Why were momemtum, kinetic energy and work introduced?

In summary: The second derivative of momentum, while important, is not used as frequently as the first derivative or the momentum itself, so it is not as necessary to have a special name for it. In summary, quantities like momentum, force, potential energy, kinetic energy, and work were introduced in physics to accurately predict a wide range of phenomena and describe the behavior of the world. They were defined based on their usefulness in making quantitative predictions, and are related to the fundamental symmetries of Newtonian and special-relativistic spacetime. These concepts are tools used to study the world around us and have been dropped or replaced in the past as our understanding of nature evolves. While a special name was given to the rate of change of velocity, momentum
  • #1
hackhard
183
15
why were quantities like momentum, force , potential energy, kinetic energy,work ,etc needed to be introduced in physics?
and why were they defined the way they are defined?.
would it not be possible to explain nature without defining these quantities or by using alternate physical quantities ?
 
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  • #2
hackhard said:
would it not be possible to explain nature without defining these quantities or by using alternate physical quantities ?

Even if it is possible, it would be MUCH more difficult. I doubt it would even be possible, really.
 
  • #3
why were quantities like momentum, force , potential energy, kinetic energy,work ,etc needed to be introduced in physics?
 
  • #4
I'd say that they relate different quantities to one another in a way that makes it possible to accurately predict a wide range of phenomena. I really don't know how to explain it very well. Without all of those concepts, physics as we know it would be much more difficult, if not impossible. Maybe someone else can explain it better. @Orodruin, any idea?
 
  • #5
hackhard said:
why were they defined the way they are defined?
The quantities were defined based on what is useful to make quantitative predictions. For example, a quantity that is conserved over time is useful to predict what will happen.
 
  • #6
It was "needed" as it was useful for describing how the world behaves, just as everything else in empirical sciences.
 
  • #7
These quantities were introduced into physics because they are very useful to describe nature. From a modern point of view you can ask, whether you need forces, but all other quantities (i.e., momentum, energy, angular momentum) are related to the most fundamental properties of our description of nature, i.e., the symmetries of Newtonian and special-relativistic spacetime. These symmetries explain a lot why the physical laws the physicists discovered over the centuries look as they do. The most fundamental discovery is the discovery of these fundamental symmetries.
 
  • #8
I'll try to answer this question in the chronology of which we study these topics. Before the time of Galileo and Newton most of the ideas about the motion of bodies were quite crude. It was Newton who first gave proper mathematical laws for the motion of bodies. His laws make use of concepts such as velocity (if we're studying motion then what better way to express it than change in position with time?), acceleration and forces ( which basically is the cause of motion or how motion is transferred b/w bodies). This was all well when we are doing problems of kinematics and simple dynamics, but then for problems such as collisions and variable mass systems, the idea of momentum and impulse was needed. Also, there were a different class of situations where the forces varied with distance instead of time, here the ideas of work and energy come into the picture. Some of these quantities, such as momentum and energy, turned out to be quite fundamental and also followed conversation laws.
These concepts are tools used to study the world around us. Why specifically these quantities? Because they seem to work best for us. Many concepts have been dropped in the past because they weren't satisfactory and in the future we probably will get some new quantities which lead to better understanding of nature.
 
  • #9
a new quantity was defined for rate of change of velocity, momentum,work,etc but no special name for rate of change of acceleration .
was it because rate of change of velocity, momentum,work, occurred frequently in equations ,hence for simplification?
 
  • #11
Drakkith said:
It's called a jerk.
alright aim of my ques was different. if consider second derivative of momentum?
a new quantity was defined for rate of change of velocity, momentum,work,etc but no special name for second derivative of linear momentum .
was it because rate of change of velocity, momentum,work, occurred frequently in equations ,hence for simplification?
 
  • #12
hackhard said:
a new quantity was defined for rate of change of velocity, momentum,work,etc but no special name for second derivative of linear momentum .
was it because rate of change of velocity, momentum,work, occurred frequently in equations ,hence for simplification?

Pretty much. Those quantities which are used the most are the ones which have names assigned to them.
 

Related to Why were momemtum, kinetic energy and work introduced?

1. Why were momentum, kinetic energy and work introduced?

Momentum, kinetic energy, and work were introduced as important concepts in physics to help explain the behavior of objects in motion. These concepts are essential in understanding the fundamental laws of motion and how they apply to real-world scenarios.

2. What is the relationship between momentum, kinetic energy, and work?

Momentum, kinetic energy, and work are all related to an object's motion. Momentum is a measure of an object's mass and velocity, while kinetic energy is a measure of an object's movement. Work is a measure of the energy transferred to or from an object as a result of a force acting on it. These concepts are interrelated and help us to understand the behavior of moving objects.

3. How do these concepts apply to everyday life?

Momentum, kinetic energy, and work are present in many aspects of our daily lives. For example, when we walk, we are utilizing these concepts as our muscles produce force to move our bodies, which requires work. Momentum is also important in sports, such as when a baseball player hits a home run, the momentum of the ball helps it to travel a greater distance. Understanding these concepts can help us to better understand and predict the behavior of objects in motion.

4. Can these concepts be applied to other fields besides physics?

Yes, the concepts of momentum, kinetic energy, and work can be applied to other fields besides physics. These concepts can be seen in economics, such as when discussing financial markets and the transfer of energy and momentum between buyers and sellers. They can also be applied in engineering and design, as understanding these concepts is essential in creating efficient and effective machines and structures.

5. How have these concepts evolved over time?

The concepts of momentum, kinetic energy, and work have evolved over time through the work of many scientists and philosophers. For example, the concept of momentum was first introduced by Galileo in the 17th century, and it was later refined by Isaac Newton in his laws of motion. Kinetic energy was first described by Gottfried Leibniz in the 17th century, and it was later further developed by other scientists such as James Joule and Hermann von Helmholtz. Work was also first studied by Galileo and later developed by scientists such as Robert Hooke and Daniel Bernoulli.

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