What Has the James Webb Space Telescope Been Up To?

PVL MSc student Madeline Walters has been following the launch and deployment of the James Webb Space Telescope with bated breath. This observatory will be a boon not only to the astronomical community, but also to the planetary science community. Above: the telescope's alignment evaluation image catches not only the target star, but myriad faint galaxies in the background.

by Madeline Walters

Since my last post about the James Webb Space Telescope (JWST), the telescope has reached its observing point and made some initial observations. The Webb is currently in orbit around L2, the second sun-Earth Lagrange point which is a gravitationally stable point about 1.5 million kilometers away from us. Since its launch, the spacecraft has gone through a few metamorphoses in preparation for its eventual observations. From testing a key antenna, to deploying its sunshield, each movement and maneuver has been integral to the telescope’s success. After successfully deploying the structure that binds the Webb’s two halves together, there was enough room to begin unfurling the massive sunshield that protects the telescope from harsh radiation. 

Soon after the sunshield was fully unfolded, the Webb deployed its two sunshield mid-booms, which stretched the sunshield out to its full length. This process requires the membranes to stretch to their proper tension, taking up to two days to tighten the sunshield. "As photons of sunlight hit the large sunshield surface, they will exert pressure on the sunshield, and if not properly balanced, this solar pressure would cause rotations of the observatory that must be accommodated by its reaction wheels," writes NASA public affairs specialist Alise Fisher in a blog post on December 30 after the launch. "The aft momentum flap will sail on the pressure of these photons, balancing the sunshield and keeping the observatory steady." It is a lot of very intricate and detailed steps that are necessary for every step of the operation-and for good reason. Every part of the unfolding must work in order to get the Webb to start observing. 

The next crucial part of the mission was the mirrors. On January 5, the telescope deployed its secondary mirror, unfolding a series of booms that hold the mirror out in front of the main mirror. This secondary mirror allows light to be collected and focused into a beam, which is then pushed down through the center of the telescope to a third mirror and other smaller ‘fine-steering’ mirrors which allow light to be properly allocated into the scientific instruments. 

Several days after the secondary mirror was deployed, the main mirror’s side panels were deployed, gearing up for the alignment of all 18 individual mirrors that make up the entire main mirror. And if you don’t think the word ‘mirror’ has been said enough so far - the observatory team spent about ten days working to move each mirror segment out of their preliminary launch alignments, and a lot longer for more precise alignment after that. However, for an instrument that will bring us observations for perhaps up to 20 years, a few months of alignment is worth it. 

Now at its destination for its science mission, the Webb has woken up, turned its instruments on, and has looked out into space to provide us with its first images. Its first telescope alignment evaluation image, made to only focus on the bright star in the center for alignment evaluation, shows background stars and galaxies due to the telescope’s optical sensitivity. Although there are still many months left before the JWST delivers its first full view of the cosmos, the telescope has already gone through an incredible journey made possible by an incredibly patient group of engineers and scientists.

How to tell time on Mars

This week, PhD Candidate Alex Innanen takes on a topic that has challenged planetary scientists and science fiction writers for decades: how do you tell time on a planet that has similarities in its revolutions to the Earth but some pesky differences? Often you'll hear of researchers working on Mars time because the length of its day is so similar to the Earth's. However, the match isn't perfect and can lead to unpleasant physiological effects for some and impractical, though hilarious, fixes. There is no 'Venus Time' or 'Jupiter Time' because their days are so different from ours that it makes no sense to try. But what to do with the extra 39 minutes in the martian day? Or the extra months needed in the martian year? 
(Image above from LMD's "Martian Seasons and Solar Longitude")

by Alex Innanen

One of my favourite things to read about are different calendars and methods of timekeeping. Here on Earth, there are all sorts of different calendars – the Gregorian, which you’re likely familiar with, the Julian calendar, and various lunar, solar or combination calendars. We also keep time within a single day in different ways – the standard now is a 24-hour clock, but at various times people have tried to introduce decimal time, where each day might have ten hours divided into 100 minutes. And this is just on our own planet, where generally the apparent movement of the sun and moon in the sky can give you a sense of when things are occurring.

Unsurprisingly, when you move to different planets things start to get more complicated.

Let’s take Mars for instance. Mars’ day (called a sol) is about 40 minutes longer than an earth day. If you want to use a 24 hour clock you either have to have a sneaky not-quite-an-hour-long 25th hour, or you have to make every hour a bit longer. Which is what the Mars clock that’s used for mission planning does. But wait, does that mean each hour has more than 60 minutes? Well, not really, if you make each minute a bit longer than an earth minute, and you can do that, not by adding extra seconds, but by making each ‘Mars second’ a bit longer than an Earth second. This way you can still use a familiar 24 hour clock.

This doesn’t mean that there’s some intrinsic ‘Martian second’ that is longer than an Earth second. While the second is an SI unit, it’s fairly arbitrary, as is splitting up a day into 24 hours. It’s just what we’re used to a second being.

One thing about round planets is that local noon – when the sun is directly overhead – happens at different times in different places. This is the reason that people on Earth invented time zones, so that local noon could line up – more or less – with noon on the clock. In reality, there’s a fair amount of variation even within a time zone. For example, there is about a 20 minute of difference between local noon in Toronto and Montreal just because of their difference in longitude, even though they use the same time zone.

There are no official time zones on Mars and missions tend to use local mean solar time (LMST), which is based on the average­ length of the sol, split into 24 hours. (There’s also local true solar time [LTST], which is referenced around the local noon, but drifts from 12:00 LMST throughout the year.) There is a generally accepted time standard for Mars, called Airy Mean Time (AMT) or Coordinated Mars Time (MTC) (comparable to Earth’s Greenwich Mean Time (GMT)/Coordinated Universal Time (UTC)) which refer to the mean solar time at Mars’ prime meridian, the crater Airy-1.

The other thing about Mars is its year is almost twice as long as an Earth year, about 668 sols or 687 Earth days. There is some familiarity, though, because Mars, like earth, has seasons! But Mars’ orbit is more eccentric than earth’s – that is to say, the path it travels around the sun is slightly more oblong. Earth also travels in an ellipse, and we do see the effects of not orbiting in a perfect circle on Earth seasons – the northern summer is about 94 days long, while the northern winter is only around 89 days – but not to so great an extent as on Mars. There the northern spring is 194 sols while the northern autumn is only 142 sols, a difference of 52 sols.

So what if we want to know what time of year it is? We can actually use the position of Mars (or any planet) in its orbit to tell this – specifically a parameter called solar longitude, shortened as Ls. We can start the year at a Ls of 0 degrees, the northern vernal equinox (the start of northern spring). Each subsequent season then starts at intervals of 90 degrees for a full 360 degree orbit. This convention is used in most scientific contexts because it can fairly easily tell you if events are occurring at around the same time year after year. It also avoids having to deal with things like leap years or leap seconds, because Mars’ orbit will always be 360 degrees – that’s just how geometry works.

All of this is what’s used currently to orient ourselves in time on Mars, but there have also been a number of attempts to create calendars and timekeeping systems that could be used by people living on Mars itself by everyone from scientists to fiction writers. The calendars divide the Martian year into months – which vary in their length, and in how many months there are in a year – and weeks – again, varying in length and quantity. Some calendars use familiar names for months and days of the week, and some make up new names, or new versions of the earth names. Getting into them all would probably take a whole series of blogposts, but it is a very fun rabbit hole to disappear down.

Lunar Cycles, Tides, and the Changing World

For those located near the coasts, it's impossible to miss the influence of planetary bodies (including the moon) upon the Earth. Twice a day, the sea level rises and falls. In some places, such as Canada's east coast Bay of Fundy, those changes can be quite dramatic. Here, liquid flowing on a spherical Earth, moving under a changing gravitational potential combines with the shallowness of the sea-floor to create a low-tide line kilometers from the high-tide line. As consistent as the system may seem, this "moon-driven [...] timeless circuit of invasion and retreat" may soon combine with longer-term effects of our changing climate, as PhD Candidate Giang Nguyen describes below.

By Giang Nguyen

Our lives are defined by astronomical cycles. How fast the Earth spins about its axis dictates our daily cycle. The angle between Earth’s spin axis with respect to its orbital plane tilts either the North Pole or South Pole towards the sun. How fast the tilt alternates between the North and the South directs our habits from season to season, year to year. These effects are the most apparent manifestations of astronomical forcing in our lives, but there are weaker forces at play that affect us in more subtle ways.
 
The Moon has its own cycles as well. The phases of the moon have often been used to keep track of time and many cultures use lunar calendars to this day. However, neither the Earth’s rotation nor the Moon’s orbit are in sync with the Earth’s orbit around the sun; we have to subtract and add days year to year to keep dates consistent with the seasons. The moon with its crescent shape is an important icon for many people across the world and indeed it does have its astronomical effect on us.
 
The moon’s gravity, along with the sun’s, exert tidal forces on Earth. These tidal forces shift water in our oceans from one place to another. You can imagine water sloshing back and forth in a bathtub and this is essentially what is happening in our ocean between the continental coasts. The movement of water will resemble standing waves where each node (point that experiences minimal amplitude change) is called an amphidromic point. Tidal forcing, along with the Coriolis effect, create huge hydrodynamical systems around these amphidromic points making them very important when trying to understand tides.
 
Seas that are somewhat enclosed by land such as the Gulf of Mexico and the Mediterranean Sea experience small tides. Regions that experience strong tides include northern Québec in Canada and France’s Bay of Biscay. These are the places where tides play a significant role in day to day lives, all resulting from how the moon orbits around Earth. Tidal effects are even strong enough to affect large climate systems [1].
 
The moon’s orbital plane around Earth does not line up with the Earth’s orbital plane around the sun. The wobble in the Moon’s orbit follows an 18.6 year cycle, called lunar standstills, and can translate to significant tidal effects. High-tide floods are already a reoccurring problem in many coastal regions. During periods in the cycle where tides are amplified, the risk of tide floods are predicted to be higher than ever. The next period of amplified tides is expected to arrive in the mid-2030s [2]. When this time comes, the Earth is predicted to be warmer and sea levels higher. Therefore, it is now more important than ever to continue to study the moon and tides and see how they affect the climate and weather around us.
 
Although our lives are mainly shaped around the sun, the moon still has its own special effects on Earth. The slight deviation in the moon’s declination as seen on Earth reveals a decade long oscillation that has significant implications on tidal forcing. This, in turn, may lead to climatic feedback that may redefine our everyday lives. Astronomical cycles remain a subject of great interest and I hope we get to learn more about it resultant from our relentless exploration of Space.

References:

[1] Lin, J., & Qian, T. (2019). Switch between el nino and la nina is caused by subsurface ocean waves likely driven by lunar tidal forcing. Scientific reports, 9(1), 1-10.

[2] Rasmussen, C. (2021). Study Projects a Surge in Coastal Flooding, Starting in 2030s. NASA JPL, https://www.nasa.gov/feature/jpl/study-projects-a-surge-in-coastal-flooding-starting-in-2030s