M. Lewkowicz scite author profile

The process of coherent creation of particle -hole excitations by an electric field in graphene is quantitatively described. We calculate the evolution of current density, number of pairs and energy after switching on the electric field. In particular, it leads to a dynamical visualization of the universal finite resistivity without dissipation in pure graphene. We show that the DC conductivity of pure graphene is . This value coincides with the AC conductivity calculated and measured recently at optical frequencies. The effect of temperature and random chemical potential (charge puddles) are considered and explain the recent experiment on suspended graphene. A possibility of Bloch oscillations is discussed within the tight binding model.

show abstract

Geometry of Hamiltonian Chaos

Horwitz

Zion

Lewkowicz

et al. 2007

Phys. Rev. Lett.

View full text Add to dashboard Cite

The characterization of chaotic Hamiltonian systems in terms of the curvature associated with a Riemannian metric tensor in the structure of the Hamiltonian can be extended to a wide class of potential models of standard form through definition of a conformal metric. The geodesic equations reproduce the Hamilton equations of the original potential model when a transition is made to an associated manifold for which the geodesics coincide with the orbits of the Hamiltonian potential model. We therefore find a direct geometrical description of the time development of a Hamiltonian potential model. The second covariant derivative of the geodesic deviation in this associated manifold generates a dynamical curvature, resulting in (energy dependent) criteria for unstable behavior different from the usual Lyapunov criteria. We discuss some examples of unstable Hamiltonian systems in two dimensions giving, as a particular illustation, detailed results for a potential obtained from a fifth order expansion of a Toda lattice Hamiltonian.

show abstract

Ballistic transport in graphene beyond linear response

et al. 2010

View full text Add to dashboard Cite

The process of coherent creation of particle -hole excitations by an electric field in graphene is quantitatively described beyond linear response. We calculate the evolution of current density, number of pairs and energy in ballistic regime for electric field E using the tight binding model. While for ballistic flight times smaller than t nl ∝ E −1/2 current is linear in E and independent of time, for larger ballistic times the current increases after t nl as J ∝ E 3/2 t and finally at yet larger times (t > tB ∝ E −1 ) Bloch oscillations set in. It is shown that the number of pairs follows the 2D generalization of the Schwinger's creation rate n ∝ E 3/2 only on certain time segments with a prefactor different from that obtained using the asymptotic formula.

show abstract

Chiral Anomaly and Strength of the Electron-Electron Interaction in Graphene

2013

View full text Add to dashboard Cite

The long standing controversy concerning the effect of electron -electron interaction on the electrical conductivity of an ideal graphene sheet is settled. Performing the calculation directly in the tight binding approach without the usual prior reduction to the massless Dirac (Weyl) theory, it is found that, to leading order in the interaction strength α = e 2 / v0, the DC conductivity σ/σ0 = 1 + Cα + O α 2 is significantly enhanced with respect to the independent-electrons result σ0, i.e. with the value C = 0.26. The ambiguity characterizing the various existing approaches is nontrivial and related to the chiral anomaly in the system. In order to separate the energy scales in a model with massless fermions, contributions from regions of the Brillouin zone away from the Dirac points have to be accounted for. Experimental consequences of the relatively strong interaction effect are briefly discussed.

show abstract

Ballistic transport, chiral anomaly, and emergence of the neutral electron-hole plasma in graphene

2010

View full text Add to dashboard Cite

The process of coherent creation of particle -hole excitations by an electric field in graphene is quantitatively described using a dynamic "first quantized" approach. We calculate the evolution of current density, number of pairs and energy in ballistic regime using the tight binding model. The series in electric field strength E up to third order in both DC and AC are calculated. We show how the physics far from the two Dirac points enters various physical quantities in linear response and how it is related to the chiral anomaly. The third harmonic generation and the imaginary part of conductivity are obtained. It is shown that at certain time scale t nl ∝ E −1/2 the physical behaviour dramatically changes and the perturbation theory breaks down. Beyond the linear response physics is explored using an exact solution of the first quantized equations. While for small electric fields the I-V curve is linear characterized by the universal minimal resistivity σ = π/2(e 2 /h), at t > t nl the conductivity grows fast. The copious pair creation (with rate E 3/2 ), analogous to Schwinger's electron -positron pair creation from vacuum in QED, leads to creation of the electron -hole plasma at ballistic times of order t nl . This process is terminated by a relaxational recombination.

show abstract

scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.

Contact Info

customersupport@researchsolutions.com

10624 S. Eastern Ave., Ste. A-614

Henderson, NV 89052, USA

This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.

Blog Terms and Conditions API Terms Privacy Policy Contact Cookie Preferences Do Not Sell or Share My Personal Information

Made with 💙 for researchers

Part of the Research Solutions Family.

M. Lewkowicz

Dynamics of Particle-Hole Pair Creation in Graphene

Geometry of Hamiltonian Chaos

Ballistic transport in graphene beyond linear response

Chiral Anomaly and Strength of the Electron-Electron Interaction in Graphene

Ballistic transport, chiral anomaly, and emergence of the neutral electron-hole plasma in graphene

Contact Info

Product

Resources

About