Your search keyword '"Gao, Yunan"' showing total 7 results

1. High Discrimination Ratio, Broadband Circularly Polarized Light Photodetector Using Dielectric Achiral Nanostructures

Author

Zhang, Guanyu, Lyu, Xiaying, Qin, Yulu, Li, Yaolong, Fan, Zipu, Meng, Xianghan, Cheng, Yuqing, Cao, Zini, Xu, Yixuan, Sun, Dong, Gao, Yunan, Gong, Qihuang, and Lu, Guowei

Subjects

Physics - Optics, Physics - Applied Physics

Abstract

The on-chip measurement of polarization states plays an increasingly crucial role in modern sensing and imaging applications. While high-performance monolithic linearly polarized photodetectors have been extensively studied, integrated circularly polarized light (CPL) photodetectors are still hindered by inadequate discrimination capability. In this study, we employ achiral all-dielectric nanostructures to develop a broadband CPL photodetector with an impressive discrimination ratio of ~107 at the wavelength of 405 nm, significantly surpassing its counterparts by two orders of magnitude. Our device shows outstanding CPL discrimination capability across the visible band without requiring intensity calibration. Its function mechanism is based on the CPL-dependent near-field modes within achiral structures: under left or right CPL illumination, distinct near-field modes are excited, resulting in asymmetric irradiation of the two electrodes and generating a photovoltage with directions determined by the chirality of the incident light field. The proposed design strategy facilitates the realization of ultra-compact CPL detection across diverse materials, structures, and spectral ranges, presenting a novel avenue for achieving high-performance monolithic CPL detection., Comment: 20 pages, 4 figures

Published

2024

2. Plasmon-Exciton Coupling Effect on Plasmon Damping

Author

Ye, Lulu, Zhang, Weidong, Hu, Aiqin, Lin, Hai, Tang, Jinglin, Wang, Yunkun, Pan, Chenxinyu, Wang, Pan, Guo, Xin, Tong, Limin, Gao, Yunan, Gong, Qihuang, and Lu, Guowei

Subjects

Physics - Optics, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Plasma Physics

Abstract

Plasmon decay via the surface or interface is a critical process for practical energy conversion and plasmonic catalysis. However, the relationship between plasmon damping and the coupling between the plasmon and 2D materials is still unclear. The spectral splitting due to plasmon-exciton interaction impedes the conventional single-particle method to evaluate the plasmon damping rate by the spectral linewidth directly. Here, we investigated the interaction between a single gold nanorod (GNR) and 2D materials using the single-particle spectroscopy method assisted with in situ nanomanipulation technique by comparing scattering intensity and linewidth together. Our approach allows us to indisputably identify that the plasmon-exciton coupling in the GNR-WSe2 hybrid would induce plasmon damping. We can also isolate the contribution between the charge transfer channel and resonant energy transfer channel for the plasmon decay in the GNR-graphene hybrid by comparing that with thin hBN layers as an intermediate medium to block the charge transfer. We find out that the contact layer between the GNR and 2D materials contributes most of the interfacial plasmon damping. These findings contribute to a deep understanding of interfacial excitonic effects on the plasmon and 2D materials hybrid.

Published

2021

3. Efficient light-emitting diodes based on oriented perovskite nanoplatelets

Author

Cui, Jieyuan, Liu, Yang, Deng, Yunzhou, Lin, Chen, Fang, Zhishan, Xiang, Chensheng, Bai, Peng, Du, Kai, Zuo, Xiaobing, Wen, Kaichuan, Gong, Shaolong, He, Haiping, Ye, Zhizhen, Gao, Yunan, Tian, He, Zhao, Baodan, Wang, Jianpu, and Jin, Yizheng

Subjects

Physics - Applied Physics, Condensed Matter - Materials Science, Physics - Optics

Abstract

Solution-processed planar perovskite light-emitting diodes (LEDs) promise high-performance and cost-effective electroluminescent (EL) devices ideal for large-area display and lighting applications. Exploiting emission layers with high ratios of horizontal transition dipole moments (TDMs) is expected to boost photon outcoupling of planar LEDs. However, LEDs based on anisotropic perovskite nanoemitters remains to be inefficient (external quantum efficiency, EQE <5%), due to the difficulties of simultaneously controlling the orientations of TDMs, achieving high photoluminescence quantum yields (PLQYs) and realizing charge balance in the films of the assembled nanostructures. Here we demonstrate efficient EL from an in-situ grown continuous perovskite film comprising of a monolayer of face-on oriented nanoplatelets. The ratio of horizontal TDMs of the perovskite nanoplatelet films is ~84%, substantially higher than that of isotropic emitters (67%). The nanoplatelet film shows a high PLQY of ~75%. These merits enable LEDs with a peak EQE of 23.6%, representing the most efficient perovskite LEDs., Comment: 52 pages, 23 figures

Published

2020

4. Phase-Modulated Degenerate Parametric Amplification Microscopy

Author

Gao, Yunan, Goodman, Aaron J., Shen, Pin-Chun, Kong, Jing, and Tisdale, William A.

Subjects

Physics - Optics, Condensed Matter - Materials Science

Abstract

Second-order nonlinear optical interactions, including second harmonic generation (SHG) and sum-frequency generation (SFG), can reveal a wealth of information about chemical, electronic, and vibrational dynamics at the nanoscale. Here, we demonstrate a powerful and flexible new approach, called phase-modulated degenerate parametric amplification (DPA). The technique, which allows for facile retrieval of both the amplitude and phase of the second-order nonlinear optical response, has many advantages over conventional or heterodyne-detected SHG, including the flexibility to detect the signal at either the second harmonic or fundamental field wavelength. We demonstrate the capabilities of this approach by imaging multi-grain flakes of single-layer MoS2. We identify the absolute crystal orientation of each MoS2 domain and resolve grain boundaries with high signal contrast and sub-diffraction-limited spatial resolution. This robust all-optical method can be used to characterize structure and dynamics in organic and inorganic systems, including biological tissue, soft materials, and metal and semiconductor nanostructures, and is particularly well-suited for imaging in media that are absorptive or highly scattering to visible and ultraviolet light.

Published

2018

5. Observation of coupling between zero- and two-dimensional semiconductor systems based on anomalous diamagnetic effects

Author

Cao, Shuo, Tang, Jing, Sun, Yue, Peng, Kai, Gao, Yunan, Zhao, Yanhui, Qian, Chenjiang, Sun, Sibai, Ali, Hassan, Shao, Yuting, Wu, Shiyao, Song, Feilong, Williams, David A., Sheng, Weidong, Jin, Kuijuan, and Xu, Xiulai

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics, Quantum Physics

Abstract

We report the direct observation of coupling between a single self-assembled InAs quantum dot and a wetting layer, based on strong diamagnetic shifts of many-body exciton states using magneto-photoluminescence spectroscopy. An extremely large positive diamagnetic coefficient is observed when an electron in the wetting layer combines with a hole in the quantum dot; the coefficient is nearly one order of magnitude larger than that of the exciton states confined in the quantum dots. Recombination of electrons with holes in a quantum dot of the coupled system leads to an unusual negative diamagnetic effect, which is five times stronger than that in a pure quantum dot system. This effect can be attributed to the expansion of the wavefunction of remaining electrons in the wetting layer or the spread of electrons in the excited states of the quantum dot to the wetting layer after recombination. In this case, the wavefunction extent of the final states in the quantum dot plane is much larger than that of the initial states because of the absence of holes in the quantum dot to attract electrons. The properties of emitted photons that depend on the large electron wavefunction extents in the wetting layer indicate that the coupling occurs between systems of different dimensionality, which is also verified from the results obtained by applying a magnetic field in different configurations. This study paves a new way to observe hybrid states with zero- and two-dimensional structures, which could be useful for investigating the Kondo physics and implementing spin-based solid-state quantum information processing., Comment: 20 pages, 7 figures in Nano Research, 2015

Published

2015

6. Ultrafast Optical Switching Using Photonic Molecules in Photonic Crystal Waveguides

Author

Zhao, Yanhui, Qian, Chenjiang, Qiu, Kangsheng, Gao, Yunan, and Xu, Xiulai

Subjects

Physics - Optics

Abstract

We study the coupling between photonic molecules and waveguides in photonic crystal slab structures using finite-difference time-domain method and coupled mode theory. In a photonic molecule with two cavities, the coupling of cavity modes results in two super-modes with symmetric and anti-symmetric field distributions. When two super-modes are excited simultaneously, the energy of electric field oscillates between the two cavities. To excite and probe the energy oscillation, we integrate photonic molecule with two photonic crystal waveguides. In coupled structure, we find that the quality factors of two super-modes might be different because of different field distributions of super-modes. After optimizing the radii of air holes between two cavities of photonic molecule, nearly equal quality factors of two super-modes are achieved, and coupling strengths between the waveguide modes and two super-modes are almost the same. In this case, complete energy oscillations between two cavities can be obtained with a pumping source in one waveguide, which can be read out by another waveguide. Finally, we demonstrate that the designed structure can be used for ultrafast optical switching with a time scale of a few picoseconds., Comment: 18 pages, 6 figures

Published

2015

7. Longitudinal wave function control in single quantum dots with an applied magnetic field

Author

Cao, Shuo, Tang, Jing, Gao, Yunan, Sun, Yue, Qiu, Kangsheng, Zhao, Yanhui, He, Min, Shi, Jin-An, Gu, Lin, Williams, David A., Sheng, Weidong, Jin, Kuijuan, and Xu, Xiulai

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics, Quantum Physics

Abstract

Controlling single-particle wave functions in single semiconductor quantum dots is in demand to implement solid-state quantum information processing and spintronics. Normally, particle wave functions can be tuned transversely by an perpendicular magnetic field. We report a longitudinal wave function control in single quantum dots with a magnetic field. For a pure InAs quantum dot with a shape of pyramid or truncated pyramid, the hole wave function always occupies the base because of the less confinement at base, which induces a permanent dipole oriented from base to apex. With applying magnetic field along the base-apex direction, the hole wave function shrinks in the base plane. Because of the linear changing of the confinement for hole wave function from base to apex, the center of effective mass moves up during shrinking process. Due to the uniform confine potential for electrons, the center of effective mass of electrons does not move much, which results in a permanent dipole moment change and an inverted electron-hole alignment along the magnetic field direction. Manipulating the wave function longitudinally not only provides an alternative way to control the charge distribution with magnetic field but also a new method to tune electron-hole interaction in single quantum dots., Comment: 19 pages,3 figures

Published

2015