77 research outputs found
Varietal differences in the texture of grape berries measured by penetration tests
Penetration tests were made on 8 mm thick flesh sections from grape berries of 22 cultivars of Vitis vinifera L. and 18 of Vitis labruscana Bailey. Deformation at the first major peak (DFP), maximum force (MF), force at the first major peak (FFP) and work to the first major peak (WFP) were recorded. High correlation coefficients were obtained between the rating of difficulty of breakdown on mastication in the sensory tests and DFP (r=0.86**), and the rating of flesh firmness in the sensory test and MF (r=0.84**). The mean value and variance of DFP and WFP were significantly higher in V. labruscana than in V. vinifera, whereas those of MF were nearly the same. DFP and MF were not correlated for V. vinifera cultivars, but were for V. labruscana cultivars (r=0.68**). These results indicate that the texture of V. labruscana had a wide variation in toughness whereas that of V. vinifera was brittle and did not have a wide variation in toughness; both groups had the same variation in firmness
Sub-Cycle Optical Response Caused by Dressed State with Phase-Locked Wavefunctions
The coherent interaction of light with matter imprints the phase information
of the light field on the wavefunction of the photon-dressed electronic state.
Driving electric field, together with a stable phase that is associated with
the optical probe pulses, enables the role of the dressed state in the optical
response to be investigated. We observed optical absorption strengths modulated
on a sub-cycle timescale in a GaAs quantum well in the presence of a
multi-cycle terahertz driving pulse using a near-infrared probe pulse. The
measurements were in good agreement with the analytical formula that accounts
for the optical susceptibilities caused by the dressed state of excitons, which
indicates that the output probe intensity was coherently reshaped by the
excitonic sideband emissions
Time-dependent density functional theory for strong electromagnetic fields in crystalline solids
We apply the coupled dynamics of time-dependent density functional theory and
Maxwell equations to the interaction of intense laser pulses with crystalline
silicon. As a function of electromagnetic field intensity, we see several
regions in the response. At the lowest intensities, the pulse is reflected and
transmitted in accord with the dielectric response, and the characteristics of
the energy deposition is consistent with two-photon absorption. The absorption
process begins to deviate from that at laser intensities ~ 10^13 W/cm^2, where
the energy deposited is of the order of 1 eV per atom. Changes in the
reflectivity are seen as a function of intensity. When it passes a threshold of
about 3 \times 1012 W/cm2, there is a small decrease. At higher intensities,
above 2 \times 10^13 W/cm^2, the reflectivity increases strongly. This behavior
can be understood qualitatively in a model treating the excited electron-hole
pairs as a plasma.Comment: 27 pages; 11 figure
Results of oceanographic and meteorological observations at Otsuchi Bay (2000)
平成12年度共同利用研究集会「棘皮動物ウニ類のボディプラン確立過程におけるシグナル伝達」(2000年10月23日~25日, 研究代表者:雨宮昭南)講演要旨Signal transduction in the process of eastablishment of sea urchin body plan(Abstracts of scientific symposia held at Otsuchi Marine Research Center in 2000
Study of P Influenced to Magnetic Characteristics of Mn-Zn Ferrites for Power Applications
We examined that influence of P which changes magnetic characteristics of Mn-Zn ferrites for power applications. As quantity of P increase, larger size grains were formed in the microstructure of ferrite and as the result, core loss increased. We found that P had high solubility on ferrite. Therefore, we supposed that P should generate a great deal of liquid phase even if the amount of P is small. Then, the melting point of ferrite-P was relatively low. As the result, we considered that the large grain is caused by liquid phase
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