Skip to main content

New answers tagged

1 vote

Understanding the parabolic state of a quantum particle in the infinite square well

As explained in previous answers, your wave function belongs to the full Hilbert space $L^2$, and the domain of $H$, but not to the domain of $H^2$. In general, unbounded operator (like $H$ or $H^2$) ...
LPZ's user avatar
  • 13.5k
10 votes

Understanding the parabolic state of a quantum particle in the infinite square well

Before we can answer the question, we need a little bit more mathematical clarity here. However, we won't be fully rigorous and leave out details which are not of interest for the question.$^\ddagger$ ...
Tobias Fünke's user avatar
-1 votes

Dirac-delta-functions as eigenbasis of the position operator - pure nonsense? Or can more be said?

I begin with a definition of the $f$ representation and $q$ representation of a wave function [1]. Next, in Proposition 1, I use the definition to show that the use of Dirac-delta distributions as ...
Michael Levy's user avatar
5 votes

Understanding the parabolic state of a quantum particle in the infinite square well

Barring the (now corrected) mistake of the omission of part of eigenvectors, the point is quite trivial: here one is referring to two different notions of energy observable but using the same name! ...
Valter Moretti's user avatar
4 votes

Understanding the parabolic state of a quantum particle in the infinite square well

Let's be clearer with the essence of your problem, now that the other answerer brought to your attention that you were missing the cosines. Your state is $\left<x|\psi\right>=\sqrt{\frac{15}{16\...
naturallyInconsistent's user avatar
7 votes

Understanding the parabolic state of a quantum particle in the infinite square well

There's a simple error in your $\psi_n$ which is screwing you up. In general, the form of the eigenstates $\psi_n(x;x_o,L)$ for a well of length $L$ starting at $x_o$ is $$ \psi_n(x;x_o,L) \propto \...
creillyucla's user avatar
4 votes
Accepted

When a function of the position operator is self-adjoint?

Necessary and sufficient conditions on $f: \mathbb{R} \to \mathbb{C}$ to make $f(A)$ selfadjoint if $A$ is selfadjoint (generally unbounded and defined in a dense domain) are that both (a) $f$ is real ...
Valter Moretti's user avatar
3 votes
Accepted

Existence of Primary operators in CFT

The correct statement is that the scaling dimension of all local operators should be bounded below, and the issue is that $K_\mu {\cal O}(0)$ is not a local operator. You are correct that $K_\mu$ can ...
liam's user avatar
  • 46
2 votes

Why does the Schriefer-Wolff transformation works for phonons?

Schrieffer-Wolff is an approximate way of diagonalizing electron-photon Hamiltonian. On the one hand it is inspired by by an exact polaron transformation (see, e.g., this thread), while on the other ...
Roger V.'s user avatar
  • 61.8k
0 votes

Decomposing operator exponentials

Equation $$e^Ae^B=e^{A+B+\frac{1}{2}[A,B]}$$ is valid for the case when $[A,B]$ is a number, i.e., commutes with both $A$ and $B$. So reversing the equation is straightforward: $$e^{A+B}=e^Ae^Be^{-\...
Roger V.'s user avatar
  • 61.8k
0 votes

How can you prove that the squares of the expected values of the three components of spin sum to 1?

The chapter initially states: There is an important theorem that you can try to prove. So what follows next is generally a consequence of that (unproven) theorem. When the author states: On the ...
PJ_Finnegan's user avatar
4 votes

Explicit Expression of $S_2(\zeta)$ on a general Fock State?

The operators $\hat a\hat b\sim K_-$ and $\hat a^\dagger \hat b^\dagger\sim K_+$ are ladder operators of the $su(1,1)$ algebra so one possibility is to use the $SU(1,1)$ disentanglement formula $$ D(\...
ZeroTheHero's user avatar
  • 46.8k
3 votes

Explicit Expression of $S_2(\zeta)$ on a general Fock State?

I think that in case of general $p$, $q$ it may be impossible to obtain simple expressions and relations for $T(m,n,p,q)$. The operator $S_2(\zeta)$ is the exponential of the quadratic boson operator, ...
Gec's user avatar
  • 6,025
1 vote

Why we have $|P\rangle =\int dp \space |p\rangle p \langle p| =-i\hbar \int dx |x\rangle \frac{d}{dx} \langle x|$?

The other answers and comments have made it clear that you can define momentum operator to satisfy $$\tag1\left<x|\hat p|\psi\right>=-i\hslash\frac{\partial\ }{\partial x}\left<x|\psi\right&...
naturallyInconsistent's user avatar
3 votes
Accepted

Why we have $|P\rangle =\int dp \space |p\rangle p \langle p| =-i\hbar \int dx |x\rangle \frac{d}{dx} \langle x|$?

The momentum operator is usually defined by its matrix elemenets, $\left\langle x\right|P\left|\psi\right\rangle :=-i\hbar\frac{d\psi\left(x\right)}{dx}$ where $\left|x\right\rangle$ is a position ...
Yuli's user avatar
  • 111
0 votes

Proving quantum operator relationship used in derivation of Radial Schrodinger Equation

I have managed to find a solution but I would appreciate some verification if the logic of this solution is correct ... So I can make it work if I should interpret any vector operator "square&...
user1488777's user avatar
0 votes

Proving quantum operator relationship used in derivation of Radial Schrodinger Equation

Your mistake happens in the last line. When you use the commutator. You get $r^2p^2=rppr+i\hbar rp$. But you still have it on the right side of your equation. Push it to the left so you get the minus ...
Ken's user avatar
  • 37
1 vote
Accepted

Occupation number doubt in QFT

Every position in a wave function/state vector corresponds to a mode - that is to a specific value of index $k$ in $a_k, a_k^\dagger$. In this sense, writing $|n_1,n_2,...\rangle$ is confusing, since ...
Roger V.'s user avatar
  • 61.8k
2 votes

The negative value of the hopping integral in the tight-binding model Hamiltonian

Hopping integral is essentially a non-diagonal matrix element in a Hamiltonian. The principal constraint is that Hamiltonian should be Hermitian, but nothing prevents the non-diagonal elements from ...
Roger V.'s user avatar
  • 61.8k
3 votes

What' the intuition behind Shankar's postulate II?

I don't know if it's the intuition, but here's one way in which one could arrive at the postulate. When you are first introduced to quantum mechanics, you usually don't work in an abstract Hilbert ...
Vercassivelaunos's user avatar
4 votes
Accepted

What' the intuition behind Shankar's postulate II?

In classical physics the evolution of the position and momentum of a particle are described by functions $x(t),p(t)$ whose values are the value you would get if you measured the position and momentum ...
alanf's user avatar
  • 9,230
1 vote

What' the intuition behind Shankar's postulate II?

You don't rationalize postulates. Postulates are the "starting point", and the rest of the theory builds from them. Then we test the validity of the set of postulates and the theory by ...
BioPhysicist's user avatar
  • 58.1k
0 votes

Ambiguity in path integral approach to 2D Liouville gravity, versus operator formalism

Lets review some basic material on Vertex opertors in the path integral setting. For a Euclidean Bosonic scalar field in the whole of ${\mathbb R}^2$ we have the Gaussian functional integral ...
mike stone's user avatar
  • 55.2k
0 votes

Ambiguity in path integral approach to 2D Liouville gravity, versus operator formalism

It seems I have found an answer to my question in the articles https://arxiv.org/abs/1712.00829 , and https://arxiv.org/abs/2404.02001 . The answer is that the construction I provided is not rigorous ...
Jeanbaptiste Roux's user avatar
1 vote

Diagonalize the Swap operator $\mathbb{S}_\text{AB} = \sum_{i,j=1}^{d} |i_\text{A}j_\text{B}\rangle \langle j_\text{A}i_\text{B}| $

For two qubits, the swap opreator acts on basis vectors as: \begin{align} \mathbb{S} &|0 0 \rangle = |0 0 \rangle, \\ \mathbb{S} &|0 1 \rangle = |1 0 \rangle, \\ \mathbb{S} &|1 0 \rangle = ...
Quantum Addict's user avatar
0 votes

Ambiguity in path integral approach to 2D Liouville gravity, versus operator formalism

Are you aware that the fields $\varphi(z_i)$ are inserted at different points $z_i\neq z_j$ on the sphere. So you cannot simply sum the exponents together. The primary fields of quantum Liouville ...
Simp's user avatar
  • 76
-1 votes

What is the mathematically precise definition of raising and lowering operators?

There is a simple way in which I understand this concept of raising and lowering operators. I'll try to explain it in two stages. First, given the assumed relation $$ [\hat{a},\hat{a}^{\dagger}] = \...
flippiefanus's user avatar
  • 15.5k
1 vote

What is the mathematically precise definition of raising and lowering operators?

There are two main different ways in which one can generalize the notion of ladder operators, but neither is particularly useful in practice: Naive ladder operators. The nice thing about linear ...
ACuriousMind's user avatar
  • 127k
1 vote

What is the mathematically precise definition of raising and lowering operators?

In general, a ladder operator $O_{\pm}$ is an operator defined for some states $|n\rangle$ as $$O_{\pm}|n\rangle = C_{\pm}(n)|n\pm1\rangle \ \ \mathrm{and} \ \ O_+^\dagger =O_- .$$ The term $C_\pm$ is ...
agaminon's user avatar
  • 2,367
1 vote
Accepted

A question about operators in QM and notation

The notation here is a bit loose. We have that $$ \hat{a}|n\rangle = \sqrt{n}|n-1\rangle $$ and hence $$ (\hat{a}|n\rangle)^{\dagger} = \langle n| \hat{a}^{\dagger} = \sqrt{n}\langle n-1|. $$ However, ...
fulis's user avatar
  • 990
2 votes
Accepted

Expectation value of angular momentum operator

Total angular momentum is a vector, $$ \begin{align} \mathbf J &= \begin{bmatrix} J_x \\ J_y \\ J_z \end{bmatrix} \end{align}$$, so an expectation ...
Agnius Vasiliauskas's user avatar
0 votes

Expectation value of angular momentum operator

It most likely refers to the magnitude of the total angular momentum, $J \equiv \sqrt{<\vec{J}^2>} = \sqrt{<J_x^2 + J_y^2 + J_z^2>}$.
Archisman Panigrahi's user avatar
0 votes

How are rotations invariant by time-reversal?

The sign of the magnitude is not preserved in reversed-time; only the magnitude itself is unchanged in 4D during acceleration. Flipping the sign of the magnitude is what makes it reverse time.
Miss Understands's user avatar
1 vote

Multiplication of operators defined by commutation relations

Algebraic structures can be defined somewhat abstractly. The Lie bracket is not necessarily represented as $[A,B] = AB-BA$, though this is the standard choice for operators as it satisfies the various ...
Cameron Williams's user avatar
6 votes

Multiplication of operators defined by commutation relations

Multiplication of generators is a feature of the representation, not the Lie algebra. Indeed, you are asking about the unital associative universal enveloping algebra of generators which defines the ...
Cosmas Zachos's user avatar
6 votes

What is the commutator of the lowering operator $J_-$ and the exponential of $J_z$, arranged so that the lowering operator is always to the right?

The other answer is perfect, but a less direct simpler method is application of Hadamard's lemma on the adjoint action, a trick you'll may well be using once a month, $$ e^{iaJ_z}J_- e^{-iaJ_z}= J_-+...
Cosmas Zachos's user avatar
5 votes
Accepted

What is the commutator of the lowering operator $J_-$ and the exponential of $J_z$, arranged so that the lowering operator is always to the right?

It is convenient to consider this problem in the basis of eigenvectors of the operator $J_z$. For any vector $|m\rangle$ such that $$ J_z|m\rangle = m|m\rangle, $$ the following equalities are true $$ ...
Gec's user avatar
  • 6,025
1 vote

How are Schwinger functions defined as moments if they are actually operators?

The correspondence between the operator/Hilbert space langauge and the measure theoretic language is the essence of the Feynman-Kac isomorphism between Euclidean quantum field theory (the analytic ...
mike stone's user avatar
  • 55.2k
3 votes
Accepted

How are Schwinger functions defined as moments if they are actually operators?

Perhaps this is not what you were asking, but just in case: The measure-theoretic formalism that you are describing is that of Euclidean field theory. It is not quantum mechanics, and the field is not ...
Prox's user avatar
  • 790
0 votes

Derivation of momentum operator from kinetic energy operator

Your question really is: how can I define the square root of an operator? The answer is diagonalise, replace the eigenvalues by their roots, transform back.
my2cts's user avatar
  • 25.9k
1 vote

Tensor Operators and Spherical Harmonics

So the last question: "then how is it true that in quantum mechanics, they can be both an eigen basis for wave functions and also an operator?" so look at ordinary cartesian coordinates $(x, ...
JEB's user avatar
  • 36.6k
1 vote

Tensor Operators and Spherical Harmonics

The spherical harmonics can be considered as tensor operators acting by multiplication on other spherical harmonics because $$ Y_{\ell_2}^{m_2}(\theta,\phi)Y_{\ell_1}^{m_1}(\theta,\phi)= \sum_{\ell} C^...
ZeroTheHero's user avatar
  • 46.8k

Top 50 recent answers are included