My sister’s dog

My sister came through town and brought her dog.
I took a bunch of glamor shots of him. He’s so cute it’s ridiculous, so I thought you all might appreciate staring at his adorable, gigantic, pit bull head.


Also, a few of the image sequences yielded cute GIFs. Which I’ve included below and uploaded to giphy (


2 GIFs

Hey all,

It has been a week, to be sure.
I chose to edit some with my minuscule amount of free time instead of writing a new short. So here are the 2 GIFs I made a while back and have been holding in reserve.


I hope the above appears whenever someone mentions “Lobster Bisque.”


And the applicability of this one speaks for itself, me thinks.

Have a great week, everyone!


Stop Motion GIFs

I decided to play with stop motion this week and made a few GIFs that I thought would be fun to share.



This was my first one. Aside from the obvious white balance issues, I still think it’s my favorite.


There’s an important lesson buried in this one: go for the head first.


This little, climbing robot GIF, I thought, was off to a good start, but then my camera ran out of batteries. :/


I resized the images, added text, compiled the GIFs using a python script that I wrote. The script is pretty messy, but if anyone is interested, I can clean it up and share it. Let me know if you would like to see it (you’ll need Python installed and the images2gif and PIL packages).

My Thesis

You’ve all had to listen to me go on and on about my thesis,¬†QUARK-HADRON COMPOSITION OF ROTATING NEUTRON STARS. Now, at long last, it has been posted to the San Diego State University library page.

You can find the thesis here:

If you just wanted to see the pretty plots and GIFs, you can find them here:


So, what does this mean?

A neutron star is the corpse of a star that had an original mass of about 8 to 25 times the mass of our sun. They are incredibly dense (about 10^14 grams per cubic cm), having a mass of about 1 to 2 times the mass of the sun (they lost a bunch during their supernova) and a diameter of only about 10 km.
The behavior of matter at high density is poorly understood. Many models exist for exploring this (called nuclear equations of state) but matter of such high densities isn’t readily available for direct comparison. One place that it’s expected to exist, as previously mentioned, is inside neutron stars. The basic idea here is to take different models for the nuclear equation of state and use them to determine what each model predicts the particle composition (what particles it’s made of) of neutron stars to be, in hopes that this will lead to some sort of observable quantity for neutron stars that is dependent on which model was used, thus allowing us to narrow down which models are more likely to be correct.
In this thesis we determined the compositions of neutron stars for each of several nuclear equations of state, and looked at how that composition is expected to change as the neutron star’s rotation slows over time (as it begins to spin less quickly, the shape will change, and so will the density, thus leading to changes in the composition).