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The Law of Conservation of Energy: Definition, Types of Energy & Measurement

December 14, 2023 658 0

Unchanging Force: The Law of Conservation of Energy:

The Law of Conservation of Energy is a fundamental principle in physics stating that the total energy of an isolated system remains constant over time. It asserts that energy cannot be created or destroyed, only transformed from one form to another.

Energetic Harmony: Exploring the Law of Conservation of Energy:

  • Eternal Equilibrium: Constant Energy: Energy can change from one form to another, yet regardless of how energy transforms, the total energy of a system remains constant, this is the law of conservation of energy.
  • Energy Metamorphosis: Unbreakable Law of total energy constancy: According to this law, energy can’t be created or destroyed but only changed from one form to another. 
    • The total energy before and after any transformation remains the same.
  • Universally Truth of Conservation across Transformations: This law holds true across all situations and all types of energy transformations.
  • Understanding Through Example: Potential to Kinetic Energy Transformation
    • Potential to Kinetic Energy: When an object with mass, m, falls freely from a height, h, its initial potential energy is mgh while its kinetic energy is zero (since its velocity is zero).
    • As it descends, its potential energy gets converted into kinetic energy.
    • The kinetic energy at any given time during the fall would be ½ mv2, where v is its velocity at that instant.
    • The further it falls, the more its potential energy decreases and its kinetic energy increases.
    • When the object is about to touch the ground, its height h=0 and velocity v will be at its maximum. 
    • Hence, its kinetic energy is maximized while its potential energy is minimized.
    • Throughout the fall, the sum of its potential energy and kinetic energy remains constant, as depicted by the equation: mgh + ½ mv2 = constant
  • Mechanical Energy: The combination of an object’s kinetic and potential energies is its total mechanical energy.
  • Transformation: In the context of the falling object, there’s a constant transformation of gravitational potential energy into kinetic energy (assuming we neglect air resistance).

How does Power, Work and the Law of Conservation of Energy interplay in Physical Systems?

  • Work Rate: From Individuals to Machines in Energy Transfer and Performance: It varies among individuals and machines. Different agents transfer energy and perform work at different rates.
    • For instance, a stronger individual might complete a task more quickly than someone less strong. 
    • Similarly, a more powerful vehicle will cover a distance in a shorter span than a less powerful one.
  • Machine Efficiency and Energy Transfer Rates: The efficiency or capability of machines, like motorbikes and cars, is often described in terms of their power. 
    • This essentially indicates the rate at which these machines can perform work or transfer energy.
  • Power and its Mathematical Expression P = W/t: Power is a measure of how rapidly work is done or energy is transferred. It can be mathematically represented as: 

Power = Work (W) / Time (t) 

  i.e. P = W/t

  • Units of Power:  Language of Power in Energy Transfer
    • The SI unit of power is the watt (W), named in honor of James Watt.
    • One Watt: It signifies the power exerted when work is done at a rate of 1 joule per second. 
      • 1 watt=1 joule/second or  or 1 W = 1 Js−1
    • For larger energy transfer rates, power is often measured in kilowatts (kW). 
  • 1 kilowatt (kW) =1000 watts (W) emphasizing the scale of power in the context of conservation of energy.

1 kW = 1000 W

1 kW = 1000Js−1

  • Average Power: A Consistent Measure of Work Rate in Energy Dynamics: Since the power exerted by an agent can fluctuate over time, the notion of average power becomes significant. 
    • Average power is computed by dividing the total energy utilized by the overall time spent.
    •  It provides a consistent measure of an agent’s work rate over a specific time frame.
  • Help in Differentiation: Evaluating efficiency across agents, machines, and individuals: Concept of power can be used to distinguish the efficiency of various agents, machines, or individuals, considering the conservation of energy.

Example: A boy of mass 50 kg runs up a staircase of 45 steps in 9 s. If the height of each step is 15 cm, find his power. Take g = 10 m s–2

Solution: 

Weight of the boy,
mg = 50kg × 10ms–2 = 500N 

Height of the staircase,
h = 45 × 15/100 m = 6.75 m 

Time taken to climb, t = 9 s , 

power, P = Work done/time taken 

= mgh / t 

= 500 N × 6.75 m / 9s 

= 375 W. 

Power is 375 W. 

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UDAAN PRELIMS WALLAH
Comprehensive coverage with a concise format
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Designed as per recent trends of Prelims questions
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