Results 151 to 160 of about 37,216 (216)
Movement beyond data: epistemic and pictorial challenges in understanding moving life. [PDF]
Front BioinformWellmann J.
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An <i>in vitro</i> study evaluating the canal centering ability, canal transportation, and remaining dentin thickness of three retreatment systems. [PDF]
J Conserv Dent EndodSneha PK +5 more
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Measuring Implicit Approach-Avoidance Tendencies Using Self-Depicting Body Pictures in Female Adults With Bulimia Nervosa, High Body Dissatisfaction and Healthy Controls. [PDF]
Int J Eat DisordXemaire J +4 more
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rTMS Suppresses Tobacco Craving via Enhanced Prefronto-Striato-Thalamic Connectivity. [PDF]
Addict BiolLuo X +6 more
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Rhythmic sampling and competition of target and distractor in a motion detection task. [PDF]
ElifeXiong C +5 more
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Momentum Flow Mechanisms and Color-Lorentz Forces on Quarks in the Nucleon. [PDF]
Research (Wash D C)Ji X, Yang C.
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Applied Physics Letters, 1969
An experiment to record a holographic motion picture is described. The source of illumination is a cw ruby laser operated in the repetitively Q-switched mode. The film was recorded at the rate of 20 frames per second on 100 ft of 70-mm film, transported by a conventional 70-mm sequential-still camera.
A. Jacobson, V. Evtuhov, J. Neeland
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An experiment to record a holographic motion picture is described. The source of illumination is a cw ruby laser operated in the repetitively Q-switched mode. The film was recorded at the rate of 20 frames per second on 100 ft of 70-mm film, transported by a conventional 70-mm sequential-still camera.
A. Jacobson, V. Evtuhov, J. Neeland
openaire +1 more source
Surface Science, 2002
Abstract The engineering of many modern electronic devices demands control over a crystal down to the thickness of a single layer of atoms—and future demands will be even more challenging. Such control is achieved by the method of crystal growth known as epitaxy, and that makes this method the subject of intense study. More than that, recent advances
Finnie, Paul, Homma, Y.
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Abstract The engineering of many modern electronic devices demands control over a crystal down to the thickness of a single layer of atoms—and future demands will be even more challenging. Such control is achieved by the method of crystal growth known as epitaxy, and that makes this method the subject of intense study. More than that, recent advances
Finnie, Paul, Homma, Y.
openaire +2 more sources