W. Wang scite author profile

Concerning laser-driven electron acceleration in vacuum, a comparison was made between using circularly polarized (CP) laser field and linearly polarized (LP) field. It has been found that the main advantage for using CP field is that its acceleration channel occupies relatively larger phase space, which can give rise to greater acceleration efficiency. This feature chiefly comes from the difference in the distribution of the longitudinal electric components of these two kinds of fields. One of the disadvantages with CP field is the “energy saturation” phenomenon as the laser intensity is sufficiently high, resulting from the enhanced Lorentz force component in CP field. Physical explanations of these characteristics are addressed as well.

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A pinhole camera for ultrahigh-intensity laser plasma experiments

Wang

Xiong

et al. 2017

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A pinhole camera is an important instrument for the detection of radiation in laser plasmas. It can monitor the laser focus directly and assist in the analysis of the experimental data. However, conventional pinhole cameras are difficult to use when the target is irradiated by an ultrahigh-power laser because of the high background of hard X-ray emission generated in the laser/target region. Therefore, an improved pinhole camera has been developed that uses a grazing-incidence mirror that enables soft X-ray imaging while avoiding the effect of hard X-ray from hot dense plasmas.

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Understanding Dark Spot Formation and Growth in Organic Light-Emitting Devices by Controlling Pinhole Size and Shape

Lim

Wang²,

Chua

2002

Adv. Funct. Mater.

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We report on our in‐situ experimental observations of dark spots in organic light‐emitting diodes using optical microscopy. Uniformly sized silica microparticles are used to intentionally create size‐ and shape‐controllable pinholes on the cathode protective layer. Subsequently, the pinholes trigger the initial formation of dark spots, which we then monitor. Due to the use of particles of various diameters, we are able to linearly associate the growth rate with pinhole size. This allows us to estimate the original pinhole sizes that give rise to the dark spots and to study their distribution. Our studies verify that pinholes on the protective layer create pathways for water or oxygen diffusion, which controls the dark spot growth rate. The pinhole size dependence illustrates that the pinhole perimeter (not the area) determines the amount of water or oxygen diffusing into the diodes at a certain time.

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W. Wang

Conceptual design of the fusion-driven subcritical system FDS-I

Polarization effect of fields on vacuum laser acceleration

A pinhole camera for ultrahigh-intensity laser plasma experiments

Understanding Dark Spot Formation and Growth in Organic Light-Emitting Devices by Controlling Pinhole Size and Shape

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