Photoexcited carrier dynamics in a GaAs photoconductive switch under nJ excitation

Xu, Ming; Wang, Yi; Li, Chun; Si, Xinyang; Gao, Rongrong; Luo, W.; Qu, Guohui; Jia, Wenping; Liu, Qian

doi:10.1088/2058-6272/ac5af8

Cited by 8 publications

(3 citation statements)

References 33 publications

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“…Operating in this mode, the switch presents the characteristics of lower jitter and long lifetime, but usually needs the ~ mJ level laser energy for the high power output. Compared to the linear mode, the PCSS in the nonlinear mode can remain in the turn-on state after the laser is extinguished, making the output pulse width reach tens of nanoseconds, or even hundreds of nanoseconds and above [8][9][10]. The switch operating in this mode features the avalanche multiplication of carriers.…”

Section: Introductionmentioning

confidence: 99%

“…Almost all existing researches indicate that the illuminating spot significantly affects the development of operation mode, further determining the on-state performances of PCSS. However, despite these efforts, the influencing mechanism of the spot size on the operation mode of GaAs PCSS is still unclear, especially when the PCSS employs the extrinsic photoconductivity, generally introducing the optical absorption depth of several millimeters and evoking the complex switching transient [9,19]. Furthermore, to take full advantage of the illuminating laser and switch material, further investigating the influencing mechanism to optimize the illuminating spot and improve the on-state performances of GaAs PCSS is of considerable practical significance.…”

Section: Introductionmentioning

confidence: 99%

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Effects of spot size on the operation mode of GaAs photoconductive semiconductor switch employing extrinsic photoconductivity

WEI 韦,

LI 李,

CHEN 陈

et al. 2024

Plasma Sci. Technol.

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To guide the illuminating design to improve the on-state performances of gallium arsenide (GaAs) photoconductive semiconductor switch (PCSS), the effect of spot size on the operation mode of GaAs PCSS based on a semi-insulating wafer with a thickness of 1 mm, triggered by a 1064-nm extrinsic laser beam with the rectangular spot, has been investigated experimentally. It is found that the variation of the spot size in length and width can act on the different parts of the output waveform integrating the characteristics of the linear and nonlinear modes, and then significantly boosts the PCSS toward different operation modes. On this basis, a two-channel model containing the active and passive parts is introduced to interpret the relevant influencing mechanisms. Results indicate that the increased spot length can peak the amplitude of static domains in the active part to enhance the development of the nonlinear switching, while the extended spot width can change the distribution of photogenerated carriers on both parts to facilitate the linear switching and weaken the nonlinear switching, which have been proved by comparing the domain evolutions under different spot sizes.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Effects of spot size on the operation mode of GaAs photoconductive semiconductor switch employing extrinsic photoconductivity

WEI 韦,

LI 李,

CHEN 陈

et al. 2024

Plasma Sci. Technol.

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“…[1][2][3][4] While semiconductor materials as main functional units with controllable carriers transport are widely used in micro/nano optoelectronics. [5][6][7] By combining to maximize the advantages of both materials, integration of semiconductor and oxide has drawn considerable attention. For example, the wafer-level bonded Sapphire-Si heterogeneous structures have shown great potential in spatiotemporal tailoring of laser beam, ultrafast laser has been successfully used in heterogeneous materials microwelding such as Cu-Si, [22] Si-GaAs, [23] and alumina-YSZ.…”

Section: Introductionmentioning

confidence: 99%

Metal Nanoparticles Assisted Ultrafast Laser Plasmonic Microwelding of Oxide–Semiconductor Interconnects

Hu,

Lin,

et al. 2024

Small Methods

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Integration of wafer‐scale oxide and semiconductor materials meets the difficulties of residual stress and materials incompatibility. In this work, Ag NPs thin film is contributed as an energy confinement layer between oxide (Sapphire) and semiconductor (Si) wafers to localize the materials interaction during ultrafast laser irradiation. Due to the plasmonic effects generated within constructed dielectric–metal–dielectric structures (i.e., Sapphire–Ag–Si), thermal diffusion and chemical reaction between Ag and its neighboring materials facilitate the microwelding of Sapphire and Si wafers. Ag NPs can be totally sintered within the junction area to bridge oxide and semiconductor, while Al─O─Ag bond and Ag─Si bond are formed at Ag–Sapphire and Ag─Si interfaces, respectively. As‐received heterogeneous joint exhibits a high shear strength up to 5.4 MPa, with the fracture occurring inside Si wafer. Meanwhile, insertion of metal nanolayer can greatly relieve the residual stress‐induced microcracking inside the brittle materials. Such wafer‐scale Sapphire and Si interconnects thus show robust strength and excellent impermeability even after thermal shocking (−40 °C to 120 °C) for 200 cycles. This metal NPs layer‐assisted plasmonic microwelding technology can extend to broad materials integration, which is promising for high‐performance microdevices development in MEMS, MOEMS, or microfluidics.

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Switching jitter of avalanche gallium arsenide photoconductive semiconductor switch influenced by multiple avalanche domains

Chen,

Wei,

Sun

et al. 2024

Review of Scientific Instruments

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The stability of synchronous operation is directly related to the time jitter of the gallium arsenide photoconductive semiconductor switch (GaAs PCSS). In this work, a numerical model for the switching jitter of avalanche GaAs PCSS is established, and the impacts of triggering optical energy and bias electric field on the switching jitter are investigated numerically based on an equivalent bulk current channel. The proposed numerical model predicts well the changing characteristics of switching time as well as switching jitter, which has been demonstrated by the experimental results. On this basis, the theory of multiple avalanche domains is introduced to compare the domain evolutions influenced by the bias electric field and triggering optical energy. The results indicate that the reduction of switching jitter is significantly determined by the accelerated formation and evolution of avalanche domains, which provides a good explanation of the jitter mechanism of switching time.

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Photoexcited carrier dynamics in a GaAs photoconductive switch under nJ excitation

Cited by 8 publications

References 33 publications

Effects of spot size on the operation mode of GaAs photoconductive semiconductor switch employing extrinsic photoconductivity

Effects of spot size on the operation mode of GaAs photoconductive semiconductor switch employing extrinsic photoconductivity

Metal Nanoparticles Assisted Ultrafast Laser Plasmonic Microwelding of Oxide–Semiconductor Interconnects

Switching jitter of avalanche gallium arsenide photoconductive semiconductor switch influenced by multiple avalanche domains

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