Questions tagged [dirac-delta-distributions]
Distributions are generalized functions, such as, e.g., the Dirac delta function. DO NOT USE THIS TAG for statistical probability distributions, profiles, graphs, plots, etc.
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2answers
66 views
Dispersion Relations in Particle Physics [on hold]
Please tell me how to get the identity(2) in this image
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0answers
19 views
Infinite Subcritical Reactor with a plane Source; Deriving analytical solution with boundary conditions [migrated]
this might aswell be a mathematics question since I am only looking for a way to solve a basic model of the neutrondistribution in an infinite plane subcritical reactor.
So the model for the ...
1
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0answers
31 views
Why Gauss divergence theorem isn't working? [duplicate]
$\vec{E}$ is electric field
$r$ is distance between source and field points
$\hat{r}$ is a unit vector from source point to field point
$x,y,z$ are Cartesian coordinates of field point
...
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1answer
28 views
Curl of magnetic field produced by current carrying wires with infinitesimal small area
Can Magnetic fields produced by thin current carrying wires with infinitesimal area have curl with a delta function in it ?? As area is Zero current density J definitely becomes infinite at where ...
4
votes
1answer
59 views
Equation for the field of a magnetic dipole
In my electrodynamics class, my professor derived the equation for the field of the magnetic dipole
$$\vec{B}(\vec{r})=\frac{\mu_0}{4\pi}\frac{1}{r^3}[3(\vec{m}\cdot\hat{r})\hat{r}-\vec{m}]+\frac{2\...
1
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2answers
64 views
Retarded potentials with a dirac delta fail to give Lienard-Wiechert
In the derivation of the Liénard-Wiechert potential the expression for the retarded potential is given
$$\varphi(\mathbf{r}, t) = \frac{1}{4\pi \epsilon_0}\int \frac{\rho(\mathbf{r}', t_r')}{|\mathbf{...
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0answers
28 views
Where does the “-”sign come from in formula (22) of Diracs principles of Quantum Mechanics, section 75?
When inserting (21) into the defining formula (20) of Delta, I don't see why there should be a minus sign. Formula (22) is used several times in section 75, so it should be correct; but I can`t see ...
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2answers
64 views
How to plot the graph of this expression which involves Dirac delta function?
I was doing a problem on electrostatics which required finding the charge density from the given electric field and then plot a graph of the charge density. I was able to find the charge density which ...
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1answer
10 views
Synchrotron emissivity change of variables
I have an expression for an emissivity $j_\nu$
$$j_\nu =a_0 \left(\frac{p}{mc}\right)^2 B^2\; \delta\mathopen{}\left(\nu -a_1 \left(\frac{p}{mc}\right)^2B\right)$$
where $a_0$ and $a_1$ are ...
2
votes
0answers
49 views
Why does $\langle x' | x \rangle$ give the Dirac delta distribution? [duplicate]
I'm having difficulty understanding why the following is true:
$$ \int_\mathbb{R} \langle x' | x \rangle dx = \int_ \mathbb{R} \delta(x-x')dx$$
where $\delta(x)$ is the delta distribution. Are we ...
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1answer
35 views
Pöschl–Teller free wave solution normalization
I'm considering one-dimentional QM ($\hbar=1$, $m=1$) with the following potential
$$
V(x) = - \frac{1}{\cosh^2 x}\;.
$$
I know that free-wave solution are
$$
ψ_k(x) = e^{\pm i k x}(\tanh x \mp ik)\;.
...
1
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2answers
60 views
Can $E=\frac{q}{4\pi\epsilon_0 r^2}$ be directly derived from differential form of Maxwell equations?
The electric field of a point charge $q$ is well known to be
$$\mathbf E=\frac{q}{4\pi\epsilon_0 |\mathbf r|^3}\hat{\mathbf r}$$
This can be derived easily from integral form of Gauss’s law. Taking $...
0
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1answer
68 views
How to integrate by parts ghost fields in electrodynamics?
When applying Faddeev-Popov method to electrodynamics in the Lorenz gauge we obtain the ghost action
$$S=\int d^4xd^4y\bar\eta(x)\left(\partial^2\delta(x-y)\right)\eta(y),\tag{0}$$
where $\partial^2$ ...
3
votes
1answer
81 views
How to derive the $\frac{4\pi}{3}\vec{p}\delta^3(\vec{r})$ element for the dipole field, from its potential?
This might be a bit more general question about how to figure out what is the appropriate (delta) expression in singular points, but e.g. for the dipole, we can derive its potential by a taylor ...
3
votes
1answer
101 views
How do you write the Wightman function $\langle\phi(t_1)\phi(t_2)\rangle$ for a massive scalar field in position space?
For a free real scalar field $\phi(t,\mathbf{x})$, we define the Wightman function as:
$$
W(t_1,t_2) \equiv \langle 0 | \phi(t_1,\mathbf{x}_1) \phi(t_2,\mathbf{x}_2) | 0 \rangle
$$
I'm suppressing the ...
0
votes
1answer
41 views
How can only 2 phases of a 3 phase power system be used to power a load?
When looking at 2 of the 3 phases on a graph, there's a point where they're both positive or both negative. How does one of the phases act as a return path?
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0answers
136 views
Probability Density Function vs Radial Distribution for 1s Orbital
What is the difference between the probability density function for the 1s orbital of hydrogen and the radial distribution function? I know that the radial distribution function is 4πr2(Rnl(r))2 but ...
0
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0answers
48 views
Fixing the Constant in the Schwarzschild Solution Using a Dirac Delta instead of the the Newtonian Limit
I have seen several derivations of the Schwarzschild solution of the Einstein equations, and they all invoke the Newtonian limit
$$
g_{00} \approx -1 + \frac{2GM}{r}
$$
for large $r$ to fix the ...
0
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1answer
38 views
How can one evaluate the expression: $\nabla_{i}\nabla_{j}\left(\frac{1}{r}\right)$, such that $i,j = x,y,z$?
I'm familiar with the Laplacian, but I'm unsure how to evaluate
$\nabla_{i}\nabla_{j}\left(\frac{1}{r}\right)$, such that $i,j = x,y,z$,
with this notation.
This is my attempt, assuming
$r=\left(...
1
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0answers
103 views
How can a Dirac delta function that does not occur under an integral be used to describe a transition rate?
In his excellent notes (found here), Mark Tuckerman shows that the transition rate of absorption between quantum states i and f, coupled by operator B, can be expressed as the fourier transform of the ...
1
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1answer
113 views
Under what conditions is a wavefunction $\psi(x)$ equal to the probability amplitudes $a(x)$?
For context, consider a general expansion of a wavefunction into continuous eigenstates of position, $\phi(x_m,x)$, multiplied by continuous probability amplitudes, $a(x_m)$
$$\begin{align}\psi(x) &...
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1answer
64 views
Delta function from poles of Green's function
In quantum mechanical scattering theory, we often use Green's functions which contain poles. For example, in Schroedinger quantum mechanics the free Green's function is given by
$$
G_0(\vec{p}) = \...
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0answers
31 views
Green's function regularization and delta distribution
I have a free Green's function which is proportional to a $2\times 2$ matrix:
$$
G_0 = \frac{1}{E^2-E_k^2}\begin{pmatrix} a & b \\ c & d \end{pmatrix}
$$
The total Green's function after ...
0
votes
1answer
57 views
To prove the Lorentz invariance of density distribution functions for massless particles in phase space
One defines the density distribution function of a collection of $N$ particles in phase space as follows, $$f(\vec{x},\vec{p},t)=\sum_{i=1}^N\delta^{(3)}(\vec{x}-\vec{x}_i)\delta^{(3)}(\vec{p}-\vec{p}...
0
votes
3answers
181 views
What is principal value in delta function integral? [closed]
The delta function may have different forms of definition. One related to Fourier transform is shown below,
$$\int_{-\infty}^{\infty}\!dt ~e^{i\omega t}~=~2\pi\delta(\omega).$$
then I wonder what if ...
0
votes
0answers
49 views
Does it matter whether or not $\delta(x)$ is a valid wave function for a particle on the real line?
We model the wave-functions of a particle on the line by vectors $\psi \in L^2(\mathbb{R})$, and the position operator $X:D(X) \rightarrow L^2(\mathbb{R})$ as the operator such that $X\psi(x) = x\psi(...
1
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2answers
96 views
Is $\delta(r-ct)/4\pi r$, the 3D wave equation elementary solution, a transverse or longitudinal wave?
Background:
https://en.wikipedia.org/wiki/Longitudinal_wave
'Longitudinal waves are waves in which the displacement of the medium is in the same direction as, or the opposite direction to, the ...
2
votes
2answers
193 views
Derivative of delta function
I am reading and following along the appendices of "The Physical Principles Of The Quantum Theory", and trying to learn how he derives Schrödinger's Equation from his Matrix Mechanics, but I have run ...
2
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0answers
72 views
How can the propagator be written in the below integral form?
I’am finding it difficult to understand as to how the delta function is written as a product of many delta functions with the integral
1
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1answer
79 views
How to prove that divergence of the current density is equal to the minus time derivative of the charge density?
Namely, in Weinberg's book (Graviation and Cosmology...) on p. 40 after eq. 2.6.5 we see:
$$\begin{align}\nabla\cdot \vec J(\vec x,t) = \sum_n e_n \frac{\partial}{\partial x^i} \delta^3(\vec x-\vec ...
2
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0answers
44 views
Half of Dirac Delta within spectral integration
I was taking a course in Quantum Information along this last semester, and apart from some mathematical details it all made sense to me. One of these mathematical tricks that I haven't been able to ...
3
votes
1answer
129 views
Triple Delta Potential in Quantum Mechanics
I am facing a problem of Quantum Mechanics, and I gently need your help in continuing to solve it.
The problem is the old usual problem of a particle subject to a potential, which this time has the ...
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1answer
34 views
Collision and impulsive forces: a formal approach
Consider two bodies $m$ and $M$. Suppose that $m$ is moving with constant velocity $v_0 > 0$ along a certain axis (e.g., it is moving on the right on the $x$-axis), and at a certain time, it ...
-1
votes
1answer
81 views
Wave-Function Normalization in Momentum Space Not Possible
Hello,
I just have a question about this passage; specifically, I do not understand why the result of the inner product (the integral of u_k* and u_k') being the delta function defies conventional ...
0
votes
1answer
31 views
Non-resting initial value problem with impulsive input
Consider a hypothetical model of an extended mechanical system (in which a derivatives of higher order than acceleration may exist d) as bellow:
$$\sum_{n=0}^N {a_n x^{(n)}}= f_0 \delta(t-t_0)$$
...
3
votes
2answers
70 views
Multiplying Distributions in finite-temperature Keldysh/Thermo-field field theory
In the real-time finite temperature formalisms (Schwinger-Keldysh or Thermo-field), the free propagators are often defined with terms like:
$$
\mathrm{Dirac\ Delta}\ \times \ \mathrm{Thermal\ ...
1
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0answers
23 views
Shifting the derivative outside the integral [closed]
In page 62 of Shankar's Principles of Quantum Mechanics, the author conveys the following: $$\int \delta'( x-x') f(x') dx' = \int \frac{d\delta(x-x')}{dx}f(x')dx'= \frac{d}{dx} \int \delta(x-x') f(x') ...
0
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0answers
112 views
What is the normalized Maxwell-Boltzmann velocity distribution for 2D lattices?
The Maxwell Boltzmann velocity distribution is most of times deduced in 3D on books. How does it looks like in 2D?
0
votes
1answer
40 views
Quantum mechanics perturbation and the orthogonality of energy states [closed]
Consider the following question and its solution:
My question is concerning the solution of $a_{nm}$.
Surely if the energy eigenstates are orthogonal then $a_{nm}$ must be equal to zero. WHy is this ...
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2answers
21 views
probability distribution of dependent random variables
If we have dependent random variables, then what how is the distribution the pdf look like? Can it be a normal distribution?
For example, additive white Gaussian noise (AWGN) has a normal distribution,...
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0answers
24 views
Use advection diffusion equation to define an initial-boundary problem via programming
Considering the advection-diffusion equation:
$$
u_t=-au_x+\mu u_{xx}
$$
for $x\in[-\infty,\,\infty]$, $0\leq t\leq T$ and $u\left(t=0,\,x\right)=u_0\left(x\right)$.
A solution to the initial value ...
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0answers
80 views
Spherical Harmonics: Physical Meaning behind the Mathematics: Dirac
Hello Physics Exchange,
I have a series of concept questions. Mostly to prove or disprove my understanding. This will be my first post, so if you have any suggestions to improve my formatting - I ...
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0answers
116 views
Scattering states in Dirac Delta potential
I was reading the solution to the Dirac delta potential well in Griffiths and for the case of scattering, the book mentioned is possible to generate normalizable functions with this eigenstates, but ...
0
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1answer
71 views
Integration over phase space for a one dimensional harmonic oscillator
The problem asks for a proof of the following equation, and I have no idea on how to approach this:
$\int dx dp \delta(E-\frac{p^2}{2m}-\frac{m \omega^2 x^2}{2})f(E) = \frac{2\pi}{\omega}f(E)$ , for ...
0
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0answers
107 views
Dirac-delta orthonormality
Is my understanding that eigenfunctions of position operator and momentum operator exhibit, Dirac-delta orthonormality. I wanted to ask if all self-adjoint operators in quantum mechanics exhibit this ...
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1answer
69 views
1D delta potential hamiltonian
I have two concerns regarding the delta potential hamiltonian:
Is my understanding that in quantum mechanics we use self-adjoint operators. However I cannot figure it out if the hamiltonian that ...
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0answers
69 views
is it true that $\lim\limits_{\epsilon \to 0^{+}} \ln( x \pm i \epsilon ) = \mathscr{P}\ln|x| \pm i \pi \Theta(-x)$?
Is the following statement true?
$$
\lim\limits_{\epsilon \to 0^{+}} \ln( x \pm i \epsilon ) = \mathscr{P}\ln|x| \pm i \pi \Theta(-x)
$$
where $\mathscr{P}$ is the Cauchy principal value. The above ...
2
votes
2answers
54 views
Calculating $\langle p|x\rangle$ and $\langle x|\hat{p}|x'\rangle$ - does one result from the other?
In showing that $$\langle x|\hat{p}|x'\rangle = -i \hbar \frac{dδ(x-x')}{dx}$$ I've seen many solutions doing something similar to Can I replace eigenvalue of p
operator with position space ...
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votes
1answer
138 views
Dirac Delta potential
As we know a particle in attractive Dirac delta potential has discontinuity in the derivative of its wavefunction.
I have two questions in this regard:
Can a second order differential equation be ...
1
vote
1answer
292 views
Solution of Schrödinger equation for Dirac delta potential $V(x) = \sum_{i=1}^P \sigma_i\delta(x-x_i)$
So, I am trying to solve Schrödinger Equation for Dirac delta potential.
The Schrödinger equation:
$$
-\frac{\hbar^2}{2m}\frac{d^2\Psi(x)}{dx^2} + V(x)\Psi(x) = E\Psi(x)
$$
And, the potential looks ...
