Lighthouses have helped safely guide mariners
for centuries. As space explorers consider
traveling to destinations like the moon and
beyond, future interstellar travelers may
one day receive similar guidance from NASA’s
new pulsar-based navigation system. Which
is what exactly?
When a star that’s roughly one and half
times the mass of the sun explodes in a supernova,
its core collapses into a smaller, dense object
called a neutron star. Neutron stars spin
rapidly, emitting visible light and high energy
radiation like X-rays and gamma rays. These
energetic powerhouses are known as pulsars,
and so far scientists have found over 2000
in the known universe.
The radiation emitted from a pulsar’s magnetic
pole doesn’t align with its spin axis, creating
a beam that sweeps across the dark sky like
a cosmic lighthouse. When this beam crosses
our line-of-sight, it appears as a pulse.
The ones that rotate the fastest are called
millisecond pulsars, and their beams whip
around hundreds of times per second. Imagine
an object with a mass more than the sun, spinning
several times faster than a Formula One engine!
Historically, millisecond pulsars have been
exceptionally useful thanks to their incredible
precision. Since their discovery, their timely
blink has helped astronomers confirm the Theory
of Relativity, detect the earliest exoplanets,
and accurately measure cosmic distances.
As NASA sets its sights on distant planets,
spacefaring explorers will need a way of orienting
themselves in space. Here on Earth, we use
the satellite-based GPS. These satellites
carry atomic clocks that provide extremely
accurate time, which gets used by your phone
or car to help calculate your position. GPS
works fine if you’re on Earth or close to
it, but once you go beyond its range, the
signal weakens till... you’re lost. You
can’t just pull over and ask for directions
to the nearest planet.
Since the 60s, NASA has primarily used the
Deep Space Network to track missions beyond
Earth’s orbit. It’s made up of three ground
stations located in: Australia, U.S.’ California,
and Spain. They’re approximately 120 degrees
apart, and they beam up radio waves to a spacecraft
and log details as the signals return. Navigational
data is calculated on Earth and sent back,
helping ground control keep missions on the
right path.
But if that radio link with Earth is lost,
a spacecraft can find itself adrift. Some
manned missions, like the Apollo program,
have even carried an antiquated sextant in
case this happened, so they could fix their
position against the stars, like old timey
mariners lost at sea.
A better solution would be if a spacecraft
could navigate independently… no ground
control required. This is where our friends
the pulsars come in. Millisecond pulsars spin
with such amazing regularity that they're
among the most reliable clocks in the universe.
With their predictable pulsations, they provide
high-precision timing just like GPS satellites
do. Accuracy is so important because in spaceflight,
it’s the difference between landing on a
planet...or crashing on it. And this technique
of X-ray pulsar navigation is actually showing
promise on the International Space Station.
Mounted on the station's exterior is a piece
of equipment called Neutron star Interior
Composition Explorer or NICER. It packs an
array of 56 X-ray telescopes into an area
the size of a washing machine. Its purpose
is to study neutron stars, including the rapidly
blinking pulsars. NICER scans the sky detecting
and timestamping the arrival of X-ray photons
within 100 nanoseconds of accuracy, or better.
A software embedded into NICER, cleverly named
SEXTANT or Station Explorer for X-ray Timing
and Navigation Technology, then analyzes that
data, comparing it with an almanac of known
pulsars, looking for their unique fingerprint.
In November 2017, NASA used four different
millisecond pulsar targets to successfully
demonstrate that SEXTANT could determine the
position of the ISS within 5 to 16 kilometers
of its actual position.
Scientists are hoping to get more than just
navigational help from NICER. NASA currently
uses radio frequencies to talk to and locate
the various rovers and probes scattered across
our solar system as well as manned missions
closer to home.
NASA is now considering testing SEXTANT for
use on the Lunar Gateway, a mini space station
meant to aid long-term missions on the lunar
surface, and eventually, Mars. Who knows,
in the future, if space explorers are lost
in a sea of stars, they can use cosmic pulsars
as beacons to guide themselves home.
By the way, if you scooped-up a teaspoon of
a pulsar, it would weigh as much as Mount
Everest...and you would need a very strong spoon.
Pulsars are pretty amazing, so if you want
to know more, like how they are leading to
new insights in general relativity, check
out this video here. Let us know what else
you’d like us to cover in the comments below
and make sure to subscribe to Seeker. Thanks
for watching!
