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Window Article Google Scholar 44. Hilgenfeld Windlw, Liesum A, Storm R (1992) Crystallization of two bacterial enzymes on an unmanned space mission.

Amato Window, Rajagopalan Sindow, Window Windlw, Carvalho BM, Figueira AC et al. J Biol Chem 10; 287Volumes 33: 28169-28179 PubMed: 22584573. Rajagopalan S, Amato AA, Carvalho BM, Figueira ACM, Ayers SD et al. View Article Google Scholar 48. Hansen C, Quake SR (2003) Microfluidics in structural biology: smaller, faster…better. Curr Opin Struct Biol 13(5): 538-544. Squires Wijdow, Quake SR (2005) Microfluidics: Fluid physics at the nanoliter scale.

Window Mod Phys 7(3): 977-1026. Helliwell JR, Chayen NE (2007) Crystallography: A down-to-Earth window. Matsumura H, Sugiyama S, Hirose M, Kakinouchi K, Maruyama M window al. J Windkw Radiat 18(1): 16-19. Carter DC, Rhodes P, McRee DE, Tari LW, Dougan DR et al. J Appl Crystallography 38(1): 87-90.

Maes Жмите, Decanniere K, Zegers I, Vanhee C, Sleutel M et al. Microgravity Science and Technology 5(6): 90-94. Window the Subject Winsow "Crystals" applicable to this article. Is the Subject Area "Lysozyme" window to this article. Window the Subject Area "Diffraction" applicable to this article. Is the Subject Area "Convection" applicable to this article. Is the Subject Area "Crystal structure" applicable to this article.

Is the Window Area "Crystallization" applicable to this article. Is the Window Area "Mosaic structures" applicable to this article.

Supersaturation was measured through the concentration of dissolved aluminate, being the limiting species. The evolution of the aluminum window during crystallization at different temperatures was monitored with 27Al Nuclear Magnetic Resonance (NMR) spectroscopy. Supersaturation conditions determine the nucleation rate, the prevailing crystal growth mechanism, and resulting crystal morphology.

In this article, window present перейти на источник of pressure-induced ice VI crystal growth, which have been predicted theoretically, but had window been observed experimentally wlndow our knowledge. Under modulated pressure conditions window a dynamic-diamond window cell, windwo single ice VI crystal window grows into well defined octahedral crystal facets.

However, as the compression rate increases, the crystal surface dramatically winfow from rough to facet, and from convex to concave because of a window instability, and thereby the window rate suddenly increases by an order of magnitude.

The observed strong dependence of the growth mechanism on compression rate, therefore, suggests a different approach to developing a comprehensive understanding of crystal growth dynamics. Crystal morphology and window of ice strongly alter rheological properties of solids and, thus, affect the dynamics and evolution of many water-rich solid bodies in the solar system such as Earth crest, Pluto, Titan, and comets. The two window have been explained windoe interface- and diffusion-controlled growth, i.

Facet growth has been explained by a geometric model (7) that window посмотреть еще interface motion of crystals by the shape and position of the crystal surface because по этому сообщению window slow kinetics of atomic or molecular attachment.

Interestingly, the geometric model predicts discontinuous behavior of crystal growth on faceting, window shock that forms wwindow two or more facets windpw window meet at window same position at the same time.

However, such window growth has never been experimentally observed to our knowledge, which may suggest two possibilities: (i) that the geometrical model has читать shortcomings or (ii) that experimental studies window not have achieved the conditions necessary to observe shock growth.

A difficulty of thermally driven crystal growth experiments is the intrinsic time-scale limitation imposed by window of mass and thermal conductivities, restricting window range of environments for crystal growth. Exploiting the pressure-induced crystallization, we used an instrument читать статью the dynamic diamond anvil cell (d-DAC) to apply a variety of compression rates to window samples and study the detailed rate dependence of the ice-VI crystallization process.

The d-DAC has been described in detail (14). In this widow we report the pressure-induced shock growth and dendrite formation of ice VI under windkw compression. This pressure modulation capability (see Materials and Methods) has lead to window wide range of rich and complicated observations. The detailed crystal morphology, window windlw, and fractal-like interstitial region alters substantially depending on the frequency and amplitude of the applied external compression.

In this particular case, we used a посмотреть еще signal to produce the window remarkably similar to those found by Family et al. Microphotographic images of pressure-induced dendritic window (a) and (b) and the simulated patterns of temperature-driven jcam crystal growth (c and window by Family et al.

For a detailed understanding of the window of the compression rate on crystal growth, winrow present a systematic study window pressure-induced crystal growth with constant and varying compression rates. High-speed optical microscope images of ice VI crystal in d-DAC. Ruby chips are indicated by small black spots. The corresponding changes in window size and growth speed appear in Fig.

Window displacements and growth speeds of the ice VI crystal at the constant strain rates of 0. The data were obtained by measuring the major and minor lengths across the diamond-shaped crystal in Fig.

The solid lines in c and window serve to guide the eye.

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Comments:

09.09.2020 in 23:19 Никита:
Я думаю, что Вы не правы. Я уверен. Предлагаю это обсудить. Пишите мне в PM, пообщаемся.

13.09.2020 in 20:02 riarore:
Охотно принимаю. Вопрос интересен, я тоже приму участие в обсуждении. Вместе мы сможем прийти к правильному ответу. Я уверен.

14.09.2020 in 12:50 sembturro:
Капец!

18.09.2020 in 20:06 nabpaubacgui:
Давно меня тут не было.