I'd start by asking, how do you define life? A lot of people would rule that nanoswarms are not life, and therefore shouldn't be picked up. And there will always thing that are in the grey area (like virii). Or better yet, define specifically what you're looking to detect. Do you want to detect bacteria, or only larger things? Once there, I'd establish a few things that most life does. Most life produces waste (i.e., 'everything poops'). Our understanding of how things metabolize is very primitive still, and in EP times is still quite primitive, but it gives us a baseline. Finding these chemical signatures suggests that there's some sort of chemical process which could indicate life (it could also indicate a number of other things, of course). With a long enough list in your checklist, and assuming some fantastic sensors and time to gather data, you may be able to say 'there is likely something here that coincides with how we understand life'.

The easiest form of "lifeform reading" would be a simple air or water sample for viral or bacteriological presence. If there is some, then the planet has life. Barring that, detecting an atmospheric admixture of oxygen and carbon dioxide is another good sign that life is present, depending on the ratio. Lastly, I've read from some astrophysicists that the very presence of liquid water may, itself, be a sign of life.

Arenamontanus wrote:

But how do you sample that? On Earth you can try looking for RNA and DNA, but if it was alien you would not know what macromolecules to look for.

Wouldn't macromolecules be a very easy clue to look for overall? Even if we found a macromolecule that wasn't DNA or RNA, wouldn't it be safe to say that the macromolecule was either a simple sign of life, or likely artificially built (and therefore [i]still[/i] a sign of life, to some degree)? How many non-biological non-artificial macromolecules are out there?

Arenamontanus wrote:

Only our kind of life. Before the cyanobacteria Earth had a thriving biosphere that would not have registered on this detector.

Admittedly this wouldn't work to detect sea life. But there aren't any anaerobic organisms that exist outside of liquid environments, and land life would no doubt lead to atmospheric presence of some electron acceptor gas... of which there aren't a dramatic amount of common natural ones to choose from. Unless you had some really crazy life, like anaerobic land animals that eject waste into an electron-accepting ground material.

Arenamontanus wrote:

Astrophysicists don't know much about biology :-) There is evidence of liquid water occasionally on Mars, but that hardly constitutes evidence for life.

So I'm guessing you disagree with the current hypothesis that Europa might harbor simple life under its ice sheets?

Decivre wrote:

Arenamontanus wrote:

But how do you sample that? On Earth you can try looking for RNA and DNA, but if it was alien you would not know what macromolecules to look for.

Wouldn't macromolecules be a very easy clue to look for overall? Even if we found a macromolecule that wasn't DNA or RNA, wouldn't it be safe to say that the macromolecule was either a simple sign of life, or likely artificially built (and therefore [i]still[/i] a sign of life, to some degree)? How many non-biological non-artificial macromolecules are out there?

Well, there is an infinite number of macromolecules out there. Plastics are good examples. If you saw something like epoxy in the environment, would you think that is a life sign? The problem is that it could be artificial, it could be weird biochemistry, it could be due to a weird non-biological process. I'm not sure what a macromolecule detector would actually be. Maybe a nanodisassembler picking apart samples atom by atom. There is nothing unifying them chemically.

Quote:

Arenamontanus wrote:

Only our kind of life. Before the cyanobacteria Earth had a thriving biosphere that would not have registered on this detector.

Admittedly this wouldn't work to detect sea life. But there aren't any anaerobic organisms that exist outside of liquid environments, and land life would no doubt lead to atmospheric presence of some electron acceptor gas... of which there aren't a dramatic amount of common natural ones to choose from. Unless you had some really crazy life, like anaerobic land animals that eject waste into an electron-accepting ground material.

Exactly. And it is not obvious to me that moving electrons around in oxidation/reduction reactions is a reliable sign of life. (I expect it to be common, though) A life detector for our kind of life is likely doable (somehow), but there doesn't seem to be any way of incorporating unknown forms - mostly because we do not have a strict definition that can be operationalized.

Quote:

Arenamontanus wrote:

Astrophysicists don't know much about biology :-) There is evidence of liquid water occasionally on Mars, but that hardly constitutes evidence for life.

So I'm guessing you disagree with the current hypothesis that Europa might harbor simple life under its ice sheets?

It might, but we don't know yet. Claiming that water *implies* life is a classic Dan Quayle quote. My personal guess is that life can be surprisingly common, perhaps due to at least local panspermia. But I also think life can be surprisingly weird. I am not going to rule out anything - not plasma-based organisms, not life on neutron stars, not cryo-life on gas giant moons or in their oceans, not weird biochemistries, not solid state machine life - until we have strong arguments against them.

NewtonPulsifer wrote:

Myself, I can't agree or disagree with a hypothesis that has zero evidence - like life on Europa. I need evidence to form a conclusion.

It depends on what you consider evidence. Researchers base the idea on extremophiles that survive in conditions that they view as very likely under Europa's ice crusts. The toughest question isn't so much about whether life could be there, but whether life could [i]start[/i] there. Biospheres and life as a whole tend to become more hardy as evolution carries on, but we have little clue as to how durable it is in a post-abiogenetic state; where life is likely still relatively fragile.

Arenamontanus wrote:

Well, there is an infinite number of macromolecules out there. Plastics are good examples. If you saw something like epoxy in the environment, would you think that is a life sign? The problem is that it could be artificial, it could be weird biochemistry, it could be due to a weird non-biological process. I'm not sure what a macromolecule detector would actually be. Maybe a nanodisassembler picking apart samples atom by atom. There is nothing unifying them chemically.

Actually, I would assume that epoxy was a sign of life. The odds of a collective soup of natural, non-biological polyamines just happening to encounter a natural epoxide on a lifeless planet near unimaginable with our current understanding of the universe. Even in the oddest case, I don't see plastics occurring naturally without either some artificial process or at least a biological compound to precede it. Admittedly, I could be wrong. That said, it shouldn't be dramatically hard to examine a suspected macromolecule, especially if we're working under the theoretical assumption that this "life detector" exists in a time period of nanotechnology and hyper-advanced computer systems. A nanoswarm can disassemble and digitalize the compound's structure, after which it can be put through a battery of simulations and tests to determine just what it is and what it might be a sign of.

Arenamontanus wrote:

Exactly. And it is not obvious to me that moving electrons around in oxidation/reduction reactions is a reliable sign of life. (I expect it to be common, though) A life detector for our kind of life is likely doable (somehow), but there doesn't seem to be any way of incorporating unknown forms - mostly because we do not have a strict definition that can be operationalized.

Well, of course. But that doesn't mean it wouldn't be feasible or useful. A life detector would be good for cursory examination of new worlds, meant to detect whether the planet has signs of already-known life. From there, exobiologists will know whether to expect something they've probably already seen to some degree, or to be wary of something new altogether. Plus like any good technology, it will likely be in a perpetual state of development. While version 1 might only detect all RNA/DNA-based organisms, version 5 might be able to detect isotope-based lifeforms, organisms that exist in wave form, and creatures with a fusion-based metabolism.

Arenamontanus wrote:

It might, but we don't know yet. Claiming that water *implies* life is a classic Dan Quayle quote. My personal guess is that life can be surprisingly common, perhaps due to at least local panspermia. But I also think life can be surprisingly weird. I am not going to rule out anything - not plasma-based organisms, not life on neutron stars, not cryo-life on gas giant moons or in their oceans, not weird biochemistries, not solid state machine life - until we have strong arguments against them.

It's not a question of ruling anything out. A life detector likely isn't going to be an end-all, be-all means of finding life. It will be a first-resort cursory examination of a locale, likely done simultaneously alongside tests to ensure that a planet has a tolerable atmosphere, temperature, etc. to (trans)humans. Even if life isn't detected, any good exobiologist will still be trying to spot various theorized forms of life once the research team arrives on site. And while water might not be a guaranteed sign of life (especially if the planet is largely hostile to complex compounds forming), it's a good starting point to search, especially while we work with limited detection systems and technologies. Hence why astrophysicists are looking for so-called Goldilocks planets; it's not about the idea that every other planet is inhospitable, so much as it's making the best use of the limited means of searching the universe that we have. As for machine life, wouldn't that be a sign of natural life by proxy? A machine is likely to have been produced artificially, which would automatically imply some organism preceded it (whether that organism is still existent or extinct).

Could there be, in the time of EP, a technology to detect certain brainwaves from a distance? By tuning it some, it could focus on human typical wavelength, with a margin of a error for the variation from individual to individual Another possibility would be derivated from T-Rays coupled with doppler to detect heartbeats. by calibrating the detectors to display only certain BPM coherent with human ranges