109 research outputs found
Trouble with the Lorentz Law of Force: Response to Critics
In a recent paper [arXiv:1205.0096], we questioned the validity of the
Lorentz law of force in the presence of material media that contain electric
and/or magnetic dipoles. A number of authors have criticized our methods and
conclusions. This paper is an attempt at answering the critics and elaborating
the relevant issues in some detail.Comment: 13 pages, 4 figures, 40 reference
Fourier Optics in the Classroom
Borrowing methods and formulas from Prof. Goodman's classic Introduction to
Fourier Optics textbook [1], I have developed a software package [2] that has
been used in both industrial research and classroom teaching [3]. This paper
briefly describes a few optical system simulations that have been used over the
past 30 years to convey the power and the beauty of Fourier Optics to our
students at the University of Arizona's College of Optical Sciences.Comment: 2 pages, 5 figures, 3 references, Published in the Proceedings of the
Optical Society of America's Imaging & Applied Optics Congress, Orlando,
Florida (June 2018
Optical Angular Momentum in Classical Electrodynamics
Invoking Maxwell's classical equations in conjunction with expressions for
the electromagnetic (EM) energy, momentum, force, and torque, we use a few
simple examples to demonstrate the nature of the EM angular momentum. The
energy and the angular momentum of an EM field will be shown to have an
intimate relationship; a source radiating EM angular momentum will, of
necessity, pick up an equal but opposite amount of mechanical angular momentum;
and the spin and orbital angular momenta of the EM field, when absorbed by a
small particle, will be seen to elicit different responses from the particle.Comment: 15 pages, 3 figures, 43 equations, 34 reference
Momentum of the Electromagnetic Field in Transparent Dielectric Media
We present arguments in favor of the proposition that the momentum of light
inside a transparent dielectric medium is the arithmetic average of the
Minkowski and Abraham momenta. Using the Lorentz transformation of the fields
(and of the coordinates) from a stationary to a moving reference frame, we show
the consistent transformation of electromagnetic energy and momentum between
the two frames. We also examine the momentum of static (i.e., time-independent)
electromagnetic fields, and show that the close connection that exists between
the Poynting vector and the momentum density extends all the way across the
frequency spectrum to this zero-frequency limit. In the specific example
presented in this paper, the static field inside a non-absorbing dielectric
material turns out to have the Minkowski momentum.Comment: 10 pages, 5 figures, 29 equations, 15 reference
Comment on "Observation of a push force on the end face of a nanometer silica filament exerted by outgoing light," Phys. Rev. Lett. 101, 243601 (2008)
In a recent paper, W. She, J. Yu and R. Feng reported the slight deformations
observed upon transmission of a light pulse through a fairly short length of a
silica glass nano-fiber. Relating the shape and magnitude of these deformations
to the momentum of the light pulse both inside and outside the fiber, these
authors concluded that, within the fiber, the photons carry the Abraham
momentum. In my view, the authors' claim that they have resolved the
Abraham-Minkowski controversy surrounding the momentum of photons inside
dielectric media is premature. A correct interpretation of the experiments of
She et al requires precise calculations that would properly account not only
for the electromagnetic momentum (both inside and outside the fiber) but also
for the Lorentz force exerted on the fiber by the light pulse in its entire
path through this nano-waveguide.Comment: 2 pages, 4 reference
Angular Momentum Exchange Between Light and Material Media Deduced from the Doppler Shift
Electromagnetic waves carry energy as well as linear and angular momenta.
When a light pulse is reflected from, transmitted through, or absorbed by a
material medium, energy and momentum (both linear and angular) are generally
exchanged, while the total amount of each entity remains intact. The extent of
such exchanges between light and matter can be deduced, among other methods,
with the aid of the Doppler shift phenomenon. The main focus of the present
paper is on the transfer of angular momentum from a monochromatic light pulse
to spinning objects such as a mirror, an absorptive dielectric, or a
birefringent plate. The fact that individual photons of frequency omega carry
energy in the amount of h_bar*omega, where h_bar is Planck's reduced constant,
enables one to relate the Doppler shift to the amount of energy exchanged.
Under certain circumstances, the knowledge of exchanged energy leads directly
to a determination of the momentum transferred from the photon to the material
body, or vice versa.Comment: 8 pages, 7 figures, 7 equations, 14 reference
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