From Refraction to Diffraction

The team expects that this will help them push forward the application of the observed effect, and potentially bring to light more differences between quantum and classical light fields. [51] This could be achieved by mapping the vibrational dynamics of complex molecules onto the propagation of photons in advanced photonic circuits. [50] Working in the lab of Mikhail Lukin, the George Vasmer Leverett Professor of Physics and co-director of the Quantum Science and Engineering Initiative, Evans is lead author of a study, described in the journal Science, that demonstrates a method for engineering an interaction between two qubits using photons. [49]

Cornell University - arXiv, 2022

Physical Review B

Foundations of Physics, 2009

A macroscopic realization of the strange virtual particles is presented. The classical Helmholtz and the quantum mechanical Schrödinger equations are analogous differential equations. Their imaginary solutions are called evanescent modes in the case of elastic and electromagnetic fields. In the case of non-relativistic quantum mechanical fields they are called tunneling solutions. The imaginary solutions of this differential equation point to strange consequences: They are non local, they are not observable, and they described as virtual particles. During the last two decades QED calculations of the imaginary solutions have been experimentally confirmed for phonons, photons, and for electrons. The experimental proofs of the predictions of the non-relativistic quantum mechanics and of the Wigner phase time approach for the elastic, the electromagnetic and the Schrödinger fields will be presented in this article. The results are zero tunneling time and an interaction time (i.e. a phase shift) at the barrier interfaces. The measured barrier interaction time (i.e. the barrier transmission time) scales approximately inversely with the particle energy.

Science, 2008

SPIE Newsroom, 2009

A chip-scale optomechanical system with extremely low dissipation might enable the observation of quantum behavior in tangible objects visible to the naked eye.

2011

A new future for metamaterials is suggested, involving the insertion of quantum degrees of freedom, under the guise of quantum dots or cold atoms, in an photonic matrix. It is argued that new emergent, quantum, properties could be obtained.

"We have to see the whole Universe and find the the essence: one Force and one Substance." (Prof.Frank Wilczek, Nobel Prize) In my opinion: The one Force and one Substance is a Special Information. It is not only an information in general but It is a special force and power too: It coded information in matter and It changes active it in time. Only such Special Information can guide every process of matter from the first moment of the Universe's evolution to the end. 1./About soliton in general 2./What is the relation between soliton and quantum wave? 1./About soliton in general: "In mathematics and physics, a soliton is a self-reinforcing solitary wave packet that maintains its shape while it propagates at a constant velocity. Solitons are caused by a cancellation of nonlinear and dispersive effects in the medium. (The term "dispersive effects" refers to a property of certain systems where the speed of the waves varies according to frequency.) Solitons are the solutions of a widespread class of weakly nonlinear dispersive partial differential equations describing physical systems. A single, consensus definition of a soliton is difficult to find. Drazin & Johnson (1989, p. 15) ascribe three properties to solitons: 1./ They are of permanent form; 2./They are localized within a region; 3./They can interact with other solitons, and emerge from the collision unchanged, except for a phase shift.. Explanation: A hyperbolic secant (sech) envelope soliton for water waves. The blue line is the carrier signal, while the red line is the envelope soliton. Dispersion and non-linearity can interact to produce permanent and localized wave forms. Consider a pulse of light traveling in glass. This pulse can be thought of as consisting of light of several different frequencies. Since glass shows dispersion, these different frequencies will travel at different speeds and the shape of the pulse will therefore change over time. However, there is also the non-linear Kerr effect: the refractive index of a material at a given frequency depends on the light's amplitude or strength. If the pulse has just the right shape, the Kerr effect will exactly cancel the dispersion effect, and the pulse's shape will not change over time: a soliton. See soliton (optics) for a more detailed description. Many exactly solvable models have soliton solutions, including the Korteweg–de Vries equation, the nonlinear Schrödinger equation, the coupled nonlinear Schrödinger equation, and the sine-Gordon equation. The soliton solutions are typically obtained by means of the inverse scattering transform and owe their stability to the integrability of the field equations. The mathematical theory of these equations is a broad and very active field of mathematical research."(Wikipedia) 2./What is the relation between soliton and quantum wave? I think that: Soliton also carries coded information as all particles and wave-function. Soliton is a real "shapeshifter"...Why? Prof.Henk Koppelaar: "Soliton is the normal form of matter and waves." Matter can be wave and particle at the same time. Why? Because every wave-function has coded information about particle nature and every particle has coded information about wave nature. We don't know where is electron in the wave-function-it can be anywhere because its place changes continuously-but we know that the real electron appears from the wave-function when we take a measurement/observation. It is possible by the coded information what determined both properties in wave-function and in electron too. Because matter can be exist only by continuously changes: so maybe every particle is a wave-pocket: soliton,-defined by coded information. Wave pocket-soliton is dense matter in a separeted part of space: one of the special features of the soliton is that it is a wave packet and it has particle properties too: we can say that soliton is a wave AND a particle at the same time. It is similar to wave-function and electron because there are informations inside of soliton which define the wave-property AND the particle-property too. When one of these informations becomes active: soliton changes in time moment. For example in DSE: electron-wave goes through the slits as a soliton-wave but it arrives to the screen as a particle. Very interesting: It is possible: Obstacle is cause of a soliton's appearance: In Double Slit Experiment the two slits are the obstacles: When the quantum-wave is near the two slits: it change soliton so the electron-wave goes through the slits: as soliton! "A solitary wave is a wave that retains its shape, despite dispersion and non-linearities. A soliton is a pulse that can collide with another similar pulse and still retain its shape after the collision, again in the presence of both dispersion and non-linearities."

Nature Communications, 2017

Atoms, Molecules and Photons, 2006

Single Photon Manipulation [Working Title]

In the domain of light emissions, quantum mechanics has been an immensely successful guiding tool for us. In the propagation of light and optical instrument design, Huygens-Fresnel diffraction integral (HFDI) (or its advanced versions) and Maxwell's wave equation are continuing to be the essential guiding tools for optical scientists and engineers. In fact, most branches of optical science and engineering, like optical instrument design, image processing, Fourier optics, Holography, etc., cannot exist without using the foundational postulates behind the Huygens-Fresnel diffraction integral. Further, the field of structured light is also growing where phases and the state of polarizations are manipulated usually with suitable classical macro-devices to create wave fronts that restructured through light-matter interactions through these devices. Mathematical modeling of generating such complex wave fronts generally follows classical concepts and classical macro tools of physical optics. Some of these complex light beams can impart mechanical angular momentum and spin-like properties to material particles inserted inside these structured beams because of their electromagnetic dipolar properties and/or structural anisotropy. Does that mean these newly structured beams have acquired new quantum properties without being generated through quantum devices and quantum transitions? In this chapter, we bridge the classical and quantum formalism by defining a hybrid photon (HP). HP is a quantum of energy, hν, at the initial moment of emission. It then immediately evolves into a classical time-finite wave packet, still transporting the original energy, hν, with a classical carrier frequency ν (oscillation of the E-vector). This chapter will raise enquiring questions whether all these observed "quantum-like" behaviors are manifestations of the joint properties of interacting material particles with classical EM waves or are causal implications of the existence of propagation of "indivisible light quanta" with exotic properties like spin, angular momentum, etc.

Further exploration of this topic would not only broaden the knowledge of Soft Mattonics, but also encourage multidisciplinary research from specialists across different disciplines and promote diverse soft and smart photonic applications. [44] This research is therefore an important step towards the understanding and efficient use of colloidal mixtures and block copolymers which helps the design of soft matter systems with desired properties. [43] NUS physicists have discovered a theoretical behavior known as the "critical skin effect" influencing how changes between different phases of matter occur.

2006

Reviews of Modern Physics, 2005

Recent advances in condensed matter theory have revealed that new and exotic phases of matter can exist in spin models (or more precisely, local bosonic models) via a simple physical mechanism, known as "string-net condensation." These new phases of matter have the unusual property that their collective excitations are gauge bosons and fermions. In some cases, the collective excitations can behave just like the photons, electrons, gluons, and quarks in our vacuum. This suggests that photons, electrons, and other elementary particles may have a unified origin -string-net condensation in our vacuum. In addition, the string-net picture indicates how to make artificial photons, artificial electrons, and artificial quarks and gluons in condensed matter systems. PACS numbers: 11.15.-q, 71.10.-w * URL: http://dao.mit.edu/~wen FIG. 1 Sound waves in a crystal are particles called phonons, according to quantum theory.

The article gives a succinct historical review of the evolution of physical concepts in photonics and light-matter coupling during the 20th century with special emphasis on noteworthy contributions made by a prominent Ukrainian theoretician Kirill Tolpygo, whose centenary will be celebrated next year. We dwell in detail on the history of elaboration of such key notions as various types of excitons, polaritons, spatial dispertion in crystals and others. Their correct understanding provides an indispensable basis for further progress in crystal optics.