RESUMO
A liquid carbon (l-C) sample is generated through constant volume heating exposing an amorphous carbon foil to an intense ultrashort laser pulse. Time-resolved x-ray absorption spectroscopy at the C K edge is used to monitor the dynamics of the melting process revealing a subpicosecond rearrangement of the electronic structure associated with a sudden change of the C bonding hybridization. The obtained l-C sample, resulting from a nonthermal melting mechanism, reaches a transient equilibrium condition with a temperature of about 14 200 K and pressure in the order of 0.5 Mbar in about 0.3 ps, prior to hydrodynamic expansion. A detailed analysis of the atomic and electronic structure in solid-density l-C based on time-resolved x-ray absorption spectroscopy and theoretical simulations is presented. The method can be fruitfully used for extending the experimental investigation of the C phase diagram in a vast unexplored region covering the 10^{3}-10^{4} K temperature range with pressures up to 1 Mbar.
RESUMO
Organisms respond to environmental stress by synthesizing a small number of highly conserved heat shock proteins. In organisms as diverse as bacteria, plants, invertebrates, and vertebrates, synthesis of these proteins is directly correlated with the acquisition of thermotolerance. While studying the freshwater coelenterate hydra, we observed that Hydra oligactis was extremely sensitive to thermal stress. In contrast, the related species Hydra attenuata survives short-term exposure to high temperatures. Furthermore, after incubation at an elevated but nonlethal temperature, H. oligactis did not become thermotolerant. H. attenuata, however, acquired thermotolerance after such a preincubation. In H. attenuata the major heat shock protein was found to be 60 kDa in size. H. oligactis did not synthesize detectable levels of this protein or any new species of proteins in response to stress. Several other species of hydra were found to behave like H. oligactis in response to stress. Thus, these findings provide direct support for the hypothesis that heat shock proteins are required for stress tolerance and that the major heat shock protein in hydra does not have any effects on normal growth or physiology. The findings also indicate that the presence of a heat shock response might be related to the natural environment in which an organism lives.
