Zhuanglei Miao scite author profile

We report new vortex lens for producing single-focus phase singularity which termed as quasi-random-dot-array binary spiral zone plates (QBSZPs). Different from the abrupt transitions of the conventional spiral zone plates (SZPs), the key idea of the QBSZPs is to realize a sinusoidal transmittance by properly arranging lots of quantum dot array which takes on the values of 0 and 1 in two dimensions. In this typical design, the number density of the selected primitives obeys sinusoidal distribution along the radial direction and quasi-random in the azimuthal direction. Theoretical analysis indicate that the higher-order foci which inevitably exist in the SZPs have been indeed effectively suppressed with the QBSZPs. Moreover, the focusing performance of the QBSZPs is influenced by the ratio of circumcircle diameter of the primitives to the outermost zone width. These findings which have been demonstrated by the performed experiment may direct new avenue towards improving the performance of biomedical imaging, quantum computation and optical manipulation.

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Accelerating superluminal laser focus generated by a long-focal-depth mirror with high numerical aperture

Fan¹,

Miao²,

Yang³

et al. 2023

Preprint

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The long-focal-depth mirror is a novel reflective element proposed in recent years. Due to the advantages of negligible dependence on wavelength and high damage threshold, it is suitable to focus ultra-short laser pulses with broadband spectra and high intensity with a focal depth of centimeter scale. To the best of our knowledge, the focusing properties of this mirror has been only studied under low numerical aperture (NA). In this paper, we extend it to the case of high NA and it is proved that an accelerating superluminal laser focus can be always generated by this extension, in which the degree of acceleration increases with the increase of NA. And the velocity of laser focus increases approximately linearly from c to 1.6c for NA=0.707. Due to its properties of tight focusing, the Richards-Wolf integrals have been used to study the intensity distribution of each polarization component for different kinds of incident light. And these are linearly polarized light, radially polarized light, azimuthally polarized light, linearly polarized light with spiral phase, and linearly polarized light with ultrashort pulses. From comparisons of numerical results, the intensity distributions are obviously different for different kind of incident light, and accelerating superluminal laser focus with special structure (such as the hollow conical beam) can be produced under appropriate condition. We believe this study can expand the fields of application for the long-focal-depth mirror.

show abstract

Accelerating superluminal laser focus generated by a long-focal-depth mirror with high numerical aperture

Fan¹,

Yang

Miao

et al. 2023

Opt. Express

View full text Add to dashboard Cite

The long-focal-depth mirror is a novel reflective element proposed in recent years. Due to the advantages of negligible dependence on wavelength and high damage threshold, it is suitable to focus ultra-short laser pulses with broadband spectra and high intensity with a focal depth of centimeter scale. To the best of our knowledge, the focusing properties of this mirror has been only studied under low numerical aperture (NA). In this paper, we extend it to the case of high NA and it is proved that an accelerating superluminal laser focus can be always generated by this extension, in which the degree of acceleration increases with the increase of NA. And the velocity of laser focus increases approximately linearly from c to 1.6c for NA = 0.707. Due to its properties of tight focusing, the Richards-Wolf integrals have been used to study the intensity distribution of each polarization component for different kinds of incident light. And these are linearly polarized light, radially polarized light, azimuthally polarized light, linearly polarized light with spiral phase, and linearly polarized light with ultrashort pulses. From comparisons of numerical results, the intensity distributions are obviously different for different kind of incident light, and accelerating superluminal laser focus with special structure (such as the hollow conical beam) can be produced under appropriate condition. We believe this study can expand the fields of application for the long-focal-depth mirror.

show abstract

Accelerating superluminal laser focus generated by a long-focal-depth mirror with high numerical aperture

Fan¹,

Miao²,

Yang³

et al. 2023

Preprint

View full text Add to dashboard Cite

show abstract

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Zhuanglei Miao

Generation of single-focus phase singularity by the annulus-quadrangle-element coded binary square spiral zone plates

Single-focus phase singularity generated by spiral zone plate with quasi-random distributed quantum dots

Accelerating superluminal laser focus generated by a long-focal-depth mirror with high numerical aperture

Accelerating superluminal laser focus generated by a long-focal-depth mirror with high numerical aperture

Accelerating superluminal laser focus generated by a long-focal-depth mirror with high numerical aperture

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