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CATEGORIES:College of Engineering,Graduate Studies,Lectures and Seminars,Th
 esis/Dissertations
DESCRIPTION:Abstract:       Self-gravity plays a crucial role in the a
 strophysics of type Ia supernovae (SNe Ia). Understanding the extreme phys
 ics of these events demands accurate hydrodynamical simulations enabled by
  multiphysics frameworks such as FLASH. In these simulations, direct pairw
 ise gravitational interactions scale as N2, which can quickly become expan
 sive for large scale simulations. To reduce the computational cost, FLASH 
 employs approximation methods, including fast multipole and BHTree solvers
 , where the computational cost scales linearly with the system. Within thi
 s framework, FLASH uses an operator-split approach to couple separately ev
 olved hydrodynamics and gravity at each timestep. My thesis focuses on the
  BHTree solver and quantifies its suitability for SNe Ia applications thro
 ugh targeted verification and performance studies. I evaluate force accura
 cy and conservation behaviour across test problems, and compare BHTree aga
 inst other gravity solvers to characterize the relevant accuracy-cost trad
 eoff for production simulations. The resulting methodology is intended to 
 guide solver selection and simulation setup for large self-gravitating cal
 culations, and to support the broader goal of reliable, scalable computati
 onal tools for stellar explosions and related astrophysical fluid systems.
  Advisor: Dr. Robert Fisher, Department of Physics, (Robert.fisher@umassd.
 edu) Committee members:    Dr. Renuka Rajapakse, Department of PhysicsD
 r.  Janyi Wang, Department of Physics Note:  All PHY Graduate Students a
 re encouraged to attend.\nEvent page: /events/cms/tr
 ee-based-gravity-solver-for-3d-hydrodynamical-simulations-of-binary-white-
 dwarfs-merger-type-ia-supernovae.php
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</script><p>Abstract:      </p>\n<p>Se
 lf-gravity plays a crucial role in the astrophysics of type Ia supernovae 
 (SNe Ia). Understanding the extreme physics of these events demands accura
 te hydrodynamical simulations enabled by multiphysics frameworks such as F
 LASH. In these simulations\, direct pairwise gravitational interactions sc
 ale as N2\, which can quickly become expansive for large scale simulations
 . To reduce the computational cost\, FLASH employs approximation methods\,
  including fast multipole and BHTree solvers\, where the computational cos
 t scales linearly with the system. Within this framework\, FLASH uses an o
 perator-split approach to couple separately evolved hydrodynamics and grav
 ity at each timestep.</p>\n<p>My thesis focuses on the BHTree solver and q
 uantifies its suitability for SNe Ia applications through targeted verific
 ation and performance studies. I evaluate force accuracy and conservation 
 behaviour across test problems\, and compare BHTree against other gravity 
 solvers to characterize the relevant accuracy-cost tradeoff for production
  simulations. The resulting methodology is intended to guide solver select
 ion and simulation setup for large self-gravitating calculations\, and to 
 support the broader goal of reliable\, scalable computational tools for st
 ellar explosions and related astrophysical fluid systems.</p>\n<p>Advisor:
  <br />Dr. Robert Fisher\, Department of Physics\, (Robert.fisher@umassd.e
 du)</p>\n<p>Committee members:    <br />Dr. Renuka Rajapakse\, Departme
 nt of Physics<br />Dr.  Janyi Wang\, Department of Physics</p>\n<p>Note: 
  All PHY Graduate Students are encouraged to attend.</p><p>Event page: <a
  href="/events/cms/tree-based-gravity-solver-for-3d-
 hydrodynamical-simulations-of-binary-white-dwarfs-merger-type-ia-supernova
 e.php">/events/cms/tree-based-gravity-solver-for-3d-
 hydrodynamical-simulations-of-binary-white-dwarfs-merger-type-ia-supernova
 e.php</a></a></p></body></html>
DTSTAMP:20260423T154846
DTSTART;TZID=America/New_York:20260507T093000
DTEND;TZID=America/New_York:20260507T114500
LOCATION:SENG 201
SUMMARY;LANGUAGE=en-us:Tree based gravity solver for 3D hydrodynamical simu
 lations of binary white dwarfs merger type Ia supernovae
UID:5e9c816630542724c6c3dca23c43fd37@www.umassd.edu
END:VEVENT
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