Standard Correlation Map
CodeDescriptionLocationTypeLink
NGSS-HS-DCI-PS3.B
Conservation of Energy and Energy Transfer
NGSS-HS-DCI-PS3.B-1
Conservation of energy means that the total change of energy in any system is always equal to the total energy transferred into or out of the system.
p. 764, ¶ 3 SB ContentView
p. 290, ¶ 5 SB ContentView
p. 287, ¶ 1 SB ContentView
p. 794, ¶ 2 SB ContentView
p. 730, ¶ 2 SB ContentView
NGSS-HS-DCI-PS3.B-2
Energy cannot be created or destroyed, but it can be transported from one place to another and transferred between systems.
NGSS-HS-DCI-PS3.B-2-1
Energy cannot be created or destroyed.
p. 252, ¶ 3 SB ContentView
p. 279, ¶ 2 SB ContentView
p. 730, ¶ 2 SB ContentView
p. 284, ¶ 3 SB ContentView
NGSS-HS-DCI-PS3.B-2-2
Energy can be transported from one place to another.
p. 472, ¶ 4 SB ContentView
p. 262, ¶ 5 SB ContentView
p. 701, ¶ 1 SB ContentView
p. 702, ¶ 1 SB ContentView
p. 559, ¶ 1 SB ContentView
NGSS-HS-DCI-PS3.B-2-3
Energy can be transferred between systems.
p. 700, ¶ 1 SB ContentView
p. 291, ¶ 1 SB ContentView
p. 559, ¶ 5 SB ContentView
NGSS-HS-DCI-PS3.B-3
Mathematical expressions, which quantify how the stored energy in a system depends on its configuration (e.g., relative positions of charged particles, compression of a spring) and how kinetic energy depends on mass and speed, allow the concept of conservation of energy to be used to predict and describe system behavior.
NGSS-HS-DCI-PS3.B-3-1
A mathematical expression can quantify how the stored energy in a system depends on its configuration.
p. 257, ¶ 3 SB ContentView
p. 259, ¶ 2 SB ContentView
p. 281, ¶ 3 SB ContentView
p. 535, ¶ 5 SB ContentView
NGSS-HS-DCI-PS3.B-3-2
A mathematical expression can quantify how the kinetic energy in a system depends on mass and speed.
p. 256, ¶ 1 SB ContentView
p. 256, ¶ 4 SB ContentView
p. 281, ¶ 3 SB ContentView
p. 273, #43 SB AssessView
p. 273, #47 SB AssessView
p. 261, #2 SB AssessView
p. 261, #3 SB AssessView
NGSS-HS-DCI-PS3.B-3-3
Mathematical expressions for the energy of a system allow the concept of conservation of energy to be used to predict and describe system behavior.
p. 282, ¶ 5 SB ContentView
p. 281, ¶ 3 SB ContentView
p. 321, ¶ 3 SB ContentView
NGSS-HS-DCI-PS3.B-4
The availability of energy limits what can occur in any system.
p. 650, ¶ 5 SB ContentView
p. 284, ¶ 5 SB ContentView
p. 288, ¶ 2 SB ContentView
NGSS-HS-DCI-PS3.B-5
Uncontrolled systems always evolve toward more stable states—that is, toward more uniform energy distribution (e.g., water flows downhill, objects hotter than their surrounding environment cool down).
p. 389, ¶ 1 SB ContentView
p. 699, ¶ 1 SB ContentView
p. 731, ¶ 1 SB ContentView
NGSS-HS-DCI-PS3.C
Relationship Between Energy and Forces
NGSS-HS-DCI-PS3.C-1
When two objects interacting through a force field change relative position, the energy stored in the force field is changed.
p. 535, ¶ 7 SB ContentView
p. 513, ¶ 5 SB ContentView
p. 535, ¶ 5 SB ContentView
NGSS-HS-DCI-PS3.D
Energy in Chemical Processes and Everyday Life
NGSS-HS-DCI-PS3.D-1
Solar cells are human-made devices that likewise capture the Sun’s energy and produce electrical energy.
p. 27, ¶ 4 SB ContentView
p. 27, ¶ 6 SB ContentView
p. 28, ¶ 2 SB ContentView
p. 29, ¶ 4 SB ContentView

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