Your search keyword '"photonic nanojet"' showing total 15 results

1. Coupling Nanowire Quantum Dots to Optical Waveguides by Microsphere-Induced Photonic Nanojet.

Author

Tsintzos, Symeon I., Tsimvrakidis, Konstantinos, Gates, James C., Elshaari, Ali W., Smith, Peter G. R., Zwiller, Val, and Riziotis, Christos

Subjects

OPTICAL waveguides, QUANTUM dots, COUPLING schemes, SEMICONDUCTOR nanowires, SILICON nanowires, SEMICONDUCTOR quantum dots, NANOWIRES

Abstract

Silica-on-silicon is a major optical integration platform, while the emergent class of the integrated laser-written circuits' platform offers additionally high customizability and flexibility for rapid prototyping. However, the inherent waveguides' low core/cladding refractive index contrast characteristic, compared to other photonic platforms in silicon or silicon nitride, sets serious limitations for on-chip efficient coupling with single photon emitters, like semiconductor nanowires with quantum dots, limiting the applications in quantum computing. A new light coupling scheme proposed here overcomes this limitation, providing means for light coupling >50%. The scheme is based on the incorporation of an optical microsphere between the nanowire and the waveguide, which is properly optimized and arranged in terms of size, refractive index, and the distance of the microsphere between the nanowire and waveguide. Upon suitable design of the optical arrangement, the photonic nanojet emitted by the illuminated microsphere excites efficiently the guided eigenmodes of the input channel waveguide, thus launching light with high-coupling efficiency. The method is tolerant in displacements, misalignments, and imperfections and is fabricationally feasible by the current state of art techniques. The proposed method enables the on-chip multiple single photon emitters' integration, thus allowing for the development of highly customizable and scalable quantum photonic-integrated circuits for quantum computing and communications. [ABSTRACT FROM AUTHOR]

Published

2024

2. Microsphere-Based Microsensor for Miniature Motors' Vibration Measurement.

Author

Xu, Kaichuan, Jiang, Chunlei, Ban, Qilu, Dai, Pan, Fan, Yaqiang, Yang, Shijie, Zhang, Yue, Wang, Jiacheng, Wang, Yu, Chen, Xiangfei, Zeng, Jie, and Wang, Feng

Subjects

*VIBRATION measurements, *MEASUREMENT errors, *LIGHT sources, *MOTOR industry, *MOTORS

Abstract

We present a microsphere-based microsensor that can measure the vibrations of the miniature motor shaft (MMS) in a small space. The microsensor is composed of a stretched fiber and a microsphere with a diameter of 5 μm. When a light source is incident on the microsphere surface, the microsphere induces the phenomenon of photonic nanojet (PNJ), which causes light to pass through the front. The PNJ's full width at half maximum is narrow, surpassing the diffraction limit, enables precise focusing on the MMS surface, and enhances the scattered or reflected light emitted from the MMS surface. With two of the proposed microsensors, the axial and radial vibration of the MMS are measured simultaneously. The performance of the microsensor has been calibrated with a standard vibration source, demonstrating measurement errors of less than 1.5%. The microsensor is expected to be used in a confined space for the vibration measurement of miniature motors in industry. [ABSTRACT FROM AUTHOR]

Published

2023

3. Photonic Hook with Modulated Bending Angle Formed by Using Triangular Mesoscale Janus Prisms.

Author

Chen, Wei-Yu, Liu, Cheng-Yang, Hsieh, Yu-Kai, Minin, Oleg V., and Minin, Igor V.

Subjects

JANUS particles, FINITE difference time domain method, PRISMS, HOOKS, OPTICAL tweezers, REFRACTIVE index, NANOPARTICLES, DOPPLER radar

Abstract

In this study, we propose a novel design of triangular mesoscale Janus prisms for the generation of the long photonic hook. Numerical simulations based on the finite-difference time-domain method are used to examine the formation mechanism of the photonic hook. The electric intensity distributions near the micro-prisms are calculated for operation at different refractive indices and spaces of the two triangular micro-prisms. The asymmetric vortices of intensity distributions result in a long photonic hook with a large bending angle. The length and the bending angle of the photonic hook are efficiently modulated by changing the space between the two triangular micro-prisms. Moreover, the narrow width of the photonic hook is achieved beyond the diffraction limit. The triangular Janus micro-prisms have high potential for practical applications in optical tweezers, nanoparticle sorting and manipulation and photonic circuits. [ABSTRACT FROM AUTHOR]

Published

2022

4. Investigation and Analysis of Acoustojets by Spectral Element Method.

Author

Mahariq, Ibrahim, Giden, Ibrahim H., Alboon, Shadi, Aly, Wael Hosny Fouad, Youssef, Ahmed, and Kurt, Hamza

Subjects

*WHISPERING gallery modes, *SOUND wave scattering, *SOUND waves, *PLANE wavefronts, *ACOUSTIC excitation, *SPECTRAL element method

Abstract

In this study, acoustic wave scattering in a homogeneous media by an obstacle is examined in the case of plane wave excitation and the formation of acoustic jets is explored. Spectral element method (SEM) is employed for the approximate solution of scattered acoustic waves' calculations. An important finding of the study is the concurrence of whispering gallery modes and acoustic jet in the case of proper adjustment of structural parameters, which has not been reported before in the literature. Furthermore, numerical findings based on SEM calculations show that the main characteristics of acoustic jet can be explored and controlled by changing the targeted parameters. Microscopy and imaging applications utilizing acoustic wave can benefit from the conducted study presented in this manuscript. [ABSTRACT FROM AUTHOR]

Published

2022

5. Generation of Photonic Hooks under Point-Source Illumination from Patchy Microcylinders.

Author

Shang, Qingqing, Xu, Chu, Tang, Fen, Li, Jiaji, Fan, Yao, Yuan, Caojin, Wang, Zengbo, Zuo, Chao, and Ye, Ran

Subjects

HIGH resolution imaging, PLANE wavefronts, CURVED beams, HOOKS, LIGHTING

Abstract

Photonic hook (PH) is a new type of non-evanescent light beam with subwavelength curved structures. It has shown promising applications in super-resolution imaging and has the potential to be used in micromachining, optical trapping, etc. PHs are generally produced by illuminating mesoscale asymmetric particles with optical plane waves. In this work, we used the finite-difference time-domain (FDTD) method to investigate the PH phenomenon under point-source illumination. We found that the PHs can be effectively generated from point-source illuminated patchy particles. By changing the background refractive index, particle diameters and the position and coverage ratio of Ag patches, the characteristics of the PHs can be effectively tuned. Moreover, the structure of the intensity distribution of the light field generated from small and large particles can have an opposite bending direction due to the near-field light-matter interaction. [ABSTRACT FROM AUTHOR]

Published

2022

6. Selecting a Proper Microsphere to Combine Optical Trapping with Microsphere-Assisted Microscopy.

Author

Liu, Xi, Hu, Song, Tang, Yan, Xie, Zhongye, Liu, Junbo, and He, Yu

Subjects

OPTICAL tweezers, HIGH resolution imaging, MICROSCOPY, REFRACTIVE index, MICROSPHERES, POLYSTYRENE

Abstract

Microsphere-assisted microscopy serves as an effective super-resolution technique in biological observations and nanostructure detections, and optical trapping is widely used for the manipulation of small particles like microspheres. In this study, we focus on the selection of microsphere types for the combination of the optical trapping and the super-resolution microsphere-assisted microscopy, by considering the optical trapping performances and the super-resolution imaging ability of index-different microspheres in water simultaneously. Finally, the polystyrene (PS) sphere and the melamine formaldehyde (MF) sphere have been selected from four typical index-different microspheres normally used in microsphere-assisted microscopy. In experiments, the optically trapped PS/MF microsphere in water has been used to achieve super-resolution imaging of a 139 nm line-width silicon nanostructure grating under white light illumination. The image quality and the magnification factor are affected by the refractive index contrast between the microspheres and the immersion medium, and the difference of image quality is partly explained by the photonic nanojet. This work guides us in selecting proper microspheres, and also provides a label-free super-resolution imaging technique in many research fields. [ABSTRACT FROM AUTHOR]

Published

2020

7. Novel Bilayer Micropyramid Structure Photonic Nanojet for Enhancing a Focused Optical Field

Author

Yingxue Xi, Wenli Li, Xueping Sun, Shaobo Ge, Shijie Li, Yechuan Zhu, Yuetian Huang, Shun Zhou, Jin Zhang, Weiguo Liu, Pengfei Yang, Yiting Yu, and Dabin Lin

Subjects

Diffraction, medicine.medical_specialty, Materials science, General Chemical Engineering, Diamond turning, Optical field, Article, Nanoimprint lithography, law.invention, law, medicine, General Materials Science, QD1-999, microfabrication, Total internal reflection, business.industry, micro-optics, Full width at half maximum, Chemistry, photonic nanojet, Thin-film optics, Optoelectronics, business, Light field, thin film optics, multilayer design

Abstract

In this paper, synthetically using refraction, diffraction, and interference effects to achieve free manipulation of the focused optical field, we firstly present a photonic nanojet (PNJ) generated by a micropyramid, which is combined with multilayer thin films. The theory of total internal reflection (TIR) was creatively used to design the base angle of the micropyramid, and the size parameters and material properties of the microstructure were deduced via the expected optical field distribution. The as-designed bilayer micropyramid array was fabricated by using the single-point diamond turning (SPDT) technique, nanoimprint lithography (NIL), and proportional inductively coupled plasma (ICP) etching. After the investigation, the results of optical field measurement were highly consistent with those of the numerical simulation, and they were both within the theoretical calculation range. The bilayer micropyramid array PNJ enhanced the interference effect of incident and scattered fields, thus, the intensity of the focused light field reached 33.8-times that of the initial light, and the range of the focused light field was extended to 10.08λ. Moreover, the full width at half maximum (FWHM) of the focal spot achieved was 0.6λ, which was close to the diffraction limit.

Published

2021

8. Novel Bilayer Micropyramid Structure Photonic Nanojet for Enhancing a Focused Optical Field.

Author

Ge, Shaobo, Liu, Weiguo, Zhang, Jin, Huang, Yuetian, Xi, Yingxue, Yang, Pengfei, Sun, Xueping, Li, Shijie, Lin, Dabin, Zhou, Shun, Zhu, Yechuan, Li, Wenli, and Yu, Yiting

Subjects

*DIAMOND turning, *NANOIMPRINT lithography, *OPTICAL measurements, *THIN films, *MECHANICAL properties of condensed matter

Abstract

In this paper, synthetically using refraction, diffraction, and interference effects to achieve free manipulation of the focused optical field, we firstly present a photonic nanojet (PNJ) generated by a micropyramid, which is combined with multilayer thin films. The theory of total internal reflection (TIR) was creatively used to design the base angle of the micropyramid, and the size parameters and material properties of the microstructure were deduced via the expected optical field distribution. The as-designed bilayer micropyramid array was fabricated by using the single-point diamond turning (SPDT) technique, nanoimprint lithography (NIL), and proportional inductively coupled plasma (ICP) etching. After the investigation, the results of optical field measurement were highly consistent with those of the numerical simulation, and they were both within the theoretical calculation range. The bilayer micropyramid array PNJ enhanced the interference effect of incident and scattered fields; thus, the intensity of the focused light field reached 33.8-times that of the initial light, and the range of the focused light field was extended to 10.08 λ. Moreover, the full width at half maximum (FWHM) of the focal spot achieved was 0.6 λ , which was close to the diffraction limit. [ABSTRACT FROM AUTHOR]

Published

2021

9. Photonic Nanojet Modulation Achieved by a Spider-Silk-Based Metal–Dielectric Dome Microlens.

Author

Lin, Ching-Bin, Lin, Yu-Hsiang, Chen, Wei-Yu, and Liu, Cheng-Yang

Subjects

GLANCING angle deposition, ERYTHROCYTES, DRUG target, OPTICAL microscopes, METALLIC surfaces, SURFACE plasmon resonance

Abstract

The photonic nanojet is a non-resonance focusing phenomenon with high intensity and narrow spot that can serve as a powerful biosensor for in vivo detection of red blood cells, micro-organisms, and tumor cells in blood. In this study, we first demonstrated photonic nanojet modulation by utilizing a spider-silk-based metal–dielectric dome microlens. A cellar spider was employed in extracting the silk fiber, which possesses a liquid-collecting ability to form a dielectric dome microlens. The metal casing on the surface of the dielectric dome was coated by using a glancing angle deposition technique. Due to the nature of surface plasmon polaritons, the characteristics of photonic nanojets are strongly modulated by different metal casings. Numerical and experimental results showed that the intensity of the photonic nanojet was increased by a factor of three for the gold-coated dome microlens due to surface plasmon resonance. The spider-silk-based metal-dielectric dome microlens could be used to scan a biological target for large-area imaging with a conventional optical microscope. [ABSTRACT FROM AUTHOR]

Published

2021

10. A Closer Look at Photonic Nanojets in Reflection Mode: Control of Standing Wave Modulation.

Author

Sergeeva, Ksenia A., Sergeev, Alexander A., Minin, Oleg V., and Minin, Igor V.

Subjects

OPTICAL devices, OPTICAL microscopes, OPTICAL resolution, STANDING waves, ALUMINUM oxide

Abstract

The photonic nanojet phenomenon is commonly used both to increase the resolution of optical microscopes and to trap nanoparticles. However, such photonic nanojets are not applicable to an entire class of objects. Here we present a new type of photonic nanojet in reflection mode with the possibility to control the modulation of the photonic nanojet by a standing wave. In contrast to the known kinds of reflective photonic nanojets, the reported one occurs when the aluminum oxide hemisphere is located at a certain distance from the substrate. Under illumination, the hemisphere generates a primary photonic nanojet directed to the substrate. After reflection, the primary nanojet acts as an illumination source for the hemisphere, leading to the formation of a new reflective photonic nanojet. We show that the distance between the hemisphere and substrate affects the phase of both incident and reflected radiation, and due to constructive interference, the modulation of the reflective photonic nanojet by a standing wave can be significantly reduced. The results obtained contribute to the understanding of the processes of photonic nanojet formation in reflection mode and open new pathways for designing functional optical devices. [ABSTRACT FROM AUTHOR]

Published

2021

11. Coated High-Refractive-Index Barium Titanate Glass Microspheres for Optically Trapped Microsphere Super-Resolution Microscopy: A Simulation Study.

Author

Liu, Xi, Hu, Song, and Tang, Yan

Subjects

BARIUM titanate, MICROSPHERES, MICROSCOPY, REFRACTIVE index, TRAPPING, OPTICAL tweezers, GLASS

Abstract

As water is normally used as the immersion medium in optically trapped microsphere microscopy, the high-refractive-index barium titanate glass (BTG) microsphere shows a better imaging performance than the low-index polystyrene (PS) or melamine formaldehyde (MF) microsphere, but it is difficult to be trapped by single-beam optical trapping due to its overly high refractive index. In this study, coated BTG microspheres with a PS coating have been computationally explored for the combination of optical trapping with microsphere-assisted microscopy. The PS coating thickness affects both the optical trapping efficiency and photonic nanojet (PNJ) property of the coated BTG sphere. Compared to the uncoated BTG sphere, the coated BTG sphere with a proper PS coating thickness has a highly improved trapping efficiency which enables single-beam optical trapping, and a better PNJ with a higher optical intensity I max and a narrower full width at half maximum (FWHM) corresponding to better imaging performance. These coated BTG spheres also have an advantage in trapping efficiency and imaging performance over conventional PS and MF spheres. The coated BTG microsphere is highly desirable for optically trapped microsphere super-resolution microscopy and potentially beneficial to other research areas, such as nanoparticle detection. [ABSTRACT FROM AUTHOR]

Published

2020

12. Large-Scale Fabrication of Photonic Nanojet Array via Template-Assisted Self-Assembly.

Author

Zhang, Pengcheng, Chen, Xi, and Yang, Hui

Subjects

HIGH resolution imaging, NANOPATTERNING, MICROSPHERES, NANOFABRICATION, INTEGRATED optics

Abstract

A large-scale homogenized photonic nanojet array with defined pattern and spacing facilitates practical applications in super-resolution imaging, subwavelength-resolution nanopatterning, nano objects trapping and detection technology. In this paper, we present the fabrication of a large-scale photonic nanojet array via the template-assisted self-assembly (TASA) approach. Templates of two-dimensional (2D) large-scale microwell array with defined pattern and spacing are fabricated. Melamine microspheres with excellent size uniformity are utilized to pattern on the template. It is found that microwells can be filled at a yield up to 95%. These arrayed microspheres on the template serve as microlenses and can be excited to generate large-scale photonic nanojets. The uniformly-sized melamine spheres are beneficial for the generation of a homogenized photonic nanojet array. The intensity of the photonic nanojets in water is as high as ~2 fold the background light signal. Our work shows a simple, robust, and fast means for the fabrication of a large-scale homogenized photonic nanojet array. [ABSTRACT FROM AUTHOR]

Published

2020

13. Flexible Photonic Nanojet Formed by Cylindrical Graded-Index Lens.

Author

Liu, Cheng-Yang

Subjects

FINITE difference time domain method, LENSES, OPTICAL limiting

Abstract

Photonic nanojets formed in the vicinity of the cylindrical graded-index lens with different types of index grading are numerically investigated based on the finite-difference time-domain method. The cylindrical lens with 1600 nm diameter is assembled by eighty-seven hexagonally arranged close-contact nanofibers with 160 nm diameter. Simulation and analysis results show that it is possible to engineer and elongate the photonic nanojet. Using differently graded-index nanofibers as building elements to compose this lens, the latitudinal and longitudinal sizes of the produced photonic nanojet can be flexibly adjusted. At an incident wavelength of 532 nm, the cylindrical lens with index grading = 2 can generate a photonic nanojet with a waist about 173 nm (0.32 wavelength). This lens could potentially contribute to the development of a novel device for breaking the diffraction limit in the field of optical nano-scope and bio-photonics. [ABSTRACT FROM AUTHOR]

Published

2019

14. Numerical Study of Tunable Photonic Nanojets Generated by Biocompatible Hydrogel Core-Shell Microspheres for Surface-Enhanced Raman Scattering Applications.

Author

Wang, Yu-Jui, Dai, Chi-An, and Li, Jia-Han

Subjects

*RAMAN scattering, *HYDROGELS, *MICROSPHERES, *OPTICAL properties

Abstract

Core-shell microspheres have been applied in various research areas and, in particular, they are used in the generation of photonic nanojets with suitable design for photonic applications. The photonic nanojet is a narrow and focused high-intensity light beam emitting from the shadow-side of microspheres with tunable effective length, thus enabling its applications in biosensing technology. In this paper, we numerically studied the photonic nanojets brought about from biocompatible hydrogel core-shell microspheres with different optical properties. It was found that the presence of the shell layer can significantly affect the characteristics of the photonic nanojets, such as the focal distance, intensity, effective length, and focal size. Generally speaking, the larger the core-shell microspheres, the longer the focal distance, the stronger the intensity, the longer the effective length, and the larger the focal size of the generated photonic nanojets are. The numerical simulations of the photonic nanojets from the biocompatible core-shell microspheres on a Klarite substrate, which is a classical surface-enhancing Raman scattering substrate, showed that the Raman signals in the case of adding the core-shell microspheres in the system can be further enhanced 23 times in water and 108 times in air as compared in the case in which no core-shell microspheres are present. Our study of using tunable photonic nanojets produced from the biocompatible hydrogel core-shell microspheres shows potential in future biosensing applications. [ABSTRACT FROM AUTHOR]

Published

2019

15. Switchable Photonic Nanojet by Electro-Switching Nematic Liquid Crystals.

Author

Du, Bintao, Xia, Jun, Wu, Jun, Zhao, Jian, and Zhang, Hao

Subjects

*PHOTONICS, *NEMATIC liquid crystals, *POLYSTYRENE, *REFRACTIVE index, *ELLIPSOIDS

Abstract

This paper first presents a switchable photonic nanojet (PNJ) generated by a polystyrene (PS) microsphere immersed in nematic liquid crystals (NLCs). The PNJ is switched by applying external voltage, which originates from the refractive index change in the surrounding medium caused by the field-induced realignment of liquid crystal molecules. By tuning the refractive index of NLCs larger or smaller than that of the PS microsphere, the PNJ can be switched off or on. Moreover, we present an optimization study to seek a better electric energy focusing property of the PNJ. Our results reveal that the switchability of PNJ can be optimized by applying a shorter incident wavelength, a double-layer microsphere, and a PS ellipsoid. The full width at half-maximum (FWHM) generated by the PS ellipsoid is narrower than that generated by the microsphere with a shorter incident wavelength. The intensity contrast of the PS ellipsoid is higher than that of the double-layer microsphere. As a whole, the switchability of PNJ can be best optimized by a PS ellipsoid. This should open the way for the development of integrated photonic devices. [ABSTRACT FROM AUTHOR]

Published

2019