Title Information
Title
Ejecta Evolution and Dynamics from Hypervelocity Impacts: Time-Resolved Experimental Studies and Applications to Planetary Cratering
Name: Personal
Name Part
Hermalyn, Brendan
Role
Role Term: Text
creator
Origin Information
Copyright Date
2011
Physical Description
Extent
xiv, 179 p.
digitalOrigin
born digital
Note
Thesis (Ph.D. -- Brown University (2011)
Name: Personal
Name Part
Schultz, Peter
Role
Role Term: Text
Director
Name: Personal
Name Part
Forsyth, Donald
Role
Role Term: Text
Reader
Name: Personal
Name Part
Mustard, John
Role
Role Term: Text
Reader
Name: Personal
Name Part
Parmentier, Edgar
Role
Role Term: Text
Reader
Name: Personal
Name Part
Crawford, David
Role
Role Term: Text
Reader
Name: Corporate
Name Part
Brown University. Geological Sciences
Role
Role Term: Text
sponsor
Genre (aat)
theses
Abstract
The ejection of mass during an impact event is a shock-driven process that shapes the distribution of materials on planetary surfaces. Ejection velocities dictate the ballistic emplacement and appearance of ejecta patterns. Prior studies of vertical impacts into granular targets provide canonical ejecta-velocity relationships; however, these do not hold during early stages of growth when velocities are highest. Virtually all planetary impacts occur at oblique angles, which cause significant deviations from vertical impacts. Additionally, temporal (rather than spatial) descriptions of velocity are required for interpretation of mission data. To date, no simple analytical ejection velocity model incorporating impactor obliquity has been proposed. This dissertation presents new temporally-resolved studies of the early- to main-stage ejecta velocity distribution from impact experiments performed at the NASA Ames Vertical Gun Range. First, the role of projectile density in vertical impacts was examined using a noninvasive high-speed imaging technique to measure ejecta velocity as a function of both time and launch position. The temporal resolution of this technique allows measurement of ejecta an order of magnitude faster (and earlier) than captured in previous studies, and reveals early-time, high-speed deviations that reflect initial conditions and material flow-field inside the transient crater. In chapter two, these results were applied to the LCROSS mission, which used an empty rocket booster as a kinetic impactor to excavate material from permanent shadow on the moon. The sunlight horizon of ~830 meters required ejection velocities corresponding to early stages of growth. The third chapter presents the first time-resolved experimental studies of ejecta velocities for oblique impacts, captured by a novel three-dimensional particle tracking velocimetry implementation developed for this application. These data permit an analytical description of ejecta velocities from oblique impacts. Lastly, chapter four employs this velocity distribution in an ejecta propagation model to reconstruct ejecta pattern emplacement. Measured obliquity effects include velocity, existence and closure of the uprange zone of avoidance, and flow-field center migration. These parameters represent a first step toward parametric investigation of the factors controlling uprange ejecta patterns and non-radial emplacement on planetary surfaces.
Subject
Topic
impact cratering
Subject
Topic
ejecta velocity
Subject
Topic
oblique impacts
Subject
Topic
hypervelocity impacts
Subject (FAST) (authorityURI="http://id.worldcat.org/fast", valueURI="http://id.worldcat.org/fast/1894897")
Topic
Particle tracking velocimetry
Record Information
Record Content Source (marcorg)
RPB
Record Creation Date (encoding="iso8601")
20111003
Language
Language Term: Code (ISO639-2B)
eng
Language Term: Text
English
Identifier: DOI
10.7301/Z0WM1BPT
Access Condition: rights statement (href="http://rightsstatements.org/vocab/InC/1.0/")
In Copyright
Access Condition: restriction on access
Collection is open for research.
Type of Resource (primo)
dissertations