14,134 research outputs found
Pat Roden
"Pat Roden (Cock) AWAS Signals D/B office, Alice Springs, Darwin Des Cock Cpl Infantry".Pat Roden (Cock). Australian Women's Army Service, Signals. D/B office, Alice Springs, Darwin. Des Cock. Corporal. Infantry
Pat Mansell
"Evacuated Koolind[a] Pat Mansell Nee Stevens Parents Eileen + Bill Stevens (Plasterer). Darwin 1935-1941"Date:199
Wall of Death Rider Pat O'Malley
Promotional photograph for Wall of Death rider Pat O'Malley showing him riding the Wall of Death. Signed 'To my Pal Billy, Bellhouse, Pat O'Malley'. Digitisation and record funded by the Pilgrim Trust
Moot Points Notes from the Sarita Kenedy East Law Library Issue 13 January and February 2011
Director's Message: Greetings and New Year, Meeting Pat Wall Filing Supervisor, Recent Faculty Publications, Notable New Acquisitions, Our Library By the Numbers, Legal Film Showcase, Popular Reading Review: Crash Into Me, New Films Now Available for C
Youthhood
TESTING-GROUND issue 03, Youthhood, examines worlds through youthful eyes, makes evident young ambitions, and questions how we can better empower young people to design cities, landscapes, and a planet that works for them. The issue includes contributions from: Carmel Keren, Jude Daniel Smith, Claire Edwards, Kazeem Kuteyi, Emmanuel Adarkwah, Reza Nik, Dan Cui, Kristofer Cullum-Fernandez, Fida Sassi, Simeon Shtebunaev, Daze Aghaji, Averill Dimabuyu, Sarri Elfaitouri, Rebecca McDonald-Balfour, and Ed Wall.
Rebecca McDonald-Balfour (Author), Jude Daniel Smith (Author), Daze Aghaji (Author), Carmel Keran (Author), Alexis Liu (Author), Dan Cui (Author), Kristofer Cullum-Fernandez (Author), Fida Sassi (Author), Averill Dimabuyu (Author), Ed
Turbulent plane Couette flow with wall-transpiration
In the present abstract, DNS results obtained for turbulent plane Couette flow with wall-normal transpiration velocity are presented. Important equations valid in such a flow are derived, describing the total shear stress and the relation between the friction velocities at the lower and upper wall. These expressions are of importance, as there are neither experimental nor DNS data to compare with. Equally important, we derive a center region and a viscous sublayer velocity scaling for the suction wall, which were both validated using the DNS data
Turbulent separation in lower curved wall channels
Turbulent boundary layer separation in channels with a lower curved wall is studied using direct numerical simulations (DNS). Turbulence dynamics are studied through classical statistical tools such as the turbulent kinetic energy budget for varying lower curved wall dimensions. The geometry features are expected to have a significant effect on the fluid flow structures and the characteristic scales of separation. The separation bubble behind the bump is studied in terms of its size, turbulent kinetic energy production mechanisms and transfer and scale-by-scale energy budget. New innovative data-analysis techniques will be used based on the generalisation of the Kolmogorov equation to anisotropic and spatially non-homogeneous flow configurations
The influence of subgrid-scale modelling on the performance of a new non-equilibrium wall-model for large-eddy simulation
The computational cost of wall-resolved large-eddy simulations (LES) rapidly becomes prohibitive with increasing Reynolds number. Wall-modelled LES attempts to significantly reduce the computational cost of simulating wall-bounded turbulent flows by modelling the effect of the near-wall small-scale motions, rather than fully or partially resolving them. The present study concentrates on a new wall-model that is able to predict fluctuating wall-shear stress given a large-scale velocity input. The velocity input for the model is affected by the choice of subgrid-scale (SGS) model. Therefore, this study also focusses on the impact of the SGS-model on the distribution of quantities at the wall. Results show that the new wall-model is able to resolve more of the wall shear-stress variance than a standard wall-model; and that the SGS-model affects the distribution of fluctuations of both wall-shear stress and wall-pressure
Identification and Characterization of Pat-6/actopaxin in Caenorhabditis Elegans Body Wall Muscle
In addition, I identified PAT-4/ILK and a novel protein, K10B2.5, as putative binding partners of PAT-6/actopaxin. PAT-6/actopaxin and PAT-4/ILK colocalize in vivo, forming a multi-protein complex with UNC-112. The accumulation of PAT-6/actopaxin in body wall muscle cells requires PAT-4/ILK kinase domain. K10B2.5 binds PAT-6/actopaxin in yeast two-hybrid assays, and also colocalizes with PAT-6/actopaxin to muscle attachment sites.Made available in DSpace on 2015-09-28T15:17:12Z (GMT). No. of bitstreams: 2
license.txt: 4848 bytes, checksum: 96035ab3f5e1c23cc7138a224ce498bd (MD5)
3101907.pdf: 3868495 bytes, checksum: d2aac3f21edcd28b2733f710de75d803 (MD5)
Previous issue date: 2003Embargo set by: Seth Robbins for item 87937
Lift date: Forever
Reason: Restricted to the U of I community idenfinitely during batch ingest of legacy ETDsRestricted to the U of I community idenfinitely during batch ingest of legacy ETDsU of I Only87 p.Thesis (Ph.D.)--University of Illinois at Urbana-Champaign, 2003
- …
