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Bat use of old growth redwood basal hollows with increasing isolation in contiguous, remnant, and legacy forest stands /Roberts, Amy L. January 1900 (has links)
Thesis (M.S.)--Humboldt State University, 2008. / Includes bibliographical references (leaves 61-67). Also available via Humboldt Digital Scholar.
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The effects of thinning intensity on snag and cavity tree abundance in an Appalachian hardwood standGraves, Aaron T. January 1999 (has links)
Thesis (M.S.)--West Virginia University, 1999. / Title from document title page. Document formatted into pages; contains viii, 75 p. : ill., map. Includes abstract. Includes bibliographical references (p. 33-41).
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Tree holes as habitat for aquatic and terrestrial invertebrates in mixed broadleaf-podocarp rainforest, New Zealand : a thesis submitted for the degree of Doctor of Philosophy in Ecology at the University of Canterbury /Blakely, Tanya J. January 2008 (has links)
Thesis (Ph. D.)--University of Canterbury, 2008. / Typescript (photocopy). Includes bibliographical references. Also available via the World Wide Web.
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Airflow patterns in ventilated wall cavitiesOdewole, Gboyega Akindeji January 2011 (has links)
Though heating, insulation, wall claddings and cavity-wall construction are considered as measures for remediating moisture and condensation in buildings, ventilation of wall cavities has however become a mantra among architects and other building professionals. Holes of any size and shape are made and located on building facades based on the accepted wisdom that a little air movement will keep the wall cavities dry. Whilst ventilation has been found to be successful in the control of moisture and condensation in rooms and larger enclosures, there is however insufficient understanding of how it works in thin spaces with high aspect ratios, such as the wall cavities studied in this thesis.In order to put in place good control and management practices in the remediation of moisture and condensation in vertical wall cavities by natural ventilation, it is vital to understand the dynamics of airflow in these cavities. In this thesis therefore, different size and shape of slots were employed to numerically investigate the effects of size, spacing and number of the slots on the characteristics of the velocity fields (patterns of airflow and distributions of velocity) in different cavity models. The Reynolds-Averaged-Navier-Stokes (RANS) methodology was employed to simulate the cavity flows under different modelling conditions using FLUENT. The BS 5925 model, an empirical relation for predicting ventilation rates in rooms and other larger enclosures, was employed and modified to predict ventilation rates in these cavities. Experimentally, the mapping of the airstreams in these cavities was obtained under similar reference (inlet) wind speeds employed for the numerical investigations.The results of this study show that there exists a potential at higher wind speeds for natural ventilation in the remediation of moisture and condensation in the cavities of vertical walls. The steady state approach employed in the RANS-based computation of cavity flows in this thesis averages out the peak values of air velocities and therefore gives no information about regions of maxima or minima velocity values even at higher wind speeds. This makes the predicted air change rates insensitive to the inlet air velocities from the ventilation slots and therefore makes the results more applicable for long term control and management of moisture in these cavities. In order to therefore put in place short, medium and long term plans for remediation of moisture in these wall cavities, a time-dependent computation is required. This will also allow the efficiency of the cavity ventilation to be properly assessed. Using the modified BS 5925 model, reasonable predictions were obtained for the air change rates of the wall cavities with the different size of ventilation slots employed. Close agreements are also obtained at lower and higher wind speeds between the predicted ventilation rates from the modified BS 5925 model and the experimental results employed as benchmark for validating the results.
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Drag reduction by gas layers and streamlined air cavities attached to free-falling spheresJetly, Aditya 11 1900 (has links)
The general objective of this thesis is to conduct experiments on sphere free-falling in liquid that advance our understanding of the drag reduction on solids moving in liquid by means of lubricating gas layers and attached streamlined air cavities.
Part I of the thesis investigates the effect of thin air layers, naturally sustained on superhydrophobic surfaces, on the terminal velocity and drag force of metallic spheres free- falling in water. The surface of 20 mm to 60 mm steel or tungsten-carbide spheres is rendered superhydrophobic by a simple coating process that uses a commercially available hydrophobic agent. By comparing the free-fall of unmodified spheres and superhydrophobic spheres, in a 2.5 meters tall water tank, it is demonstrated that even a very thin air layer (~ 1 – 2 μm) that covers the freshly dipped superhydrophobic sphere, can reduce the drag force on the spheres by up to 80 %, at Reynolds numbers 105 to 3×105, owing to an early drag crisis transition.
Part II of the thesis investigates the drag reduction by means of the dynamic Leidenfrost vapor-layer sustained on the surface of heated metallic spheres free-falling in a fluorocarbon liquid, FC-72 (perfluorohexane). In these experiments we employed two tall liquid tanks: a 3 meter tall 14 cm wide tank and a 2 meter tall 20 × 20 cm cross-section tank with a heater device. These tanks are significantly larger than the tanks used in prior studies and allow us to track the extended fall trajectories and to compare the drag on room-temperature no-vapor-layer spheres to that of heated Leidenfrost vapor-layer spheres. Analysis of the extended free-fall trajectories and acceleration, based on the sphere dynamic equation of motion, enables the accurate evaluation of the vapor-layer-induced drag reduction, without the need for extrapolation. We demonstrate that the drag on the Leidenfrost sphere in FC-72, can be as low as CD = 0.04 ± 0.01, or an order of magnitude lower than the values for the no-vapor-layer spheres in the subcritical Reynolds number range. This drag reduction extends into the supercritical Reynolds number range. The analysis method developed herein, to describe the sphere trajectories, can be applied in other related studies.
Part III of the thesis examines a recently demonstrated phenomenon of the formation of stable-streamlined gas cavity following the impact of a heated Leidenfrost sphere on a liquid surface or a superhydrophobic sphere on water. The sphere encapsulated in a teardrop-shaped gas cavity was found to have near-zero hydrodynamic drag due to the self-adjusting streamlined shape and the free-slip boundary condition on the cavity interface. Here it is shown that such cavities can be formed following the water impact from a sufficient height of non-superhydrophobic spheres with water contact angles between 30° and 120°. In this case the streamlined cavity is attached just above the sphere’s equator, instead of entirely wrapping the sphere. Nevertheless, this sphere with attached cavity has near-zero drag and predetermined free-fall velocity in compliance with the Bernoulli law of potential flow. Last, the effect of surfactant addition to the water solution is investigated. The shape and fall velocity of the sphere with streamlined cavity formation were unaffected by the addition of low-surface-modulus synthetic surfactants, but was destabilised when a solution containing high-surface-modulus surfactants, such as soaps were used.
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Laminar Natural Convection in Air-Filled Rectangular Cavities With and Without Partitions on WallsWu, Wenjiang 12 1900 (has links)
<p>The laminar natural convection in air-filled rectangular cavities with and without a
partition on the wall was experimentally investigated. Temperature measurements
and flow visualizations were performed for cases with heated and cooled vertical
walls (corresponding to global Grashof numbers GrH of approximately 1.4 x 10^8 to
1.8 x 10^8) and non-dimensional top wall temperatures θT of 0.52 (insulated) to 2.3.
In the rectangular cavities without the partition and with aspect ratios of 0.5, 1.0
and 2.0, the heated top wall caused the natural convection boundary layer flow to
separate from either the top wall (for the cases with Or ;S 1.2) or the heated vertical
wall (for the cases with θT >~ 1.2) due to the negative buoyancy force. For the
cases with θT >~ 1.2, there is an anti-clockwise recirculating flow in the upper left
corner region. The extent of the recirculating flow decreased with an increase of the
aspect ratio. The temperature gradient in the core region, dθ∞ /d(y/H), increased
with an increase of θT. For a given aspect ratio, dθ∞/d(y/H) changed more rapidly
with the change in θT for the cases with θT <~ 1.2 compared to the cases with θT >~
1.2. The increase in dθ∞/ d(y/H) was more significant for the smaller aspect ratio
cavity. The temperature profiles predicted from the similarity solutions proposed by
Kulkarni et al. [1] and from the non-similarity model developed by Chen and Eichhorn
[2] for natural convection on an isothermal vertical wall in a stratified environment
were compared to the measurements in the current cases. These models were not able to accurately describe the characteristics of the natural convection flow in the
rectangular cavities.</p> <p>An aluminium partition with non-dimensional heights Hp/H of 0.0625 and 0.125 was attached either to the heated vertical wall or top wall at y/H = 0.65,
0.95 and x/H = 0.1, 0.2, 0.4 and 0.6 to study the effect of the partition on the
laminar natural convection flow in a square cavity. The blockage and thermal effects
of the partition resulted in changes in the temperature and flow fields, but were
mainly limited in the vicinity of the partition. The effect of the partition changed
with the height and location of the partition. When the partition was attached to the
heated top wall, a recirculating flow was formed between the partition and the heated
vertical wall. For a given partition height, the structure of this recirculating flow was
dependent on the partition location and θT. A thermal boundary layer developed
along the rear surface of the partition due to the thermal effect of the partition. The
ambient temperature outside the boundary layer and Nu near the corner region were
affected by the partition height due to the changes in the recirculating flow and the
rear surface of the partition.</p> / Thesis / Doctor of Philosophy (PhD)
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Experimental and Numerical Analysis of Hydroformed Tubular Materials for Superconducting Radio Frequency (SRF) CavitiesKim, Hyun Sung 31 August 2016 (has links)
No description available.
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Modeling of Flow Mode-Transition of Natural Convection in Inclined CavitiesWang, Hongda 09 1900 (has links)
Steady two-dimensional natural convection in air-filled, regular and irregular inclined enclosures has been investigated numerically. The effect of various configurations of bidirectional temperature gradients on mode transition of thermal convection inside the cavity has been investigated. Numerical treatment of temperature discontinuity at the comer points of the cavity and its effect on the calculated Nusselt number has been discussed. Rayleigh numbers range between 103 and 104, aspect ratio (width/height) =1,2,4, and angle of inclination in the range between 0 and 90°. While the cavity bottom and top walls were kept at constant temperatures at Th (heated) and at Tc (cooled), respectively, thermal conditions of end walls were varied. In addition to the base case of insulated end walls, seven different configurations of thermal conditions of the two side walls have been studied. Results show that numerically predicted heat transfer rates strongly depend on the numerical treatment of temperature discontinuities at cavity comer points. Results also indicate that thermal conditions of cavity end walls have a significant effect on mode-transition of thermal convection flows; and hence, on heat transfer effectiveness inside the cavity, and on the Hysteresis phenomenon occurred as the cavity angle of inclination varied from zero (horizontal position) to 90 ° (vertical position) and back to zero. The effect of curved bottom is carried out by replacing flat bottom of the cavity with a curved one. Only insulated end walls were discussed in curved case. Results indicated that heat transfer rate and mode transition are strongly dependent on the height of curvature of the bottom wall, which offers more flexibility in controlling flow mode-transition, and hence, effectiveness of heat transfer inside the cavity. / Thesis / Master of Applied Science (MASc)
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The fauna of tree-holes in relation to environmental factorsKitching, Roger Laurence January 1969 (has links)
No description available.
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The optical study of semiconductor quantum microcavitiesArmitage, Adam January 1998 (has links)
No description available.
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