We generate optical beams analogous to the Wannier–Stark states in semiconductor superlattices and observe that the two main lobes of the WS beams self-bend (accelerate) along two opposite trajectories in a uniform one-dimensional photonic lattice. Such self-accelerating features exist only in the presence of the lattice and are not observed in a homogenous medium. Under the action of nonlinearity, however, the beam structure and acceleration cannot be preserved. Our experimental observations are in qualitative agreement with theoretical predictions
We theoretically and experimentally demonstrate self-accelerating Bessel-like optical beams propagat...
We report the experimental observation of energetically confined self-accelerating optical beams pro...
The application of an external electric field parallel to the growth axis of a superlattice quantize...
We generate optical beams analogous to the Wannier-Stark states in semiconductor superlattices and o...
We generate optical beams analogous to the Wannier-Stark states in semiconductor superlattices and o...
Within the framework of the tight-binding model we demonstrate that Wannier-Stark states can freely ...
We study self-acceleration in a parabolic tight-binding lattice and construct a self-accelerating wa...
We study nondiffracting accelerating paraxial optical beams in periodic potentials, in both the line...
We study nondiffracting accelerating paraxial optical beams in periodic potentials, in both the line...
We study nondiffracting accelerating paraxial optical beams in periodic potentials, in both the line...
We observe Wannier-Stark (W-S) localization in curved photonic lattices, realized using arrays of ev...
We report on optical analogues of well-known electronic phenomena such as Bloch oscillations and ele...
We report on optical analogues ofwell-known electronic phenomena such as Bloch oscillations and elec...
We present self-accelerating self-trapped beams in nonlinear optical media, exhibiting self-focusing...
We show that only in a unique class of z-dependent lattices a true accelerating and diffractionless ...
We theoretically and experimentally demonstrate self-accelerating Bessel-like optical beams propagat...
We report the experimental observation of energetically confined self-accelerating optical beams pro...
The application of an external electric field parallel to the growth axis of a superlattice quantize...
We generate optical beams analogous to the Wannier-Stark states in semiconductor superlattices and o...
We generate optical beams analogous to the Wannier-Stark states in semiconductor superlattices and o...
Within the framework of the tight-binding model we demonstrate that Wannier-Stark states can freely ...
We study self-acceleration in a parabolic tight-binding lattice and construct a self-accelerating wa...
We study nondiffracting accelerating paraxial optical beams in periodic potentials, in both the line...
We study nondiffracting accelerating paraxial optical beams in periodic potentials, in both the line...
We study nondiffracting accelerating paraxial optical beams in periodic potentials, in both the line...
We observe Wannier-Stark (W-S) localization in curved photonic lattices, realized using arrays of ev...
We report on optical analogues of well-known electronic phenomena such as Bloch oscillations and ele...
We report on optical analogues ofwell-known electronic phenomena such as Bloch oscillations and elec...
We present self-accelerating self-trapped beams in nonlinear optical media, exhibiting self-focusing...
We show that only in a unique class of z-dependent lattices a true accelerating and diffractionless ...
We theoretically and experimentally demonstrate self-accelerating Bessel-like optical beams propagat...
We report the experimental observation of energetically confined self-accelerating optical beams pro...
The application of an external electric field parallel to the growth axis of a superlattice quantize...