My first love was for the night sky.
Love is complicated.
You're looking at a fly-through of the
Hubble Space Telescope Ultra-Deep Field,
one of the most distant images
of our universe ever observed.
Everything you see here is a galaxy,
comprised of billions of stars each.
And the the farthest galaxy is
a trillion, trillion kilometers away.
As an astrophysicist, I have
the awesome privilege of studying
some of the most exotic objects
in our universe.
The objects that have captivated me
from first crush, throughout my career
are supermassive,
hyperactive blackholes.
Weighing 1 to 10 billion times
the mass of our own sun,
these galactic black holes
are devouring material,
at a rate of upwards of
a thousand times more
than your "average"
supermassive black hole.
(Laughter)
These two characteristics,
with a few others, make them quasars.
At the same time, the objects I study
are producing some of the most
powerful particle streams
ever observed.
These narrow streams, called jets,
are moving at 99.99 percent
of the speed of light,
and are pointed directly at the earth.
These jetted, earth-pointed, hyperactive
and supermassive black holes
are called blazars, or blazing quasars.
What makes blazars so special
is that they're some of the universe's
most efficient particle accelerators,
transporting incredible amounts
of energy throughout a galaxy.
Here, I'm showing an
artist's conception of a blazar.
The dinner plate by which
the material falls unto the black hole
is called the accretion disc,
shown here in blue.
Some of that material is sling-shotted
around the blackhole
and accelerated to insanely high speeds
in the jet, shown here in white.
Although the blazar system is rare,
the process by which nature
pulls the material via a disk,
and then flings some of it out via a jet,
is more common.
We'll eventually zoom out of
the blazar system
to show its approximate relationship
to the larger galactic context.
Beyond the cosmic accounting
of what goes in to what goes out,
one of the hot topics in
blazar astrophysics right now
is where the highest energy
jet emission comes from.
In this image, I'm interested in where
in where this white blob forms
and if, as a result, there's any
relationship between the jet
and the accretion disc material.
Clear answers to this question
were almost completely
inaccessible until 2008,
when NASA launched a new telescope
that better detects gamma ray light,
that is, light with energies
a million times higher
than your standard x-ray scan.
I simultaneously compare variations
between the gamma-ray light data
and the visible light data from
day-to-day and year-to-year,
to better localize these gamma-ray blobs.
My research shows that in some instances,
these blobs form much closer
to the black hole
than we initially thought.
As we more confidentially localize
where these gamma ray
blobs are forming,
we can better understand how jets
are being accelerated,
and ultimately reveal
the dynamic processes
by which some of the most
fascinating objects
in our universe are formed.
This all started as a love story.
And it still is.
This love transformed me from
a curious, stargazing young girl,
to a professional astrophysicist,
hot on the heels of celestial discovery.
Who knew that chasing after the universe
would ground me so deeply
to my mission here on earth.
Then again, when do we ever know
where love's first flutter
will truly take us.
Thank you.
(Applause)