- #1
issacnewton
- 1,000
- 29
Hi
I was reading from Serway in the chapter of "Energy and energy transfer". In this chapter the
author is introducing the concept of system and environment and then work. He also talks about kinetic energy and work-kinetic energy theorem and then conservation of energy theorem. I have attached a snapshot from the book. He says in bold letters that work is an energy transfer. Technically speaking, it should be "mechanical energy transfer" because
when the work done on the system is positive, its the mechanical energy that is transferred to the system. I know that this is chapter of work and author probably means that but later in the chapter, author also talks about other mechanisms of 'energy transfer' like heat, radiation. so the beginning students can become confused.
Also another related question regarding the work done. now its defined as
[tex]W=\int \, \vec{F}\cdot \vec{dr}[/tex]
in one dimension case when the object is moving left on positive x axis, and if there is
constant force [tex]\vec{F}=-F \hat{i}[/tex] should [tex]\vec{dr}[/tex] be
[tex]-dx\,\hat{i}[/tex] or [tex]dx\, \hat{i}[/tex].
I think it should be [tex]-dx\,\hat{i}[/tex] since differential position vector is the difference
between the final position vector and initial position vector. But if we do this, and if the object is moving from x2 to x1 (x2>x1)
then we get
[tex]W\,=\,\int_{x_2}^{x_1} (-F\hat{i})\cdot(-dx\, \hat{i})[/tex]
which is
[tex]W\,=F(x_1-x_2)[/tex] and this is negative. but since the external force is applied
to the system of particle, work should be positive since its mechanical energy
is increasing... so am I taking differential vector wrong ?
thanks
I was reading from Serway in the chapter of "Energy and energy transfer". In this chapter the
author is introducing the concept of system and environment and then work. He also talks about kinetic energy and work-kinetic energy theorem and then conservation of energy theorem. I have attached a snapshot from the book. He says in bold letters that work is an energy transfer. Technically speaking, it should be "mechanical energy transfer" because
when the work done on the system is positive, its the mechanical energy that is transferred to the system. I know that this is chapter of work and author probably means that but later in the chapter, author also talks about other mechanisms of 'energy transfer' like heat, radiation. so the beginning students can become confused.
Also another related question regarding the work done. now its defined as
[tex]W=\int \, \vec{F}\cdot \vec{dr}[/tex]
in one dimension case when the object is moving left on positive x axis, and if there is
constant force [tex]\vec{F}=-F \hat{i}[/tex] should [tex]\vec{dr}[/tex] be
[tex]-dx\,\hat{i}[/tex] or [tex]dx\, \hat{i}[/tex].
I think it should be [tex]-dx\,\hat{i}[/tex] since differential position vector is the difference
between the final position vector and initial position vector. But if we do this, and if the object is moving from x2 to x1 (x2>x1)
then we get
[tex]W\,=\,\int_{x_2}^{x_1} (-F\hat{i})\cdot(-dx\, \hat{i})[/tex]
which is
[tex]W\,=F(x_1-x_2)[/tex] and this is negative. but since the external force is applied
to the system of particle, work should be positive since its mechanical energy
is increasing... so am I taking differential vector wrong ?
thanks
