Your search keyword '"Shao Zhenhua"' showing total 3 results

1. Overview of Advanced LIGO Adaptive Optics

Author

Brooks, Aidan F., Abbott, Benjamin, Arain, Muzammil A., Ciani, Giacomo, Cole, Ayodele, Grabeel, Greg, Gustafson, Eric, Guido, Chris, Heintze, Matthew, Heptonstall, Alastair, Jacobson, Mindy, Kim, Won, King, Eleanor, Lynch, Alexander, O'Connor, Stephen, Ottaway, David, Mailand, Ken, Mueller, Guido, Munch, Jesper, Sannibale, Virginio, Shao, Zhenhua, Smith, Michael, Veitch, Peter, Vo, Thomas, Vorvick, Cheryl, Willems, Phil, Brooks, Aidan F., Abbott, Benjamin, Arain, Muzammil A., Ciani, Giacomo, Cole, Ayodele, Grabeel, Greg, Gustafson, Eric, Guido, Chris, Heintze, Matthew, Heptonstall, Alastair, Jacobson, Mindy, Kim, Won, King, Eleanor, Lynch, Alexander, O'Connor, Stephen, Ottaway, David, Mailand, Ken, Mueller, Guido, Munch, Jesper, Sannibale, Virginio, Shao, Zhenhua, Smith, Michael, Veitch, Peter, Vo, Thomas, Vorvick, Cheryl, and Willems, Phil

Abstract

This is an overview of the adaptive optics used in Advanced LIGO (aLIGO), known as the thermal compensation system (TCS). The thermal compensation system was designed to minimize thermally-induced spatial distortions in the interferometer optical modes and to provide some correction for static curvature errors in the core optics of aLIGO. The TCS is comprised of ring heater actuators, spatially tunable CO$_{2}$ laser projectors and Hartmann wavefront sensors. The system meets the requirements of correcting for nominal distortion in Advanced LIGO to a maximum residual error of 5.4nm, weighted across the laser beam, for up to 125W of laser input power into the interferometer.

Published

2016

2. Fluid dynamics alter Caenorhabditis elegans body length via TGF-β/DBL-1 neuromuscular signaling

Author

Harada, Shunsuke, Hashizume, Toko, Nemoto, Kanako, Shao, Zhenhua, Higashitani, Nahoko, Etheridge, Timothy, Szewczyk, Nathaniel J., Fukui, Keiji, Higashibata, Akira, Higashitani, Atsushi, 原田, 俊介, 橋爪, 藤子, 根本, 華奈子, 東谷, なほ子, 福井, 啓二, 東端, 晃, 東谷, 篤志, Harada, Shunsuke, Hashizume, Toko, Nemoto, Kanako, Shao, Zhenhua, Higashitani, Nahoko, Etheridge, Timothy, Szewczyk, Nathaniel J., Fukui, Keiji, Higashibata, Akira, Higashitani, Atsushi, 原田, 俊介, 橋爪, 藤子, 根本, 華奈子, 東谷, なほ子, 福井, 啓二, 東端, 晃, and 東谷, 篤志

Abstract

Skeletal muscle wasting is a major obstacle for long-term space exploration. Similar to astronauts, the nematode Caenorhabditis elegans displays negative muscular and physical effects when in microgravity in space. It remains unclear what signaling molecules and behavior(s) cause these negative alterations. Here we studied key signaling molecules involved in alterations of C. elegans physique in response to fluid dynamics in ground-based experiments. Placing worms in space on a 1G accelerator increased a myosin heavy chain, myo-3, and a transforming growth factor-β (TGF-β), dbl-1, gene expression. These changes also occurred when the fluid dynamic parameters viscosity/drag resistance or depth of liquid culture were increased on the ground. In addition, body length increased in wild type and body wall cuticle collagen mutants, rol-6 and dpy-5, grown in liquid culture. In contrast, body length did not increase in TGF-β, dbl-1, or downstream signaling pathway, sma-4/Smad, mutants. Similarly, a D1-like dopamine receptor, DOP-4, and a mechanosensory channel, UNC-8, were required for increased dbl-1 expression and altered physique in liquid culture. As C. elegans contraction rates are much higher when swimming in liquid than when crawling on an agar surface, we also examined the relationship between body length enhancement and rate of contraction. Mutants with significantly reduced contraction rates were typically smaller. However, in dop-4, dbl-1, and sma-4 mutants, contraction rates still increased in liquid. These results suggest that neuromuscular signaling via TGF-β/DBL-1 acts to alter body physique in response to environmental conditions including fluid dynamics., Physical characteristics: Original contains color illustrations, 形態: カラー図版あり

Published

2016

3. Overview of Advanced LIGO Adaptive Optics

Author

Brooks, Aidan F., Abbott, Benjamin, Arain, Muzammil A., Ciani, Giacomo, Cole, Ayodele, Grabeel, Greg, Gustafson, Eric, Guido, Chris, Heintze, Matthew, Heptonstall, Alastair, Jacobson, Mindy, Kim, Won, King, Eleanor, Lynch, Alexander, O'Connor, Stephen, Ottaway, David, Mailand, Ken, Mueller, Guido, Munch, Jesper, Sannibale, Virginio, Shao, Zhenhua, Smith, Michael, Veitch, Peter, Vo, Thomas, Vorvick, Cheryl, Willems, Phil, Brooks, Aidan F., Abbott, Benjamin, Arain, Muzammil A., Ciani, Giacomo, Cole, Ayodele, Grabeel, Greg, Gustafson, Eric, Guido, Chris, Heintze, Matthew, Heptonstall, Alastair, Jacobson, Mindy, Kim, Won, King, Eleanor, Lynch, Alexander, O'Connor, Stephen, Ottaway, David, Mailand, Ken, Mueller, Guido, Munch, Jesper, Sannibale, Virginio, Shao, Zhenhua, Smith, Michael, Veitch, Peter, Vo, Thomas, Vorvick, Cheryl, and Willems, Phil

Abstract

This is an overview of the adaptive optics used in Advanced LIGO (aLIGO), known as the thermal compensation system (TCS). The thermal compensation system was designed to minimize thermally-induced spatial distortions in the interferometer optical modes and to provide some correction for static curvature errors in the core optics of aLIGO. The TCS is comprised of ring heater actuators, spatially tunable CO$_{2}$ laser projectors and Hartmann wavefront sensors. The system meets the requirements of correcting for nominal distortion in Advanced LIGO to a maximum residual error of 5.4nm, weighted across the laser beam, for up to 125W of laser input power into the interferometer.

Published

2016