What Is The Difference Between These Dielectric Terms?

AI Thread Summary
The discussion clarifies the differences between dielectric terms: the dielectric constant refers to a material's ability to store electrical energy, while the relative dielectric constant compares this ability to that of a vacuum. Dielectric loss indicates energy dissipation in a dielectric material, often represented by a resistance in a capacitor. The symbols "δ" and "εr'" relate to the loss angle and relative permittivity, respectively. The equation provided describes how the dielectric properties affect wave propagation in materials. Understanding these concepts is essential for analyzing the behavior of capacitors with non-ideal dielectrics.
FredericChopin
Messages
101
Reaction score
0
What Is The Difference Between These "Dielectric" Terms?

Can someone please explain to me what the difference between these terms are?

1. Dielectric constant
2. Relative dielectric constant
3. Dielectric loss

I came across them on this website:

http://www.lsbu.ac.uk/water/microwave.html#pen

Also, I don't really know what "δ" and "εr'" on the website are meant to represent.

All and any help would be appreciated.

Thank you.
 
Physics news on Phys.org
Also, does anyone know the derivation to the equation:

$$\alpha = \frac{2 \pi }{ \lambda } \sqrt[]{ \frac{ \varepsilon_r \sqrt[]{1 + tan^{2} \delta } - 1}{2} }$$

, which is also on the website?

Thank you.
 
An ideal capacitor has no losses, a dielectric introduced between the plates just changes the total capacitance in proportion to the relative dielectric constant.

An non-ideal dielectric also introduces a loss, which we represent by a resistance between the plates. So the real capacitor shows both capacitance and resistance; I think that leads to the angle you have there, δ.
 

Thread 'Maxwell stress tensor'

This is from Griffiths' Electrodynamics, 3rd edition, page 352. I am trying to calculate the divergence of the Maxwell stress tensor. The tensor is given as ##T_{ij} =\epsilon_0 (E_iE_j-\frac 1 2 \delta_{ij} E^2)+\frac 1 {\mu_0}(B_iB_j-\frac 1 2 \delta_{ij} B^2)##. To make things easier, I just want to focus on the part with the electrical field, i.e. I want to find the divergence of ##E_{ij}=E_iE_j-\frac 1 2 \delta_{ij}E^2##. In matrix form, this tensor should look like this...
View full post »
Thread 'Applying the Gauss (1835) formula for force between 2 parallel DC currents'

Thread 'Applying the Gauss (1835) formula for force between 2 parallel DC currents'

Please can anyone either:- (1) point me to a derivation of the perpendicular force (Fy) between two very long parallel wires carrying steady currents utilising the formula of Gauss for the force F along the line r between 2 charges? Or alternatively (2) point out where I have gone wrong in my method? I am having problems with calculating the direction and magnitude of the force as expected from modern (Biot-Savart-Maxwell-Lorentz) formula. Here is my method and results so far:- This...
View full post »

Similar threads

A Capacitor With A Dielectric But Also Free Space in Between
Replies
5
Views
2K
Energy changes upon insertion of a solid dielectric in a capacitor
Replies
2
Views
2K
Work done when Inserting a Dielectric between Capacitor Plates
Replies
3
Views
5K
Electric field in a capacitor with multiple dielectrics
Replies
2
Views
4K
Dielectric Constant of Food in microwave
Replies
3
Views
3K
Trying to understand Maxwell's equation in a medium
Replies
3
Views
1K
What is the relationship between permeability and dielectric constant?
Replies
1
Views
3K
Relationship Between Conductance and the Dielectric Constant
Replies
1
Views
7K
Layering different dielectric materials to increase breakdown voltage
Replies
5
Views
5K
Help with Dielectric Constants
Replies
4
Views
2K

Hot Threads

Recent Insights

Back
Top