Your search keyword '"pulse shaper"' showing total 2 results

1. Annular Pulse Shaping Technique for Large-Diameter Kolsky Bar Experiments on Concrete

Author

AIR FORCE RESEARCH LAB EGLIN AFB FL MUNITIONS DIR/ORDNANCE DIVISION, Martin, Bradley E, Heard, William F, Slawson, Thomas, Nie, Xu, Basu, P K, AIR FORCE RESEARCH LAB EGLIN AFB FL MUNITIONS DIR/ORDNANCE DIVISION, Martin, Bradley E, Heard, William F, Slawson, Thomas, Nie, Xu, and Basu, P K

Abstract

The goal of this study is to design a novel annular pulse shaping technique for large-diameter Kolsky bars for investigating the dynamic compressive response of concretes. The purpose of implementing an annular pulse shaper design is to alleviate inertia-induced stresses in the pulse shaper material that would otherwise superpose unwanted oscillations on the incident wave. This newly developed pulse shaping technique led to well-controlled testing conditions enabling dynamic stress equilibrium, uniform deformation, and constant strain-rate in the testing of a chosen concrete material. The observed dynamic deformation rate of the concrete is highly consistent (8 % variation) with the stress in the specimen well equilibrated confirming the validity of this new technique. Experimental results at both quasi-static and dynamic (100/s, 240/s) strain rates showed that the failure strength of this concrete is rate-sensitive. (PA# 96TW-2014-0048), Published in Experimental Mechanics, v54 p1343-1354, published online 13 Jun 2014. Prepared in collaboration with U.S. Army Engineer Research and Development Center, Vicksburg, MS; Department of Mechanical and Energy Engineering, University of North Texas, Denton, TX; and Department of Civil and Environmental Engineering, Vanderbilt University, Nashville, TN. The original document contains color images.

Published

2014

2. From few-cycle femtosecond pulse to single attosecond pulse-controlling and tracking electron dynamics with attosecond precision

Author

Wang, He. and Wang, He.

Abstract

The few-cycle femtosecond laser pulse has proved itself to be a powerful tool for controlling the electron dynamics inside atoms and molecules. By applying such few-cycle pulses as a driving field, single isolated attosecond pulses can be produced through the high-order harmonic generation process, which provide a novel tool for capturing the real time electron motion. The first part of the thesis is devoted to the state of the art few-cycle near infrared (NIR) laser pulse development, which includes absolute phase control (carrier-envelope phase stabilization), amplitude control (power stabilization), and relative phase control (pulse compression and shaping). Then the double optical gating (DOG) method for generating single attosecond pulses and the attosecond streaking experiment for characterizing such pulses are presented. Various experimental limitations in the attosecond streaking measurement are illustrated through simulation. Finally by using the single attosecond pulses generated by DOG, an attosecond transient absorption experiment is performed to study the autoionization process of argon. When the delay between a few-cycle NIR pulse and a single attosecond XUV pulse is scanned, the Fano resonance shapes of the argon autoionizing states are modified by the NIR pulse, which shows the direct observation and control of electron-electron correlation in the temporal domain.

Published

2010