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{{Short description|Particle effect}}
'''Zitterbewegung''' ("trembling motion" in ]) is a predicted rapid oscillatory motion of elementary particles that obey ]. The existence of such motion was first proposed by ] in 1930 as a result of his analysis of the ] solutions of the Dirac equation for ] electrons in free space, in which an ] between positive and negative ]s produces what appears to be a fluctuation (up to the speed of light) of the position of an electron around the median, with an ] of {{math|{{sfrac|2''mc''<sup>2</sup>|''ℏ''}}}}, or approximately {{val|1.6|e=21}} radians per second. A reexamination of Dirac theory, however, shows that interference between positive and negative energy states may not be a necessary criterion for observing zitterbewegung.<ref>{{cite journal|last=David Hestenes|title=The zitterbewegung interpretation of quantum mechanics|journal=Foundations of Physics|year=1990|volume=20|issue=10|doi=10.1007/BF01889466|bibcode = 1990FoPh...20.1213H|pages=1213–1232|citeseerx=10.1.1.412.3589}}</ref>
In ], the '''zitterbewegung''' ({{IPA|de|ˈtsɪtɐ.bəˌveːɡʊŋ}}, {{ety|de|zittern|to tremble, jitter||Bewegung|motion}}) is the theoretical prediction of a rapid oscillatory motion of ] that obey ]. This prediction was first discussed by ] in 1928<ref>{{Cite journal|last=Breit|first=Gregory|author-link=Gregory Breit|date=1928|title=An Interpretation of Dirac's Theory of the Electron|journal=Proceedings of the National Academy of Sciences|language=en|volume=14|issue=7|pages=553–559|doi=10.1073/pnas.14.7.553|issn=0027-8424|pmc=1085609|pmid=16587362|bibcode=1928PNAS...14..553B |doi-access=free}}</ref><ref>{{Cite book|last=Greiner|first=Walter|date=1995|title=Relativistic Quantum Mechanics|url=https://link.springer.com/book/10.1007/978-3-642-88082-7|language=en-gb|doi=10.1007/978-3-642-88082-7|isbn=978-3-540-99535-7|s2cid=124404090 }}</ref> and later by ] in 1930<ref>{{cite book |first= E. |last= Schrödinger |title= Über die kräftefreie Bewegung in der relativistischen Quantenmechanik |language= de |trans-title= On the free movement in relativistic quantum mechanics |pages= 418–428 |date= 1930 |oclc= 881393652 }}</ref><ref>{{cite book |first= E. |last= Schrödinger |title= Zur Quantendynamik des Elektrons |language= de |trans-title= Quantum Dynamics of the Electron |pages= 63–72 |date= 1931}}</ref> as a result of analysis of the ] solutions of the ] for relativistic ]s in free space, in which an ] between positive and negative ]s produces an apparent fluctuation (up to the speed of light) of the position of an electron around the median, with an ] of {{math|{{sfrac|2''mc''<sup>2</sup>|''ℏ''}}}}, or approximately {{val|1.6|e=21}} radians per second.


For the ], the zitterbewegung produces the ] which plays the role in the ] as a small correction of the energy level of the ]. This apparent oscillatory motion is often interpreted as an artifact of using the Dirac equation in a single particle description. For the ], the zitterbewegung is related to the ], a small correction of the energy level of the ].<ref>{{Cite book |last=Tong |first=David |url=https://www.damtp.cam.ac.uk/user/tong/aqm/aqm.pdf |title=Applications of Quantum Mechanics |publisher=University of Cambridge |year=2017}}</ref>


==Theory for a free fermion== ==Theory==


===Free spin-1/2 fermion===
The time-dependent ] is written as The time-dependent ] is written as
:<math> H \psi (\mathbf{x},t) = i \hbar \frac{\partial\psi}{\partial t} (\mathbf{x},t) </math>, :<math> H \psi (\mathbf{x},t) = i \hbar \frac{\partial\psi}{\partial t} (\mathbf{x},t) </math>,


where <math>\hbar </math> is the (reduced) ], <math>\psi(\mathbf{x},t) </math>is the ] (]) of a ]ic particle ], and {{mvar|H}} is the Dirac ] of a ]: where <math>\hbar </math> is the ], <math>\psi(\mathbf{x},t) </math> is the ] (]) of a ]ic particle ], and {{mvar|H}} is the Dirac ] of a ]:


:<math> H = \beta mc^2 + \sum_{j = 1}^3 \alpha_j p_j c </math>, :<math> H = \beta mc^2 + \sum_{j = 1}^3 \alpha_j p_j c </math>,
Line 15: Line 17:
where <math display="inline">m </math> is the mass of the particle, <math display="inline">c</math> is the ], <math display="inline">p_j </math> is the ], and <math>\beta </math> and <math>\alpha_j </math> are matrices related to the ] <math display="inline">\gamma_\mu </math>, as <math display="inline">\beta=\gamma_0 </math> and <math display="inline"> \alpha_j=\gamma_0\gamma_j </math>. where <math display="inline">m </math> is the mass of the particle, <math display="inline">c</math> is the ], <math display="inline">p_j </math> is the ], and <math>\beta </math> and <math>\alpha_j </math> are matrices related to the ] <math display="inline">\gamma_\mu </math>, as <math display="inline">\beta=\gamma_0 </math> and <math display="inline"> \alpha_j=\gamma_0\gamma_j </math>.


The ] implies that any operator {{mvar|Q}} obeys the equation In the ], the time dependence of an arbitrary observable {{mvar|Q}} obeys the equation


:<math> -i \hbar \frac{\partial Q}{\partial t} = \left .</math> :<math> -i \hbar \frac{d Q}{d t} = \left .</math>


In particular, the time-dependence of the ] is given by In particular, the time-dependence of the ] is given by
:<math> \hbar \frac{\partial x_k(t)}{\partial t} = i\left = \hbar c\alpha_k </math>. :<math> \frac{d x_k(t)}{d t} = \frac{i}{\hbar}\left = c\alpha_k </math>.


where {{math|''x<sub>k</sub>''(''t'')}} is the position operator at time {{mvar|t}}. where {{math|''x<sub>k</sub>''(''t'')}} is the position operator at time {{mvar|t}}.


The above equation shows that the operator {{mvar|α<sub>k</sub>}} can be interpreted as the {{mvar|k}}-th component of a "velocity operator". To add time-dependence to {{mvar|α<sub>k</sub>}}, one implements the Heisenberg picture, which says The above equation shows that the operator {{mvar|α<sub>k</sub>}} can be interpreted as the {{mvar|k}}-th component of a "velocity operator".

Note that this implies that

:<math> \left\langle \left(\frac{d x_k(t)}{d t}\right)^2 \right\rangle=c^2 </math>,

as if the "root mean square speed" in every direction of space is the speed of light.

To add time-dependence to {{mvar|α<sub>k</sub>}}, one implements the Heisenberg picture, which says


:<math> \alpha_k (t) = e^\frac{i H t}{\hbar}\alpha_k e^{-\frac{i H t}{\hbar}}</math>. :<math> \alpha_k (t) = e^\frac{i H t}{\hbar}\alpha_k e^{-\frac{i H t}{\hbar}}</math>.


The time-dependence of the velocity operator is given by The time-dependence of the velocity operator is given by
:<math> \hbar \frac{\partial \alpha_k(t)}{\partial t} = i\left = 2\left(i \gamma_k m - \sigma_{kl}p^l\right) = 2i\left(p_k-\alpha_kH\right) </math>, :<math> \hbar \frac{d \alpha_k(t)}{d t} = i\left = 2\left(i \gamma_k m - \sigma_{kl}p^l\right) = 2i\left(cp_k-\alpha_k(t)H\right) </math>,


where where
:<math>\sigma_{kl} \equiv \frac{i}{2}\left .</math> :<math>\sigma_{kl} \equiv \frac{i}{2}\left .</math>


Now, because both {{mvar|p<sub>k</sub>}} and {{mvar|H}} are time-independent, the above equation can easily be integrated twice to find the explicit time-dependence of the position operator. Now, because both {{mvar|p<sub>k</sub>}} and {{mvar|H}} are time-independent, the above equation can easily be integrated twice to find the explicit time-dependence of the position operator.


First: First:
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:<math> x_k(t) = x_k(0) + c^2 p_k H^{-1} t + \tfrac12 i \hbar c H^{-1} \left( \alpha_k (0) - c p_k H^{-1} \right) \left( e^{-\frac{2 i H t}{\hbar}} - 1 \right) </math>. :<math> x_k(t) = x_k(0) + c^2 p_k H^{-1} t + \tfrac12 i \hbar c H^{-1} \left( \alpha_k (0) - c p_k H^{-1} \right) \left( e^{-\frac{2 i H t}{\hbar}} - 1 \right) </math>.


The resulting expression consists of an initial position, a motion proportional to time, and an unexpected oscillation term with an amplitude equal to the ]. That oscillation term is the so-called zitterbewegung. The resulting expression consists of an initial position, a motion proportional to time, and an oscillation term with an amplitude equal to the reduced ]. That oscillation term is the so-called zitterbewegung.


==Interpretation==
The zitterbewegung term vanishes on taking expectation values for wave-packets that are made up entirely of positive- (or entirely of negative-) energy waves. This can be achieved by taking a ]. Thus, we arrive at the interpretation of the zitterbewegung as being caused by interference between positive- and negative-energy wave components.

In quantum mechanics, the zitterbewegung term vanishes on taking expectation values for wave-packets that are made up entirely of positive- (or entirely of negative-) energy waves. The standard relativistic velocity can be recovered by taking a ], when the positive and negative components are decoupled. Thus, we arrive at the interpretation of the zitterbewegung as being caused by interference between positive- and negative-energy wave components.<ref>{{Cite book|last=Greiner|first=Walter|date=1995|title=Relativistic Quantum Mechanics|url=https://link.springer.com/book/10.1007/978-3-642-88082-7|language=en-gb|doi=10.1007/978-3-642-88082-7|isbn=978-3-540-99535-7|s2cid=124404090 }}</ref>

In ] (QED) the negative-energy states are replaced by ] states, and the zitterbewegung is understood as the result of interaction of the electron with spontaneously forming and annihilating electron-positron ].<ref>Zhi-Yong, W., & Cai-Dong, X. (2008). Zitterbewegung in quantum field theory. Chinese Physics B, 17(11), 4170.</ref>

More recently, it has been noted that in the case of free particles it could just be an artifact of the simplified theory. Zitterbewegung appears as due to the "small components" of the Dirac 4-spinor, due to a little bit of antiparticle mixed up in the particle wavefunction for a nonrelativistic motion. It doesn't appear in the correct ], or rather, it is resolved by using ] and doing ]. Nevertheless, it is an interesting way to understand certain QED effects heuristically from the single particle picture. <ref>{{Cite web|url=https://physics.stackexchange.com/questions/28672/is-zitterbewegung-an-artefact-of-single-particle-theory|title = Dirac equation - is Zitterbewegung an artefact of single-particle theory?}}</ref>

=== Zigzag picture of fermions ===
{{See also|Feynman checkerboard}}

An alternative perspective of the physical meaning of zitterbewegung was provided by ],<ref name="PenroseZigzag">{{cite book |last1=Penrose |first1=Roger |title=The Road to Reality |date=2004 |publisher=Alfred A. Knopf |isbn=0-224-04447-8 |edition=Sixth Printing |pages=628–632}}</ref> by observing that the Dirac equation can be reformulated by splitting the four-component ] <math>\psi</math> into a pair of massless ] ] <math>\psi = (\psi_{\rm L}, \psi_{\rm R})</math> (or ''zig'' and ''zag'' components), where each is the source term in the other's equation of motion, with a coupling constant proportional to the original particle's ] <math>m</math>, as

:<math>
\left\{\begin{matrix}\sigma^\mu \partial_\mu \psi_{\rm R} = m \psi_{\rm L}\\
\overline{\sigma}^\mu \partial_\mu \psi_{\rm L} = m \psi_{\rm R}
\end{matrix}\right.
</math>.

The original massive Dirac particle can then be viewed as being composed of two massless components, each of which continually converts itself to the other. Since the components are massless they move at the speed of light, and their spin is constrained to be about the direction of motion, but each has opposite helicity: and since the spin remains constant, the direction of the velocity reverses, leading to the characteristic ''zigzag'' or zitterbewegung motion.


== Experimental simulation == == Experimental simulation ==
Zitterbewegung of a free relativistic particle has never been observed. However, it has been simulated twice. First, with a trapped ion, by putting it in an environment such that the non-relativistic Schrödinger equation for the ion has the same mathematical form as the Dirac equation (although the physical situation is different).<ref>{{cite journal|title=Quantum physics: Trapped ion set to quiver|url=http://www.nature.com/nature/journal/v463/n7277/full/463037a.html|newspaper=Nature News and Views | volume=463|issue=7277|pages=37–39|doi=10.1038/463037a|pmid=20054385|year=2010|last1=Wunderlich|first1=Christof}}</ref><ref>{{cite journal|last1=Gerritsma|last2=Kirchmair|last3=Zähringer|last4=Solano|last5=Blatt|last6=Roos|title=Quantum simulation of the Dirac equation|journal=Nature|year=2010|volume=463|issue=7277|doi=10.1038/nature08688|pmid=20054392|arxiv = 0909.0674 |bibcode = 2010Natur.463...68G|pages=68–71}}</ref> Then, in 2013, it was simulated in a setup with ]s.<ref>{{cite journal|last1=Leblanc|last2=Beeler|last3=Jimenez-Garcia|last4=Perry|last5=Sugawa|last6=Williams|last7=Spielman|title=Direct observation of zitterbewegung in a Bose–Einstein condensate|journal=New Journal of Physics|year=2013|url=http://iopscience.iop.org/1367-2630/15/7/073011|volume=15|issue=7|doi=10.1088/1367-2630/15/7/073011|page=073011|arxiv=1303.0914}}</ref> Zitterbewegung of a free relativistic particle has never been observed directly, although some authors believe they have found evidence in favor of its existence.<ref>{{Cite journal |last1=Catillon |first1=P. |last2=Cue |first2=N. |last3=Gaillard |first3=M. J. |last4=Genre |first4=R. |last5=Gouanère |first5=M. |last6=Kirsch |first6=R. G. |last7=Poizat |first7=J.-C. |last8=Remillieux |first8=J. |last9=Roussel |first9=L. |last10=Spighel |first10=M. |display-authors=3 |date=2008-07-01 |title=A Search for the de Broglie Particle Internal Clock by Means of Electron Channeling |journal=Foundations of Physics |volume=38 |issue=7 |pages=659–664 |doi=10.1007/s10701-008-9225-1 |bibcode=2008FoPh...38..659C |s2cid=121875694 |issn=1572-9516}}</ref> It has also been simulated in atomic systems that provide analogues of a free Dirac particle. The first such example, in 2010, placed a trapped ion in an environment such that the non-relativistic Schrödinger equation for the ion had the same mathematical form as the Dirac equation (although the physical situation is different).<ref>{{cite journal|title=Quantum physics: Trapped ion set to quiver|url=http://www.nature.com/nature/journal/v463/n7277/full/463037a.html|newspaper=] | volume=463|issue=7277|pages=37–39|doi=10.1038/463037a|pmid=20054385|year=2010|last1=Wunderlich|first1=Christof|bibcode=2010Natur.463...37W |doi-access=free}}</ref><ref>{{cite journal|last1=Gerritsma |first1=R. |last2=Kirchmair |first2=G. |last3=Zähringer |first3=F. |last4=Solano |first4= E. |last5=Blatt |first5=R. |last6=Roos |first6=C. F. |title=Quantum simulation of the Dirac equation|journal=]|year=2010|volume=463|issue=7277|doi=10.1038/nature08688|pmid=20054392|arxiv = 0909.0674 |bibcode = 2010Natur.463...68G|pages=68–71|s2cid=4322378}}</ref> Zitterbewegung-like oscillations of ultracold atoms in optical lattices were predicted in 2008.<ref>
{{cite journal
|last1= Vaishnav |first1=J. Y.
|last2= Clark |first2= C. W.
|title= Observing Zitterbewegung with Ultracold Atoms
|journal=]
|year=2008
|volume=100
|doi= 10.1103/PhysRevLett.100.153002
|pages=153002|arxiv=0711.3270
}}
</ref> In 2013, zitterbewegung was simulated in a ] of 50,000 atoms of <sup>87</sup>Rb confined in an optical trap.<ref>
{{cite journal
|last1=Leblanc |first1=L. J.
|last2=Beeler |first2=M. C.
|last3=Jimenez-Garcia |first3=K.
|last4=Perry |first4=A. R.
|last5=Sugawa |first5=S.
|last6=Williams |first6=R. A.
|last7=Spielman |first7=I.B.
|title=Direct observation of zitterbewegung in a Bose–Einstein condensate
|journal=]|year=2013
|volume=15
|issue=7
|doi=10.1088/1367-2630/15/7/073011
|page=073011
|arxiv=1303.0914
|s2cid=119190847}}
</ref>


An optical analogue of zitterbewegung was demonstrated in a quantum cellular automaton implemented with orbital angular momentum states of light<ref>
{{cite arXiv |title=Photonic cellular automaton simulation of relativistic quantum fields: observation of Zitterbewegung |first1=Alessia |last1=Suprano |first2=Danilo |last2=Zia |first3=Emanuele |last3=Polino |first4=Davide |last4=Poderini |first5=Gonzalo |last5=Carvacho |first6=Fabio |last6=Sciarrino |first7=Matteo |last7=Lugli |first8=Alessandro |last8=Bisio |first9=Paolo |last9=Perinotti |arxiv=2402.07672 }}</ref>

Other proposals for condensed-matter analogues include semiconductor nanostructures, ] and ].<ref>{{cite journal|title=Zitterbewegung of Electronic Wave Packets in III-V Zinc-Blende Semiconductor Quantum Wells |last=Schliemann|first=John |journal=] |volume=94 |number=20 |year=2005|pages=206801 |arxiv=cond-mat/0410321|doi=10.1103/PhysRevLett.94.206801 |pmid=16090266|bibcode=2005PhRvL..94t6801S |s2cid=118979437}}</ref><ref>{{cite journal|title=Zitterbewegung, chirality, and minimal conductivity in graphene |last=Katsnelson |first=M. I. |journal=] |volume=51 |number=2 |year=2006 |pages=157–160 |arxiv=cond-mat/0512337|doi=10.1140/epjb/e2006-00203-1 |bibcode=2006EPJB...51..157K |s2cid=119353065 }}</ref><ref>{{cite journal|title=Optically engineering the topological properties of a spin Hall insulator |last1=Dóra |first1=Balász |last2=Cayssol |first2=Jérôme |last3=Simon |first3=Ference |last4=Moessner |first4=Roderich |arxiv=1105.5963 |journal=] |volume=108 |number=5 |year=2012 |pages=056602 |doi=10.1103/PhysRevLett.108.056602|pmid=22400947 |bibcode=2012PhRvL.108e6602D |s2cid=15507388 }}</ref><ref>{{cite journal|title=Anomalous Electron Trajectory in Topological Insulators |last1=Shi |first1=Likun |last2=Zhang |first2=Shoucheng |last3=Cheng |first3=Kai |journal=] |volume=87 |number=16 |year=2013 |page=161115 |doi=10.1103/PhysRevB.87.161115 |arxiv=1109.4771|bibcode=2013PhRvB..87p1115S |s2cid=118446413 }}</ref>
==See also== ==See also==
* ] * ]
* ] * ]
* ]: Zitterbewegung is explained as an interaction of a classical particle with the ]


==References and notes== ==References==
{{reflist}} {{reflist}}


==Further reading== ==Further reading==
* {{cite book |first= E. |last= Schrödinger |title= Über die kräftefreie Bewegung in der relativistischen Quantenmechanik |language= de |trans-title= On the free movement in relativistic quantum mechanics |pages= 418–428 |date= 1930 |oclc= 881393652 }}
* {{cite book |first= E. |last= Schrödinger |title= Zur Quantendynamik des Elektrons |language= de |trans-title= Quantum Dynamics of the Electron |pages= 63–72 |date= 1931 }}
* {{cite book |first= A. |last= Messiah |title= Quantum Mechanics |volume= II |chapter= XX, Section 37 |pages= 950–952 |date= 1962 |chapter-url= https://archive.org/details/QuantumMechanicsVolumeIi |chapter-format= pdf |isbn= 9780471597681 }} * {{cite book |first= A. |last= Messiah |title= Quantum Mechanics |volume= II |chapter= XX, Section 37 |pages= 950–952 |date= 1962 |chapter-url= https://archive.org/details/QuantumMechanicsVolumeIi |chapter-format= pdf |isbn= 9780471597681 }}


== External links == == External links ==
* *

*


] ]

Latest revision as of 14:55, 17 December 2024

Particle effect

In physics, the zitterbewegung (German pronunciation: [ˈtsɪtɐ.bəˌveːɡʊŋ], from German zittern 'to tremble, jitter' and Bewegung 'motion') is the theoretical prediction of a rapid oscillatory motion of elementary particles that obey relativistic wave equations. This prediction was first discussed by Gregory Breit in 1928 and later by Erwin Schrödinger in 1930 as a result of analysis of the wave packet solutions of the Dirac equation for relativistic electrons in free space, in which an interference between positive and negative energy states produces an apparent fluctuation (up to the speed of light) of the position of an electron around the median, with an angular frequency of ⁠2mc/⁠, or approximately 1.6×10 radians per second.

This apparent oscillatory motion is often interpreted as an artifact of using the Dirac equation in a single particle description. For the hydrogen atom, the zitterbewegung is related to the Darwin term, a small correction of the energy level of the s-orbitals.

Theory

Free spin-1/2 fermion

The time-dependent Dirac equation is written as

H ψ ( x , t ) = i ψ t ( x , t ) {\displaystyle H\psi (\mathbf {x} ,t)=i\hbar {\frac {\partial \psi }{\partial t}}(\mathbf {x} ,t)} ,

where {\displaystyle \hbar } is the reduced Planck constant, ψ ( x , t ) {\displaystyle \psi (\mathbf {x} ,t)} is the wave function (bispinor) of a fermionic particle spin-1/2, and H is the Dirac Hamiltonian of a free particle:

H = β m c 2 + j = 1 3 α j p j c {\displaystyle H=\beta mc^{2}+\sum _{j=1}^{3}\alpha _{j}p_{j}c} ,

where m {\textstyle m} is the mass of the particle, c {\textstyle c} is the speed of light, p j {\textstyle p_{j}} is the momentum operator, and β {\displaystyle \beta } and α j {\displaystyle \alpha _{j}} are matrices related to the Gamma matrices γ μ {\textstyle \gamma _{\mu }} , as β = γ 0 {\textstyle \beta =\gamma _{0}} and α j = γ 0 γ j {\textstyle \alpha _{j}=\gamma _{0}\gamma _{j}} .

In the Heisenberg picture, the time dependence of an arbitrary observable Q obeys the equation

i d Q d t = [ H , Q ] . {\displaystyle -i\hbar {\frac {dQ}{dt}}=\left.}

In particular, the time-dependence of the position operator is given by

d x k ( t ) d t = i [ H , x k ] = c α k {\displaystyle {\frac {dx_{k}(t)}{dt}}={\frac {i}{\hbar }}\left=c\alpha _{k}} .

where xk(t) is the position operator at time t.

The above equation shows that the operator αk can be interpreted as the k-th component of a "velocity operator".

Note that this implies that

( d x k ( t ) d t ) 2 = c 2 {\displaystyle \left\langle \left({\frac {dx_{k}(t)}{dt}}\right)^{2}\right\rangle =c^{2}} ,

as if the "root mean square speed" in every direction of space is the speed of light.

To add time-dependence to αk, one implements the Heisenberg picture, which says

α k ( t ) = e i H t α k e i H t {\displaystyle \alpha _{k}(t)=e^{\frac {iHt}{\hbar }}\alpha _{k}e^{-{\frac {iHt}{\hbar }}}} .

The time-dependence of the velocity operator is given by

d α k ( t ) d t = i [ H , α k ] = 2 ( i γ k m σ k l p l ) = 2 i ( c p k α k ( t ) H ) {\displaystyle \hbar {\frac {d\alpha _{k}(t)}{dt}}=i\left=2\left(i\gamma _{k}m-\sigma _{kl}p^{l}\right)=2i\left(cp_{k}-\alpha _{k}(t)H\right)} ,

where

σ k l i 2 [ γ k , γ l ] . {\displaystyle \sigma _{kl}\equiv {\frac {i}{2}}\left.}

Now, because both pk and H are time-independent, the above equation can easily be integrated twice to find the explicit time-dependence of the position operator.

First:

α k ( t ) = ( α k ( 0 ) c p k H 1 ) e 2 i H t + c p k H 1 {\displaystyle \alpha _{k}(t)=\left(\alpha _{k}(0)-cp_{k}H^{-1}\right)e^{-{\frac {2iHt}{\hbar }}}+cp_{k}H^{-1}} ,

and finally

x k ( t ) = x k ( 0 ) + c 2 p k H 1 t + 1 2 i c H 1 ( α k ( 0 ) c p k H 1 ) ( e 2 i H t 1 ) {\displaystyle x_{k}(t)=x_{k}(0)+c^{2}p_{k}H^{-1}t+{\tfrac {1}{2}}i\hbar cH^{-1}\left(\alpha _{k}(0)-cp_{k}H^{-1}\right)\left(e^{-{\frac {2iHt}{\hbar }}}-1\right)} .

The resulting expression consists of an initial position, a motion proportional to time, and an oscillation term with an amplitude equal to the reduced Compton wavelength. That oscillation term is the so-called zitterbewegung.

Interpretation

In quantum mechanics, the zitterbewegung term vanishes on taking expectation values for wave-packets that are made up entirely of positive- (or entirely of negative-) energy waves. The standard relativistic velocity can be recovered by taking a Foldy–Wouthuysen transformation, when the positive and negative components are decoupled. Thus, we arrive at the interpretation of the zitterbewegung as being caused by interference between positive- and negative-energy wave components.

In quantum electrodynamics (QED) the negative-energy states are replaced by positron states, and the zitterbewegung is understood as the result of interaction of the electron with spontaneously forming and annihilating electron-positron pairs.

More recently, it has been noted that in the case of free particles it could just be an artifact of the simplified theory. Zitterbewegung appears as due to the "small components" of the Dirac 4-spinor, due to a little bit of antiparticle mixed up in the particle wavefunction for a nonrelativistic motion. It doesn't appear in the correct second quantized theory, or rather, it is resolved by using Feynman propagators and doing QED. Nevertheless, it is an interesting way to understand certain QED effects heuristically from the single particle picture.

Zigzag picture of fermions

See also: Feynman checkerboard

An alternative perspective of the physical meaning of zitterbewegung was provided by Roger Penrose, by observing that the Dirac equation can be reformulated by splitting the four-component Dirac spinor ψ {\displaystyle \psi } into a pair of massless left-handed and right-handed two-component spinors ψ = ( ψ L , ψ R ) {\displaystyle \psi =(\psi _{\rm {L}},\psi _{\rm {R}})} (or zig and zag components), where each is the source term in the other's equation of motion, with a coupling constant proportional to the original particle's rest mass m {\displaystyle m} , as

{ σ μ μ ψ R = m ψ L σ ¯ μ μ ψ L = m ψ R {\displaystyle \left\{{\begin{matrix}\sigma ^{\mu }\partial _{\mu }\psi _{\rm {R}}=m\psi _{\rm {L}}\\{\overline {\sigma }}^{\mu }\partial _{\mu }\psi _{\rm {L}}=m\psi _{\rm {R}}\end{matrix}}\right.} .

The original massive Dirac particle can then be viewed as being composed of two massless components, each of which continually converts itself to the other. Since the components are massless they move at the speed of light, and their spin is constrained to be about the direction of motion, but each has opposite helicity: and since the spin remains constant, the direction of the velocity reverses, leading to the characteristic zigzag or zitterbewegung motion.

Experimental simulation

Zitterbewegung of a free relativistic particle has never been observed directly, although some authors believe they have found evidence in favor of its existence. It has also been simulated in atomic systems that provide analogues of a free Dirac particle. The first such example, in 2010, placed a trapped ion in an environment such that the non-relativistic Schrödinger equation for the ion had the same mathematical form as the Dirac equation (although the physical situation is different). Zitterbewegung-like oscillations of ultracold atoms in optical lattices were predicted in 2008. In 2013, zitterbewegung was simulated in a Bose–Einstein condensate of 50,000 atoms of Rb confined in an optical trap.

An optical analogue of zitterbewegung was demonstrated in a quantum cellular automaton implemented with orbital angular momentum states of light

Other proposals for condensed-matter analogues include semiconductor nanostructures, graphene and topological insulators.

See also

References

  1. Breit, Gregory (1928). "An Interpretation of Dirac's Theory of the Electron". Proceedings of the National Academy of Sciences. 14 (7): 553–559. Bibcode:1928PNAS...14..553B. doi:10.1073/pnas.14.7.553. ISSN 0027-8424. PMC 1085609. PMID 16587362.
  2. Greiner, Walter (1995). Relativistic Quantum Mechanics. doi:10.1007/978-3-642-88082-7. ISBN 978-3-540-99535-7. S2CID 124404090.
  3. Schrödinger, E. (1930). Über die kräftefreie Bewegung in der relativistischen Quantenmechanik [On the free movement in relativistic quantum mechanics] (in German). pp. 418–428. OCLC 881393652.
  4. Schrödinger, E. (1931). Zur Quantendynamik des Elektrons [Quantum Dynamics of the Electron] (in German). pp. 63–72.
  5. Tong, David (2017). Applications of Quantum Mechanics (PDF). University of Cambridge.
  6. Greiner, Walter (1995). Relativistic Quantum Mechanics. doi:10.1007/978-3-642-88082-7. ISBN 978-3-540-99535-7. S2CID 124404090.
  7. Zhi-Yong, W., & Cai-Dong, X. (2008). Zitterbewegung in quantum field theory. Chinese Physics B, 17(11), 4170.
  8. "Dirac equation - is Zitterbewegung an artefact of single-particle theory?".
  9. Penrose, Roger (2004). The Road to Reality (Sixth Printing ed.). Alfred A. Knopf. pp. 628–632. ISBN 0-224-04447-8.
  10. Catillon, P.; Cue, N.; Gaillard, M. J.; et al. (2008-07-01). "A Search for the de Broglie Particle Internal Clock by Means of Electron Channeling". Foundations of Physics. 38 (7): 659–664. Bibcode:2008FoPh...38..659C. doi:10.1007/s10701-008-9225-1. ISSN 1572-9516. S2CID 121875694.
  11. Wunderlich, Christof (2010). "Quantum physics: Trapped ion set to quiver". Nature News and Views. 463 (7277): 37–39. Bibcode:2010Natur.463...37W. doi:10.1038/463037a. PMID 20054385.
  12. Gerritsma, R.; Kirchmair, G.; Zähringer, F.; Solano, E.; Blatt, R.; Roos, C. F. (2010). "Quantum simulation of the Dirac equation". Nature. 463 (7277): 68–71. arXiv:0909.0674. Bibcode:2010Natur.463...68G. doi:10.1038/nature08688. PMID 20054392. S2CID 4322378.
  13. Vaishnav, J. Y.; Clark, C. W. (2008). "Observing Zitterbewegung with Ultracold Atoms". Physical Review Letters. 100: 153002. arXiv:0711.3270. doi:10.1103/PhysRevLett.100.153002.
  14. Leblanc, L. J.; Beeler, M. C.; Jimenez-Garcia, K.; Perry, A. R.; Sugawa, S.; Williams, R. A.; Spielman, I.B. (2013). "Direct observation of zitterbewegung in a Bose–Einstein condensate". New Journal of Physics. 15 (7): 073011. arXiv:1303.0914. doi:10.1088/1367-2630/15/7/073011. S2CID 119190847.
  15. Suprano, Alessia; Zia, Danilo; Polino, Emanuele; Poderini, Davide; Carvacho, Gonzalo; Sciarrino, Fabio; Lugli, Matteo; Bisio, Alessandro; Perinotti, Paolo. "Photonic cellular automaton simulation of relativistic quantum fields: observation of Zitterbewegung". arXiv:2402.07672.
  16. Schliemann, John (2005). "Zitterbewegung of Electronic Wave Packets in III-V Zinc-Blende Semiconductor Quantum Wells". Physical Review Letters. 94 (20): 206801. arXiv:cond-mat/0410321. Bibcode:2005PhRvL..94t6801S. doi:10.1103/PhysRevLett.94.206801. PMID 16090266. S2CID 118979437.
  17. Katsnelson, M. I. (2006). "Zitterbewegung, chirality, and minimal conductivity in graphene". The European Physical Journal B. 51 (2): 157–160. arXiv:cond-mat/0512337. Bibcode:2006EPJB...51..157K. doi:10.1140/epjb/e2006-00203-1. S2CID 119353065.
  18. Dóra, Balász; Cayssol, Jérôme; Simon, Ference; Moessner, Roderich (2012). "Optically engineering the topological properties of a spin Hall insulator". Physical Review Letters. 108 (5): 056602. arXiv:1105.5963. Bibcode:2012PhRvL.108e6602D. doi:10.1103/PhysRevLett.108.056602. PMID 22400947. S2CID 15507388.
  19. Shi, Likun; Zhang, Shoucheng; Cheng, Kai (2013). "Anomalous Electron Trajectory in Topological Insulators". Physical Review B. 87 (16): 161115. arXiv:1109.4771. Bibcode:2013PhRvB..87p1115S. doi:10.1103/PhysRevB.87.161115. S2CID 118446413.

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