Daniel and Kelly’s Extraordinary Universe - Is the standard model of dark energy in trouble?
Episode Date: May 22, 2025Daniel and Kelly talk about recent measurements that leave us confused about the expansion of the Universe.See omnystudio.com/listener for privacy information....
Transcript
Discussion (0)
This is an I-Heart podcast.
It's important that we just reassure people that they're not alone, 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 Schick as they
bring you to the front lines of One Tribe's mission.
One Tribe saved my life twice.
Welcome to Season 2 of The Good Stuff.
Listen to the Good Stuff podcast on the IHeart Radio app, Apple Podcasts, or wherever you get your podcast.
Hi, it's Honey German, and I'm back with season two of my podcast.
Grasias, come again.
We got you when it comes to the latest in music and entertainment with interviews with some of your favorite Latin artists and celebrities.
You didn't have to audition?
No, I didn't audition.
I haven't audition in like over 25 years.
Oh, wow.
That's a real G-talk right there.
Oh, yeah.
We'll talk about all that's viral and trending with a little bit of time.
achievement and a whole lot of laughs.
And of course, the great bevras you've come to expect.
Listen to the new season of Dresses Come Again on the IHeartRadio app, Apple Podcasts, or wherever you get your podcast.
I'm Dr. Scott Barry Kaufman, host of the psychology podcast.
Here's a clip from an upcoming conversation about how to be a better you.
When you think about emotion regulation, you're not going to choose an adaptive strategy,
which is more effortful to use, unless you think to.
there's a good outcome. Avoidance is easier. Ignoring is easier. Denials easier. Complex problem solving
takes effort. Listen to the psychology podcast on the IHeartRadio app, Apple Podcasts, or wherever you get your
podcasts. Let's start with a quick puzzle. The answer is Ken Jennings' appearance on The Puzzler with
AJ Jacobs. The question is, what is the most entertaining listening experience in podcast land?
Jeopardy Truthers believe in
I guess they would be
conspiracy theorists
That's right
To give you the answers
And you still blew it
The puzzler
Listen on the IHeart Radio app
Apple Podcasts
Or wherever you get your podcasts
You get your podcasts
Physics lets us ask
Big, fat, juicy
questions about the universe
I would claim that these are
The biggest, the fattest, the juiciest questions, though chemists and biologists may disagree,
of course.
But physics lets us discover new elements of the universe like dark matter that tell us our
whole picture of what the universe is made of was wrong.
It lets us think about the size of the entire universe and whether it's expanding.
It gives us the tools that will let us discover the forces that are capable of squeezing
and stretching galaxies and clusters and structures beyond even our capacity.
to hold in our minds.
Probably the most powerful and mysterious discovery in physics maybe ever is dark energy.
The accelerating expansion of the universe has changed our picture of where the energy in the cosmos is,
what it does, and how it shapes the present and future of the entire universe.
Will things be torn apart, left to huddle together with a few other bits of matter among a vast, empty cosmos?
Will things rush back together to collapse everything in every one?
and every one into incredible density mimicking the conditions of the early universe.
Only dark energy has the sheer scale and scope to determine the fate of the universe,
which is why we are all so desperate to understand it.
And dark energy is recent, a concept from the last couple of decades,
which means we have a lot left to learn and that surprises deliciously await us.
Recently, you might have heard that our understanding of dark energy was thrown into new disarray
by some recent measurements.
What does that mean about dark energy?
What does it mean for our understanding of the universe?
What does it mean about the future of the universe?
Should you still save for retirement or just fly to Vegas tomorrow and blow it all in a weekend of excess and debauchery?
We'll dig into the history and the latest mystery and let physics do its best to answer these questions.
Welcome to Daniel and Kelly's extraordinary expanding universe.
Hello, I'm Kelly Weiner-Smith, and I study space and parasites, and I am so glad we have
finally figured out dark energy.
Right, Daniel?
That's what we're talking about today, isn't it?
Wow, what a setup.
What a setup.
Hi, I'm Daniel.
I'm a particle physicist, and I wish I was as cool as dark energy.
sounds. Oh, it does sound pretty cool. You all are really hit and miss on terms of naming stuff,
but with dark energy and dark matter, the goth in me really digs it. Yeah, I don't know if they're
appropriate in the sense that they describe it well, but they do sound very cool. And, you know,
that's one angle for sure. Yeah, no, for sure. So what percent of the articles that you see online
about dark matter and dark energy do you feel are like completely accurate? Completely accurate?
Wow, that is a small fraction.
Oh, man.
Unfortunately, there is so much clickbait nonsense out there.
And that really disappoints me because I imagine if I wasn't an expert and I was curious, like lots of our listeners are, who want to understand the universe in good faith, they read these things and they don't know whether it's nonsense or not.
So if you're out there and you're reading an article and it tickles your nonsenseometer, feel free to send it to us.
I will let you know if you should believe it or not.
But unfortunately, on average, the answer is no.
Because science journalism is hard and getting all the nuances right is very, very hard.
Yeah, that's true.
But I got to say, you know, Ed Young, for example, so he's our biology king of science
journalism.
And he does a really good job of like running stuff by people to check.
So like you can't possibly know everything as a science journalist if you're covering a broad
range of topics.
But I do feel like if you run it by experts, like, why aren't you getting an email every
single day from like people writing about this to be like, hey, can I run it by an expert
before I put it online?
Yeah, well, there's a lot to dig into there.
I think that a lot of folks don't run things by experts.
They read other popular science coverage and get their information from there because
not that many experts are accessible.
You know, professors don't usually answer their emails, though some of us do, and they
don't respond on time and you have a deadline.
So instead of talking to somebody who is a professor about dark matter, you read a bunch
of other articles about dark matter, especially if you're not a physicist yourself so you can't
read the primary literature and decode those weird scientific squiggles.
So, yeah, I think a lot of us are inaccessible.
But hey, that's what this podcast is about, right?
Is making all this science accessible without dumbing it down, digging deep into what's
actually going on and giving everybody out there and understanding and an opportunity to
ask questions.
So if you're a science journalist and you want to write an article about dark matter and dark
energy and you have a question or something you don't think you fully understand, don't
write about it.
If you don't understand it, ask me and I will explain it to you.
There you go. Well, today we are tackling a topic that is really making the rounds that is not quite accurate. Is that safe to say?
I think there's a lot of coverage of this issue, which misses a lot of the important details, yeah.
Okay. All right. So the question we're asking today is, is the standard model of dark energy in trouble? And I'll be honest, I thought the standard model just referred to a thing. And I didn't think that it included dark energy. So are there multiple standard models? Or does the standard?
model I'm thinking of also encompassed dark energy.
So the standard model you're probably thinking of is a standard model of particle physics,
and you're right that does not encompass dark energy.
In fact, it doesn't include anything about gravity.
It's just the quantum forces and the particles and that kind of stuff.
So that's of particle physics.
There's another standard model of cosmology, sometimes called Lambda CDM.
And that's like our picture of the history of the universe and how it expands and dark matter
and dark energy and all of those things.
It's sort of the standard model of cosmology.
Oh, okay, that sounds super interesting.
Yeah.
And this is sort of standard model in a lowercase sense.
Standard model of particle physics, often written with uppercase sense and just refers to who is the standard model.
But, you know, you could have a standard model of, I don't know, parasite interactions or something I imagine, right?
And it's sort of just like the normal usage of the words.
And for that one, it would be capital letters, the best standard model or the most interesting standard model.
But anyway, moving on.
We asked our audience, is the standard model of dark energy in trouble?
And here's what they had to say.
Yes, because recent research has indicated that dark energy weakens over time
and therefore is not constant as astrophysicist first belief.
I would say yes, and I wouldn't be surprised about it.
So quantum dark energy, that disagrees with the standard model.
So yes.
Well, what would you expect if all you do is hide out in shadowy places
and make yourself unknown, of course you'd get into trouble.
The cosmological constant is not a constant, so yeah, I'd say it could be in trouble.
This can only be a good thing as we are becoming one step closer to understanding the truth.
Given how little we understand today of dark energy,
I really hope the latest findings do put the model in trouble
because otherwise what's it going to do run away from us and an accelerating rate forever.
I didn't think the standard model included dark matter,
dark energy so i'm going to surmise that the standard model is not in trouble judging from the
headlines i would say yes so i'm just curious with the standard model of dark energy have to go
the principal's office um have to hire a lawyer have to appear before congress it may well be in
trouble from some of the headlines you read but uh i'll like to delve further and uh so
Dr. Dan's got to say.
Dark energy may be changing over time and may not at all be constant.
The standard model of dark energy is no longer in line with data that's coming in.
So, yeah, I think it needs to go to the principal's office.
I seem to remember hearing something about the expansion of space being variable.
Is that something to do with it?
I wasn't aware that there was a standard model for dark energy, but I suppose the question being asked assumes that it is.
So I'm going with yes.
As always, I love you all.
The answers are either deeply insightful or absolutely hilarious.
And so thank you for writing in.
You too can participate, send us your response to the questions of the day.
ride to us to questions at danielankelly.org and we will hook you up what did you think of these responses
i thought they were great some very insightful some totally hilarious some echoing your question
about like hold on if you're talking about the standard model that already doesn't include dark matter
and dark energy so yeah great stuff yeah i bet there were a bunch of people who are like this is
another trick question from daniel because he loves those they're not trick questions
It's just that, you know, if I'm asking about something, then we expect it's probably something interesting we learned recently in the news. So, yeah.
All right. Well, let's start from the beginning. What is dark energy? I mean, I know because it's physics. You're going to be like, oh, we don't know.
It's great to define these terms because, like, just in philosophy, you can avoid a lot of talking past each other if you're clear about what you mean. And so the best way.
to understand dark energy is to understand that it's just our observation of how the universe is expanding
and accelerating. And that's a very recent observation. And it's important, I think, to put that
in historical context and remember, like, what we used to think was happening to the universe,
what we used to think was natural or made sense. Only like 100 years ago, before Hubble and Levitt
and those folks, we thought the universe was static. We thought there was just a single galaxy,
just a bunch of stars hanging out in space.
And that was it.
That was the universe.
And it wasn't shrinking.
It wasn't expanding.
There weren't stars that went on forever.
It was just like one,
our little blob of stars hanging out in space.
And that was people's mental picture of the universe.
Your mental picture,
probably influenced by wonderful programs like Nova
and pictures from James Webb,
is of a universe filled with galaxies upon galaxies upon galaxies.
It's a very different context.
And for me,
the context of our lives,
that's what physics is about, right?
So this, like, is a complete shift in the universe we think we're living in.
I mean, if there were more parasites in space, I'd probably be way more excited.
But that is an inspirational thing to think about.
The day the James Webb Space Telescope discovers space parasites, I'm also going to be excited about parasites.
That's what it would take, huh?
At a minimum.
All right, so before Hubble, we think there's just one galaxy hanging in space.
And that's natural.
People imagine, like, oh, it's probably been like that forever, because why wouldn't it be?
You know, the idea of an infinite past was sort of fine, not a big deal.
But then Hubble and Henry Ed. Leavitt figured out a way to measure the distance to stuff.
This is really important because when you're looking out into space and you're looking at a star, you can't tell, hey, is that star incredibly bright but really far away so it looks kind of dim or actually kind of dim and like not terribly far away, cosmologically speaking?
You can't tell the difference if you're just looking at the intensity of the star because you don't know how bright it actually.
is. And if you want to make a 3D map of the universe, knowing how far away things are
is crucial, right? Because otherwise, you're just looking at like the equivalent of a 2D
screen that surrounds the Earth. And so how do you calibrate so that you can figure that
stuff out? Yeah. So we can actually tell how far away stuff is, if it's pretty close by using
parallax. It's the same principle that you can use to like tell whether a baseball is close to you
or far away from you. It's the fact that you have two eyes, binocular vision, and they
give a different view of the same object.
And if something is close by, your eyes have a very different perspective on them.
And if something is far away, they have basically the same perspective.
Like if you hold up your coffee cup in front of your face and you close one eye and open the other one and go back and forth, you can see that the picture looks very different.
And your brain uses that information to say, okay, the coffee cup is close.
But if it's farther away and you do the same thing, it's hardly a difference.
Your brain does all the math and tells you where the baseball or the coffee cup is.
So that's parallax.
we can do the same thing in space
because the earth goes around the sun
and so over the year we have different
views of the cosmos.
So if something is pretty close to us
then it looks pretty different from one side of the sun
and the other side of the sun
whereas if it's like a gazillion light years away
that hardly matters.
Wow! So we can use that to measure the distance
to nearby stuff. So you've got to be pretty
patient to figure this stuff out then because it's like
six months or something in between
data collection moments. Yeah.
And this is actually the reason
that the Greeks got the solar system wrong.
The Greeks knew about this method, and they used this method, and they tried to see how far away
the stars were, and they couldn't see any wiggles at all, because the stars are pretty far away.
They assumed they were pretty close.
And so because they didn't see the stars wiggling, they assumed the earth doesn't move around
the sun.
Oh, that's fascinating, but we have better instruments so we can calculate that.
Is that the difference?
Yeah, exactly.
It wasn't until, like, the 1800s that we could see the stars wiggle, because the wiggled.
is small, right? And so without those instruments and without the assumption that the stars are
close, you can actually tell how much the stars are wiggling and then you can tell the distance to
them. So the Greeks assumed the stars were close and they couldn't see them wiggling. So they assumed
the flaw was that the earth wasn't moving. Of course, the earth was moving. It's just that the
stars were further than they thought. Sort of fascinating history of like what people think is natural.
That is a pretty clever way to try to figure out if the earth is moving or not. Like good on them.
Yeah, exactly. People are always dumping on the Greeks.
including me for many years, for not doing empirical science,
but like this is a good example of coming up
with a clever technique, taking some data,
using it to draw conclusions.
And you know, they got the wrong conclusion
because they had one mistake and assumption,
but it's pretty solid work.
Yeah.
Anyway, we can do that for nearby stuff.
More distance stuff is hard because if it's not wiggling,
you can't tell is an a zillion miles away
or two zillion or half a zillion.
And so what Levitt and Hubble figured out
was a way to measure the distant to more distant star
stars by looking for a particular kind of star called sephids.
Sefids are star that have variable brightness.
Like they're not just like the sun that mostly burns the same.
They go brighter and dimmer and brighter and dimmer.
And that's because of stuff that's happening on the inside.
There's like hot layers that rise to the surface and then collapse.
There's like, you know, crazy stellar chemistry going on there.
Hmm.
Are they made out of different things than our sun?
It's definitely connected to what they're made out of it because part of the star is opaque to its own radiation.
And so the glow from the inner part of the star then pushes that part of the star out and so you have to have some sort of opaque layers and they think this might be involved with helium, but it's not totally understood. There's some similar stuff going on inside our star with layers of opacity and transparency. We can talk about that another time. We talk about the solar magnetic field, but the cool thing about these stars is that the variability in their brightness is very closely connected to their actual brightness.
So if you, for example, watch one of these stars and you say, oh, it goes bright and dim with a period of a day or five days or 10 days, you can use that to determine how bright it actually is.
So you can measure the actual brightness of it just by measuring its variability.
Wow. Okay. All right. So now we know about variability of brightness and we know how it appears to change as you move locations.
And what do those two pieces of information tell us?
So they allow us to weave together what we call a distance ladder.
For nearby stuff, we use parallax.
And then near the edge of our ability to do parallax, there are some sephids, some of these
variable stars, and we can use parallax to calibrate the sephids, and then we can use sephids
to go even further.
Because if you know how bright a star is, actually, it's true brightness, and then you measure
its brightness here on Earth, you can tell how far away it is.
That was the missing piece, right?
We didn't know if this star is bright and far away or dim and close, but now because we
know whether it's actually.
bright or actually dim, we can tell if it's close or far, by its apparent brightness here on Earth.
And the crucial thing is that these two ladders, the parallax and the sephids overlaps,
which is a period where we can use parallax to calibrate the sephids and then extrapolate further
for stuff that we couldn't use parallax for.
And this gave Hubble this incredible 3D view of the universe we didn't have before.
He could tell the distance to all kinds of stuff that nobody knew, hey, is that actually a smudge
in the sky but pretty close?
Or is it something incredible and massive, but deeply, deeply distant?
And is this how he figured out that the universe was expanding because things changed their location over time?
Well, number one, he discovered that there are other galaxies.
We used to see these things in the sky and we called them nebulae because they were sort of like smudgy in our telescopes and people are like, hmm, maybe they're just big clouds of gas.
Turns out, no, there are actually entire galaxies that are much bigger in many cases than our galaxy, like Andromeda, so much bigger than our galaxy.
He was able to unravel this puzzle because he could measure the distance to them.
He found sephids in those nebulae, and he was able to tell, oh, my gosh, that thing is so much
further away than anything else, any of the other stars.
It's its own galaxy.
Oh, my gosh.
Instantly, this like mental picture of the universe just expands from, we have one galaxy
with some fuzzy clouds in it to take all those fuzzy clouds and promote them to their own
super distant, incredibly large galaxies, and the universe now filled with galaxies.
That's often overlooked in the story about the expanding universe because what Hubble actually discovered is that the universe is filled with galaxies, not just our own.
And around when was that happening?
This is the 1920s.
So it's just like 100 years ago, right?
Most of humanity had no idea that this was the case.
But you're right.
The other crucial thing that Hubble discovered is he was able to measure the apparent velocity of these galaxies.
By looking at the light that came from the galaxies and how he was shifted by velocity,
If something is moving away from you,
its wavelengths are lengthened.
And if it's moving towards you,
its wavelength are shrunk.
And so if something is redshifted,
it means it's moving away from you.
And all the galaxies were redshifted.
And the ones that were further
were redshifted more.
And so this is Hubble's discovery
that there's a close relationship
between the distance to a galaxy
and its apparent velocity.
Things that are close by are moving away from us slowly.
Things that are further away are moving away from us faster.
Things that are very, very distant
are moving away from us even fast.
So this is Hubble's view of the expanding universe.
And this was like second mind-blowing revelation.
Not only is the universe filled with galaxies,
they're all running away from us.
Yeah, right. So if everything is running away from us,
does that mean that we're the stinky galaxy?
Or does that mean that we're the center of everything?
Or like, why is everything moving away from us?
Mm-hmm.
Everything is moving away from us,
but everything is moving away from everything.
Oh.
The whole universe is expanding.
The mental picture in your mind,
Actually, velocity is not the best way to think about it because when we get to acceleration in a minute, somebody is going to be like, hold on.
Daniel said you could measure acceleration.
Acceleration is absolute.
And they're going to be right.
The right way to think about it is in terms of expansion.
Space is growing.
So everywhere space is just stretching, which is why the raisin bread analogy is actually kind of perfect.
Like all the raisins and the raisin bread are getting further away from all the other raisins.
No matter where you look in the universe, everything is moving away from you.
It's not because we're in the center.
We're not special.
There is no center.
Everywhere in the universe sees everything moving away from it.
Well, I also try to move away from raisins as much as I can.
But all right, so where do we go from here?
So Hubble measured this relationship between the velocity of distant galaxies and their distance from us.
You plot those on a graph.
You get a straight line.
The slope of that line is the Hubble constant.
It's this relationship between them.
And this we know now is a number that's something like 70 kilometers.
per second per megaparsec, which essentially is a measurement of the expansion rate of the universe.
It's not a velocity. It's a velocity per distance. Because as distances grow, the apparent velocity
the galaxies are moving away from each other with grows also. So you can't like compare this to the
speed of light as the wrong units. But this is the crucial number. It tells us how fast is the universe
expanding. And it's called the Hubble constant, even though it's not a constant. Thanks, physics.
But we have now this new view of the universe that everything is expanding.
And for decades and decades, that's what people thought was happening.
The universe was expanding and they were wondering about the future.
Like, hmm, is it going to continue to expand or is gravity going to eventually win
and pull all these galaxies back together into some sort of big crunch?
That was the big question being asked in like the 1990s when people tried to look even
further into space.
That sounds existential, but don't be scared.
We're going to give you some more information
when we get back from the break.
Hola, it's HoneyGerman.
And my podcast, Grasias Come Again, is back.
This season, we're going even deeper
into the world of music and entertainment
with raw and honest conversations
with some of your favorite Latin artists and celebrities.
You didn't have to audition?
No, I didn't audition.
I haven't auditioned in, like, over 25 years.
Oh, wow.
That's a real genius.
We've got some of the biggest actors, musicians, content creators, and culture shifters
sharing their real stories of failure and success.
You were destined to be a start.
We talk all about what's viral and trending with a little bit of chisement, a lot of laughs,
and those amazing vibras you've come to expect.
And of course, we'll explore deeper topics dealing with identity, struggles, and all the issues
affecting our Latin community.
You feel like you get a little white.
because you have to do the code switching?
I won't say whitewash because at the end of the day, you know, I'm me.
Yeah.
But the whole pretending and code, you know, it takes a toll on you.
Listen to the new season of Grasas has come again as part of my Cultura podcast network
on the Iheart radio app, Apple Podcast, or wherever you get your podcast.
I had this, like, overwhelming sensation that I had to call it right then.
And I just hit call.
I 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 battle.
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 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 mystery.
Don't 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 Podcasts, 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,
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, Apple Podcasts, or wherever you get your podcast.
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 salvage
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. Daniel just made us all a little bit nervous that the universe might have a big crunch at some point where everything sort of smooshes back in on itself. So Daniel, help me sleep tonight. Give me some more information.
Well, I can sell you some big crunch insurance, if you like. It's a really big payout. If the universe collapses into a mega black hole, you will get a big deposit in your bank account. How about that?
Doesn't make any sense. I'm not convinced.
Some people just buy insurance to feel better.
Remember those folks who were buying like Y2K insurance?
Like they say, if society collapses, we will helicopter you a bunker with weapons and food and whiskey.
And I was like, they're never getting that delivery.
No, no.
I've started researching having pigs and I've been watching videos about pigs.
And one of the videos, you know, nonchalantly they said, oh, no, it was geese.
It was geese.
I've been researching a lot of animals lately.
Anyway.
It's not that easy to confuse.
Pigs and geese.
Well, I want both of them.
Make sure you click the right button when you order because, and I hate to be the one
to bring up cannibalism, pigs will eat your children and geese will not.
That's true.
And pigs will eat each other, as we learned in the Trichinella episode.
Anyway, one of the videos that I was watching in a totally like nonchalant voice was like,
well, and from a prepper perspective.
And I was like, oh, this is the community that I'm associated with now.
My interests align with this community.
All right.
Anyway, back to dark energy.
So in the 1990s, we wanted to look even first.
further into space to understand the broader scope of this expansion because the further we look
in the space, the further back we look in time, right? Because remember, light traveled at finite
speed. And so if something is happening across the universe right now, we can't see it for billions of
years. But when we do look out deep into the universe and we see light that has taken billions of
years to get here, we're seeing things that happened billions of years ago. So if you want a timeline
of the expansion of the universe, so you can better predict the future, for example, like what is
the trajectory, it's useful to look further into the universe and to know how far away is that
stuff and how quickly is it moving away from us that gives you like a deeper picture and lets
you extrapolate to the future. And sephids are cool, but only if you can pick them out, right?
Only if you can like find an isolated sephid in that distant galaxy so you can identify it.
That works great for stars and for regions of our galaxy and for nearby galaxies, it's okay.
but thinking about really distant galaxies in the early universe,
Ceph is basically peter out.
So we needed a new technique, a new element of our distance ladder
to look further into the universe and into the history of the expansion.
Okay, and I keep asking, tell us about dark energy,
but we don't really get to it.
So is dark energy going to be the answer now?
We're just about to get to the dark energy
because in the 90s, people figured out another standard candle.
These are type 1A supernova.
And these are incredible collisions,
when a neutron star, which failed to go nova or fail to become a black hole, gobbles
up a little extra bit of matter and goes supernova in this very precise, very predictable way.
The light curve rises and then it drops.
And it's not that all Type 1a supernova are the same, but from the shape of the light curve,
you can determine the true brightness.
Just like with the Sephids, there's something you can measure without knowing the distance
that tells you the true brightness, and then from the true brightness and the apparent brightness,
you can tell the actual distance.
Type 1A supernova are perfect for looking deep into the universe because they're incredibly
mind-bogglingly bright.
Like a type 1-A supernova can be brighter than its entire galaxy for a moment.
Oh my gosh.
So people realized this and then there was a huge race.
There was a team in Australia and a team at Berkeley that realized if they gathered enough
of these type 1-A supernova and watched them, they can make a 3D map of the universe that dwarfed
Hubble's map and went deeper in the history of the universe, which would allow us to make
fit and project and predict what's going to happen for the future of the universe like what an
exciting moment when you realize you have an ability just on this tiny little planet in the corner
of the universe to understand the fate of the entire cosmos like oh my god drunk with power right
were you at berkeley at this time this was before you all the stuff was happening while i was at
berkeley i was not involved in it at all but yeah i knew it was happening at the time it was really
exciting and they were like really racing both teams knew like okay we know how to do this and it's
going to take a few months, let's not be scooped. In the end, it was kind of a big tie, which is
great. But they discovered something shocking. You know, they discovered that the expansion of
the universe is not slowing down and it's not just continuing smoothly. It's speeding up, right?
That's dark energy. Dark energy is the observation that the expansion of the universe is
accelerating. That year after year, this quantity we call the Hubble constant is going to be
growing. The expansion of the universe is increasing. And I remember that you told us in a
prior episode what is energy or where does energy come from that as the universe expands it seems like
more dark energy is made is that right but i'm still having trouble thinking of dark energy as
the expansion of the universe is it like the battery that's fueling the motion outward how do i think
of this yeah so the phrase dark energy is sometimes used to describe this observation we know the
universe is expanding and that expansion is accelerating and then naturally you're like well
what's doing it, what's an explanation?
Daniel, what's the theory of it?
And there are few possible explanations for what could be creating this accelerating expansion.
And sometimes they are described as dark energy, but really they're all very loose placeholders.
And the sort of leading candidate until recently was what you described, the idea that space
might have some inherent energy within it, a potential energy.
And energy in general relativity is complicated.
A lot of people think, oh, general relativity tells us,
energy makes curvature, you know, just like mass and anything causes things to collapse.
But general relativity is complicated.
We talked about in our potato episode, different kind of energies contribute differently.
And if you have potential energy in all the space, it actually creates repulsive gravity, pushes
things apart.
It accelerates the expansion of the universe.
So on one hand, we observe the accelerating expansion of the universe.
On the other hand, we have a way within general relativity to create accelerating expansion
of the universe.
So there's a knob there called the cosmological constant.
You just put this number into the equations and say,
if space has this energy inherently in it,
then that would cause the accelerating expansion.
Now, we haven't observed that energy directly.
It's not like we found that energy.
Not like we identified where it comes from or what quantum field it would be or whatever.
It's just like, okay, this number would work if we could figure out
if that's really happening.
But that number, as you say, assumes dark energy is constant.
You make more space, you get more dark energy.
And that predicts a very specific way in which dark energy grows over time.
Because it actually starts to take over.
As the universe expands, matter gets diluted, right?
You have the same number of protons, more space, its density goes down.
Radiation gets diluted even more because it also gets redshifted.
But dark energy doesn't.
But a cosmological constant, dark energy, see, I just used it to describe the explanation, not the observation.
it doesn't get diluted.
The universe expands, more space.
It's a constant in space, and so therefore it goes up in its fraction.
And the naive prediction then of the future is that dark energy just is a runaway effect
because as the universe expands, its density is the same, which means its overall fraction keeps rising.
So that's sort of the standard model of cosmology until very recently.
People were like, well, look, this works pretty well.
We have some dark energy.
We have some dark matter.
We have this history of stuff.
how matter used to dominate, how radiation used to dominate, how as the universe expands, those
things change, and that described things pretty well. And people are like, okay, let's really nail
it down. Let's measure things super duper precisely in lots of different ways and make sure we always
get a consistent answer. Because if so, that tells us we know what we're doing. Over the last
few years, though, there's been some tension in this concept, this standard model of cosmology.
And it goes by the name of the Hubble tension. And it's old news, but it's important to keep in your
mind when we talk about the new news and dark energy because the two tell very different
stories about the future.
So the Hubble tension is like a great piece of science.
You know, anytime you see something new in the universe, you want to check your assumptions.
You want to measure three different ways with different assumptions because that could
reveal that, oh, actually we don't know what we're doing or no, we really do understand
this.
Like, you know, we saw the top core of the Tebatron.
We measured its properties.
Then we measured it in completely different collisions and a different collider in a different
country with different detectors and different people, we got the same numbers. We're like,
okay, probably was there. We got that right. If not, we'd be upset, right? Or we'd be confused
and we'd think there's a hint. So they did the same thing with measuring the Hubble constant.
The measurement I told you about is what we call the late universe measurement. We're looking at
the expansion of recent times. We're using parallax. We're using Sephids. We're using type 1A
supernova. That's like, you know, in the last 10 billion years of the expansion of the universe. They can't
penetrate all the way to the very beginning because you need type 1a supernova and they do eventually
get dim but that's what we call the late universe measurement so you measure that you get one number
for the Hubble constant it's like 74 kilometers per second per megaparsec and a lot of careful
work has been done there because like what if you don't understand supernova what if the different
kinds of supernova what if the light is passing through different stuff and there's like entire
batteries of people whose entire PhD was like thinking about a way maybe this went wrong and
and finding some clever way to check it.
It's incredible what folks are doing in astrophysics.
So you had mentioned that the Hubble constant
isn't actually constant, it's a number that's changing.
So that number that you gave us,
is that a value for Friday, March 23rd?
Yes.
OK.
Yeah, it's the recent measurement, right?
It's the late-time expansion number.
But you can also measure this in the early universe,
because if we look at the most ancient light in the universe,
the cosmic microwave background light,
it's light from when the universe was very dense,
It was a hot plasma, and it was glowing, and suddenly it became transparent.
So instead of that light continuously being emitted and absorbed, it was just emitted, not absorbed, and is still around.
And if you look at that light, you can learn so much about the density of the universe and what it was made out of.
You can tell how much dark matter there was.
You can tell the expansion rate.
You can tell how much matter there was.
It's really incredibly rich.
And we can have a whole other episode digging into that science.
But essentially, what you can do is from the wiggles in the cosmic microwave background
radiation, you can measure the expansion rate of the universe.
And then you can propagate that forward and say, if we measure the number from the early
universe, what number should we measure today?
So now you can compare these two numbers, apples to apples.
And the C and B measurement, what we call the early time measurement, propagated forward
to compare, gives us a different number.
Gives us a number like 67.
And when these two numbers came out, people were like, hmm, that's weird.
you know, the uncertainties were kind of big, like 67 isn't that different from 74 if they both
have like a plus or minus 10 on them. But as people spent more time and more energy whittling down
these uncertainties and measuring these more precisely, the numbers didn't change. Just the
uncertainties shrink. And now we're like, yeah, these are two different numbers. And that's a
concern because if it's right, it means dark energy can't be constant. It means like maybe dark energy
is growing with time, right? Dark energy was weaker and now it's stronger in late times.
So this is the sort of context for these recent measurements by Daisy and dark energy we're
going to talk about in a minute. Dark energy, this incredible story of discovering the
accelerating expansion of the universe, an attempt to describe it using a simple model,
the cosmological constant, which requires dark energy to be constant in space and therefore
grow in a certain way. But then our observation, this Hubble tension, that it doesn't quite
work that our measurements from the early universe and our measurements from the late universe don't
jive with the way we think dark energy operated that maybe it wasn't a constant in space right maybe
that whole assumption was wrong maybe it's not a cosmological constant maybe it's some other weird
thing that's sort of similar but not quite so that was sort of the context for this recent study
okay so the tension is that 74 is not 67 that's right okay and remember to explain this tension
you need some theory where dark energy is getting stronger recently all right
Well, let's take a break.
And when we come back, we're going to find out what this new experiment tells us about this tension.
And also, I hope one day there'll be a Weiner-Smith conflict to match the Hubble tension.
Well, it's good to have goals in science.
Hola, it's HoneyGerman.
And my podcast, Grasias Come Again, is back.
This season, we're going even deep.
into the world of music and entertainment
with raw and honest conversations
with some of your favorite Latin artists and celebrities.
You didn't have to audition?
No, I didn't audition.
I haven't auditioned in like over 25 years.
Oh, wow.
That's a real G-talk right there.
Oh, yeah.
We've got some of the biggest actors, musicians,
content creators, and culture shifters
sharing their real stories of failure and success.
You were destined to be a start.
We talk all about what's viral and trend,
with a little bit of chisement, a lot of laughs,
and those amazing Vibras you've come to expect.
And, of course, we'll explore deeper topics
dealing with identity, struggles,
and all the issues affecting our Latin community.
You feel like you get a little whitewash
because you have to do the code switching?
I won't say whitewash because at the end of the day, you know, I'm me.
But the whole pretending and code, you know, it takes a toll on you.
Listen to the new season of Grasasas Come Again
as part of my Cultura podcast network
on the IHartRadio app, Apple Podcast,
or wherever you get your podcast.
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 nonprofit 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 line
of one tribe's mission. I was married to a combat army veteran and he actually took his own
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. I don't 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 two of the Good
Stuff. Listen to the Good Stuff podcast on the Iheart radio app, Apple podcast, 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 get caught, and I just looked at my computer screen.
I was just like, ah, got you.
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.
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 a
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, Apple Podcast, or wherever you get
your podcast.
All right, we're back.
So Daniel, you were telling us about the Hubble tension and that labs have been working
hard to try to figure out what is causing this difference between the two different
measures for the expansion of the universe.
What have we learned recently?
Yeah.
So there's been a lot of really interesting stuff happening with dark energy, including new
theories, like, I want to spend one minute talking about this time.
A lot of people heard about huge PR echo chamber from this one paper where somebody suggested that, wait, maybe the universe isn't actually accelerating in its expansion.
Maybe we've messed it all up.
And his theory was that time is slowed down near massive objects.
We know that to be true.
So maybe the universe is lumpier than we thought and there are parts of it that are denser and that's affecting the way we're interpreting this stuff.
And so this theory went by the very cool name of timescape.
and it pinged around the internet
and I got a bunch of emails
and a bunch of listeners heard about it
and thought, oh my gosh,
are we getting rid of dark energy?
And that would be very cool
and we're open to that.
But this theory requires
the universe to be a lot lumpier
than we see it to be.
Like it would require a lot more mass
in areas to create this kind of effect.
So the data just are not consistent
with the timescape theory.
Nobody I know in cosmology
is taking that seriously at all,
even though we got a lot of press.
So there's not often a lot of correlation
between like how excited the science journalism core is about an idea and how excited the actual
scientists are about an idea.
But there is something that happened very recently, measurements from the Daisy experiment.
They used a completely different method to measure the expansion of the universe, one that fits
sort of very nicely between the very early universe measurements from the cosmic microwave
background and sort of later time measurements from the supernova crew.
They use something called baryon acoustic oscillations where they see the,
these rings of matter from oscillations in the early universe.
And by looking at these rings of matter, it sounds like you just said that it agreed with both
of the values, so it agrees with 67 and 74.
So this is a new technique, and it's cool that it's complementary.
By complementary, I just mean like they're using another approach.
Okay.
When I say it fits nicely in between.
I don't mean that their measurement is in agreement with the other folks.
I mean that the time period they could study is deeper into the past than the supernovae
folks and not all the way back to the beginning of the universe. So in the universe timeline is sort of
a nice like probe of the sort of middle section. Okay. All right, cool. And it's very cool
study. What they're looking for are these incredible echoes in hot plasma from the early
universe. And so, you know, you imagine the early universe. It's very hot. It's very dense. You got like
protons. You got electrons. You got dark matter in there. It's incredible. And it's mostly
radiation dominated. Like the early universe, mostly folks.
like a billion photons for every electron.
It's hard to wrap your mind around because we're definitely not photon dominated now.
And that's because the very early universe made matter and antimatter, which then mostly annihilated into photons.
So that's why it's bathed in photons.
Anyway, these photons are flying around and they're pushing on the electrons and on the protons, right?
Because that's what photons do.
They interact with charged particles.
And so this plasma made of protons and electrons is opaque.
to the photons, it's pushing on them, just like the light inside the variable stars creates
this outward pressure, creates this density waves, right? But dark matter, on the other hand,
is pulling the stuff in because of gravity. Dark matter ignores all this pressure. Photons
fly right through it. So you have these two different effects. The photons pushing out and the
dark matter pulling in, and you get these density ripples. So we know that dark matter does act
on electrons and protons. Is that what you were saying? It acts on electrons and protons only
through its gravity. But there's a lot of it in the early universe. It's very dense. So this does
have an effect. And so these density ripples are moving through the early universe at a really
incredible rate. You know, the speed of sound depends on the density of something. So,
for example, speed of sound through air is pretty high, but it's tiny compared to the speed
of light. But the speed of sounds through water or through the earth is faster, right? A speed
of sound through steel. That's why you could like feel a herd of buffalo coming through the ground
before you heard them salivating or crushing you, for example.
They're herbivores, I think, Daniel.
They would still crush you.
Yeah, that's true.
Anyway, in the early universe, it's so dense that the speed of sound is about half of the
speed of light.
Wow.
Incredible density.
So these pressure waves are shooting out at half the speed of light, but then at some
moment the universe is expanding and it's cooling.
And so protons and electrons come together to make neutral hydrogen, right?
and now they are transparent to those photons.
So the photons are flying through them instead of pushing on them.
And that's a little bit of quantum mechanics right there, you know, because a free electron,
one that's just flying around, it's not an hydrogen atom, same with a free proton,
can absorb a photon of any energy.
It's just like no big deal.
It's only when you can find them that you get the energy levels, this quantization of the energy levels,
that the electrons become so picky and say, I'm only going to absorb a photon of this energy
or of that energy.
Posh electrons.
I know.
They become all snobby in their fancy houses.
And now the universe is transparent, so the pressure stops.
So you get these rings that were created, and then at some moment they get, like, frozen
in because they can no longer change.
There's no more outward pressure, right?
So you get these high-density regions in the universe.
You might think, why do I care about early universe high-density regions?
Well, dense regions in the early universe lead to structure in the later universe.
Like, why do we have a galaxy here and not over there?
Because 14 billion years ago, there was a little bit higher density of stuff.
And then gravity took over and gathered that together into a big blob of stuff that became a galaxy.
So what they do in this experiment is they don't look at the early universe plasma.
They look at the distribution of galaxies in the universe.
They just like make a huge map of galaxies.
And they look for rings.
And they find these bubbles, these same literal bubbles.
You can see them in the universe.
It's incredible.
Oh, do you have this like foam of galaxies where the galaxies are mostly on the edges?
And then you also have galaxies in the middle, but there's a higher density along these bubbles.
So incredible.
So much cleverness here to see this early history of the universe.
So around 20 years ago, we saw these first evidence that like we can actually see the baryon acoustic oscillations from the early universe as it transforms into the structure of the universe today.
And the recent measurement by Daisy is like a super big.
camera that looked at more galaxies than anybody ever had measured them deep into time, deep into
the history of the universe all the way back to like 300 million years. So you can see this
structure early on. You can see it later. And because it was sort of a fixed yardstick,
you can measure the expansion of the universe by seeing the size of these bubbles over time.
It's sort of like, you know, a standard candle again. So they recently came out with the results.
And this fills in a gap, right? We saw the early universe measurement.
We saw a pretty late universe measurement.
This is sort of like the middle age universe measurement?
People wondering like, what's it going to say?
And is it consistent with the dark energy density that's a constant in space or what's the behavior of it?
And so the result's very confusing.
Oh, no.
I thought you were going to give me a clear answer, Daniel?
No.
Unfortunately, or excitingly, it's in chaos.
So they see something that doesn't look like dark energy is constant in space.
The expansion of the universe that they measure is not consistent with a dark energy that
just has constant density and therefore grows at a certain rate as the universe is expanding.
And you might think, okay, that's cool.
The Hubble tension already told us that, right?
Yes, but the Hubble tension told us it was different from constant in a different way.
The two are inconsistent.
This new measurement from the variant acoustic oscillations is inconsistent with constant dark energy
and inconsistent with the Hubble tension explanation.
Yeah, so this sees dark energy as weakening.
According to Daisy, dark energy is getting weaker over time.
The Hubble tension needs something that's getting stronger at the end of the late universe.
I mean, there are other ways to explain it as well.
But it's not like, oh, this nicely clicks together with this other story we already were getting hints of from these other experiments.
So I talked to a cosmologist in my department here, Kev Abizajan, and he calls this chaos cosmology because something basic is wrong, you know.
And that's fine.
It's early days.
we've only been studying dark energy for a couple of decades, right?
So, like, of course we're still learning really basic things about how it works.
And what we've done is apply a very simple model.
Take the cosmological constant, use it to describe dark energy, see if that works.
Amazingly, it kind of worked for 20 years until we made more and more precise measurements.
Now we're saying that it doesn't really work, and we don't have a better framework right now.
We don't have an explanation that can explain these recent results from Daisy, the barrier on
acoustic oscillations and the Hubble tension that we've been puzzling over for the last 10
years or so.
So there's a lot of exciting discoveries to be made.
Does this mean that the universe is not necessarily expanding anymore or just that our
understanding of the mechanism is not good?
The universe is definitely expanding.
We don't really know if it's accelerating at the same level as we thought it was.
Okay.
And we don't know how that acceleration is changing.
Right? So it's sort of like another derivative there, the jerk of the universe, if you will. And that says a lot of
important stuff about the future, right? The previous view, the simple view, the cosmological constant,
that dark energy was constant in space and therefore increasing as a fraction of the universe over time,
that painted a picture of a universe torn apart by dark energy. Because as things get further apart and
dark energy takes over, then they just move apart faster and faster and faster and faster.
And the future of that universe is a bunch of galaxies that collapse into black holes that are
just like incredibly far away from all the other black holes.
That would be the future of the universe if the cosmological constant was the thing
causing the accelerating expansion.
But if Daisy is right and dark energy is somehow weakening, then that acceleration is not
necessarily going to keep ramping up.
And it could be that it slows down.
And it could even turn around.
We could be heading for a time when you wish you had purchased Daniel's extra premium
dark crunch insurance policy.
You con man.
That's what this whole episode is just a grift for me to sell you my insurance.
Look, I promise you, Kelly, if the universe collapses into a black hole, I will be there
with like a cabin and goats and whiskey and whatever you need to survive the end times.
And pigs and geese.
Exactly.
We'll put that on your policy, no extra charge.
Oh, thanks, Daniel.
I love a good deal.
A lot of information came at me today.
So forgive me if I'm totally getting this wrong.
But I thought the explanation for why the galaxy has rings depended on our understanding of dark energy.
Dark matter.
Dark matter.
Oh, I'm always mixing those two up.
Dark matter is providing the gravity to pull back and to make these things oscillate.
Exactly.
That's what's called barion acoustic oscillation.
And then it's frozen in time.
but one certain moment in those oscillations
because the photons can no longer push on that stuff
because it becomes neutral.
Yeah, dark matter, dark energy.
I know it's also dark.
It's a dark universe out there.
Yep, yep.
Okay, so now what do we do?
We've got this third way of measuring it
and we're even more confused.
Do we just look for a fourth way to measure it?
Yes, and of course we're going to work on that.
But also we have some theoretical work to do.
We need to understand how you could describe
what we see in a way that's consistent
and make sense across these different experiments.
That's why it's so important to do these measurements in so many different ways
because we need to unravel like, well, what assumption are we making in this one?
The same way, like the Greeks made the wrong conclusion about the solar system
because they had one wrong assumption that the stars were pretty close.
Maybe there's a basic assumption about the universe we're all making
that's leading us to miss the obvious explanation for what's going on here.
And podcast in 5,000 years can be like, ha, ha, ha, they didn't realize, I don't know what it is.
That makes it so obvious why they were seeing what they saw.
Well, I hope we figure out immortality so that you and I can be having that discussion.
We'll look back and be like, oh, we were so silly when we were young.
Life insurance policy is basically like immortality insurance.
Anyway, I'm not selling any insurance.
I'm just hoping that everybody out there enjoys the mysteries of the universe.
We live in a very turbulent time when we don't understand the universe,
and we're constantly getting these updates that remind us that there are huge discoveries
to be made. So aspiring young cosmologists out there, don't worry, there are lots of things
for you to figure out.
Daniel and Kelly's Extraordinary Universe is produced by IHeart Radio. We would love to hear from
you. We really would. We want to know what questions you have about this extraordinary
universe. We want to know your thoughts on recent shows, suggestions for future shows. If you
contact us, we will get back to you.
We really mean it. We answer every message.
Email us at questions at danielandkelly.org.
Or you can find us on social media.
We have accounts on X, Instagram, Blue Sky,
and on all of those platforms, you can find us at D&K Universe.
Don't be shy. Write to us.
It's important that we just reassure people that they're not alone,
and there is help out there.
The Good Stuff Podcast, Season 2, takes a deep blow.
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. One Tribe, save my life twice.
Welcome to Season 2 of the Good Stuff.
Listen to the Good Stuff podcast on the Iheart Radio app, Apple Podcasts, or wherever you get your
podcast.
Hi, it's Honey German, and I'm back with season two of my podcast.
Grazias, come again. We got you when it comes to the latest in music and entertainment
with interviews with some of your favorite Latin artists and celebrities.
You didn't have to audition?
No, I didn't audition.
I haven't auditioned in like over 25 years.
Oh, wow.
That's a real G-talk right there.
Oh, yeah.
We'll talk about all that's viral and trending
with a little bit of cheesement and a whole lot of laughs.
And of course, the great vivras you've come to expect.
Listen to the new season of Dacus Come Again
on the IHeartRadio app, Apple Podcast,
or wherever you get your podcast.
you really need another podcast with a condescending finance brof trying to tell us how to spend our
own money no thank you instead check out brown ambition each week i your host mandy money gives you real talk
real advice with a heavy dose of i feel uses like on fridays when i take your questions for the b aqa
whether you're trying to invest for your future navigate a toxic workplace i got you listen to
brown ambition on the i heart radio app apple podcast or wherever you get your podcast
Every case that is a cold case that has DNA right now in a backlog will be identified in our lifetime.
On the new podcast, America's Crime Lab, every case has a story to tell, and the DNA holds the truth.
He never thought he was going to get caught, and I just looked at my computer screen. I was just like, ah, gotcha.
This technology's already solving so many cases.
Listen to America's Crime Lab on the IHeart Radio app, Apple Podcasts, or wherever you get your podcasts.
This is an I-Heart podcast.