Energy Graphs: Difference between revisions

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YU ZHOU FALL 2025
THOMAS SCHIAVO FALL 2026
Short Description of Topic


==The Main Idea==
1. What Is an Energy Graph?
Energy graphs typically plot:


State, in your own words, the main idea for this topic
Electric Field of Capacitor


===A Mathematical Model===
  Energy vs. position → U(x), K(x), E(x)


What are the mathematical equations that allow us to model this topic.  For example <math>{\frac{d\vec{p}}{dt}}_{system} = \vec{F}_{net}</math> where '''p''' is the momentum of the system and '''F''' is the net force from the surroundings.


===A Computational Model===
  Energy vs. time → U(t), K(t), E(t)


How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]


==Examples==
They allow you to:
  visualize where forces act
  determine where motion is possible
  identify equilibrium points
  find turning points
  compare speeds instantly


Be sure to show all steps in your solution and include diagrams whenever possible


===Simple===
2. Potential Energy Graphs U(x)
===Middling===
Potential energy graphs contain the most information.
===Difficult===
  Force is the negative slope of the graph:
      F(x) = – dU/dx


==Connectedness==
  If U slopes up → force points left
#How is this topic connected to something that you are interested in?
  If U slopes down → force points right
#How is it connected to your major?
  Steeper slope → stronger force
#Is there an interesting industrial application?


==History==
[[File:Screenshot 2026-04-28 at 8.05.36 PM.png|center]]


Put this idea in historical context. Give the reader the Who, What, When, Where, and Why.
Equilibrium Points
Equilibrium occurs where:
  slope = 0 → F = 0


== See also ==
Types:


Are there related topics or categories in this wiki resource for the curious reader to explore?  How does this topic fit into that context?
  Minimum of U(x) → stable equilibrium
  Maximum of U(x) → unstable equilibrium


===Further reading===


Books, Articles or other print media on this topic
3. Total Mechanical Energy
Total energy is:
  E = K + U


===External links===
For conservative systems, total energy is constant → horizontal line on graphs.


Internet resources on this topic
Allowed Motion
Motion is only possible where:
  E ≥ U(x)


==References==


This section contains the the references you used while writing this page
  If U > E → forbidden region
  If U = E → turning point


[[Category:Which Category did you place this in?]]
 
 
Turning Points
At turning points:
 
  K = 0
  velocity = 0 (object reverses direction)
 
 
4. Kinetic Energy Graphs K(x)
Kinetic energy is:
  K(x) = E – U(x)
Since:
  K = ½mv²
 
  High K → fast motion
  Low K → slow motion
  K = 0 → object stops
 
 
Important:
 
  K is always ≥ 0
 
 
 
5. Most Important Potential Shapes
 
A. Spring Potential (Harmonic Oscillator)
  U(x) = ½kx²
 
  Parabola opening upward
  Minimum at x = 0 → stable equilibrium
  Motion is oscillatory
 
[[File:Screenshot 2026-04-28 at 8.01.36 PM.png|center]]
 
B. Gravitational Potential (Near Earth)
  U = mgh
 
  Linear with height
  Used for ramps and hills
  Speed depends only on height difference, not slope.
 
[[File:Screenshot 2026-04-28 at 8.03.19 PM.png|center]]
 
C. Attractive Potentials (Gravity / Electric)
  U(r) = –k/r
 
  Negative potential energy
  Stronger interaction at small r
 
 
D. Repulsive Potentials
  U(r) = +k/r
 
  Positive potential energy
  Objects are pushed apart
 
 
6. Bound vs Unbound Systems
 
Bound System
 
 
  E < 0
 
  Object is trapped
  Motion occurs between turning points
  Example: orbiting planet
 
 
Unbound System
 
  E > 0
 
  Object escapes
  Example: spacecraft leaving a planet
 
 
Escape Energy
  E = 0
 
  Object barely escapes
  Final velocity approaches 0 at infinity
 
 
7. How to Read Any Energy Graph
 
 
  Where U is low → speed is high
 
  Where U is high → speed is low
 
  U = E → turning point
 
 
  Slope of U → direction of force
  Steeper slope → stronger force
  Minimum → stable equilibrium
  Maximum → unstable equilibrium
 
 
  K(x) = E – U(x) always

Latest revision as of 20:06, 28 April 2026

THOMAS SCHIAVO FALL 2026

1. What Is an Energy Graph? Energy graphs typically plot: 


  Energy vs. position → U(x), K(x), E(x)



  Energy vs. time → U(t), K(t), E(t)


They allow you to: 

  visualize where forces act
  determine where motion is possible
  identify equilibrium points
  find turning points
  compare speeds instantly


2. Potential Energy Graphs U(x) Potential energy graphs contain the most information. 

  Force is the negative slope of the graph:
     F(x) = – dU/dx

  If U slopes up → force points left
  If U slopes down → force points right
  Steeper slope → stronger force

Equilibrium Points Equilibrium occurs where: 

  slope = 0 → F = 0

Types: 

  Minimum of U(x) → stable equilibrium
  Maximum of U(x) → unstable equilibrium


3. Total Mechanical Energy Total energy is: 

  E = K + U

For conservative systems, total energy is constant → horizontal line on graphs.

Allowed Motion Motion is only possible where: 

  E ≥ U(x)



  If U > E → forbidden region
  If U = E → turning point


Turning Points At turning points: 

  K = 0
  velocity = 0 (object reverses direction)


4. Kinetic Energy Graphs K(x) Kinetic energy is: 

  K(x) = E – U(x)

Since: 

  K = ½mv²

  High K → fast motion
  Low K → slow motion
  K = 0 → object stops


Important: 

  K is always ≥ 0


5. Most Important Potential Shapes

A. Spring Potential (Harmonic Oscillator) 

  U(x) = ½kx²

  Parabola opening upward
  Minimum at x = 0 → stable equilibrium
  Motion is oscillatory

B. Gravitational Potential (Near Earth) 

  U = mgh

  Linear with height
  Used for ramps and hills
  Speed depends only on height difference, not slope.

C. Attractive Potentials (Gravity / Electric) 

  U(r) = –k/r

  Negative potential energy
  Stronger interaction at small r


D. Repulsive Potentials 

  U(r) = +k/r

  Positive potential energy
  Objects are pushed apart


6. Bound vs Unbound Systems

Bound System 


  E < 0

  Object is trapped
  Motion occurs between turning points
  Example: orbiting planet


Unbound System 

  E > 0

  Object escapes
  Example: spacecraft leaving a planet


Escape Energy 

  E = 0

  Object barely escapes
  Final velocity approaches 0 at infinity


7. How to Read Any Energy Graph 


  Where U is low → speed is high

  Where U is high → speed is low

  U = E → turning point



  Slope of U → direction of force
  Steeper slope → stronger force
  Minimum → stable equilibrium
  Maximum → unstable equilibrium



  K(x) = E – U(x) always
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