Physics Asked by Gary on December 10, 2020
Recent papers have shown evidence for the existence of the long sought after Chiral axial anomaly to be present in certain Weyl semi-metals….
Usually they talk of the parallel B and E fields inducing violation of symmetry so as to create oppositely chiral “Weyl nodes” (that results the “chiral magnetic effect” in violation of conserved current)…..and sometimes they show evidence of Fermi arcs .
But in all the reports I have seen I have never seen any indication of the magnitude of the spatial separation of the nodes….or even the number of nodes per amount of volume of material, etc. …. Usually only comments about the phenomenology between two nodes….
So 1st…what is a “node”? Isn’t it the place of accumulation of a number of chiral “quasi-particles”??…
and 2. What is the typical spatial separation of two nodes and what determines the amount of that separation?
(I mean are we talking microns or inches?? )
….or am I missing the whole idea due to my ignorance of solid state physics.?
Thanks for the help.
1) The Weyl node is the point at which the two energy zones of the semimetal - the valence and the conductivity zones - are intersected. The particles spectrum in corresponding Brilloiun zone is continuously deformed from the standard Schroedinger one (in general the spectrum is determined from the material lattice structure) to the linear one, which is the Weyl fermion spectrum. So, the Weyl node contains effective massless Weyl fermions. Here You need to learn some details.
2) The non-zero separation between the given pair of the Weyl nodes are rather in energy-momentum space. This is preferable since when we discuss the solid body lattice we typically make the Fourier transformation, for time as well as for spatial coordinates. The presence of this separation depends on whether the parity and time reversal symmetries is broken in semimetal lattice or not. This creates two classes of semimetals - Dirac or Weyl.
Which nodes are separated? In fact, if there exist the node with given chirality $lambda$ and given momentum $mathbf p_{W}^{lambda}$, then there must exist the another node with the chirality $-lambda$ and momentum $mathbf p^{-lambda}_{W}$. This statement is known as Nielsen-Ninomiya theorem. It can be argued in a following way. Each Weyl node is the source for the so-called Berry curvature - the monopole-like field in momentum space, with the charge determined by the chirality $lambda$. Its field lines must be ended somewhere in the Brillouine zone. The only way to do this is to require that there must be the node with an opposite chirality $-lambda$. These two nodes - with chirality $lambda$ and $-lambda$ - may be separated by the finite distances in momentum and energy space, given by $$ tag 2 mathbf b equiv mathbf p_{W}^{lambda}- mathbf p_{W}^{-lambda}, quad b_{0} equiv H_{0}^{lambda} - H_{0}^{-lambda} $$ So, there is even number of nodes, and the number of pairs is determined by the number of semimetal energy zones intersections.
What determines the distance between Weyl nodes? In fact, it is determined by the parity and time reversal symmetries on a semimetal lattice. This can be easily see from the explicit form of the hamiltonian $H$, given by $(1)$ and $(2)$: $$ H(mathbf b, b_{0}) = begin{pmatrix} b_{0} + sigma cdot (mathbf p - mathbf b)& 0 0 & -b_{0}-sigma cdot (mathbf p + mathbf b)end{pmatrix} $$ Under parity transformation, $H$ is transformed into $H(mathbf b, -b_{0})$, while under time reversal transformation, $H$ is transformed into $H(-mathbf b , b_{0})$. So that we see that if $mathbf b neq 0$, then the time reversal symmetry is broken, while if $b_{0} neq 0$, then the parity symmetry is broken. If at least one of quantities $b_{0},mathbf b$ is non-zero, then the semimetal is called the Weyl semimetal. The case $b_{0} = 0, mathbf b = 0$ is called the Dirac semimetal.
3) Finally, since the Weyl fermion theory in presence of external electric and magnetic fields is anomalous, then the full effective theory of semimetal, desctibing the pairs of Weyl nodes, generate anomalous transport phenomena - the anomalous Hall effect and the chiral magnetic effect.
Answered by Name YYY on December 10, 2020
WOW ; Thank you, YYY, for taking the time to do such an in-depth explanation of Wyle fermions. It will still take a bit of time to assimulate the implications of all the details you have written. Like i said; I am not adept to some condensed matter terminology. This information, though enlightening, has spurred a milion new questions.
To clarify, for starters, would you please answer a few related questions concerning the - and + chirality of the Wyle fermions:
In a quantum sense do the separate chiral weyl fermions have (or is it equivalent to) quantum spin; are the nodes they quantized, like spin +1 and spin -1, and if so, how do they add up to spin 1/2 when added to form an electron.?? You state they are given chirality +1 and -1 ; how does that add up to the spin 1/2 of a "normal" fermion?
You state; "The system tends to levels repulsion by generating the perturbation δH, which can be given in the general form δH=a⋅σ, where a is the perturbation and σ is the set of three Pauli matrices. In order to set a to zero we have to tune at least 3 free parameters c. In 3D space the only these parameters are the lattice momentum p components. By tuning 3 parameters we fix the given point pW, which is called the Weyl node." .So in a practical sense how are the weyl nodes generated: Or more precisely; what provides the "perturbation" and the "tuning" of the "free parameters"? Are these indigenous to the crystal lattice itself, or is there some external "perturbation" and "tuning" that must be done "artificially", ie., externally ? In practice, what is that process?
3.Can b be referred to as a Lorentz boost; what about b(0) ?
4.What determines whether the two chiral Hamiltonians are different; in a practical sense how is that difference "produced"?
How about the same question for the momentums ...what makes them different?
Thanks for helping edumucate me...
Answered by Gary on December 10, 2020
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