the proportion of carbon's radioactive isotope to calculate the age of ancient organic objects
|
|
solar collection:
|
a device where the incoming solar radiation is converted into heat in an efficient way.
|
|
Carbon dating uses a measurement of...
|
the proportion of carbon's radioactive isotope to calculate the age of ancient organic objects
|
|
Carbon dating uses a measurement of...
|
the proportion of carbon's radioactive isotope to calculate the age of ancient organic objects
|
|
Carbon dating uses a measurement of...
|
the proportion of carbon's radioactive isotope to calculate the age of ancient organic objects
|
|
Radiometric dating of rocks is based on measuring...
|
proportions of the parent and daughter material.
|
|
Radiometric dating of rocks is based on measuring...
|
proportions of the parent and daughter material.
|
|
Carbon dating uses a measurement of...
|
the proportion of carbon's radioactive isotope to calculate the age of ancient organic objects
|
|
respiration
|
the process by which all living things use energy
|
|
Radiometric dating of rocks is based on measuring...
|
proportions of the parent and daughter material.
|
|
Carbon dating uses a measurement of...
|
the proportion of carbon's radioactive isotope to calculate the age of ancient organic objects
|
|
Radiometric dating of rocks is based on measuring...
|
proportions of the parent and daughter material.
|
|
respiration
|
the process by which all living things use energy
|
|
Radiometric dating of rocks is based on measuring...
|
proportions of the parent and daughter material.
|
|
2 disadvantages of renewable energy sources
|
they are intermittent and unpredictable
|
|
Radiometric dating of rocks is based on measuring...
|
proportions of the parent and daughter material.
|
|
Radiometric dating of rocks is based on measuring...
|
proportions of the parent and daughter material.
|
|
Carbon dating uses a measurement of...
|
the proportion of carbon's radioactive isotope to calculate the age of ancient organic objects
|
|
Radiometric dating of rocks is based on measuring...
|
proportions of the parent and daughter material.
|
|
2 disadvantages of renewable energy sources
|
they are intermittent and unpredictable
|
|
Radiometric dating of rocks is based on measuring...
|
proportions of the parent and daughter material.
|
|
Carbon dating uses a measurement of...
|
the proportion of carbon's radioactive isotope to calculate the age of ancient organic objects
|
|
Radiometric dating of rocks is based on measuring...
|
proportions of the parent and daughter material.
|
|
Radiometric dating of rocks is based on measuring...
|
proportions of the parent and daughter material.
|