The Antimatter Plot Thickens…

30 04 2013

I realize it’s been egregiously silent here at the Astrowright blog for some time.  Apparently, I am not immune to the same disappointing (as a reader) dry spells experienced in/by so many other blogs I’ve followed during the years. 

(With grad school, teaching at CSN, my day-job working for DOE, a side-business or two in flux, moonlighting the occasional and surreal TV project, and with a 1&1/2-year-old at home – let’s just say I’ve come to terms with the reality that I’m not a juggling Jedi yet.)

Excuses aside, however, I wanted to take a moment to relay a devastatingly exciting potential discovery, which itself was prompted by a pleasant surprise…

CERN's ALPHA experiment.  (Credit: CERN)

CERN’s ALPHA experiment – our Anti-Virgil into Dante’s Antimatter Inferno? (Credit: CERN)

Antimatter in Focus

AntimatterSymbolOnlyAs reported on and, which prominently featured the antimatter symbol I created a couple of years back (i.e., the pleasant surprise – thanks, Keith!), we may be one giant leap closer to figuring out antimatter – and with it, peer a little farther into the mysterious underpinnings of the Fundamental Forces of Nature.

In an article titled, “Does Antimatter Fall Up or Down?” Keith Cowing reports that researchers at CERN’s Alpha Experiment recently published in Nature Communications their tantalizing antimatter research progress.  

Specifically, these CERN specialists have identified a process for finally determining whether or not gravity acts upon antimatter the same way it does upon “ordinary” matter, even if they haven’t answered the question quite yet.  (See Keith’s article for more details on their experiment, what it means, and where it’s going.)

Down the Anti-Rabbit Hole

So, why do we or should we care about figuring out what antimatter really is and how the universe treats it?  Well, quite simply, it has the possibility of providing new solutions to many current problems in physics. 

Dark EnergyDark Matter, and questions about early Cosmic Inflation all essentially deal with versions of the same issue: There are apparent problems with the amount of force we see in the universe versus how much we should expect. 

Perhaps a shift in our understanding of fundamental forces, like gravity, will shed new light.

This is to say nothing of the mystery concerning why the universe appears to be all matter and generally no antimatter.  According to physics as we understand it, there’s no reason for the bias.  (Why not areas of high concentrations of antimatter and others of normal matter?)

Why did matter win?

And to make matters yet more interesting, the late, great Dr. Richard Feynman (and others) have described antimatter as being inditinguishable from (or perhaps actually being!) ordinary matter moving backwards through time.  While few physicists believe this is actually the case, it certainly bends neurons considering that it remains a physical possibility*.

(*I should note that this idea of antiparticles moving “backwards” in time, in order to be true, requires a reconstruction of what we mean by “time.”  This is because antiparticles don’t blip out of existence as they move to the “past” with respect to us as we, presumably, continue to move into the “future.”  Instead, we remain with the antiparticles in the same measurable “now” in the universe…)

Antimatter – A Guiding Star

Keep an eye on this one, folks.  It could very well be that the study of antimatter provides us the wedge we need to evolve beyond peering through the keyhole at the universe and instead throw open the door.

Optimistic?  Admittedly. 

However, we’re due for our big 21st Century paradigm shift in the sciences.  What with the recent 100 Year Starship Symposium hinting at what the future has to offer us (along with humanity’s expanding view of our galactic neighborhood and our desire to get out there and engage it), it’s high time we get on inventing that superluminal propulsion system to Alpha Centauri, already.

I’m not getting any younger.


Ultimately, Time Travel is essential for Space Travel

17 04 2011

Long-time readers may note that this blog bounces (veers?) between space-related content and time/temporal physics-related content.  Today, aside from admitting that (not surprisingly) the two topics are primary passions of mine, I’ll tell you why they’re related, and intimately so.

It’s all Einstein’s fault.

After an interstellar trip, a faulty suspended animation chamber reduces an astronaut to an ancient corpse. (From Planet of the Apes; Credit: 20th Century Fox)

Put very simply, according to Relativity: When dealing with events in the universe, it is impossible to separate the distance of space from the passage of time.

This is why astrophysicists and cosmologists speak of actions in the universe occurring and affecting “space-time.”  (Hence the “space-time continuum” that makes such a frequent appearance in sci-fi technobabble.)

What does this mean for us?  Well, in day-to-day experience, not much more than the odd reality that the moon we see is 1 second old.  Similarly, the sun we see is lagging 8 minutes behind us in time.

Why?  Well, it takes the light that bounces off of the surface of the Moon 1 second to cross the 230,000-mile distance between the Earth and Moon to strike the retina of your eye, and it takes 8 minutes for the light that leaves the sun to cross the 93-million mile orbital void to get to Earth and reach your eye.  As a result, we see the Moon and Sun as they appeared when the light left them, not when the light reaches us.

The same can be said of distant stars.  The farther away a star is, the older it is. (Even if it’s 200,000 light years away – then you’re seeing it the way it looked 200,000 years ago.)

So, quizzically, yes – this means that universe we see is actually a horrible garble of apparent objects from intermixed times.  Fortunately for us,  compared to the incredible speed of light, we’re close enough (distance) to everything we need to experience, (e.g., our limbs, food, loved ones, walls, etc.,) so that this time lag is unnoticeable.

But when we start peering out into the rest of the cosmos, this distortion really matters.  Many of the stars we’re studying may have already exploded… but if they exploded a few years ago, we won’t know it until light from the explosion reaches us, which could take millions of years if the star is far away.

Now, let’s take our time-distance thought exercises a step farther and ask what happens if we score the holy grail of the Search for Extraterrestrial Intelligence.  What if, for the sake of argument, we receive and translate a friendly message from an incredibly advanced race of aliens?  And what if, by fortuitous happenstance, they (hoping to aid other, younger life-forms) offer unlimited knowledge to any beings that can meet them on their world, face-to-face?  Well, the offer doesn’t do us more than a hill of beans of good if it takes us 200 years for a multi-generational craft to get there, only to find that the benevolent race has gone extinct due to a problem with their parent star.  We want to reach them as soon as we translate the message.

We want to separate the distance of space from the passage of time.

So, if we can conceptually and technologically conquer time travel, we will have in essence conquered space travel.  If one can manipulate the passage of time, then the time taken to cross the distance of space with any type of propulsion system becomes an almost trivial tally – little more significant than the miles-per-gallon of a modern automobile.

Conventional propulsion systems will get us around in space for the foreseeable future, and more exotic systems will likely take us to the nearest stars.  However, I believe it will be the mastery of time that will transform our race from provincial planet-hoppers to truly savvy, galaxy-trotting, cosmic-colonial game-changers.

Something to think about.

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