Fuerzas no conservativas

../../_images/rozamiento_velocidad1.png

Fig. 117 The usual friction force opposes, in direction, the velocity. Thus, even though its modulus is constant it is a velocity-dependent force and is non-conservative.

../../_images/rozamiento_energiainterna.png

Fig. 118 Friction produces a decrease in the energy of the system. This energy is transfered to the contact surface in the form of heat.

Time-dependent forces

(238)\[\vec{F}=\frac{d\vec{p}}{dt} \rightarrow d\vec{p}=\vec{F}dt \rightarrow \Delta \vec{p}=\int_{t_0}^{t_1}\vec{F}dt\]
(239)\[\vec{I}=\Delta\vec{p}=\int_{t_0}^{t_1}\vec{F}dt\]

Velocity-dependent forces

Magnitudes escalares

I am writing an equation inline \(x=-i\hbar\psi=\hat{h}\psi\).

If the equation is by itself,

(240)\[-i\hbar\psi=\hat{h}\psi\]

I am going to add a figure

2_mecanica/trabajo_energia/../img/logo/logo_fisica.png

Fig. 119 Here is my figure caption!

:::{admonition,warning} This is also Markdown This text is standard Markdown :::

:::{admonition,note} This is also Markdown This text is standard Markdown :::

:::{admonition,tip} This is also Markdown This text is standard Markdown :::

Magnitudes vectoriales

There are many ways to write content in Jupyter Book. This short section covers a few tips for how to do so.

I am going to cite a reference [HdHPK14]

Now I am going to cite section escalares Sec. Magnitudes escalares

The Schrödinger equation is Eq. (195)

I am citing the figure: Fig. 102

Unidades

Problemas y ejemplos resueltos

  • This is the text of a problem

I can start solving like this

(241)\[x=-2\pi\]

Some text needs to go between sidebars

(242)\[y=-log(e)\]

And at the end

  • This is the text of another problem

Bibliografía