1,170 research outputs found
Study on the Design of Writing Activities for the Integrative Review of High School English Units Based on the “Large Unit” Mode
The “large unit, overall context and major task” teaching mode marks the transformation of English teaching. Under the new situation of cultural conflicts, integration and innovation, the establishment of English learning task groups with English core competence as the guideline and students’ English practice as the focus is an innovative teaching mode to meet the demands of the times, namely “influencing people through culture and cultivating people via learning”. Applying the teaching mode of “large unit, overall context and major task” to the writing teaching can enrich the text contents and imbue teaching with poetic charm. Taking “Cultural Relics: Topic Writing Based on Modular Review” in the reading section in Unit 1 of Oxford High School English Book 2 as an example, this paper introduces how the teacher presents the topic writing method through the examples in the textbook, which takes the textbook as the foundation, focuses on the contents of the whole unit, and transcends the text by secondary processing, and finally generates the materials required in teaching. This method aims to encourage students to learn from words to sentences and then to paragraphs by way of gradation and progress with tiered difficulty. Text processing based on profound understanding strengthens students’ impression and memory, displaying a new teaching perspective for the writing
Generation of Intense High-Order Vortex Harmonics
This paper presents the method for the first time to generate intense
high-order optical vortices that carry orbital angular momentum in the extreme
ultraviolet region. In three-dimensional particle-in-cell simulation, both the
reflected and transmitted light beams include high-order harmonics of the
Laguerre-Gaussian (LG) mode when a linearly polarized LG laser pulse impinges
on a solid foil. The mode of the generated LG harmonic scales with its order,
in good agreement with our theoretical analysis. The intensity of the generated
high-order vortex harmonics is close to the relativistic region, and the pulse
duration can be in attosecond scale. The obtained intense vortex beam possesses
the combined properties of fine transversal structure due to the high-order
mode and the fine longitudinal structure due to the short wavelength of the
high-order harmonics. Thus, the obtained intense vortex beam may have
extraordinarily promising applications for high-capacity quantum information
and for high-resolution detection in both spatial and temporal scales because
of the addition of a new degree of freedom
Chlorine Dioxide-Iodide-Methyl Acetoacetate Oscillation Reaction Investigated by UV-Vis and Online FTIR Spectrophotometric Method
In order to study the chemical oscillatory behavior and mechanism of a new chlorine dioxide-iodide ion-methyl acetoacetate reaction system, a series of experiments were done by using UV-Vis and online FTIR spectrophotometric method. The initial concentrations of methyl acetoacetate, chlorine dioxide, potassium iodide, and sulfuric acid and the pH value have great influence on the oscillation observed at wavelength of 289 nm. There is a preoscillatory or induction period, and the amplitude and the number of oscillations are associated with the initial concentration of reactants. The equations for the triiodide ion reaction rate changing with reaction time and the initial concentrations in the oscillation stage were obtained. Oscillation reaction can be accelerated by increasing temperature. The apparent activation energies in terms of the induction period and the oscillation period were 26.02 KJ/mol and 17.65 KJ/mol, respectively. The intermediates were detected by the online FTIR analysis. Based upon the experimental data in this work and in the literature, a plausible reaction mechanism was proposed for the oscillation reaction
Experimental Study of Closed System in the Chlorine Dioxide-Iodide-Sulfuric Acid Reaction by UV-Vis Spectrophotometric Method
The mole ratio r(r = [I−]0/[ClO2]0) has great influence on ClO2-I−-H2SO4 closed reaction system. By changing the initiate concentration of potassium iodide, the curve of absorbance along with the reaction time was obtained at 350 nm and 297 nm for triiodide ion, and 460 nm for iodine. The changing point of the absorbance curve's shape locates at r = 6.00. For the reaction of ClO2-I− in the absence of H2SO4, the curve of absorbance along with the reaction time can be obtained at 350 nm for triiodide ion, 460 nm for iodine. The mole ratio r is equal to 1.00 is the changing point of the curve's shape no matter at which wavelength to determine the reaction. For the reaction of ClO2-I−-H+ in different pH buffer solution, the curve of absorbance along with the reaction time was recorded at 460 nm for iodine. When r is greater than 1.00, the transition point of the curve's shape locates at pH 2.0, which is also the point of producing chlorite or chloride for chlorine dioxide at different pH. When r is less than 1.00, the transition point locates at pH 7.0
Topology, Vorticity and Limit Cycle in a Stabilized Kuramoto-Sivashinsky Equation
A noisy stabilized Kuramoto-Sivashinsky equation is analyzed by stochastic
decomposition. For values of control parameter for which periodic stationary
patterns exist, the dynamics can be decomposed into diffusive and transverse
parts which act on a stochastic potential. The relative positions of stationary
states in the stochastic global potential landscape can be obtained from the
topology spanned by the low-lying eigenmodes which inter-connect them.
Numerical simulations confirm the predicted landscape. The transverse component
also predicts a universal class of vortex like circulations around fixed
points. These drive nonlinear drifting and limit cycle motion of the underlying
periodic structure in certain regions of parameter space. Our findings might be
relevant in studies of other nonlinear systems such as deep learning neural
networks.Comment: Main body: 16 pages, 3 figures; Supplementary: 14 pages, 6 figure
Generation of Ultra-intense Gamma-ray Train by QED Harmonics
When laser intensity exceeds 10^22W/cm^2, photons with energy above MeV can
be generated from high-order harmonics process in the laser-plasma interaction.
We find that under such laser intensity, QED effect plays a dominating role in
the radiation pattern. Contrast to the gas and relativistic HHG processes, both
the occurrence and energy of gamma-ray emission produced by QED harmonics are
random and QED harmonics are usually not coherent, while the property of high
intensity and ultra-short duration is conserved. Our simulation shows that the
period of gamma-ray train is half of the laser period and the peak intensity is
1.4e22W/cm^2. This new harmonic production with QED effects are crucial to
light-matter interaction in strong field and can be verified in experiments by
10PW laser facilities in the near future.Comment: 12 pages, 4 figure
Ultra-bright, ultra-broadband hard x-ray driven by laser-produced energetic electron beams
We propose a new method of obtaining a compact ultra-bright, ultra-broadband hard X-ray source. This X-ray source has a high peak brightness in the order of 1022 photons/(s mm2 mrad2 0.1\%BW), an ultrashort duration (10 fs), and a broadband spectrum (flat distribution from 0.1 MeV to 4 MeV), and thus has wide-ranging potential applications, such as in ultrafast Laue diffraction experiments. In our scheme, laser-plasma accelerators (LPAs) provide driven electron beams. A foil target is placed oblique to the beam direction so that the target normal sheath field (TNSF) is used to provide a bending force. Using this TNSF-kick scheme, we can fully utilize the advantages of current LPAs, including their high charge, high energy, and low emittance
Proton Acceleration in Underdense Plasma by Ultraintense Laguerre-Gaussian Laser Pulse
Three-dimensional particle-in-cell simulation is used to investigate the
witness proton acceleration in underdense plasma with a short intense
Laguerre-Gaussian (LG) laser pulse. Driven by the LG10 laser pulse, a special
bubble with an electron pillar on the axis is formed, in which protons can be
well-confined by the generated transversal focusing field and accelerated by
the longitudinal wakefield. The risk of scattering prior to acceleration with a
Gaussian laser pulse in underdense plasma is avoided, and protons are
accelerated stably to much higher energy. In simulation, a proton beam has been
accelerated to 7 GeV from 1 GeV in underdense tritium plasma driven by a
2.14x1022 W/cm2 LG10 laser pulse
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