R. J. Churchill scite author profile

We transform the two-dimensional Dirac-Weyl equation, which governs the charge carriers in graphene, into a nonlinear first-order differential equation for scattering phase shift, using the so-called variable-phase method. This allows us to utilize the Levinson theorem, relating scattering phase shifts of a slow particle to its bound states, to find zero-energy bound states created electrostatically in realistic structures. These confined states are formed at critical potential strengths, which leads us to posit the use of "optimal traps" to combat the chiral tunneling found in graphene: this could be explored experimentally with an artificial network of point charges held above the graphene layer. We also discuss scattering on these states and find that the s states create a dominant peak in the scattering cross section as the energy tends towards the Dirac point energy, suggesting a dominant contribution to the resistivity.

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Electromagnetic reflection, transmission, and energy density at boundaries of nonlocal media

Churchill

Philbin

2016

Phys. Rev. B

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We consider a semi-infinite spatially dispersive dielectric with unequal transverse and longitudinal susceptibilities. The effect of the boundary is characterized by arbitrary reflection coefficients for polarization waves in the material that propagate to the surface. Specific values of these coefficients correspond to various additional boundary conditions (ABC) for Maxwell's equations. We derive the electromagnetic reflection and transmission coefficients at the boundary and investigate their dependence on material parameters and ABC. We also investigate the electromagnetic zero-point and thermal spectral energy density outside the dielectric. The nonlocal response removes the boundary divergence of the spectral energy density that is present in a local model. The spectral energy density shows a large dependence on the difference between the transverse and longitudinal susceptibilities, even at distances up to 10nm from the boundary.

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Effect of Material Parameters on the Charging Characteristics of Irradiated Dielectrics

Hazelton¹,

Yadlowsky²,

Churchill³

et al. 1981

IEEE Trans. Nucl. Sci.

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Laser cutting of amorphous alloy ribbon and POWERCORE® consolidated metal strip

Glass

Groger

Churchill

et al. 1990

J. Materials Engineering

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R. J. Churchill

Progress in Reentry Communications

Optimal traps in graphene

Electromagnetic reflection, transmission, and energy density at boundaries of nonlocal media

Effect of Material Parameters on the Charging Characteristics of Irradiated Dielectrics

Laser cutting of amorphous alloy ribbon and POWERCORE® consolidated metal strip

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