Spatiotemporal splitting of global eigenmodes due to cross-field coupling via vortex dynamics in drift wave turbulence

Spatiotemporal splitting events of drift wave (DW) eigenmodes due to nonlinear coupling are investigated in a cylindrical helicon plasma device. DW eigenmodes in the radial-azimuthal cross section have been experimentally observed to split at radial locations and recombine into the global eigenmode with a time shorter than the typical DW period (t≪fDW(-1)). The number of splits correlates with the increase of turbulence. The observed dynamics can be theoretically reproduced by a Kuramoto-type model of a network of radially coupled azimuthal eigenmodes. Coupling by E×B-vortex convection cell dynamics and ion gyro radii motion leads to cross-field synchronization and occasional mode splitting events.

Simultaneous use of camera and probe diagnostics to unambiguously identify and study the dynamics of multiple underlying instabilities during the route to plasma turbulence

We use multiple-tip Langmuir probes and fast imaging to unambiguously identify and study the dynamics of underlying instabilities during the controlled route to fully-developed plasma turbulence in a linear magnetized helicon plasma device. Langmuir probes measure radial profiles of electron temperature, plasma density and potential; from which we compute linear growth rates of instabilities, cross-phase between density and potential fluctuations, Reynold's stress, particle flux, vorticity, time-delay estimated velocity, etc. Fast imaging complements the 1D probe measurements by providing temporally and spatially resolved 2D details of plasma structures associated with the instabilities. We find that three radially separated plasma instabilities exist simultaneously. Density gradient driven resistive drift waves propagating in the electron diamagnetic drift direction separate the plasma into an edge region dominated by strong, velocity shear driven Kelvin-Helmholtz instabilities and a central core region which shows coherent Rayleigh-Taylor modes propagating in the ion diamagnetic drift direction. The simultaneous, complementary use of both probes and camera was crucial to identify the instabilities and understand the details of the very rich plasma dynamics.

Plasma blob generation due to cooperative elliptic instability

Using fast-camera measurements the generation mechanism of plasma blobs is investigated in the linear device CSDX. During the ejection of plasma blobs the plasma is dominated by an m=1 mode, which is a counterrotating vortex pair. These flows are known to be subject to the cooperative elliptic instability, which is characterized by a cooperative disturbance of the vortex cores and results in a three-dimensional breakdown of two-dimensional flows. The first experimental evidence of a cooperative elliptic instability preceding the blob-ejection is provided in terms of the qualitative evolution of the vortex geometries and internal wave patterns.

Hydrogen peroxide modulates meiotic cell cycle and induces morphological features characteristic of apoptosis in rat oocytes cultured in vitro

Hydrogen peroxide (H2O2) is known to induce cell cycle arrest and apoptosis in various somatic cell types cultured in vitro. We hypothesize that this reactive oxygen species (ROS) could modulate cell cycle and induce morphological features characteristics of apoptosis in oocytes cultured in vitro. To test this hypothesis, immature and mature oocytes were cultured in medium containing various doses of H2O2 with or without caspase-3 inhibitor for various times. The treatment of H2O2 induced germinal vesicle break down (GVBD) in all immature oocytes followed by initiation of shrinkage. Some of immature oocytes (but not mature oocytes) also showed membrane blebbing. On the other hand, H2O2 treatment inhibited first polar body emission in mature oocytes just prior to initiation of shrinkage. The cytoplasmic granulation and fragmentation into apoptotic bodies were observed in mature oocytes during later stages of H2O2 treatment. The shrinkage was induced by H2O2 in a dose- and time-dependent manner in both immature and mature oocytes. Although, H2O2-induced degeneration was observed in both immature and mature oocytes after 2.0 hrs of treatment, immature oocytes were more susceptible to undergo quick shrinkage, membrane blebbing and degeneration. Co-addition of caspase-3 inhibitor prevented shrinkage and degeneration of both immature and mature oocytes except membrane blebbing that was observed at higher doses of H2O2 after 1.0 hr of culture. Treatment of H2O2 induced bax protein expression (3 times), DNA fragmentation and caspase-3 activity (2.5 times) in oocytes undergoing morphological apoptotic changes. These findings clearly suggest that H2O2 induced GVBD in immature oocytes, inhibited first polar body extrusion in mature oocytes prior to initiation of morphological changes characteristic of apoptosis such as shrinkage, membrane blebbing and cytoplasmic fragmentation prior to degeneration.