Media coverage of the National Hockey League (NHL) has brought public attention to many accounts of physical and sexual violence, hazing, and illicit drug use by players and coaches over the past 20 years. My research investigates the institutional mechanisms the NHL, its teams, and the players union use in response to cases of criminal behavior by their athletes. I ask how consequences for player criminality vary by type of crime, status of player, and player network. I compiled a dataset of all incidents covered in the news or social media between 2009 and the present, and then identified the response type through qualitative coding and comparison. Given prior theorizations of men’s collegiate athletics as crime-facilitative environments based on low punishment risk and high temptation to participate in criminal deviance, I expect to find that fine-related punishments are levied more frequently against high-status NHL players and high level player networks than are playing-time related penalties, protecting their ability to continue contributing to a franchise’s game performance. I also predict violent crimes will more frequently include playing-time related penalties, with League Commissioner approval more consistently mandated. I anticipate the team sub-organization to most frequently levy punishments for player criminality. This research introduces a more comprehensive examination of NHL player criminality, extending beyond existing approaches of case-based analysis. Importantly, this allows for future comparison to leagues such as the National Football League and its handling of player criminality over time. More broadly, I clarify the consistency with which deterrence measures are employed by the organization, contributing to the body of literature analyzing private organizations and their governing power over employees.

This project evaluates the flight mechanics of a class of Autonomous Underwater Vehicles (AUVs) known as gliders using digital simulation via Python code. When used in the real world, these gliders perform vertical profiling of important marine quantities like temperature and salinity. These are then used by oceanographers and others to help them gain a deeper understanding of the ocean environment. The overall goal of the project is to optimize the trajectories of a fleet of vehicles to minimize energy consumption while maximizing uniformity of ocean coverage. Using specific engineering data on real world glider flight as well as public domain ocean environmental models, I have coded a custom Python application with guidance from my mentor at the Applied Physics Lab. We chose a computer simulation of glider flight so that multiple variables could be easily manipulated without the risk of losing a valuable glider if certain parameters are not favorable. This simulation produces data that describes the vehicles’ locations and energy states over time. The software is structured such that important parameters are specified in an easily-modified configuration file. The parameters I alter include geographic area, the number of gliders, the maximum flight depth, the vehicle’s available buoyancy range, and the glide angle. Then, using the data that the simulation produces, I analyze variations in energy consumption, uniformity of coverage, and the time required for each glider to reach their destination. The oceans, which cover about 70% of the planet’s surface, have a huge impact on the climate and health of the Earth as a whole. The result of this analysis is useful to real-world AUV operations by helping determine how to program them to fly more efficiently and maximize their utility as scientific instruments.

Skin is a densely innervated sensory organ that protects us every day from environmental trauma. As a barrier organ, skin is susceptible to frequent damage that must be promptly and properly healed to prevent infection and restore sensory function. Our lab uses adult zebrafish as a model to study skin injury and repair. Adult zebrafish skin is similar in composition to human skin and transparent, lending itself to high-resolution microscopy. Previous experiments in our lab revealed that dynamic, skin-resident immune cells known as Langerhans cells (LCs) rapidly engulf cellular and axonal debris after injury in the zebrafish skin. Calcium signaling regulates phagocytosis and cell motility in other immune cells, but the role of calcium signaling in LCs is unstudied. Through skin explant assays, various injury paradigms, and confocal fluorescence microscopy, I have established a model for monitoring calcium signaling in LCs. I found that LCs exhibit rapid, transient calcium flashes under homeostatic conditions. However, upon engulfment of large cellular debris generated by precise laser-ablation of skin cells, LCs exhibit an atypical sustained calcium signal lasting an hour on average. To test the requirement of calcium during engulfment by LCs, I treated skin with the drug Thapsigargin to perturb calcium flux. I confirmed that Thapsigargin increases intracellular calcium in LCs and keeps intracellular calcium concentrations elevated for hours after drug addition. During Thapsigargin treatment, I showed that LCs formed phagocytic cups around cellular debris but engulfed fewer laser-ablated corpses compared to controls. Thapsigargin-treated LCs also experienced normal migration to a wound site. My results indicate that calcium flux regulates LC engulfment of large debris, but not through migration. Identifying the molecular mechanisms underlying LC motility and debris removal is ultimately relevant to understanding skin repair and disease states in which the wound healing response is attenuated, such as in chronic wounds.

Smartphone use among adolescents has dramatically increased in the past decade, with adolescents allocating more time inside on their screens and less time outside in nature. Given these shifts in behaviors, there has been a rise in concerns about the impact of smartphones on adolescents’ mental health. Studies on nature exposure have found that spending time in nature promotes human well-being; however, a limited body of research exists exploring how smartphone use impacts our ability to experience these physical and psychological benefits of nature exposure. To address this gap in the literature, we conducted a between-subjects experiment with college students at the University of Washington (N ~ 40) randomly allocated to one of two conditions to spend 20 minutes in nature: a smartphone condition and a no-smartphone condition. Participants self-reported on positive and negative affect and rumination before and after their experience in nature. After completing these scales, participants reported on their experience of Presence, a state of being in which the mind is highly aware but without active thought, by self-reporting on a recently validated 14-point scale and writing about it for further analysis using an interaction pattern approach. I anticipated that participants who feel more attached to their smartphones spend more time using them in nature and, in turn, are less likely to experience the emotional benefits of nature. If the findings reflect this, future research should explore how smartphones impact adolescents’ mental health and the extent to which smartphone-free time spent outside in nature can improve their well-being.