Daniel and Kelly’s Extraordinary Universe - DKEU Listener Questions Volume #3
Episode Date: January 9, 2025Daniel and Kelly answer listener questions about soil on Mars, the double slit experiment, and adaptations for surviving on the Red Planet. See omnystudio.com/listener for privacy information....
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Hello, friends.
One of my favorite parts of co-hosting this podcast with Daniel is that it's given me the chance to meet and interact with a bunch of you.
I've really enjoyed learning about your backgrounds, your interests, and some of you have.
cracked me up in some of the emails. You're a funny bunch. And in particular, I love getting your
questions. Y'all ask some incredible questions, and often they're questions I had never thought
about before. And Daniel and I love that we get to find answers to questions that keep you up at
night. So today, Daniel and I are going to tackle three questions that we've received from listeners.
And we take the responsibility of finding answers to your questions quite seriously. So after we
have an answer to these questions recorded, we check back with the listeners to see how we did
with the answers. Essentially, we let you all greet us. And if we fail to give a clear answer,
we're going to try again. And in this way, you all can help us learn how to explain things even
more clearly. So thank you. If you want to send us a question, you can either join us on our
Discord channel, or you can send us an email at Questions at Daniel and Kelly.org. We hope to hear from
you. And welcome to Daniel and Kelly's Extraordinary Universe.
Hi, I'm Daniel. I'm the particle physicist, and I love getting your questions.
I'm Kelly Weiner-Smith. I study parasites. And as you already know from the opening, I love getting
your questions, too.
do your kids ask you science questions you can't answer kelly oh yeah so my daughter asked me a good science
question that i sent to you the other day uh so i know the right people um and every once in a
while she will ask a question that's like at a very deep level of why and i won't know the answer
and she'll stump me sometimes but she also doesn't like talking to me about biology too much
because she knows which is such a bummer but uh is that because your answer you're answering
answers are too long. Is that why?
That's exactly why. That is exactly the problem we have.
Yeah. Oh, yeah. Do your kids ask you questions you can't answer?
They do sometimes ask me questions. I can't answer, but they always stop me after a few sentences.
And Hazel's favorite line is like, I didn't ask for a college lecture.
I mean, your dad's a college professor. That's what you're going to get.
And your mom, too.
Yeah, that's right.
What do you expect?
But it's fun. I love their question.
and I love the challenge of trying to answer it within that teenager attention span of like six seconds.
It certainly forces you to be succinct and clear.
It's good practice.
Yes, exactly.
But it's not naturally how I roll.
But that's okay because we have at least 20 minutes to answer each one of these questions
so we can go ahead and get into a nice bit of detail.
Our first question is, you know, exactly the kinds of amazing questions that I hadn't thought of ahead of time,
but I love getting a chance to think about.
So the first one is about, you know, soil on Mars and what makes soil.
And I just thought this was such a fantastic question, but I didn't know the answer.
And so it's also a great chance to bring a friend on the show.
Hello, Daniel and Kelly.
After two Mars episodes, a question or two popped in my brain.
Mars does not have soil now.
But if there was life a long time ago on Mars, could there be soil deeper down in the ground?
Also, if they used to be live on Mars, could that have created oil deep underground?
Can single cells produce oil, or do we need at least bigger life than that?
Thank you for the podcast.
Kind regards, Joost.
Okay, so this sounds like a geology question.
And lucky for me, I have a geology friend.
He was my quarantine buddy in the pandemic.
So we're bringing on to the show, Callan Bentley, who's an associate professor of geology.
at Piedmont Virginia Community College,
and he's co-author of the free online textbook
Historical Geology.
Callan, what's up?
Hey, thanks for having me.
I'm glad to be here.
We're happy to have you here.
So I read this question, and I remembered
that I had a conversation with you once
about what's the difference between Regolith and soil,
and I think I remember you just sighed and walked away,
or something.
It was something like, my sense was that, oh, these,
It's just jargon.
But so what can you tell me?
What is the difference between soil and just dirt and regalith?
Yeah.
So dirt doesn't really have a scientific meaning, but regolith does and soil does.
And the difference between them is that soil has organic matter in it, which we call humus here on this planet.
Not to be confused with the delicious dip with tahini in it.
That's right.
That is hummus.
And there is a difference of one M.
I see.
Here on Earth, humus gets added from the top.
So basically, like this time of year, the leaves are dropping off of many of the trees in
the northern hemisphere.
And that's basically a rich source of organic matter.
And that drops onto the soil.
And those leaves fall apart or they get tugged underground by earthworms and basically get
mixed in with the rock fragments and mineral grains that make up the other sort of solid bulk
of the soil.
It's important to realize that soil actually consists of, you know, solid stuff, but also a lot of empty space, which can be filled with either air or water, depending on whether you're in a drought or it rained recently or how deep you are in the soil.
So, you know, if you went and looked at the Apollo astronauts' footprints on the moon, those are in Regolith because there's no organic matter on the moon.
We don't know about, you know, sort of the constituents of Mars as well as we know about the moon
because we haven't been there and picked up samples and, you know, brought them back and, you know,
we've done a few sort of remote experiments, but the sort of mechanism of folding organic
material into the, you know, putative Martian soil would seem to be lacking.
And so, at least in the present day.
Now, if it existed in the past, you know, that's, I suppose, a possibility if Mars had a thicker
atmosphere in the past and a more pronounced greenhouse effect. You know, perhaps there was
life there in the terrestrial realm at that time that could produce organic material and add it to
the regolith and turn it into soil. And it is indeed possible as the listener asks that those
old soils could be buried under subsequent sedimentary layers, perhaps with zero organic
content. We have examples of buried soils here on Earth. We call them paleosols. And there are a lot of
examples of them. They have various characteristics that are signatures of the conditions under which
they formed, just like sedimentary rocks contain signatures of the circumstances under which the
sediments accumulated. So you make soil on the surface, and then it can get buried. And so you're saying
if you had life a long time ago, you would have made soil. And then if life all died out, you continue
to make layers and that buries the old soil into, is that paleo soil? Paleo soil. So they drop the eye.
Yeah, soils are a little bit weird. They call the soils themselves by these names that all end in S-O-L-S, like aridicols and jellisols and I don't know, a bunch of them.
Soil scientists are really into classifying things. They've like organized all of the planet Earth soils into like 19,000 soil orders or soil series and then those are grouped into like a dozen or maybe 14 soil orders.
Honestly, it's not my area of expertise. The main thing that seems to be,
a driver for my sort of basic level understanding is that the climate really controls what sort of soil you get in a given area.
So soils and deserts tend to be really jacked up in terms of their evaporate mineral content because water gets wicked through them carrying material in solution.
And then that gets precipitated as the water goes into the atmosphere.
So they tend to be very hard and calcareous.
Soils in the tropics tend to be really clay rich because the most common,
mineral in the crust of the planet, Feltzbar,
rots under warm, wet conditions, and it makes clay.
So you get these bright red iron oxide stained,
clay-rich tropical soils.
So Mars has red soils like that.
Is there any similarity there, or am I just reaching?
There's definitely oxidized iron in the,
what I would call regolith and sedimentary rocks of Mars.
So, yeah, that's a similarity that the iron there reacted with oxygen.
And under what circumstances that occurred, I couldn't tell you, whether that was in the open air, you know, whether it was submarine or whether it was, you know, in a freshwater system or whether it was underground due to groundwater flow or, you know, there's a lot of possibilities there.
How much do we know about the surface of Mars?
I mean, I know we've had rovers there for decades and they, like, pick up rocks and they drill into them.
But how far, like, down, have we dug into Mars?
Not far.
Yeah, there was an attempt a few years back to, you know, basically drill the deepest hole yet dug on Mars in the service of installing a seismometer so we could listen for Marsquakes.
Love that word, Marsquakes.
Yeah.
And I don't think it got very far.
I think it got stuck.
And so it was sort of an abortive kind of thing.
Kelly's nodding.
So maybe she's more familiar with the history of that.
I think it was more than one problem.
One, I think things were more compact than they had expected them to.
be so it's harder to get through. And then also it was having trouble gripping and staying in one
spot. It got only a fraction of the goal of the depth that it was shooting for. It's just hard to
work in space. My Wikipedia research tells me that the deepest hole on Mars is nine millimeters deep,
which is not very impressive. Oh, man. So if there's soil on Mars, probably it's just
bacteria that's adding the like lifey component to it. Is there anywhere? There's probably nowhere on
Earth where it would be just like that. Probably anywhere else you'd also find like nematodes and
stuff. Well, yeah, not anymore. There certainly would have been paleo environments on Earth when it would
have just been microbial. And those would have lasted for a very long time for, you know, the first
several billion years of Earth history. You know, some of those microbes would be prokaryotic,
of course, and then eventually eukaryotes show up as well. But yeah, probably it would be unicellular,
if anything, big if. Could having just unicellular organisms result in
oil or do you need bigger stuff to get oil? Oh, wait, wait. We're going into oil now. I thought we were
talking about soil. So have we dropped the S? You dropped the eye and went to Salls. Now we're going to drop
the ass and go to oils, yeah. Okay, so with with oil, the story is a little different. It's a little
more complicated. So when I think of soils, I am thinking of terrestrial regolith with organic
material being added from the top and then gradually getting mixed in. But the organic content would
decrease the deeper you go. Hold on. Did you just say terrestrial regolith? That means regalists on Earth?
Yeah. Thank you so much for asking that clarifying question about the words I'm using. What I meant was
not underwater, not in the ocean. So I meant on the land. All right. So my default setting would not be
to call marine sediments by the name soil. I would call them sediments. And they might have a high
organic content or they might not. But that is not what I'm saying when I'm talking about soils. I'm talking
about land-based settings.
So that's what I mean by terrestrial.
But you said terrestrial regolith.
You used the R word.
Originally, it would have been regalith, right?
And then eventually, sometime in Earth history,
it started becoming soil through the addition
of this magical ingredient of humus.
This clears up an argument Daniel and I had in the past.
Thank you.
Turns out you can turn regalith into soil
just by adding hummus or hummus.
You could add, yes, you could do the job with hummus
or other forms of it.
Humus.
Tahini is like magic, really.
It's life-giving.
The scientific community argues at meetings, like at geological meetings like the
Geological Society of America, there are periodically sessions about the terrestrial
biosphere during the Cambrian.
And what they're not saying there is the biosphere on Earth.
They're talking about the biosphere on land.
So we have a much better geologic record about what was happening in the oceans, because
that's a place where sediments tend to get deposited and tend not to get eroded. Whereas the land
is a place where sediments tend to get eroded and tend not to get deposited, at least in the long-term
sense. We do have terrestrial in here, again, I mean land, deposits of sedimentary rocks,
but they are far less common, fewer and further between than marine sediments. We were going to get
back to oils. So that's basically what I was saying for soils, okay? And yeah, basically we don't know
when the humus started getting added. People argue about that, and they look at various,
you know, biotracers, geochemical signals, things like that. As far as oil, oil is a liquid hydrocarbon
cocktail that is formed due to cooking algae, cooking phytoplankton. All right. So I'm using
algae here in the most inclusive sense. But basically, you know, phytoplankton photosynthesizing
in the upper sunlit portions of bodies of water, usually the ocean, but potentially also,
you know, large lakes and things like that.
They capture energy from the sun doing photosynthesis.
They lock that up in their organic molecules.
Then they kick the bucket and they die.
And if they avoid getting eaten, then they fall down and their little dead bodies accumulate
on the bottom of that body of water.
They are likely to accumulate there if there's not a lot of things that are grazing them,
trying to eat them, and oxygen levels are relatively low. So if you bury this organic rich
stuff and you warm it up, then you can cause chemical reactions to take place that produce the stuff
that we call oil and the stuff that we call natural gas, which again is a cocktail of a bunch
of different ingredients, but in the case of natural gas, they are in the gas state, not in the
liquid state. So with accumulating that phytoplankton here on Earth, you know, there's certain
conditions that we need to kind of go through to get that stuff and get it down to the bottom of
the ocean. And then it has to be buried. And then it has to warm up to the right temperature.
So before we started our podcast today, I made a cup of coffee. And that's about the right temperature
that you need to warm up your dead phytoplankton in order to get them to produce oil.
If you don't heat them up enough, they don't make the oil.
And if you heat them up too much, it basically reacts away and makes other compounds
that are not capable of flowing and being pumped out of the ground.
So the happy place for oil production is around 100 degrees Celsius, okay?
The temperature of an espresso.
This sounds kind of complicated and not so easy to arrange.
How is it that we have so much oil on Earth?
Well, we would have more if it wasn't so darn complicated.
And, you know, we have some, but we don't have.
an infinite amount. So it's these circumstances might sound really far-fetched and unlikely to occur,
but they have occurred. And if they hadn't, you know, we would probably be living very, very
different lives. So Mars used to be warmer because it had flowing water at one point. Was it
that warm? So what I'm talking about is not the temperature at the surface. And if if the temperature
at the surface was 100 degrees C, you wouldn't have flowing water. You'd have, you know, water vapor, right?
or, you know, the transition between those, what I'm talking about is burial conditions.
So deep in the earth, and, you know, there's usually some amount of overburden, some amount of
pressure of overlying sedimentary layers weighing down on this sort of pressure cooker where these
phytoplankton are getting simmered, and that's the right condition to produce the oil.
Then if that is up near the surface of the earth, you're on earth.
If it flows out at the surface, then a couple of things happen.
One is it can devolatilize, and so that will release the stuff that kind of keeps it low viscosity, and it tends to get more gooey and sticky and tar-like at that point.
And ultimately, the high levels of oxygen in Earth's atmosphere will react with those leaking petroleum deposits on the surface, and ultimately, you know, they will release their energy through reaction with oxygen.
but in a way that's not conducive to humans capturing that energy and putting it to work.
So there are places where that occurs, and you probably have heard of the Labreia tar pits
or the beaches at Carpenteria in California.
Those are places where petroleum is actively leaking out onto Earth's surface naturally.
But in order to utilize oil, what we do is we try and find places where that hasn't occurred,
but where it has pooled in the subsurface.
So, Daniel, if you thought it was complicated before,
there's actually another step,
which is that we need to take the oil out of these nice warm source rocks
and then move it into someplace where it will pool
in an accessible sort of setting.
And so, you know, ideally that would be some sort of subterranean trap, we call them.
And one of the most common ones is a fold in the rock layers that goes up in the middle.
It's so-called anti-cline.
And if you have a sort of sandwich of less permeable and more permeable and less permeable
rock layers, such as shale, sandstone shale, then that provides a nice little, and then you fold it
into like a rainbow shape. The sandstone can soak up lots of oil and natural gas, and the shale
basically keeps it from leaving that arch. So because oil is less dense than water, it rises
to the top of the arch, but then it can't rise any higher. The overlying shale acts as like a ceiling.
keeps it from, you know, escaping.
This is like a geological Rube Goldberg machine.
Yeah, man, it is.
And so people have tried to shortcut this, you know, in some places where they've, you know,
said like, hey, we've got these tar sands up in northern Alberta.
They're full of petroleum, but it hasn't yet escaped the source rock.
But we can make it escape by grinding up those things and then boiling them essentially
and then we can let the oil out and then we can burn the oil.
But that takes a lot more energy investment.
And so that really only becomes viable economically if oil prices are really high, like, higher than $150 a barrel.
So I bet they'd really like to have oil on Mars, though.
And if you're already spending all that money to get to Mars, maybe you're willing to spend as much as it takes to get the oil out.
Is it hidden in difficult places or does Mars just not have the right conditions?
I mean, I think Mars does not have the right condition.
So if we think about the various things that are necessary, like did Mars have oceans in the past?
yeah, maybe probably. Did those have life in them? That seems like it's a little less likely.
Did Mars have a sufficiently active surface environment to bury sediments? You know, enough
subsidence in these areas where you'd get organic sediments buried. Mars certainly doesn't have
plate tectonics, which is what crumples those sedimentary layers up into those folds that
concentrate the oil. But maybe there would be some other equivalent trap on Mars. It does seem like,
though each of these things is far less likely on a planet like Mars than it is on a planet
like Earth. How likely do you think it is in general? We took a random planet and I said there
are oceans and there was microbial life. What are the chances that it has oil on it? Are we talking
like one in two, one in two million? Insufficient data, Daniel. Insufficient data. So we do not know
the parameters of these different exoplanets. But like one of the things that's necessary here
on Earth to bury the phytoplankton in their little graveyard at the bottom of the sea is you need
to have something to bury them with, right? So you need to have sediments. Well, where are those
sediments coming from? They're coming from terrestrial. And again, I mean land source areas here where
rocks are being weathered and they're shedding off particles big and small. But if you have a planet
that's completely aqueous where it's got no land, then what is going to bury those things in the
first place? There's no source for sediments other than like chemical precipitates from the ocean
itself. So there's no way I could put a number on how likely it would be. I appreciate the
question. It's worth articulating, but I cannot answer that. We have focused on single-celled
organisms because we got this great question that focused on single-celled organisms. On Earth,
is all of our oil from algae, or is it also from like dinosaurs and stuff? Because that would
be cooler. Okay. So it's not from dinosaurs and stuff. So dinosaurs and stuff are terrestrial
organisms, they live on the land, they wander around on the land. When they die, they're very
unlikely to be preserved in the fossil record. You know, we are very attracted to dinosaurs. We go to
museums to see their fossil remains, but the reality is that they are far, far, far, far less common
than marine organisms, particularly marine invertebrates. So the fossil record is strongly biased
towards things that live in the ocean, things that don't have backbones, things that lived
a long time ago, like during the Paleozoic, dinosaurs, you know, were limited to a relatively
brief window of geologic time. And also, the fossil record is biased towards things that have
hard parts, such as bones or shells or teeth. Dinosaurs do have bones, of course. But, you know,
three of those four are kind of stocked against dinosaurs, basically entering the fossil record in the
first place. Usually when a dinosaur dies, its flesh rots away because it's out here in the open
atmosphere where there's lots of oxygen that wants to react with all the carbon in its body.
And that's if it doesn't get eaten or scavenge, right? So what we really want is circumstances
where, you know, a dinosaur maybe, you know, died, bloated with gas, a flood washed it out to sea,
then out at sea, it popped, and then its skeleton and its remains could join the oil forming
process. But that is really unlikely because that's not its natural habitat. No, it's not dinosaurs.
But basically, it's anything organic that could enter these low oxygen settings where sediments
will then bury them and they'll get warmed up to the right temperature. Let me maybe at this
point invoke an organism that you may have heard of or may not have the conodont. Do you guys know
what conodonts are? No. Okay. So for a very long time, geologists are trying to figure out how old
sedimentary layers are. And we figured out that the fossils in those sedimentary layers change through
time. So, for instance, you find dinosaurs in some layers. You find trilobites in other layers. You find
woolly mammoths in other layers still. Right. So there is a time progression to the geologic
record where the fossils change in a regular and predictable way. This is awesome on many levels.
It's a record of past biological evolution on our planet. But it also is kind of
of a tool for figuring out how old the sedimentary layers are. And when coupled with other tools,
such as isotopic dating, say, have a granite dike that cuts across a trilobite-bearing shale,
you can then figure out by dating the dike how old the shale must be. The shale must be older
than this igneous rock that cuts across it, right? So we've been using this principle of relative
dating by fossil succession for centuries now to figure out how old sedimentary rocks are.
she even practice this. All right? So these fossils are most useful when they are distinct and
recognizable, when they're very cosmopolitan and widespread all over the planet, not limited to
some particular habitat or landmass or island or whatever. And when they are limited to a brief
period of geologic time. So those three characteristics make for a good index fossil. Cockroaches are
lousy index fossils because they've been around for, you know, hundreds of millions of years. So you
find a rock with a cockroach in it, no big deal. It doesn't really tell you that much. But conodonts are
powerful index fossils. So they are these little things shaped kind of like teeth or spike balls or
they look like sort of sadistic ice skates or something like that. They are made out of a mineral
complex called hydroxyl apatite. And they're found in sedimentary rocks, the world over,
from the Cambrian period of geologic time
up through the Triassic or Jurassic,
sometime in the Middle Mesozoic.
And people were like, hey, these things are awesome.
You can really use them to tell these rocks apart
but they're different ages.
We had no idea what they were.
Right?
So they were just these things that we could find,
these entities.
And we were like, okay, they're useful,
but we don't know what they are.
And recently, they found out
that they're part of the head region
of an eel-like critter.
So a very small little thin fish where the other parts of its skeleton are not hard enough to enter the fossil record.
But they found one of these rare fossil occurrences where we've got the soft tissues preserve, the muscle blocks and some of the skin, the eyeballs, they've got great big eyes.
So they look to be like sort of gill support structures or something related to the mouth, but not traditional teeth like you or I have.
And these things are really neat because they can not only tell us time, but they change color when they get different.
temperatures. So a geologist at the United States Geological Survey, Anita Epstein, figured out that
you could use the color of conodonts to figure out if the rocks had gotten to the right temperature
to generate oil. So they would basically go from sort of a yellow color to an orange to a burnt
umber kind of orangey brown to a gray brown to black. And you could figure out exactly the
temperature they were cooked at. And that could tell you whether the rocks at that depth got to be
the right temperature for oil production.
A pretty neat trick.
They call it the conodont alteration index.
And there's a nice little article on Wikipedia you can read if you're interested in exploring
that more.
So when people are like trying to figure out where oil is, if they find one of these things
and it's the right color, are they like, okay, now we need to dig in this area a lot more
and that's like an indicator that you're in the right spot.
Yes.
And if it's the wrong color, don't bother.
Okay.
And Mars will have none of this.
So we're out of luck there.
But that's awesome.
My last question is, do all these names that they give to soils and rocks whenever?
Do these actually make sense?
Or is it a big pile of nonsense the way it is in astronomy with arbitrary dotted lines that
date back to like some old man in robes in 1700s who gave something the wrong name?
I mean, I'd love to tell you that it all makes perfect sense.
But, you know, like the English language, the geological lexicon has adopted words from other
traditions, other languages. I really like thinking about the origins of these different words.
I think conodont, I'm sure that breaks down into something like cone-shaped tooth in terms of its
etymology. But geology is very rich with words from French, Italian, Scottish, even Indonesian.
Bahasa Indonesia has contributed major words to the geological lexicon. And I love that sort of
melting pot aspect of the science. It's very appropriate.
for the Indonesians to have a word for a volcanic mud flow, a Lahar, but you wouldn't expect that to
originate from Scotland. But it's very appropriate for the Scots to come up with words like
Esker and Tarn, which describe glacial features. So it tells you something sort of almost
anthropological about the place where these words originate. There's like sediments of words that
build up over time. That's a good way of thinking of it. And probably some of these words are almost like
index fossils, right? Where they come into fashion for a while, they're used, and then you can only
find them in the deepest, dustiest pages of the literature. Which is where we love to explore.
All right. Well, thank you so much, Callan. This was super helpful, and we're going to send your
answer to Eust, and he'll tell you if he feels like his question was answered. Right on. Okay, good
luck, everybody. I love talking to geologists. They rock. I bet Callan's never heard that before.
I'm sure. First time. Hi, Callan, Daniel, and Kelly.
you for those rock solidances. I'll put my plans for a oil company on Mars on the world now.
Thank you. All right. Well, I am so glad that Eust felt like he got his question answered.
And so now let's take a break and we'll move on to a question from Scott, who unfortunately is
from California. We don't all get to pick where we're from.
Imagine that you're on an airplane. And all
of a sudden you hear this.
Attention passengers. The pilot
is having an emergency
and we need someone,
anyone, to land this plane.
Think you could do it? It turns out that
nearly 50% of men
think that they could land the plane
with the help of air traffic control.
And they're saying like, okay, pull this.
Do this. Pull that. Turn this.
It's just... I can do my eyes close. I'm Mani.
I'm Noah. This is Devin.
And on our new show, no such thing.
We get to the bottom of questions
like these. Join us as we talk to the leading expert on overconfidence. Those who lack
expertise lack the expertise they need to recognize that they lack expertise. And then as we
try the whole thing out for real. Wait, what? Oh, that's the run right. I'm looking at this
thing. Listen to no such thing on the Iheart radio app, Apple Podcasts, or wherever you get your
podcasts. I had this like overwhelming sensation that I had to call it right then.
And I just hit call, said, you know, hey, I'm Jacob Schick.
I'm the CEO of One Tribe Foundation, and I just wanted to call on and let her know.
There's a lot of people battling some of the very same things you're battling.
And there is help out there.
The Good Stuff podcast, Season 2, takes a deep look into One Tribe Foundation,
a non-profit fighting suicide in the veteran community.
September is National Suicide Prevention Month,
so join host Jacob and Ashley Schick as they bring you to the front lines of One Tribe's mission.
I was married to a combat army veteran.
And he actually took his own life to suicide.
One tribe saved my life twice.
There's a lot of love that flows through this place and it's sincere.
Now it's a personal mission.
Don't want to have to go to any more funerals, you know.
I got blown up on a React mission.
I ended up having amputation below the knee of my right leg and a traumatic brain injury because I landed on my head.
Welcome to Season 2 of the Good Stuff.
Listen to the Good Stuff podcast on the IHeart Radio app, Apple Podcast, or wherever you get your podcast.
Hey, sis.
What if I could promise you you never had to listen to a content?
to sending finance bro. Tell you how to manage your money again. Welcome to Brown Ambition. This is the
hard part when you pay down those credit cards. If you haven't gotten to the bottom of why you were
racking up credit or turning to credit cards, you may just recreate the same problem a year from now.
When you do feel like you are bleeding from these high interest rates, I would start shopping for
a debt consolidation loan, starting with your local credit union, shopping around online, looking for
some online lenders because they tend to have fewer fees and be more affordable. Listen, I
I am not here to judge.
It is so expensive in these streets.
I 100% can see how in just a few months
you can have this much credit card debt
and it weighs on you.
It's really easy to just like stick your head in the sand.
It's nice and dark in the sand.
Even if it's scary, it's not going to go away
just because you're avoiding it.
And in fact, it may get even worse.
For more judgment-free money advice,
listen to Brown Ambition on the IHeart Radio app,
Apple Podcast, or wherever you get your podcast.
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A foot washed up.
a shoe with some bones in it.
They had no idea who it was.
Most everything was burned up pretty good from the fire that not a whole lot was salvageable.
These are the coldest of cold cases, but everything is about to change.
Every case that is a cold case that has DNA.
Right now in a backlog will be identified in our lifetime.
A small lab in Texas is cracking the code on DNA.
Using new scientific tools, they're finding clues in evidence so tiny.
you might just miss it.
He never thought he was going to get caught.
And I just looked at my computer screen.
I was just like, ah, gotcha.
On America's Crime Lab, we'll learn about victims and survivors.
And you'll meet the team behind the scenes at Othrum,
the Houston Lab that takes on the most hopeless cases
to finally solve the unsolvable.
Listen to America's Crime Lab on the IHeart Radio app, Apple Podcasts,
or wherever you get your podcasts.
All right, we're back and we're answering questions from listeners like you.
If you have a question about the universe that nobody you know can answer, send it to us.
We will answer it for you.
We write back to everybody.
Send us an email to questions at danielandkelly.org.
Try to get you an answer.
Not all questions have answers, but we will do our best.
But I guess there's no answer is also a kind of answer.
Yeah, the answer nobody knows is unfortunately the answer to most questions.
And today we have a thorny question from Scott from California.
He's asking about a famous physics experiment that leads to all sorts of tricky philosophical wrinkles.
This is Scott from California.
I have a question about the double slit experiment.
I am imagining a probability wave of a particle approaching the first barrier that has the slits in it.
As the wave approaches that first barrier, I'm assuming that the universe has to make a decision about whether the particle is going to hit the barrier or go through a slit.
That is, the wave function would collapse and the particle would find itself hitting somewhere on the barrier or perhaps find itself right where a slit is.
If it finds itself right where a slit is, does the wave function then instantly uncollapse such that it goes through both slits simultaneously?
This question has been bothering me for a long time, so I'm really looking at.
looking forward to getting an answer. Thank you so much.
Oh, man, Scott. That is a great question. And I have vague memories of the double
slit experiment from freshman year of college. But I guess that's 20 years ago now. Oh, my gosh.
So, Daniel, refresh my aging memory. What's the double slit experiment?
Yeah, I think it's useful to nail down exactly what we're talking about so we can figure out
how best to answer Scott's question. This is a famous experiment that's been done in many ways
with changing interpretations over time.
So the first version of this experiment was done with light.
You have some source of light, a light bulb, or a laser, or whatever,
and you shine it on some barrier.
And most of the light is absorbed, but you have two little slits in the barrier.
And where those slits are, the light can go through.
So now on the other side of the barrier,
you have these two little narrow slits,
which act like sources of light themselves, right?
Almost like you have two little light bulbs right there.
And then the light that comes from these slits hits some screen,
and that's where you're observing it.
You see on the screen, it's not just like light from the two slits.
You see an interference pattern.
You see that in some places it's dark, even though the light hits it.
In other places, it's very bright.
And that's explained by light being a wave and cancelling out in some places and adding up in other places.
So the first earliest version of this experiment showed us that light had these wave-like properties because it interfered with itself on the screen.
Okay, I'm following that, but I feel like I also have a vague memory of physical.
is this talking about light as a particle.
Yeah, what's going on there?
So now it gets weird.
Remember, the crucial explanation for why do we have interference is that we have light coming
from both slits, right?
Each one is like a little source, and sometimes their waves go up, and the other one is
going down, and sometimes they're both going up, so they add up.
But the crucial thing is you have two sources, which is why you have interference.
So then slow the experiment down.
Now we know light is actually made out of little packets.
It's not like a continuous stream, right?
When you turn on your flashlight, it's actually shooting out little packets.
of light, these things we call photons.
And so you can make this experiment more interesting
by slowing it down and saying what happens
if we only have one photon in the experiment at a time, right?
Instead of huge numbers of photons
which are interfering with each other,
what happens you have a single photon?
And then you see something very strange,
which is the interference pattern builds up
gradually on the screen.
So one photon comes through and it lands in one spot,
another photon goes through, it lands in a different spot,
and then the third one in another spot,
But if you do a million of these, it adds up to give you the same pattern you saw
when you illuminated it with a huge amount of photons all at the same time.
So the confusing thing there is, and I can see Kelly's faces going, huh?
Yep, what?
Is what's doing the interfering?
Because in the earlier version, I explained that the interference pattern is coming from having two sources.
But if the one photon is in the experiment at a time, what is it interfering with?
That's the big puzzle.
Is the answer going to be quantum entanglement or something?
Why do you all always make this so complicated?
The answer is definitely quantum mechanical, though not entanglement.
What's happening here is that the photon is not like a little particle that has a specific path
and it goes through this slit and then hits the screen.
The photon has a probability to go through one slit or the other slit or to get absorbed by the barrier.
We don't know where an individual photon is going to go.
And it's that uncertainty, that probability that's doing the interfering.
So remember that picture I paint.
in your mind of light going through the experiment and coming out of the slits as little sources
and then interfering with itself, you can use that exact same picture, except instead of thinking
about it in terms of light, think about it in terms of probability for one photon. So you send
that photon against the barrier. It has a probability to hit one slit or the other slit. That
probability passes through both slits, right? And then that probability interferes with itself
and creates a probability distribution on the screen in the back.
Then the universe has to pick, okay, where is this photon actually going to go?
So I can put it somewhere on the screen,
and it draws from that probability distribution,
and it puts one photon.
So that probability distribution guides each individual photon.
It puts more where the probability distribution is high,
in other words, where the interference pattern is bright,
and fewer where it's dark,
so that gradually it builds up the same interference pattern you saw
pattern you saw when you shone the light brightly. So you just replaced the concept of light waves with
probability waves and all the same math works. Awesome. I think I had been imagining when we were
sending a particle through the slits that we had directed it to one slit in particular. Not that it could
have gone through both, but it's not like I had the probability stuff in my head. So I still, yeah,
anyway, makes sense now. Awesome. Yeah, it's crucial that you don't know in advance which slit it
goes through, that you have the possibility for it to go through both slits. Because in the other version
of this experiment is, well, what if we check?
What if we put a little detector like a camera or something that can tell
whether the photon went through slit A or slit B?
Then what happens?
Well, then the universe picks which slit it went through
because you put a detector there.
So you've collapsed the probability.
Instead of allowing for the possibility that the photon goes through either slit,
you now force the universe to pick which slit it goes through.
So then the interference pattern disappears
and you just get photons going through one slit or the other slit
and you get a geometric shadow instead of an imperfect.
interference pattern because there isn't probability coming out both slits because you force the
universe to pick and now it just sends a photon to one slit or the other slit. This is this
bizarre process. We don't fully understand of how possibility becomes reality when the quantum
meets the classical. It still absolutely blows my mind that just measuring it changes the pattern
that you get on the back wall. Like, is it just shy? What is the leading theory for why observing it changes
things. It's not something we understand very well. And this is called the measurement problem
in philosophy of physics. It's really a puzzle. I mean, we have this quantum theory that says
things at the quantum level follow these equations of probability. And that's the Schrodinger
equation. And they can have weird properties like not having a specific location, but instead
having a probability to have several locations or having probability to be spin up or spin down.
you can maintain a superposition of different possible outcomes, different possible properties for
yourself. That's what quantum objects can do. But we know that classical objects can't. Like
when you have a screen, the photon either hits here or there. It doesn't like half hit here and
half hit there. Or when you flip a coin, it's either heads or tails. It's not like half heads and half
tails. So we have these two different worlds, the quantum world where you can have superpositions
and the classical world where you can't. And we don't really understand the transition between them.
It's confusing because everything in the classical world, like quarters and me and you, are made up of quantum things.
So the leading theory is sort of nonsensical.
The leading theory called the Copenhagen interpretation says that, all right, you have quantum stuff and it can have multiple possibilities and it can do all sorts of crazy wave-like things like interfere with itself and its own probability.
But then when you interact with a classical object like an eyeball or a detector or a screen, then the wave function collapses.
And the universe has to pick.
It says instead of this whole spectrum of possibilities, you just pick one.
And that allows us to have classical outcomes like, hey, it's up or it's down.
The photon is here.
Photon is there.
This collapse theory doesn't really work because, number one, it violates like basic quantum
mechanical rules, like quantum information is never lost.
And also, it's not really well defined.
Like when I said a quantum object meets a classical object, I wasn't clear on, well,
what is a classical object exactly?
Because as I said earlier, all classical objects are made of quantum objects.
And that's the puzzle.
Nobody can define the barrier between quantum and classical objects.
So we don't really understand it.
We don't have a great explanation.
It's one of the biggest open questions in philosophy of physics.
Still so much left to do.
Still so much left to do, exactly.
So let's get to Scott's question.
And Scott is thinking about what happens when the photon is approaching that barrier.
And I think that he's imagining that either the photon hits,
the barrier and is absorbed or hits one of the slits and goes through. And I think Scott is thinking
that maybe the universe collapses it at that moment when it either hits the barrier or goes through
a slip because it sort of encountered some big classical object. And then he's confused about how
later we can say it maybe went through both slits and is there some uncollapsed. Like how do you get
multiple possibilities through that barrier? I think is essentially Scott's question. And the answer
is that hitting that first barrier doesn't collapse the wave function because you've still left
multiple possibilities. It can go through slit one or go through slit two. So both of those
possibilities propagate forward. So the short answer is the first barrier doesn't collapse the
wave function unless you have a detector there that's saying like, hey, did you go through slit one
or slit two? Because you allow the possibility of multiple slits, you allow the quantum
mechanical properties to maintain and for there to be a superposition of two possible outcomes.
And so then both of those possibilities go through the slits and then you get the interference from those two possibilities.
Great. So if it collapses at the two slits instead, you get a totally different answer.
Yeah. If you collapse it at the two slits, which you can do, if you put a little detector there and you say, I want to know which one it went through, then you get a totally different answer.
Exactly. You get a different pattern on the screen. And crucially, you can't uncollapse.
Like when you collapse the wave function, you go from here, the whole bunch of possible outcomes to now there's just one.
and you can't ever uncollapse it.
You've lost information, which is why it's so confusing.
We've said on the podcast before, like, you can't lose quantum information.
It can't be deleted from the universe, but this collapse theory does violate that principle
of quantum mechanics.
And people out there might be like, hold on, aren't you contradicting yourself?
Yeah, absolutely.
And this is one reason why we haven't really figured this problem out.
Like, we have this best explanation we have violates other things we know about the universe.
So it's like a work in progress.
Yeah, this is one of the really fun things I think about podcast.
podcasting with a physicist. I hadn't realized there were so many works in progress. But it's
exciting that there's so much left to discover. So I feel like I understood that. But let's go
ahead and test ourselves and ask Scott, did we actually answer the question that you were asking?
And if so, was the answer clear? That's right. Or did we just collapse his brain?
Okay. So it's my pleasure to welcome to the podcast, Scott Goldman. Scott, thanks so much for
writing in with your really fun question. Yes. Thank you. So tell me, you heard me,
and Kelly talk about the double slit experiment
and what happens to the wave front
as it hits the first barrier and interferes afterwards.
Tell me, did that make sense to you?
What questions do you have remaining?
So it makes sense to me.
I guess it all comes down to one question.
And that is every time a particle is shot at that double slit,
the barrier with the double slit in it,
there's a probability wave that comes to that barrier.
it goes through both slits, interferes with itself.
And when it gets to that detector screen,
the universe at that point, then I guess
has to make a decision where it hits.
My question is, does every particle that
is shot at that barrier with the double slits
go through and then hit the detector screen?
Or do some particles not hit the detector screen
because they actually hit the barrier somewhere,
instead of going through the two slits.
Yeah, great question.
The answer is the second one.
Not every particle makes it through, but, and there's always a but,
every particle has a probability of making it through.
So there's sort of a lot of different outcomes.
One outcome is you make it through one of the slits and you end up somewhere on the screen
as a dot.
Another possible outcome is you don't make it through at all.
So imagine that probability wave approaches the first barrier or the one with the slits in it.
Some of the probability wave makes it through and interferes with itself and gives it a probability to hit the back screen, but a lot of it, as you say, hits the barrier.
So then when you force the universe to roll the dice and say, what is the outcome for this particular particle, a lot of them are going to hit the barrier.
In most of the descriptions of this experiment, they sort of ignore that part because that's not so interesting.
We pay attention mostly to the ones that go through because those are the ones that do the interfering.
But yeah, a lot of them, if you ask, like, hey, what happened to this particular particle?
the answer would be that a lot of them hit the barrier and don't make it through.
Okay, so that's the part, I guess, where I'm having trouble understanding
because I'm imagining this probability wave approaching the barrier
and then when it gets to the barrier with the slits,
the universe has to decide like, oh, am I going to hit the barrier?
Or no, I didn't hit the barrier.
I happened to, I'm going to be right in this little space where there's a slits.
but then it goes through both slits.
Right. Yeah. So the universe doesn't necessarily have to decide there, right?
What it can do is have several possible outcomes. The wave approaches the barrier and now there
are three possible outcomes. You go through one slit, you go through the other slit or you
reflect or maybe get absorbed depending on the nature of the barrier. So the probability
sort of fragment there, but they don't have to collapse, right? They only collapse when you insist
you know. But if you don't insist you know, you're like, well, I'm just going to allow
the universe to keep doing its thing, I'm going to keep that within a black box or keep my eyes
closed for that part of it, the equivalent, then it can continue to propagate all three possibilities
that it reflects back or that it goes through one slit or that it goes through the second
slit. It can maintain all of those. And it's maintaining the uncertainty that allows it to make
that interference pattern. So some of the probabilities go through the slit and then when it gets
the detector screen at that point, it decides whether it actually made it through or hit the barrier.
Mm-hmm. Yeah, exactly. It doesn't have to collapse when it hits the barrier.
Oh, my gosh. Sorry.
Yeah, no, that's, yeah, it's amazing. It's sort of crazy. But the way to think about it is that it's allowing some of that probability. You can also think of it another way. You can think, you know, the probability, most of it gets zeroed out, and only those two little narrow slits of probability remain. But there's still uncertainty there. There's still, you don't know which way. And so that's what allows for the interference.
And I think a lot of people are confused by that.
They're like, well, why doesn't the barrier collapse the wave function, right?
Right.
And you can think about it that way also.
And you can, for example, add detectors to the barrier so that the only possibilities for the particle are that it goes through a slit or it hits the detector.
And that doesn't collapse the wave function completely.
That just says if it hits the barrier, then I want to know.
If it doesn't hit the barrier, there's still uncertainty because it could still go through either slit.
And then you'll still get the interference pattern.
So that scenario, you could sort of partially collapse the wave function.
You can be like, if it hits the barrier, I want to know.
Otherwise, I'm going to allow for the uncertainty to propagate through both slits.
So there's an infinite number of confusing and amazing ways to do this experiment.
All right.
Well, I hope that helped you understand.
Thanks so much for asking the question.
Thank you.
Imagine that you're on an airplane.
all of a sudden you hear this.
Attention passengers, the pilot is having an emergency, and we need someone, anyone, to land this plane.
Think you could do it?
It turns out that nearly 50% of men think that they could land the plane with the help of air traffic control.
And they're saying like, okay, pull this, do this, pull that, turn this.
It's just, I can do it my eyes close.
I'm Mani.
I'm Noah.
This is Devon.
And on our new show, no such thing.
We get to the bottom of questions.
like these. Join us as we talk to the leading expert on overconfidence. Those who lack
expertise lack the expertise they need to recognize that they lack expertise. And then as we
try the whole thing out for real. Wait, what? Oh, that's the run right. I'm looking at
this thing. Listen to no such thing on the Iheart radio app, Apple Podcasts, or wherever you get
your podcasts. A foot washed up a shoe with some bones in it. They had no
idea who it was. Most everything was burned up pretty good from the fire that not a whole lot was
salvageable. These are the coldest of cold cases, but everything is about to change. Every case
that is a cold case that has DNA right now in a backlog will be identified in our lifetime.
A small lab in Texas is cracking the code on DNA. Using new scientific tools, they're finding
clues in evidence so tiny you might just miss it. He never thought he was going to
caught. And I just looked at my computer screen. I was just like, ah, gotcha.
On America's Crime Lab, we'll learn about victims and survivors, and you'll meet the team
behind the scenes at Othrum, the Houston Lab that takes on the most hopeless cases to finally
solve the unsolvable. Listen to America's Crime Lab on the IHeart Radio app, Apple Podcasts, or wherever
you get your podcasts. Your entire identity has been fabricated. Your beloved brother
goes missing without a trace. You discover the depths of your mother's illness, the way it has
echoed and reverberated throughout your life, impacting your very legacy. Hi, I'm Danny Shapiro,
and these are just a few of the profound and powerful stories I'll be mining on our 12th season of
Family Secrets. With over 37 million downloads, we continue to be moved and inspired by our guests
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I can't wait to share
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I hope you'll join me
and my extraordinary guests
for this new season of Family Secrets.
Listen to Family Secrets
Season 12 on the IHeart Radio app,
Apple Podcasts,
or wherever you get your podcasts.
I had this, like, overwhelming
sensation that I had to call her right then and I just hit call said you know hey I'm Jacob
Shick I'm the CEO of One Tribe Foundation and I just wanted to call on and let her know there's a lot
of people battling some of the very same things you're battling and there is help out there
the Good Stuff podcast season two takes a deep look into One Tribe Foundation a non-profit fighting suicide
in the veteran community September is national suicide prevention month so join host jacob and ashley
shick as they bring you to the front lines of one tribe's mission i was married to a combat army veteran
and he actually took his own life to suicide one tribe saved my life twice there's a lot of love that
flows through this place and it's sincere now it's a personal mission don't want to have to go to any more
funerals you know i got blown up on a react mission i ended up having amputation below the knee of my
right leg and the traumatic brain injury because i landed on my head welcome to season two of the
good stuff listen to the good stuff podcast on the iheart radio app apple
podcast or wherever you get your podcast. Hey, sis, what if I could promise you you never had to listen to
a condescending finance bro? Tell you how to manage your money again. Welcome to Brown Ambition.
This is the hard part when you pay down those credit cards. If you haven't gotten to the bottom of
why you were racking up credit or turning to credit cards, you may just recreate the same problem
a year from now. When you do feel like you are bleeding from these high interest rates, I would start
shopping for a debt consolidation loan, starting with your local credit union, shopping around
online, looking for some online lenders because they tend to have fewer fees and be more
affordable. Listen, I am not here to judge. It is so expensive in these streets. I 100% can see
how in just a few months you can have this much credit card debt when it weighs on you. It's
really easy to just like stick your head in the sand. It's nice and dark in the sand. Even if it's
scary, it's not going to go away just because you're avoiding it. And in fact, it may get even
worse. For more judgment-free money advice, listen to Brown Ambition on the IHeart Radio app,
a podcast or wherever you get your podcast.
And we're back.
Our final question of the day is a question from Lewis on Discord.
And here is his question.
Hi, Daniel and Kelly.
I was wondering, what kind of adaptations might we make to humankind,
whether genetic or bionic or anything to help us to live on a place like Mars.
Thanks.
Looking forward to hearing your answer.
All right.
Oh, my gosh.
There's so many problems on Mars.
Which ones should we try to solve?
I'm excited that you're optimistic about this.
I thought your answer might be like, it's impossible to give up.
I mean, the back of my mind is saying that.
But I'm going to, let's try to have some fun.
start with the problems that could kill us. And so those problems are probably radiation,
partial gravity, and depressurization. So I think those are the top three. What do you think,
Daniel? Are those the top three worst problems on Mars? Those sound pretty bad, yeah. And I think
I'd love to hear solutions to those. And this is great because it gives you an opportunity to
demonstrate your optimistic side instead of just throwing cold water on humanity's prospects.
Oh man, I hope that doesn't mean this is going to be a bad answer because it's not in my skill set to
be optimistic. Okay. Let's see. All right, let's hold off on the depressurization problem until
the end because the initial set of solutions that I have are not really good for depressurization.
So one problem is radiation. So as we've discussed on a couple of other episodes,
space has different kinds of radiation than we typically encounter on Earth. So you have solar
flares and solar particle events and these are like shooting protons. You can die right away from
something like radiation sickness, just shuts a bunch of your organs down all at once. Or you can get
cancer, which will kill you slowly. Also, we have galactic cosmic radiation. Not 100% sure where
it comes from. Could be from exploding stars and black holes, but we don't really know. Right, Daniel?
Yeah, exactly. All right. So the galactic cosmic radiation tends to be bigger, like charged ion
particles. I saw this one paper, it was an old paper from like the 70s, but they got a gel that was
meant to be sort of like the human body and they shot an iron ion through it. And it blew a hole the
size of a human hair, which like does, I mean, usually like, oh, size of a human hair
that's used to indicate something small, but like, I don't want holes the size of a human hair
in my brain. Like, that's no good. No, and that's a great image because it reinforces the
message that these things are not like little fuzzy quantum objects to somehow interfere with you.
They are basically space bullets, right? Space is shooting bullets at you. And we have a bulletproof
vest here on Earth, right? Our atmosphere is protecting us. It's absorbing all that kinetic energy.
and we're lucky.
And so, yeah, how do we deal with life on Mars without our atmospheric bulletproof vest, Kelly?
The easiest solution is probably something related to shielding.
But radiation, well, space makes everything complicated.
But one way radiation is complicated is because of something called spolation.
So when galactic cosmic radiation hits your habitat, it hits particles that it then breaks into other kinds of particles
that are also radioactive and now rain down on you in what's called a nuclear shower.
See, Daniel, you asked me for a solution, and I'm giving you reasons why it's worse.
My pessimism is winning.
All right, I'm backing up.
Okay.
Wait, so you're saying if I walk around Mars with like an umbrella of some very heavy-duty material to protect myself from radiation,
it's actually just going to generate like showers of radiation underneath the umbrella.
Depending on what the umbrella is made out of, yes.
So there are some particles that are better at absorbing things.
I don't think anything's really great at absorbing galactic cosmic radiation without breaking up,
but could bury your habitat in regolith, which we've talked about before.
But, you know, human bodies can repair some damage, and some of us are better repairing damage than others.
And so let's assume that part of the solution is you're burying your habitat in regolith, but you could also specifically send to Mars people from Earth who are more radiation resistant.
And to be honest, I don't know how we pick those people yet, because, like, we don't have a lot of experience with space radiation, but presumably there's variation in this trait.
So you could send more radiation-resistant people up to space, and at least for the first
generation, that might help, maybe.
Because they're, like, less likely to get cancer, they have some sort of, like,
genetic predisposition, like, biologically, how does that work?
What is it about some people that makes them, like, more rad-proof than others?
Yeah, no, great question.
Who knows, right?
Here's Kelly.
We don't really know.
And so that there are some people who are like, well, you know, we can pick people who are
more radiation resistant, and then we could figure out what it is about them that makes them
more radiation resistant. And then we could try to use genetic engineering to tinker to make
the next generation more radiation resistant. And like through this combination of crew selection
and genetic engineering, we can create people who can survive better in space. Here's a tiny little
bit of pessimism really quick. I won't linger too long, but, you know, most of the important
human traits are not controlled by like a gene that you can tinker with. So like our genetic
engineering of humans that has gone best so far has involved tinkering with genes that don't get past
to babies and dealing with diseases that are caused by like a mutation in one spot. So if radiation
is controlled by 100 genes, you could tinker with all those genes, but the other problem is that
genes usually don't just do one thing. So when you tinker with all those 100 genes, you might be
messing up other stuff too. So actually, let's go ahead and say that's not the best solution.
And now, because I have a physicist on the show and an optimist, maybe, I'm going to kick to you.
So let's imagine that we are living in an environment where we have, where money is no problem and we have as many nuclear, portable nuclear power plants as we could possibly need.
Could you use electricity in some way to protect your habitat from space radiation?
I know it's energetically expensive, but like, could we super cool?
Like, what are our solutions here?
Yeah.
Yeah. Well, these things are mostly ions, right? And so these, they are charged particles,
and those charged particles can be repelled or redirected by electric fields. But they're very, very high energy.
The good thing is that the very high energy ones are rarer. So while it'd be much more challenging to redirect the high energy ones, there are less common.
The rate falls very, very quickly with energy. But yeah, it would cost a huge amount of energy.
I mean, really the better way to do it is a magnet, right? Rather than relying on their electric.
field because that's what the earth does. The earth has a magnetic field and we deflect a lot of this
stuff. There actually is a fun proposal to put a huge magnet between the sun and Mars to create like a
magnetic shadow for Mars to deflect these particles. And I have a friend of mine who's a planetary
scientist who has actually worked on like Mars missions and he says, quote, this is literally the dumbest
idea I have ever heard. I almost fell out of my chair when I saw someone presenting it.
Okay. I feel like this person would be good friends with me as a fellow pessimist.
I know. And I asked him to elaborate and he says, quote, there are so many reasons it's stupid.
You have to somehow make a giant magnet. You'd have to put it on a ginormous spaceship and keep it in orbit around the Lagrange point.
And he goes on to point out that not all of the radiation comes directly from the sun.
So the shadow wouldn't even protect you. And a lot of the radiation are UV photons, which do not have a charge and will not be defunds.
reflected by magnets or electric fields.
You really need the combination of a magnetic field for your whole planet,
not just a shadow, and you need an atmosphere to absorb the stuff that isn't charged.
So yeah, physics doesn't have an answer for this one either.
Oh, man.
Okay.
Well, let's move on to the next problem.
I don't have an answer, really.
And then, of course, there's all the ethical things that we just completely glanced over with genetic engineering.
So that is something else holding this all back.
All right, so then the second problem is partial gravity.
So Mars has 40% of the gravity we find on Earth.
We know that astronauts who experience no gravity when they're in free fall lose muscle mass, bone density.
And that might explain why they start losing some of their vision, or some of them, not all of them.
Because the fluids, you know, we're adapted to have gravity pulling our fluids back down.
So when we don't have that, like, benefit, fluids tend to go up and they like push on our brain and they might be changing the shape of our eyes.
So 40% gravity.
would that solve the problem?
We don't know.
Like some of those problems, maybe bones and muscles, for example,
that could possibly be solved by, like,
putting on really heavy, weighted outfits that sort of make it
so that you're carrying around as much weight as you'd be carrying around on Earth.
That might help keep everything nice and strong.
I don't know if that's going to help with, like, fluid-related problems
or, like, anything else in your body that's associated with partial gravity.
But you could, and I've seen proposals for this,
create banked racetracks to create artificial gravity.
And you could, I don't know, maybe sleep in those, and that might be enough.
And then I also have seen proposals for what are called sucky pants or sucky sleeping bags.
And they create a different kind of pressure and it pulls the fluids down.
And so you could like sleep in these or wear these.
They're like, you have to tune them well because sometimes when they turn them on like too fast or too strong,
the fluids rush out of your brain and people like,
pass out, which is not great.
And they don't look super comfy.
But so there are some technological solutions.
But to be clear here, you're saying that we know there are problems in zero gravity.
And now we're asking, like, is 40% gravity enough?
Like, do we still have those problems in 40%?
And then what can we do about solving that additional bit, right?
Yeah, right.
So I am assuming that 40% is not going to solve all of our problems.
If it does, then great, we don't need any extra help.
If we do need extra help, here are some things we could do.
But who wants to live on like a banked racetrack their whole life?
That doesn't sound like a fun place to hang out.
Or maybe only part of the time you need to be on the racetrack?
Yeah, we don't know.
Maybe you could sleep on the racetrack and that would be enough.
But we don't know.
Well, what about something like more inherent?
Is there something we can do inside the body, you know, like to modify the structure of our bones
or change some fundamental process inside of us that will just make us more naturally suited
to that kind of environment?
I'm thinking like really science fiction craziness here.
Science fiction craziness.
Okay, so, right, so one of the questions would be, like, does our current genetic makeup include enough variability where we could tinker with things in the right way to make us survive better in these environments?
And so, you know, maybe there are, for starters, people who have bones that are thicker than others and would maybe do better in an environment like this.
And if we can figure out why they have thicker bones, maybe we could tinker with the DNA of future genes.
generations, which is a phrase that makes me shudder just thinking about it.
But anyway, we could do that maybe and, like, thicken up their bones so that maybe it wouldn't
matter if they're in an environment where you would expect bones to atrophy because they
were already stronger to begin with.
Like, maybe that'll be enough.
I really don't know.
For this one, I kind of come up at a loss.
With radiation, I felt like it was maybe a little easier to imagine.
Well, my question is, like, who's working on this stuff?
like can you do any kind of ethical research here in terms of like bioengineering humans
or are people doing like bioengineering on rats and dogs and stuff or just sort of theoretical?
Is it possible to do research in this area?
So with new CRISPR technology, it's easier for us to tinker with genetic information.
So to like cut bits out and replace it with other bits that we want.
And we have used that to help out with some diseases.
So, for example, sickle cell anemia by tinkering with some genes using CRISPR, Cass 9,
we've been able to, like, make people's lives way better.
So we are getting better at using some of these techniques in humans, which is a big step.
I think, and so we're getting a little outside of my expertise,
I think the first time that technique was used on babies in a way that it would be transmitted
across generations was done in China, and they got thrown in jail for that,
because the whole international community was like, no, no, no, no, no.
We were not okay.
None of us are okay with this.
You jumped way too far ahead.
And so I think that research is going to not move forward.
I hope for a while.
And if I could press on that for a moment, like,
I've always wondered, is there a crisp understanding of why it's okay to breed humans
by selecting your mate, but not by editing their genome?
Is the only answer just like, well, this is a dull enough strategy that you can't, like,
feel too bad if you mess up and, you know, your kid doesn't have the genetics you wanted or something?
Like, is it just the power of this technology to create horrendous outcomes?
I think it's a couple things.
So one thing is that we as a species have a lot of experience with mating and having babies and seeing how that turns out.
But when you start tinkering with things at the genetic level, things don't always go the way you think they're going to.
You know, you think you understand a system, you tinker with it, and maybe that child will have catastrophic issues they'll have to deal with for their whole life because you're,
decided to tinker with their DNA. But just to play devil's advocate, the same thing can happen when you
choose your mate. Like, for example, if you're in a small community and you choose to select your
partner inside your community, you open them up to possible conditions that come from small
genetic populations. You know, like, I'm an Ashkenazi Jew. I know that Tasek syndrome would have been
a real risk if my partner was also an Ashkenazi Jew. Yeah. And so I don't think Zach would mind me
admitting that he's a carrier and that I had to get.
get that test because that was a real risk for us, but I think that is why we try to have
genetic testing so that you can be aware of these potential issues and make decisions
based on that to avoid these worst case scenarios. And so I think we would say we don't want
to stop people from marrying and having children with the people that they love, but we do
whatever we can to minimize the negative impacts of that. I think trying to improve a bad
situation you find yourself in is very different than trying to tinker to get something better that
you would ideally have. And so I, and I think that leads to the second problem with genetic engineering
is that there's this concern that people who can afford to tinker with their kids are going to end up
having like what often gets called in the press as like designer babies and that we're going to
further see inequality sort of exacerbated by by this kind of thing. Right. Like I want my kid to be
a long jump champion. So I'm going to give them this genetic package, which costs a million
dollars or whatever. Yeah, that does seem like terrifying. I'm already terrified to make any sort
of decisions from my kids. Like, oh, we're going to this high school or that high school or
you have to eat this way or that way. And I wonder like by the consequences for the rest of their
lives. So, yeah, I'm glad to not have to have made some genetic decisions. Yeah. And we should have
like, you know, maybe one day we'll have a bioethicist on the show to talk about this stuff because
it's complicated. And I feel like the more you think about it, the more you're like, oh, but it would
be great if we could do that, but it would be catastrophic if we could do that. And like,
you know, there are people who spend their whole lives thinking about this much in much more
detail than I did. Yeah. And the technology will be available eventually. And then we're going
to figure out like what to do about that. But yes, let's have an expert on who actually knows how
I think about this stuff. So staying on genetic engineering for a second, there are folks who argue
that we need to start doing this kind of engineering now because it's really important that we
start having self-sustaining settlements on Mars as soon as we can. Because we never know when
something catastrophic could happen to the earth, and it seems like a lot of catastrophic things
are happening lately. So it's important that as soon as we can, we get people living on Mars in a way
that can happen sustainably. And so maybe that should make all of our ethical concerns. Those
concerns should be dwarfed compared to the importance of keeping the human species going. I don't
personally buy that argument. But, you know, there are these emerging debates about the ethics of doing it
and how those ethics sort of change if we think that this is something we need to.
to be doing quickly for the safety of our species.
Wow, it's so hard to imagine what the future of humanity holds.
It can go in so many different directions.
And because I'm a pessimist, I will go ahead and note the one final way you can get humans
that are well adapted to the Martian surface, which is natural selection, which every
once in a while you'll see noted in the literature as like, oh, well, you know, after enough
generations, we'll have people who are well adapted to the Martian surface.
And of course, that means many, many people will die and root.
It's not even 100% certain that we have the right kind of genetic variability where eventually there will be people who can survive, you know, radiation on Mars or living in 40% gravity.
And so we might just lose a bunch of people, which sounds really awful.
Also, don't you assume that you start from a pretty large population?
Like, if you start from 10 people, it's unlikely you're randomly going to have the right genetic mutation.
You need to start from a pretty big population, right?
Which means a lot of people are going to die, like big numbers.
Wow.
Agreed.
Yes. You know, but, you know, Musk would argue with Starship, he can get a million people there in 30 years and he can, you know, keep sending people. I should clarify, Musk is not the one who has said, we're going to let natural selection solve the problem. He hasn't been clear on how this problem's going to get solved. Free market somehow. Free market, something, something.
The next thing we're going to talk about wouldn't solve the partial gravity problem, but would solve problems related to radiation to some extent and depressurization. So the problem is the problem.
with depressurization is that when human bodies go from an area of higher pressure to an area of
lower pressure, the nitrogen bubbles out of our blood. And if it gets stuck in your joints, it causes
the bends because it hurts so much that you bend over in pain. If those bubbles get stuck in
your lungs, you get the chokes, it's hard to breathe. If they get stuck in your nervous system,
you get the staggers, you get these nervous system problems. But if it happens to you in space,
you're just going to get the death, which unfortunately is what happened to the crew of
solute one. They got exposed to the vacuum of space in the 70s. So how do we make a
Martian atmosphere thick enough with enough pressure so that you could go outside without a
space suit? And you wouldn't have to worry about your habitat depressurizing. And Daniel, I think the
only solution to that would be terraforming. Could you thicken up the atmosphere and the pressure
enough by the proposals that I saw involved like sending nuclear weapons to the poles so that you
could blow up the ice there and that that ice would then distribute itself in the atmosphere and
would thicken up the atmosphere and that might even warm up the planets. Could that solve the
atmosphere thickness problem and radiation? Or are we just nuking a planet for no reason?
It's not an easy answer. Like Mars is like 1% of the Earth's atmosphere. So you'd need to
increase the atmospheric pressure by a lot. And there definitely is CO2. And there definitely is CO2 and
the poles of Mars and you could release some of it. But the problem is that if you release
too much CO2, then the atmosphere becomes poisonous to humans. And so it doesn't really solve
the problem. And you'd need a lot of CO2. You'd need to like scoop up some of it from Venus and
transfer it over to Mars. So there's not an easy way to manufacture the kind of atmosphere you want.
Ideally, you want a huge amount of oxygen in the atmosphere. So you can walk around without a suit,
but oxygen is hard to make. You know, you basically need some sort of like microbes growing on
is eating the CO2 and producing oxygen, and my wife is a microbiologist, and she thinks that
would take millions of years optimistically, and on Earth it took quite a long time. And the
rocks are going to drink a lot of that oxygen before it even stays in the atmosphere. And we know
that Mars is like, likes to get rusty, and we don't know if you can gobble up more of that
oxygen. So terraforming is not an easy solution, which is why I think this question is actually asking
for another kind of solution. Like, what can we do to change ourselves so we can, we can
walk around in that 1% like could we engineer some sort of crazy high pressure skin that's basically
like a suit or some change something fundamental about a biochemistry so we could just happily
walk around in 1% atmosphere Daniel nothing's coming to me do you have an answer I mean even if
you had high pressure skin or like what would high pressure skin be like like you turn your skin to
metal basically I just have a natural suit you know as part of your body it's not really an
answer. Basically, you're wearing a suit, but it's part of who you are now. So technically, it might
be a solution. But like if you open your eyes or your mouth, aren't you exposing yourself to the
pressure change? Like, I don't see this working. Look, I only solve the problem for a minute. I don't
just to lunch. Well, you got, you know, incremental. You got to let the market something, something.
Exactly. The first candidate survived until lunchtime and then they depressurize. So let, you know,
take a break and come back and solve the rest of the problem.
time. Yeah, I think the answer is that it's hard, right? Pressure is important and we are just
really not designed to survive in a low pressure environment. You're right, we exchange all sorts
of fluids and materials with the environment and so sealing ourselves off from it is not really
a solution and it's hard to imagine. Well, what if we somehow like inflated humans that we lived
in a low pressure environment? I'm imagining like a completely different kind of biological being,
you know, where like your insides are actually at lower pressure. I can't imagine you'd be able to
do that with current genetic variability that's like available but but i mean you could i guess like
every generation you lower the pressure in the habitat and uh whoever survives you work with that
but that would take a long time and would not be ethical no not even close to ethical no absolutely
not all right so it sounds like we're not going to be adapted to living on the surface of mars very
soon, and even our craziest technological solutions are not really well suited to the task.
I have to admit, I don't feel like we came up with any super satisfying answers, but let's go
ahead and ask Lewis if he feels like we did the best we could.
I'm terrified. What kind of grade we're going to get?
Thanks so much, Daniel and Kelly. I did not appreciate quite the can of worms I was
opening there, and I definitely get the message. I think I'm
I'm going to stick around on Earth for a little while longer.
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