And to think I assumed Astronomy was a stagnant field some decades ago. I have no idea why I thought that. Maybe that optical resolution from ground-based telescopes was not going to advance orders of magnitudes? Maybe I didn't think the sciences would continue to get money for space telescopes?
Astronomy has been in a golden age for the last 35 years, based on:
1. Digital cameras, and the computers to analyze images.
2. Space telescopes (Hubble Space Telescope, the first large space telescope, only launched in 1990).
3. The building of massive ground-based telescopes. Before 1990, the largest telescope had a mirror diameter of 6 meters. Now, multiple 30-meter telescopes are under construction. Collecting power goes with the square of the diameter, so this is an increase of 25 times in collecting power!
4. Very recently, the development of gravitational-wave interferometers, which allow astronomers to observe a totally new type of radiation.
It always surprises me how my enthusiasm for scientific discovery is affected by fears of a dystopian future. My understanding is that with red shift calibration here we'll get a much better idea of the 'when' in terms of various galactic structures emerged, that might give us an interesting idea of where we are in the life-cycle of the Milky Way. But the observation of water signatures will be the most interesting to me. Presumably there is a lot of water tied up in comets and such, but will SPHERE be able to detect those signatures near planets?
The galactic and extragalactic science cases (meaning, “stuff in the Milky Way” vs “everything inside the Milky Way”) are actually pretty unrelated here.
We actually have quite a good idea about the history of the Milky Way and all the smaller galaxies that it’s eaten (and will eat, such as our main current satellites the Small and Large Magellanic Clouds). We’re even pretty sure that the MW merged with another large galaxy about 11bil year ago, sometimes called “Kraken”
https://en.wikipedia.org/wiki/Kraken_galaxy?wprov=sfti1. SPHEREx is not interested in any of that, and it looks like it’s galactic science will mostly be mapping out where clouds of ice crystals are in the Milky Way. SPHEREx has very low spatial resolution (about 6 arcsec), so it’s certainly not observing any exoplanets, but that’s the trade off with an all-sky mission like this.
One of the big drivers of the extragalactic science, though, is looking for signatures of cosmic inflation in the distribution of galaxies on large scales. IMO this is by far the most interesting science case, and will be genuinely exciting and novel. Its survey design doesn’t give it great resolution, but it’s amazing IR spectrophometry will let it map the rough distribution of galaxies at redshifts we haven’t been able to survey before. This is called intensity mapping
Hard for me to parse as well — but I think OP is talking broadly about humans being able to keep our shit together long enough to be able to reach other solar systems before we outgrow our own.
"The SPHEREx mission <snip> will map the entire sky four times over two years, offering scientists a chance to study how galaxies form and evolve, and providing a window into how the universe came to be."
So each object will be scanned ~6 months from the previous scan. How much evolving within the universe will be noticeable within that 2 year run? My gut response is not much, but that's why we do the science to see the changes.
"designed to map the celestial sky in 102 infrared colors "
So I'm guessing the coolant used to make IR scanning possible will be the limiting factor on operational time span. This article didn't say where this satellite will be parked either, but wikipedia[0] shows it to be a geosync orbit. Would have been interesting to be able to design a replaceable coolant module to extend the observations to really make seeing the evolution possible. Obviously complexity adds to cost and design time, so of course they didn't. Just dreaming
As an example, the study of the stars orbiting around SagA* are very revealing, but have required > 10 years of observations.
- It is passively cooled rather than using an expendable coolant- "SPHEREx relies on an entirely passive cooling system — no electricity or coolants are used, simplifying the spacecraft’s design and operational needs."
- It is a Medium-Class Explorers (MIDEX) mission - Investigations characterized by definition, development, mission operations, and data analysis costs not to exceed $180 to $200 million total cost to NASA.
I think the cost of ground support eats into the budget length. The original estimate for project was $241M, so it was a large MIDEX
- It is in a Polar orbit around Earth at the day-night (terminator) line
Possibly stupid question: how does this polar orbit stay over the terminator? And how is the terminator defined for a polar orbit here, since both the north and south poles are on the terminator only at the equinoxes?
>how does this polar orbit stay over the terminator?
Because it's launched at a angle greater than a straight north-south 90 degree orbit, so orbital precession will correctly follow the terminator. Depending on the orbital altitude this can be more than 140 degrees: https://en.wikipedia.org/wiki/Sun-synchronous_orbit
ah, I misread the Orbital Parameters on the wiki. that day-night orbit is also a LEO which makes it even more possible to do a manned mission for upgrades. Oh, wait, we no longer have a shuttle for those types of missions.
Remember, it is passively cooled (a major design plus and, I assume, part of why it was able to achieve the cost it did). So there would be no need for a manned mission. And in fact, at that cost, it wouldn’t make sense anyway.
Dragon lacks a Remote Manipulator System (Robot Arm) and a airlock. things that make servicing objects in space a lot easier. Im sure somewhere at NASA or SpaceX there is rough set of specs on what a shuttle like starship would look like complete with payload bay, robot arm, and eva airlock.
If you're alluding to Russia, they've had them. They even failed in making their version of a shuttle. With what money would they do anything with now?
If you're alluding to China, they probably had the data from the Russians anyways.
> They even failed in making their version of a shuttle.
Nitpick: It was sort of successful. They built a shuttle, and it successfully flew a single (un-crewed) mission of a couple orbits. The collapse of the USSR / lack of funding killed it.
It's amazing how all it takes is a few threats of annexation, and for GOP thought-leaders like Ben Shapiro to start talking about enslaving you[1] to work on the Panama Canal to make another country rethink its relationship with you.
Absolute animals. As is anyone else carrying water for these politics. There's no excuse for it.
If you had anything at all to do with putting these clowns in power - reign them back in. They are supposed to work for you. Remind them of this.
A nearby (excellent) comment (https://news.ycombinator.com/item?id=43338459) gives further context, but: the 6-month revisit period is just an artifact of the Earth-orbit-based sky scanning strategy. In 6 months the satellite, precessing at 1 degree/day, and facing away from the sun during data collection, will scan the sky completely. (See Fig 1 of the paper [0]).
So in particular, the 6-month period is not to revisit these distant galaxies more than once to observe spectral changes. The strategy, indeed, is to “stack” the multiple exposures to beat down noise. (Fig.6 of [0], top left).
It is possible that they have designed the system so that it could produce “just good enough” results in 6 months, with one complete scan. This is called a “threshold mission” and it would only be described in the full proposal.
I looked through the rest of the science cases (which are secondary to the driving case of this mission), and none of them seem to be reliant on revisits. (But open to correction on this.)
Any chance there will be enough "parallax" in the 6-month period to get a stereo-distancing map for the galaxies? Or do we already have that from red-shift, relative luminance or some other means?
Andromeda (the nearest) is 2e19 km away and has a relative motion of 300 km/s in the radial direction. If we assume the tangential motion is similar, that's 5e9 km of tangential displacement over 6 months, for a total angular displacement of 5e-5 arcseconds (50 microarcseconds).
That's well below the precision of every telescope. (Admittedly GAIA, the one designed for parallax measurements, comes close, but its techniques only work on very bright point-source objects).
They're talking about galaxy evolution in the early universe, over timescales of millions of years. Statistics measured across the (large) sample group, not within one galaxy. Scroll down to "It will classify galaxies according to redshift accuracy..."
This is nonsensical. Do you mean a tiny movement in the field of view, which should be measured in angular distance?
Or do you mean actual motion through the universe, in which case the galaxies are moving at hundreds of kms per second, which means they would move billions of kms in 6 mos.
Most things astronomers observe do not change much over the course of 6 months. For comparison, it takes the Sun about 200 million years to orbit around the center of the Milky Way once, so a galaxy like the Milky Way would hardly change in 6 months.
However, there is an entire field of astronomy, called "time-domain astronomy," that deals with things that do change on human timescales. There are pulsating stars, supernovae, galaxies with rapidly accreting central black holes, and many other types of objects. Surveys that focus on the "time domain" have survey strategies that are tailored to whatever type of object they're looking at. For example, if you're looking for planets that transit in front of their host stars, you should look every ~30 minutes or so, because planet transits only last around that amount of time.
- "The telescope is passively cooled to below 80 K in low-Earth orbit by three nested V-groove radiators. An additional radiator cools the long wavelength focal plane temperature below 60 K to reduce detector dark current."
The Spitzer used passive cooling, but only as a method to reduce the amount of coolant required. It still needed a coolant.
"One of the most important advances of this redesign was an Earth-trailing orbit.[1] Cryogenic satellites that require liquid helium (LHe, T ≈ 4 K) temperatures in near-Earth orbit are typically exposed to a large heat load from Earth, and consequently require large amounts of LHe coolant, which then tends to dominate the total payload mass and limits mission life. Placing the satellite in solar orbit far from Earth allowed innovative passive cooling. The sun shield protected the rest of the spacecraft from the Sun's heat, the far side of the spacecraft was painted black to enhance passive radiation of heat, and the spacecraft bus was thermally isolated from the telescope. All of these design choices combined to drastically reduce the total mass of helium needed, resulting in an overall smaller and lighter payload, resulting in major cost savings, but with a mirror the same diameter as originally designed. This orbit also simplified telescope pointing, but did require the NASA Deep Space Network for communications"[0]
As another comment mentions, SPHEREx is passively cooled. But fwiw, plenty of infrared space telescopes use consumable coolant:
> Notable infrared missions that carried consumable cryogen include IRAS (1983), ISO (1995–1998), Spitzer (2003–2009 in cryo mode), Herschel (2009–2013), WISE (2009–2011 in cryo mode), and Planck (2009–2013). Each relied on a finite liquid helium (or solid hydrogen) supply to keep detectors cold and reverted to a warmer operating mode or ended once their coolant was depleted.
Every system I'm familiar with that used liquid nitrogen to cool the IR instruments has had a operational lifespan based on the coolant. JWST is one such. "The coolant will slowly vaporize, limiting the lifetime of the instrument from as short as a few months to a few years at most."[0]
Well, it doesn't apply to either JWST or the subject of the article, so kind of feels like it's worth mentioning.
It doesn't change your specific, exact point (about previous cooling systems you were aware of), but it makes the conversation a lot less likely to confuse people IMO.
Do these missions ever build back-up hardware? What if the probe is lost because of a lunch mishap, or there is a malfunction during the deploy (see Viasat VS3 antenna deploy failure).
It is an added cost, but it cannot be that much compared to the overall R&D/tooling/launch/ect cost.
Into the 1970's, NASA did that. That was why there was Viking 1 and 2, Voyager 1 and 2, Pioneer 10 and 11, etc. Since then, however, NASA has stopped doing that. It became a balancing act- yes, 0 to 1 is much more expensive than 1 to 2, (1 to n is not quite as cheap as it is with software but it's still much cheaper than 0->1), but NASA Science is in the business of answering questions. The question is, will building, launching, and operating (the expensive part) two Parker Solar Probe's and two Juno's answer more questions than building one Parker Solar Probe, one Juno, and one OSIRIS-Rex? Almost certainly the three different probes answers more questions than two copies of two different probes. So once launch vehicle reliability got to be good enough that the fear of total mission failure went down low enough (1), duplicate missions basically went away.
1: Edited to add: this is actually tied into the Space Shuttle in interesting ways. See T.A. Heppenheimer, _The Space Shuttle Decision_ for why the STS became the sole space launch system for all of the US Government. Of course if it's manned it's reliability has to be so high that you don't have to worry about loss of payload, so building two copies of it was no longer necessary.
> Of course if it's manned it's reliability has to be so high that you don't have to worry about loss of payload, so building two copies of it was no longer necessary.
I wasn't expecting a space shuttle tie in, but of course there would be. They sure had to promise a lot to get that thing off the ground.
“Space is big. You just won't believe how vastly, hugely, mind-bogglingly big it is. I mean, you may think it's long way down the road to the chemist's, but that's just peanuts to space.”
450M is somewhere between .1% and 0 % of the total number of galaxies in the observable universe, so I am laying claim to 50, galaxies, which is hopefully a full set of galaxie types, but with a little haggling and trading, buying and selling galaxies I can figure that out later.
My Mom says as a child she sent away and got title to one sqare inch of the moon, but it was a much smaller universe then, especialy before inflation.
This is so cool, but I did not see a key piece of info in the article: does the ongoing operation of this mission fall under NASA's science budget and therefore at risk of cuts and defunding under Trump [1]?
Sure, the launch will go through, but SpaceX doesn't see any recurring revenue from later operations, and I wouldn't put it past the current administration to cut NASA's budget such that continuing operations are affected.
I'm not sure how to make out of comments like this. Is SpaceX actually launching customer payloads under $50m or whatever? Because, unless they are, it won't be long before JAXA/MHI starts selling H3 at half the cost of H-IIA, which is already like 15t to LEO for $67m at 150 JPY/USD, which leaves F9 reusable barely competitive in price. I don't know what India or China charge for foreign customers, but is it really reasonable to expect worse deal than Mitsubishi from them? ...
Superheavy-Starship reusable launches at F9 price would completely destroy everything in space space, but so far the only things it had disrupted are itself and airline services under its flightpath. And even F9 is starting to show increasingly clear signs of repetitive "old space" scrubs as NASA gets more disrupted.
Is that really a meaningful statement that stands, or it that just hand wavy glance away one now?
Costs are largely meaningless when talking about global situation and other nations and their strategic interests. Europe will move fully to ESA for anything actually important, China and India have their own stuff too.
Private satellites, sure why not if companies are OK with risking of getting their payload removed at last minute because somebody again bruised musk's ego.
Business can't be done in an environment with zero trust, doesn't matter how much better the offer looks on paper. That trust with spacex is gone for good.
Yep, it looks like it will be cut and closed, which is truly unfortunate. It’s disappointing to see that science nor innovation are not a priority for this administration. And this doge cutting of funding or even shutting down important projects will have long-term consequences, impacting research, education, and technological advancements that benefit everyone.
Trump created the Space Force so he will presumably want some amount of funding for rockets and what not. If Space Force fails it would make him look bad after all.
Trump is the one who actually decided to go through with the creation of a distinct branch rather than having it as a command. I think it is fair to say he created it.
There are all sorts of politicians and military members who advocate for a distinct Cyber branch of the military instead of Cyber Command. If a politician ends up doing that, then he should get credit for creating it even though it has been a long time coming.
> distinct Cyber branch of the military instead of Cyber Command
It's not 'instead', it's adding a cyber branch to a different org chart. There are two major org charts in the US military:
The services, such as Army, Navy, Space Force, etc., which are generally defined by domain (land, sea, orbit) and whose role is to recruit, organize, train, and equip forces - to prepare them, but not to deploy or command them in operations.
The combatant commands, which are defined by geography - such as Africa Command, Indo-Pacific Command - and sometimes by geography-independent domains, such as as Space Command or Cyber Command. The combatant commands deploy the resources provided by the services in various combinations. Modern conflicts generally require resources from multiple services/domains working jointly.
It makes some sense - you want domain experts to train and equip them for their domain, then you must necessarily deploy them jointly. Who should organize, train, and equip sea-born forces? Probably you want the Navy to do that, not the Army. Who should organize, train, and equip electronic domain forces (I hate the term 'cyber')? Do you want your IT organization organized, trained, and equipped (think of the importance of each step) by the US Marine Corps, or maybe by some actual researchers, engineers, and experienced managers?
Could you please stop taking HN threads on generic flamewar tangents? You've been doing it repeatedly, unfortunately. It's not what this site is for, and destroys what it is for.
Trump 1 mostly targeted climate and Earth science (when it came to NASA funding). Trump 2/Musk is going after everything. They've just shut down the Office of the Chief Scientist at NASA and are planning to cut fully half of the remaining science budget.
This administration under through Elon is pushing to cut 50% of NASA's science funding. Mapping galaxies we'll never visit is a purely scientific endeavor. Trump seems to care more about military expansion or for lack of a better term more "masculine" expansion of space. The science stuff is not interesting to him, and I'm honestly not sure I think Musk cares about it that much anymore either.
I don't think it's unfounded. This mission is purely about science, in the pursuit of understanding our universe, and is unlikely to lead to any military applications (and even if it might, I doubt Trump et al. would have the foresight to see it).
From the Musk perspective, he wants to go to Mars. Anything that doesn't contribute to that goal could easily go on the chopping block.
Regarding China and the moon, this particular science experiment has nothing to do with that.
They're working on it. NASA HQ has already cut their "Office of the Chief Scientist" (among others) and the current proposal is to cut 50% of the science budget (which would effectively kill it, it's already been squeezed).
And to add to that, DOGE has been known to cancel contracts where the money has already been paid (so we're effective paying for nothing); SpaceX already has what it needs from this contract and has nothing to lose by cancelling the mission now.
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