By Benjamin Vermette 

Third time’s a charm: SpaceX landed their rocket! 

After two failed attempts in January and April 2015, the private company SpaceX finally succeeded in landing their… rocket!

Owned by young billionaire Elon Musk, SpaceX rewrote history books on December 21st as they performed a vertical landing of the first stage of their Falcon 9 rocket back at Cape Canaveral, about 10 minutes after it launched.

The second stage of the rocket (the upper part) carried 11 small communication satellites while the first stage (the bottom part) had 9 SpaceX Merlin engines to power them into orbit.

Once the first stage burn was over, the two stages cleanly separated while the bottom one turned around and started an engine burn to slow down as it was headed to the landing zone in Florida.

As it was trying to steady itself, the first stage deployed four landing struts and touched down safely at precisely 9 minutes 44 seconds after it departed: 

It may seem an easy thing to do, but don’t fool yourself: nothing in space is easy. As Miles O’Brien, science reporter, pointed out in an interview with CNN, “this is like balancing a broom pole on your nose, and only harder, lots harder.”

Still not convinced? Look at this video Musk took after the landing, it shows how huge the rocket is!

Minutes after the rocket landing, the second stage completed the mission: it successfully deployed the 11 communication satellites. What a wonderful comeback for SpaceX as their last mission on June 28 was a complete disaster: the rocket blew up in the sky and all the cargo was lost (Read my previous column for more details on this). 

Such a performance is a major breakthrough: it reduces launch cost while creating a 100% reusable rocket!

"Falcon 9 back in the hangar at Cape Canaveral." Musk said on Instagram on January 1st. "No damage found, ready to fire again."

We need private companies like SpaceX to lead the way in attempting risky and futuristic feats such as a vertical rocket landing: only then will modern spaceflight evolve.

Congrats SpaceX on such a milestone!

Einstein’s theory of General Relativity turns 100… Relative to Earth

“Time travel used to be thought of as just science fiction, but Einstein's General theory of Relativity allows for the possibility that we could warp space-time so much that you could go off in a rocket and return before you set out.” - Professor Stephen Hawking

Basically everything you know about gravity is wrong – unless you’re a physicist, in which case I’m sorry for the offense.

In 1905, shortly after working as a patent clerk, the young Albert Einstein proposed a new theory: the Special theory of Relativity, or STR (not to confound with the General theory of Relativity).

Briefly, it proposes a connection between space and time, which translates into a breathtaking phenomenon. For instance, according to STR, the faster you go, the slower time passes (note that this was tested multiple times, and turns out to be true). Imagine: you’re in a spaceship, going 50% the speed of light (about 150 000 km/s) and you decide to go around our solar system for a while. After a certain amount of time (relative to you) you decide to come back on Earth for a drink (because you’re feeling it). However, when you come back, it is possible, depending on the amount of time you just spent at high speeds, that humanity is gone, or that the Earth is gone, or just that your grandkids are older than you. That’s simple STR fun facts.

However, gravity didn’t seem to apply to Einstein’s STR, so he decided to create a whole new theory which completely changed the world’s way of seeing space and time. 10 years later, on November 25th, 1915, Einstein published his final paper on his theory of General Relativity, just before lecturing his colleagues at the prestigious Prussian Academy of Sciences in Berlin.

The major breakthrough of General Relativity from a popular standpoint is that it defines gravity. We know Isaac Newton discovered, in the XVIIth century, a mysterious force: gravity. He wrote a couple mathematical laws describing this force (which is still used today) without further knowing what it was.

Einstein showed – I recall, 100 years ago – that space is something, like a fabric, and it can get bent, distorted, ripped apart, or compressed, by matter. And the bending of space is what causes gravity.

So forget everything you heard in high school (maybe not): two masses don’t attract each other. Masses bend space around them; think of it like a bowling ball on a mattress. What happens if you slide a golf ball next to the bowling ball on your mattress? It curves. Its path will change, like the Moon around the Earth, like the Earth around the Sun, and so on. Did its path bend because of a force of attraction between the two? No! It followed its natural motion.

You don’t stand on the Earth because you are attracted by it, you are just falling, and following your natural motion.  The Earth merely stops you from falling.

Anyway, just try to generally see it that way: matter tells space how to bend, and space tells matter how to move.

In sum, Einstein showed space can warp, causing gravity, and he also showed time can warp. So, Einstein’s theory of General Relativity just turned 100 relative to Earth. At another place in space, in may only be 1 year old!

Everything is… relative!

1st mirror now installed on promising James Webb Space Telescope

With a primary mirror 6 times larger in area than Hubble’s, the James Webb Space Telescope (JWST) will be the biggest and most powerful astronomical observation-object of all times. With its full structure as big as a tennis court, it will be placed between the Earth and the Sun at a Lagrange point, 1.5 million km from Earth, as Hubble orbits at about 250 km of altitude. Currently in the process of construction, it has a ticket to launch in 2018. 

Recently, towards the end of November, NASA successfully installed the first of 18 mirrors on the JWST, initiating a major construction breakthrough.

The engineers of NASA’s Goddard Space Flight Center in Maryland strategically used a robot arm to install a 1.3-meter hexagonal-shaped gold-plated mirror. Along with another 17 of its kind, this mirror will form what is called the primary mirror, which is 6.5-meter long (for comparison, this is 2.7 times larger than Hubble’s one). The full assembly of these mirrors should be completed towards the beginning of 2016. 

“After a tremendous amount of work by an incredibly dedicated team across the country, it is very exciting to start the primary mirror segment installation process," said Lee Feinberg, JWST optical telescope element manager at Goddard. "This starts the final assembly phase of the telescope."

The gold coating on the mirrors were chosen for its capacities to reflect infrared light, as the mirrors are primarily made of lightweight beryllium, chosen for its usefulness in extremely low temperatures.

The JWST is a major technological achievement, and will surely answer big cosmological questions, such as: how did the universe begin and evolve, how will it end (or will it end?), how did our solar system form and will help astronomers and scientists on the search for extraterrestrial life.

We, Canadians, can be proud: the Canadian Space Agency works with NASA and the international science community to make this project reality! 

Japanese spacecraft finally enters Venus’ orbit 5 years after its 1st try

What a show of interplanetary mechanics-application and perseverance.

The Japanese Aerospace Exploration Agency (JAXA) finally succeeded – after a first try five years ago to the day, in December 2010 – to place its Akatsuki spacecraft in Venus’ orbit.

Back then, on its initial try on December 6 2010, Akatsuki – which means “Dawn” – brushed past Venus at high speeds on what was supposed to be a lovely orbital catch. JAXA’s engineers later determined that this failure was due to the probe’s main engine incapacity to generate power in reason of a cracked valve in the propulsion system.

The following five years was for Akatsuki somehow a bright “dark” period. In orbit around the Sun, it was depressively waiting for the mission’s officials to make a decision about its fate. But as you may have guessed, the team didn’t give up: they gave Akatsuki a second opportunity to complete its tasks.

On December 6, 2015 this time, the spacecraft relied on the firing of its minor thrusters to escape the Sun’s orbit and head towards the cloud-covered planet. And it worked! Even if the probe isn’t as close as previously planned to Earth’s sister, it will still be able to fulfill its scientific objectives – as long as it stays in good shape – such as studying the planet’s greenhouse gas-filled and toxic atmosphere.

It’s like being on a commercial flight and trying to land a second time 5 years after the first attempt!