Episode Transcript
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Speaker 1 (00:05):
Hey, you welcome to stuff to blow your mind. My
name is Robert Lamb and I'm Joe McCormick, and it's Saturday.
The vault lies open, and inside the vault this time
I see not just avoid but a planet on the darkness,
the planet Iracus, Dune itself. We're going back to our
classic Dune episodes. These were some fan favorites back in
(00:26):
the day. So there were two episodes on Dune we did.
We did uh episode about the technology of Dune in
an episode about the biology of Dune back in September
and October. So this is going to be the first
episode of our Dune revival. This this one originally aired
on September and it was called the Science of Dune Technology. Right,
(00:48):
one of the main focuses in this episode is going
to be the still suit. These are, of course the
water reclamation suits that you see in the movie adaptations
and of course appears in the original nine book by
Frank Herbert as well. Right, Robert, are you ready for
another Dune movie or you just pretty satisfied with our
with what exists now? I am satisfied with what we
(01:09):
have now, but I am all in on a new
vision a new cinematic vision of of the Dune universe.
Listeners out there, I've got homework for you. If you
have never seen David Lynch's Dune, or if you have
seen it, either way, you should go watch David Lynch's
Dune and just take notes on all the scenes that
have a pug in them. There's a pug, a royal pug.
(01:29):
I don't think the pug was in the book. I
don't remember anything about a pug. Maybe in the sequels.
Are there are there pug sequels? They should do one.
They should have like the pugs of House of Tradees.
That would be a wonderful focus for for one of
the prequel novels. But in David Lynch's movie, there is
totally a pug in several scenes, like sometimes he's sitting
in Karl McLaughlin's lap. Sometimes Captain Picard is about to
(01:53):
run into battle on the planet Iracus and he's just
gotta do He's got a pug in his arms. Dune pug. Yeah,
it's just one of the mini wonderful visual features of
that film. An imperfect adaptation. But I am I am
not the sort of Dune fan that can completely hate
upon film adaptation I will kill him. Yes, all right,
(02:16):
Well it's a long episode, so without further ado, let
us enter the vault. Welcome to Stuff to Blow Your
Mind from how Stuff Works dot Com. Hello, this is Edric,
(02:42):
your gul navigator speaking, just letting you know that we've
begun our approach to a minimal safe departure for our
one way John to the planet Oracus. This is, of
course just a precaution, as the Spacing Guild currently holds
an impeccable record of Holtzmann enabled space fabric distortion travel.
(03:02):
And as always you can rest assured that no thinking
machine has taken your lives. It's care, but rather the
President Lunge augmented powers of the human mind. So set back,
enjoy our in flight presentation of maud By conversations, and
our flight attendants will check in with him shortly. Hey you,
(03:30):
welcome to Stuff to Blow Your Mind. My name is
Robert Lamb and I'm Joe McCormick, and uh, I want
to thank a musician or Raleigh porter for that bit
of music there. That's the laxo off his two thousand
eleven album Aftertime, released by Subtext Recording, and you'll find
a link on the landing page for this episode to
learn more about that work. But it's the title of
this episode and our our intro narration. Um UH Presents
(03:54):
were of course talking about the Done universe in this
week's episodes, so we've probably heard us talking about Dune
on recent episodes of the show. I've mentioned several times
that I've been reading it. I finally finished reading it.
I loved this book. Yeah, I'm about halfway through my
my reread of it, and this I think this will
be the third time I've read it, and it's it's
(04:16):
a book that has a special place in my heart
as well. It's very strange to me that a book
written fifty years ago. That's one of the reasons we're
doing this is that this year in it's the fiftieth
anniversary of the publication of Dune, that a book this
old can feel so fresh and imaginative. So much science
(04:36):
fiction is disturbingly familiar when you when you go to it.
I don't know. When I went into the world of Done,
I was constantly surprised by what I encountered. Yeah, it's
so unlike, you know, anything that had come before it,
and and and unlike even though it's it's had a
huge impact on the genre. Um, there's nothing quite like
(04:57):
it to this day. I mean it's, uh, you have
this space age feudalistic society and it's full of you know,
you have profits, you have fabulous creatures, you have strange science,
strange technology that's changing the shape of life. Yeah. So
to describe the influencer in terms of the influenced, a
(05:17):
young person approaching done today might want to think of
it as sort of like Game of Thrones in space
because a lot of political intrigues, Yeah, but also with
with a lot of philosophical commentary. And I have to say,
this is the most ecological novel I've ever read. I've
never read anything as concerned with ecology and the conservation
(05:40):
of resources. Yeah, A tremendous amount of thought went into
the creation of this, this alien ecosystem, an alien ecosystem
that is not only intrinsically interesting, but but plays an
enormously important role in the plot. Right, So we're gonna
do two episodes about the science of Dune, talking about
the world of imagined by Frank Herbert In in his
(06:02):
novel Dune and in the larger Doune universe, but then
also real world parallels to this science and how Doone
has influenced science fiction. Yeah, so we're gonna be discussing
some of the science fiction, some of the actual science.
But one of the reasons that they the sci fi
aspects of Frank Herbert's done, you know, continues to resonate
so well is, first of all, it's set tremendously long
(06:23):
period of time in the future, and he does a
great job about giving me some details but leaving a
lot of the details a bit ambiguous and unexplained, and
you're just sort of left to fill in fill in
the blanks in your own mind, right, and if you
know how sci fi fans work, they will fill in
those blanks. Yes. So two of our primary resources here
(06:45):
um are, first of all, a fabulous new publication titled
The Science of Doone, edited by Kevin R. Grazier, ps PhD.
It's an unauthorized exploration into the real science behind Frank
Herbert's fictional universe. And it's a series of essays all
all you know by experts in their in their field, planetologist, cosmologists,
(07:05):
et cetera. It's a fabulous book. We'll have a link
to where you can pick up a copy on the
landing page. For this episode, we also doug in a
little bit into the Dune Encyclopedia, which came out in
It's long out of print, but there are used copies
out there available for purchase. And this was compiled by
Dr Willis E. Nick and Nelly and uh. This also
(07:28):
involved a number of different freelance writers and U and
some scientists weighing in on not only the science potential
science underlying the details of Herbert so a Universe, but
also some of just the cultural aspects as well. Right,
it's got recipes for frem and flatbread. Yes, I was
you pointed that out yesterday, and I was very fascinated
(07:51):
by the top of They're also lyrics to songs. There's
as well as some uh, some some science into how say,
you know, sandworms or face stand answers may have worked.
You know, thinking about the recipe for frem and flatbread,
I wonder why the fremen would cook anything, because cooking
is almost always the cause of much evaporation and loss
(08:12):
of moisture. Well, perhaps they have a special oven like
a still of and that captures all that moisture. Yes,
so they seal off the kitchen and no moisture can escape,
and then you can cook. Yeah, indeed, that makes sense. Now.
I also just wanna don't want to preface here too
that they were dealing primarily with the nineteen novel Dune,
with some discussion of details that may pop up in
(08:35):
Frank Herbert's later novels. We don't really get into any
of the more recent works by by Brian Herbert. Brian
Herbert is, of course the son of Frank Herbert, and
he continued the saga, did some prequels in a number
of Legends of Dune books with with his collaborator, But
I have personally not read them. I know a lot
of people enjoy them, so um, Yeah, we would love
(08:57):
to hear from anyone who who has read those books,
who has additional information they want to share based on
their enjoyment of that sort of continued universe. Right, But
these two episodes we're doing are going to be primarily
the first novel, Dune, and then our wonderful supplementary materials. Yeah,
the kind of stuff that I think for the most part,
people even who haven't read the book, might be familiar
with from either the Of course, the David Lynch film adaptation.
(09:22):
Oh and we got to talk about that. Oh yeah,
the Sci Fi Channel mini series from several years back,
or just sort of the general cultural residents of the series. Um,
and we're gonna try and make sure it's not too deep,
so if you have little or no understanding of the
Done Universe, will hold your hand through the stands. So
we mentioned it's going to be a two part episode.
This first episode today is going to be about primarily
(09:45):
the technology of the Done Universe, and then the next
episode we do or we're going to try to focus
on the organic components, the biology and the ecology of
the Done Universe. But before we get into the meat
of today's episode, I think we should just give a
very very brief cursory plot synopsis to people who haven't
(10:05):
read the book but want to be able to have
a basic idea of what's going on. So what happens
in the novel Dune, Well, essentially you have a space
opera in which you have a galactic civilization spread across
various planets right right, and there is one precious key
resource in the universe that everybody wants and sort of
controls all trade, and that resources, the spice milange. It
(10:29):
comes from one planet in the entire universe, and that
planet is a raucous also known as Dune. Yeah, it's
the stuff that really makes uh, ultimately travel between planets possible.
It makes the interplanetary economy possible. So everything is hinging
on this one precious commodity. It's kind of the It's
essentially the oil of the done universe, right, and you
(10:51):
can't get it anywhere else. So the characters that come
in on the story that there are two main houses
in the story. There's House of trade Ees and his
House Harconan. The Tradees are it's it's kind of manniche
and I guess the Tradees are the good guys and
the Harconan's are very very bad guys. Yeah, but I
mean the Hardconans are they're they're they're a product of
(11:13):
the environment to to a certain extent, but yeah, they're
they're pretty villainous. Yeah, And they are essentially competing for
control of the planet that produces spice. And there's a
lot of warfare and backstabbing and treachery and double crossing
and and tests of loyalty, but ultimately the main thrust
(11:33):
of the story is the adventure of Paula Tradees, the
young son of House of Tradees, and his mother Jessica,
while they're learning how to live on the planet Dune
and eventually participating in a journey of cosmic discovery and
revenge and drugs. Like at the heart, it's such a quintessential,
(11:54):
like nineties sixties product, right, because it's about a young
man who takes an allucinage and and h then saves
the calaxy. You know, I never thought of it that way,
but that's that's pretty much right. We'll get way more
into the drugs in the second episode. But today we
wanted to talk about the technological theater of the Dune universe.
(12:18):
And I think one of the coolest concepts that's created
in the book that that Frank Herbert comes up with
is the idea that this is a future scenario without
computers or robots. Right, yeah, it is a post Buttlerian
jihad world. Uh So, basically, imagine that the singularity has occurred.
(12:38):
We have thinking machines everywhere that are caring for is
looking after us more of I tend to interpret more.
It's like the beneficial aspects of of a post singularity
world in which your computers are not like you know,
enslaving you and making you were working their salt minds,
but they've just become such a ubiquitous aspect of our lives,
and eventually humans rebel against that. Yeah. So there is
(13:02):
in the past of this universe a great war against
the machines, and it's it's referred to, as you said,
by the name the but Larry and Jihad from the
name Butler, but Larry and Jihad. And I like the
idea that it invokes the concept of jihad. So it's
not just like in the Terminator movies where there is
(13:22):
a war for survival against the machines, or maybe like
you might find in the Matrix or something like that,
the machines take over, they decide they want to kill
us or enslave us, and we fight back. There is
there is that element, I think, but there is also
a deeper, more spiritual element, which is where the concept
of the jihad comes in. It's a physical struggle, but
(13:42):
it's also a spiritual struggle for the soul of humankind. Yeah. Indeed,
like some of the Herbert Frank, Herbert himself didn't really
give you a lot of details on you left it.
You know, like a lot of the details in the
universe a little ambiguous, and you're helping. You left to
sort of um, you know, dwell on the philosophical implications,
but just a few quotes from the fictional tombs such
(14:04):
as the Orange Catholic Bible that play a prominent role
in the universe. Thou shalt not create a machine in
the likeness of a human mind. Thou shalt not disfigure
the soul. And then this is a great line from
some of the appendix material uh in novel. Then came
the but Lerrian Jihad, two generations of chaos, the god
(14:25):
of machine logic was overthrown among the masses, and a
new concept scept raised man may not be replaced. I've
been thinking a lot about this, um just in my
daily life, you know, about not even with like thinking machines,
but just the use of Facebook in your daily life,
you know, the the use of social media, the use
of all these gadgets. And so for me, when I
(14:48):
think of this spot Lerrian jihad, it's it seems as
much rebellion against that as it is against you know,
some robot with a with a laser gun. Sure, and
it's not unusual for our technology change us, right, I mean,
it doesn't just make our lives easier, it changes the
way we we prioritize things and the way we we
(15:08):
go about our lives. One way of looking at this
might be something like agriculture. I mean, that's a technology
that I think a lot of people would argue fundamentally
change the human animal Homo sapiens is not the same
anymore after we invented agriculture. And you could probably look
at the rise of thinking machines, of computers and perhaps
the same way it is changing us in a very
(15:30):
fundamental way. I mean, who knows what that look like
ten thousand years in the future, as as the done
universe imagines, But it's doing something to our brains. When
we can have vast computational power, vast power of storage
of information, and as imagined by this sort of singularity,
(15:51):
future decision making power that we can outsource two machines. Yeah,
I just think of all the things we outsourced already,
all the things we no longer bother to remember because
the machine remembers it for us. So yeah, like you said,
your your interpretation of this coming in I agree with
this about the butlerry and jihad having something to do
with the way humans are changed by our dependence on machines.
(16:14):
So either way, we end up with a situation in
these these books, in this world where we've kicked out
the computers. We kicked out humans one, the humans one.
But now all the humans have to do all the
things of the machines were doing beforehand. So what do
you do when suddenly, uh, you know, just think about
a business, so you can't depend on accounting software anymore,
you need what do you do? You have to turn
(16:35):
to the human mind to deal with all that accounting.
What do you do when it comes to navigational concerns?
I mean, even in our own lives will become dependent
on these uh like things like Google maps and ways
right to tell us how to get from point A
to point B. If we throw that out the window,
suddenly we have to look at maps. Suddenly we have
to know which way is north and south. It falls
to the human to know how to navigate. Yeah, and
(16:56):
it gets even tougher of course when you're in space.
So without the aid of advanced computer computation, um, they
have to turn to human capabilities uh and they have
to essentially breed and train uh special classes of humans
to to to take on these varying taxing tasks. Right,
(17:18):
and so some of these classes that you encounter in
the Doune universe, well, one of them, the most straightforward
upgrading of the human mind to replace computers would be
the mentats. There are several characters in the book who
are explained to be men tats. And this is pretty
straightforwardly a human computer. It's a person whose mind has
(17:42):
been trained and I think in some ways stimulated by drugs. Yeah,
they're constantly consuming some variation with some wine type eli
SATs sort of supercharge them. It's kind of like a
red buy. Yeah. It talks about their purple stained lips.
And these mentats really do in some ways fulfill the
function of computers. And otherwise they're sort of like advisors.
(18:03):
They're they're sort of the perfect computer human hybrid. They
can do computation, they can store vast amounts of information.
They seem to pretty much remember everything like that. They
do not ever forget any details, or at least as
far as I can tell from the first novel um.
But then also they they are attuned to human nuance.
(18:25):
It's something that's not true the computers today. They might
be more replacement for the kind of you know, superhuman
artificial intelligence that we imagine in the post singularity world. Yeah,
and it's interesting too that they have kind of an
ethical guideline to them. And if you want one that's twisted,
you have to Essentially, it's like a jail broken iPhone.
(18:46):
I want to order a sociopathic mentap Yeah, in that case,
you have to go to the Relaxa and they will
provide you with one. And of course one of them
is a is a major character in the early goings
of the novel. Yeah, that's true. And then of course
there's the spacing guilt. These are individuals who handle in
your planetary travel and this is a very complex, dangerous arrangement.
So you have Guild navigators, individuals who have been specially
(19:10):
bread trained and to varying degrees engineered to make the
kind of advanced navigational computations necessary to get from planet
day to planet B without just popping out of existence. Yeah. Now,
we mentioned that the mentats rely on some kind of
drug that stains their lips purple. The Guild navigators definitely
(19:30):
rely on a drug, and that drug is the drug
we talked about of the opening, Spice. That will will
go more into the spice and the effects of Spice
in the second episode, but it's a key part of
their outlook of their abilities is not just this computational power,
but also sort of the ability to see the future,
which Spice gives them. Yeah, at least a very limited amount,
(19:52):
just so you can see what where your various choices
will take you, and you can, at least in the
next few seconds a avoid the ones that will destroy you. Yeah,
and therefore sort of feel your way through the dark,
uh safely from point A to point B. Yeah. And
then there's a third group of these sort of advanced
humans that I think is is maybe the most interesting
(20:14):
of the three and also the hardest to pin down
and define. But they're the Binny Jesseret. So the main
character of the novel Poul Trades, his mother is Jessica,
and she's a Binny Jesseret trained woman. The Binni jesssere
At are a a female order of super smart, very perceptive,
(20:35):
highly trained priestesses of some kind who haven't they haven't
They have an aptitude for politics, for one thing like
that they are tuned into all the finer points of
human expression that we miss every day. There's sort of
human lie detectors. They can tell what people are thinking
and what they're gonna do by micro expressions on their faces,
(20:57):
tonal shifts in their voices. And they command a sort
of supreme knowledge of the human animal and how it works.
And they play a fascinating long game too, of manipulating mythology,
um mamonics and UH and culture to their benefit. Yeah.
One of the most interesting examples of this that comes
(21:19):
up in the novel is the idea of them. Is
it the called the Missionary of Protectiva? Yes, which is
this fascinating idea that the this order goes throughout the galaxy,
seeding planets with mythology that later members of the order
can rely upon if they're in a pinch. So it says,
(21:39):
if you went to every city in the country you
live in, spreading rumors about I don't know, prophecies about
someone who would come to your community and save it
from poverty and and and everything, and then you tell
all your friends exactly what to do to fulfill those prophecies. Yeah. Yeah,
So it's a factless failsafe. Also, they're gonna laying the
(22:01):
grounds for future manipulation. Uh. And of course at their
heart they also have a breeding program, yeah, which has
some I think some creepy similarities to eugenics programs. Yeah, Andy,
there's definitely a eugenic vibe to it. They're trying to
breed a specific person a what they call the quistat's
hat iraq um, a term signifying one who can be
(22:22):
many places at once. I thought the translation of that
term was the shortening of the way. Yes, that right, Yeah,
I believe, Yeah, that is also invoked as well. But
according to the Don Appendix, in simpler terms, what they
saw it is quote a human with mental powers permitting
him to understand and use higher order dimensions. So they're
(22:43):
trying they're essentially trying to breed a superman tat, a
human supercomputer with from some preceientabilities found in the Guild Navigators,
but without necessarily without the without necessarily having to imbue
the spice. Yeah. Yeah, So in a sense, they're trying
to to get to that next phase of evolution in
terms of human thinking, the human thinking apparatus. I don't
(23:07):
think you can make evolution happen. You just gotta wait
on it. They're they're determined them. And then on top
of that, you have the beneath a laxu who have
continued to refine human form and function, often in ways
that push the envelope of acceptabilities. Though, and this you
see that, you know that post human conundrum, like how
much can you change a human and it still be
(23:27):
a human? Yeah? I love this aspect of the universe,
that it's so fresh and interesting that they imagine a
future without robots and computers, because robots and computers, of
course are ubiquitous and uh in science fiction, and I
think a lot of times with good reason, because that
it certainly does seem to be the trend in human
history is outsourcing all of our capabilities to machines that
(23:50):
can do them better, or at least do them cheaper,
or I don't know, a greater scale. But here we
have human technology. It is really the wet war future
universe where all of the things that computers used to do,
or even that you know they can't do for us
today but we only imagine they could do, are all
(24:12):
replaced by human perfection. Yeah, you know, and it all
makes me think two of our episodes and techno religion. Right, so,
particularly some of the conundrums of how do I create
a refrigerator that will operate in keeping with the laws
of the Stabbas? Right, You're you're having to advance your technology,
but do so within search certain religious frameworks and religious guidelines. Right. Oh, yeah,
(24:36):
because we don't want to lose sight of that. It
is dictated in the Orange Catholic Bible. And it's not
just that people sort of frown on computers. The Bible
says you shall not do it, right, It's it's blasphemy
to do this sort of thing, so you have to
you have to work around it. Yeah. So the sort
of upgraded advanced human brain technology is a larger feature
(24:57):
of the Doune universe, and if we want to try
to relate that to real technology, I can't see that
there's all that much we could say about it, except that,
of course people can there are some people with exceptional
mental abilities. People can hone their their skills in certain areas.
But I don't know if there's a wine you can
(25:18):
drink that will make you a ment at And I'm
doubtful we will ever discover such a thing because I
tend to assume that the human mind is already operating
probably a pretty close to its capacity. I don't buy
into this whole like, you know, we only use ten
percent of our brains. No, yeah, yeah, that that they
tend to throw that out the window when you start
and also when you start looking at like what makes
(25:38):
an individual genius? You know, it's not just in nature,
but it's also nurture. There are several different factors. And granted,
I'm sure the manipulations of the Beni gesture it would
involve both nature and nurture, but but still yeah. But
on the other hand, if we do want to isolate
specific capabilities of these people, say the capability of the
(26:00):
Beni Jesstera to read micro expressions, I think that very
well could be trained in a person. Uh. And then
other things like the ability of a ment at to
recall vast amounts of information beyond what would normally be
accessible to the average humans memory. I think you could
compare that to what the really good people, the memory
(26:21):
athletes do, you know, like we talked about in the
Memory Palace episode of people make these memory palaces that like,
how exactly does that work? Oh? That's of course, just
using a different type of memory and invoking spatial memory
to to memorize say a list of terms or a
you know, or a table of information. Yeah, so if
you have a list of five hundred numbers that you
could never remember, well, what if you imagine those numbers
(26:45):
as objects that are kind of strange oriented in a
room that you're familiar with. Some people can use methods
like this to recall things that we would never normally recall.
But anyway, that's sort of the the human technology and
(27:06):
the broader universe of doone. I think we should now
zero in on the planet Dune itself, the planet Iracous,
because the physical conditions on the surface of this planet
constitute a huge part of the struggle of this book.
A lot of the plot is just based around the
fact that this is a desert planet. Water is extremely scarce.
(27:28):
People are constantly fighting to stay alive and preserve moisture
in a place where every single drop of water wants
to evaporate and disappear. Yeah, it's like an extremely harsh
life and it requires some some rather ingenious cultural innovations,
but also technological innovations. Yeah, and I think one of
the most interesting pieces of technology we encounter in the
(27:48):
book Dune is the still suits. So what are the
still suits? All? Right? So still suit and this is
something I imagine people are definitely familiar with from the
movies and and and again may just be from leader
with outside of having ever seen or read anything doing related.
But it's a second skin worn by the deserted inhabiting
fremen of Iracus, and it traps body moisture and recycles
(28:12):
it through tubes, cooling the wear and also preventing water loss.
So they collect your sweat, your urine moisture from your
fecal matter, and then coils it around you, cools you
down a bit, and then you drink it out of
a little a little straw in your mouthpiece. Yeah. So,
if you've seen pictures of kar McLaughlin with little things
dangling out of his nose in the desert, that's probably
(28:33):
from the movie Dune, unless he did in another movie
with stuff hanging out of his name in the desert.
That's from the movie Dune. And he's wearing the at
least the David Lynch version of what the still suit
looks like. The fremen you mentioned or these are sort
of the native inhabitants of the planet Iracus. These are
the people who are perfectly adapted over many generations to
(28:54):
life in this extremely harsh desert condition. Yeah, and the Fremen,
they take their still sue disciplined very seriously. They don't
waste any water. They keep their still suits on unless
they're in a sealed off place that can retain moisture.
And it sounds like a rough life, but it's also
very interesting is described in the novel because of course,
(29:15):
what happens to you in the desert without a still suit, Well,
you die. And uh, it's we're told that if you're
out there unprotected in the desert, you can't last a
full day unless you have just a massive amount of
water on hand. It just burns you right out right.
But if you have the Fremen still suit, proper frem
and still suit, not one of those city models, you
can you can actually limit your water loss to fifteen
(29:37):
mil liters a day and so so yeah, it's an
invention of of necessity by these uh, these Fremen who
were former nomads that you know says they were zen
sunny no ensunning nomads who popped around from planet to planet,
evidently picking up different technologies and uh and you know
material technology along the way, which they then implement into
(30:00):
signing the suit. Yeah. And so there's a scientist character
in the novel Dune named Kinds lee at Kinds who
explains how the still suits work. Yeah and most and
again this is another example of Herbert giving us some details,
perhaps in this case a few too many details. This
we'll get into, but leaving a lot of the the
(30:20):
the nitty gritty stuff to the reader to to figure out.
So Kins tells us that is still suit as a
micro sandwich quote, a high efficiency filter and heat exchange system.
So you have a layer that touches the skin that's
porous and perspiration passes through it, and it cools the
body in a manner that maintains the existing cooling process
(30:41):
of the bodies, which we'll get into that's key and problematic.
And then you have two additional layers on the suit
that include heat exchange filaments and a salt of precipitators. Uh,
the ladder of which is used to reclaim salt. Now,
why do we call it a still suit? H? What
does that mean? It's just like a unshine still distillery. Yeah,
(31:02):
you're separating which is you know, all about separating different liquids.
The still up in the Appealachian Mountains, Uh, that's all
about separating alcohol. But with the still suits about separating
potable water from salt, h and other waste materials in
a wares excretions. Now, what I immediately wonder when I
(31:23):
encountered this concept is Okay, that sounds very interesting. I
wonder if something like that could be done in real life.
But one of the main questions is where does it
get its energy from? Like how how is this distillation
process powered? Because if you think of a still, you've
got to boil things. You've got to be feeding energy
into the system to power the distillation process. What's going
(31:43):
on in the still suit, Well, according to two kinds
and ultimately according to Frank Carpet here, Uh, it's all
due to body movement, especially breathing, and then this and
some ausomatic action. It's providing the pumping force for all
of this water. Uh. And again, as we'll get into that,
there are a lot of questions surrounding how that would
actually work. But then, of course, once the water gets distilled,
(32:07):
it gets filtered into these things that they talked about
in the novel called catch pockets, which is great because
then you just got a little straw and you can
just suck the water straight out of your suit when
you're thirsty. Yeah. Yeah, and um used to be your pa.
Now it's tasty desert water. Yeah, and it and yet
you'urin in. Feces are processed in your thigh pads, which
is a detail I remember kind of sticking on when
(32:28):
I read this for the first time, like back in
junior high or high school. They just mentioned that so briefly. Yeah,
because it also it makes it makes you feel like
you're you're probably constantly aware of the like the poop
cakes that are stored in your in the thighs of
your your pants. I'm like, Frank, tell me more about
the feces. I've gotta know, Like does it We were
talking about this the other day, like does it? Like
(32:49):
I was kind of imagining it's it's kind of cleaning
out of the filter on your dryer, except every so
often a fremen has to stop and remove this this
flat cake of like super dry poop. Yeah. I imagine
it for some reason as a powder. Okay, I think
that would make sense to Yeah, if you if you've
removed all of the liquid from it, I guess it
could pretty easily be disintegrated into a powder. You can
(33:11):
just sort of dust out the back of your suit. Yeah,
I can see that working. You just drop your poop powder.
And then again, if it's a powder, you might be
that you might easily inhale it. I don't know. Speaking
of breathing, that's another way your body loses moisture, right,
every time you exhale, you're you're wasting some precious water
vapors going straight out your nose, that's right. And that's
(33:31):
why on the still suit you breathe in through a
mouth filter and you breathe out through the nose, and
then you have that little nostril toe that's really supposedly
reclaiming moisture from your exhalation. And that's pretty much it, right,
I mean, Herbert doesn't give us all that much detail
and exactly how the steel suit works, despite how important
it is in the novel, that's right. So it we
have to turn to uh two expert commentators to figure
(33:54):
out exactly how it might work and how it maybe
doesn't work based on our current technological understanding, Okay, is there? Uh?
Should we should we go first to the Dune Encyclopedia
or the Science of Dune? Um. I think we're gonna
go to the Science of Dune first because I think
this has the most robust explanation. Uh. And then the
and then the Doing Encyclopedia potentially fills in some some gaps.
(34:15):
So the still suit article wasn't by the editor Grazier,
but was by a different guy. Yes, NASA engineer John C.
Smith wrote this one. Uh. The top tackles the topic
at some length in the piece still Suit. Uh. He
points out that we've seen a lot of still suit
patents over the decades since the release of Dune, but
they all kind of muck up the thermodynamics, and the
(34:36):
thermodynamics are really one of the sticking points here, um
he made. Ultimately, he maintains that if you take a
strict literal interpretation of Herbert's writing, the still suit quote
probably would not work and most likely would cook the
wear like a crop pile. Yeah that's awesome, you know.
And yet we can we can certainly envision technological advancements
(35:00):
that would make a still suit possible in the future,
and and since we're talking about a sci fi realm
thirteen thousand years in the future, that's certainly time enough
for various UH technologies and especially meta materials to come
online to enable it. Right. Well, okay, well maybe we
should look at this one energy loss source at a time.
(35:20):
So let's think about sweat first. Sweat does something really important.
It cools you. This might not always be the case
if you live in a very moist environment where it's
hard for the sweat to evaporate. But if you're in
a place like Aracus, if you're in a desert environment,
a dry environment, and you're sweating, that evaporation is bringing
your temperature down, right, I mean it's even taking place
(35:42):
in just a a very ambient level. Um Failure to
sweat leads to heat stroke and death. And uh. As
Smith points out in his in his piece here the
Golden Gal and gold Finger, you might remember she's painted
gold and then she dies. Uh. It's often uh, you know,
they're saying, oh, she's suffocated, But in real holidy shoe,
he says, she would probably die from heat stroke. I
feel like I've heard a lot of disputes about whether
(36:04):
that person who's got the full body paint job would
survive or not. I think I've read people saying that
that wouldn't actually kill you. Yeah, I think I've seen
people go back and forth on that as well. Um,
all of us missing probably the point that they just
wanted to put up dead naked golden lady on the
screen there. But but either way, if you enclose the
(36:25):
entire body in a sealed suit like this, you're courting
death in the form of heat stroke. And that's one
of the primary design flaws with a still suit. Even
when inactive, the body has to dissipate about ninety watts
of heat just to balance out the heat of your metabolism.
So even if you're not who have sweaty sweat is
still an important process. Most of the most of the
(36:45):
body heat arises from the liver, the brain, heart, and muscles,
and uh it's dissipated through blood circulation at the skin
level along with the primary method of sweating. So even
when passive sweat glands extreet excrete point six ms of
perspiration per day, maximum rate one point five liters per hour.
(37:06):
And it's also worth noting you see images of people
throwing the hood back on that that's still super right. Yeah.
In the movie, the hood is essential because your Ekron
sweat glands are all over the body, but they have
the highest concentration in the forehead and the Akron sweat
glands those are the ones that are tied, uh, you know,
exclusively to cooling. Not to be confused with any of that,
have you know, hormonal issues. Yeah, so you said that.
(37:28):
John C. Smith mentions that there are patents out for
still suits. I tried to find an example of a
still suit in the wild. I was looking around on
the internet to see if anybody had made one. I
didn't find one. I did find a Gizmodo article from
July proclaiming in the headline quote the sweat to water
purifier real life dunes still suit will save lives. Unfortunately,
(37:52):
this was interesting but turned out to be kind of
an exaggeration, so it referred back to a BBC article
about this inventor named Andreas Hammer who he invented a
device called the sweat machine, which was designed to reclaim
and distill water from sweaty clothing through a process known
as membrane distillation, and essentially the machine spins clothing in
(38:14):
a centrifuge to pull all the liquids out. So if
you have a high efficiency washing machine, uh that it
does the same thing, though maybe not to the same
level of extraction as the centerfuge. But the idea is
that high efficiency washing machine spins the wet clothes really
fast to drain out all of the moisture, and then
the clothes spend less time in the energy gobbling dryer.
(38:36):
But in the sweat machine instead of the washer water,
it's pulling out some salty, nasty sweat and then it
distills that liquid by heating it and then circulating it
between two membranes. And basically the way the membranes work
is that the membranes are hot on the sweaty side
and cool on the other side, and this creates a
(38:57):
vapor pressure differential that pulls water and only water, so
not all of the other molecules, just the H two
O molecules through the membrane and leaves all the other
stuff on the other side. So they say that one
sweaty T shirt typically contains roughly ten milli leaders are
about point three ounces, which is about a mouthful of water. Okay,
(39:19):
so this is your sweaty t shirt is a sip okay,
so it's a it's a body water reclamation technology, but
not something that you could actually use in a suit. No, unfortunately,
so you can drink it. They say it's cleaner than
tap water, and they even they cited one example of
when they served the product of this machine to a
bunch of people in the public at this event called
(39:40):
the Gothia Cup in Gothenburg, Sweden. I looked it up.
That's like a football slash soccer tournament. Uh, And it's interesting,
But looking at the setup of the machine, I can't
really see how this could be incorporated into a feasible
body suit. It's pretty big, especially given the necessity of
the center fugere process to extract the liquid in the beginning. Like,
you couldn't have the machine be part of a suit
(40:05):
if it needs to extract the liquid from the suit.
So I don't really begrudge them a cool headline referring
to a still suit, but the comparison doesn't really seem
app to me. But it is an interesting invention nonetheless,
and of course sweat is not the only way the
body wastes precious moisture. As if H two O, we're
(40:25):
just cheap and abundance. Yeah, as we mentioned already, you
gotta take into account urine. It's water. The rest is
metabolic waste, salts, organic materials. You can drink a little
lot bit and feel okay, and some people even claim
therapeutic benefits, but it's ultimately like cutting your kidneys out
of the waste removal process if you just keep guzzling urine. Uh.
So you have to take the waste out. And of
(40:47):
course this is also a very real area of of
waste processing technology. Sure. Yeah, reclaiming water from urine is
something that happens in space all the time, for example,
So shipping water or to space is really expensive. We
talked about the costs of of getting cargo into orbit before.
Uh it's hard to put an exact figure on the
(41:08):
cost per pound to lower th orbit today, but traditionally
around estimate they used to give was ten dollars per pound.
We don't know how much it costs today, but it's expensive. Um.
And you know that great feeling you get when you've
just been doing strenuous exercise and then you sit down
and drink a whole glass of water at once. Astronauts
on the I S s have to exercise all the
(41:29):
time to mitigate the effects of bone and muscle density
loss that you experience in microgravity. Um So, without reclamation efforts,
that refreshing glass of water you get right after an
hour on the treadmill is gonna do you know? That
might be a ten tho dollar glass of water? Who knows? Uh. So,
instead of constantly shipping up new water, the crew members
(41:51):
on the I S S rely on in uh it's
called the Environmental Control and Life Support System or the
e c l s S, and that has within it
water reclamation system. So when the astronauts exhale some hot
moist breath on each other, the habitat can recycle and
reclaim it. When the astronauts p or spit in the
sink during oral hygiene routines, the station can capture that water.
(42:15):
In a space dot Com article I read about this,
the author Denise Chow said that without the recycling system,
an average of roughly ten thousand pounds of water per
crew member would be required from Earth each year to
keep the station properly functioning. So it's it's kind of
being in space is kind of like being on Iracus,
(42:35):
Like you know, it's it's very it's mighty precious. You've
got to hang onto it. And so there have been
a lot of efforts at research for reclaiming water for
space missions. Early space missions, like the Apollo missions came
up with solutions like electrolytics, silver ion generators, and apparently
these could disinfect drinking water. They would like remove bacteria
(42:56):
from the water without having to dump a bunch of
bleach or other chemicals in there. Uh. And then today
the I S S uses a more complex filtration system
that's got three steps. It's basically got a a filter
step that gets out particles and junk from the liquid,
and then they push it through a semi permeable membrane
that has these substances and in it that that pull
(43:18):
out organic materials. And then finally they have a catalytic
oxidation reactor and that kills bacteria and it takes all
the other organic compounds out of it. But of course
that's at the space station level. It's still not a suit.
Could you shrink it down to the individual level sort of,
but not exactly so. Uh. NASA scientists have equipped at
(43:43):
least some astronauts headed for the I S S with
test demonstrations of personal sized water purification bags that don't
drain energy like the large scale recycling systems, but instead
depend on this process known as forward osmosis. Generally this
concept is called the forward osmosis bag or FOB fob yeah,
(44:03):
and so. Forward osmosis takes place when you've got two
liquid solutions separated by another one of these semi permeable membranes.
One of the liquid solutions is a lower concentration that
this is probably gonna be your dirty water, and then
one has a higher concentration, and that's this electrolyte filled solution,
which I think is like gatorade or or something pretty
(44:24):
much along those lines. And then the water flows naturally
from the lower concentration solution to the higher and the
semi permeability of the membrane means that it allows water
molecules to pass through, but not larger molecules or objects
like bacteria and proteins. From what I can tell, NASA
is still investigating how well and under what conditions these
(44:44):
devices work. I read a Wired report in that said
that they hadn't been able at that time to prevent
urea which is a waste product that you find in
urine from getting through in the osmosis bag. But apparently
a Japanese TV crew member a decided to try some
of the product of the Forward osmosis bag despite the
despite that warning, and he said it tasted like Caprice Son.
(45:08):
So there's your your free ad for Caprice Son. A
more recent work I found on the it's a NASA
research report from that mentioned the fact that these osmosis
powered devices work slower in microgravity, and they're testing ways
of solving that problem. But okay, so sweat you're in
kind of gross but at least basically liquid. Are we
(45:30):
ready to talk about feces? Uh? Well, we are in
the podcast, But the larger concern is that we're really
not as a civilization. UM feces is of course sev water.
The rest is undigested food bacteria. But but there's water
in there, water that is ideally worth reclaiming. But we've
actually seen far fewer studies regarding fecal water reclamation. Though.
(45:55):
The thing is, of course this takes place, as does
urine water reclamation, sweat red recommation, whatever, via the natural
water cycle on our on the planet itself. Now, um
In in his UM s. A. Smith points to a
University of Colorado study on water recycling for a Mars
mission that found that reclaim water would be minimal from
(46:16):
from the species. Uh, and that they'd also have to
factory in quote psychological concerns unquote for the crew and
so in in this yeah, and this we get back
to the psychological contagion inherent in any water reclamation effort.
And uh, I mean, I've I've blogged about this in
the past. You have to be able to wrap your
(46:37):
mind around the fact that the water you're drinking used
to be urine or used to be part of poop
when really, I mean you can essentially say any water
you drink was you may have been poop at some
point in the past, may have been dinosaurs. Right. But
but yeah, you have to deal with you know, how
is the how is the user in that experience working out?
(47:00):
And it's uh, it's it's interesting because it could be done. Uh,
and we we just haven't faced a dire enough circumstance
despite the fact that we're talking about a trip to
Mars here um. Interestingly enough, in the book Packing for
Mars by Mary Roach, she mentions that NASA scientists at
one point, we are actually pondered recycling fecal matter into food,
(47:23):
but they never pursued it at all, just because of
that ig factor. And part of this is she lays
out of you have at the time, you know, or
especially early on in the in the space program, you
have the very sort of cowboy mentality of the you know,
the x U test pilots who are becoming astronauts, the explorers,
and then you have the scientists, and the scientists are
(47:43):
are are more inclined to to present some out there
notions such as what if you could eat portions of
the spaceship. That was another idea that came up eating
what if the like the insulation itself was food, or
you know, making small cakes out of out of poop,
and of course the astronauts themselves, we're not going to
go for that idea on any level again, due to
(48:04):
the psychological contagion inherent in fecal water reclamation. That's so gross,
I gotta admit. I mean, it's one of those things
where I wonder if there's an equivalent to the mentor
the Benny jesserat the Guild Navigator, the person who has
upgraded their mental faculties to escape the factor. It's an
icles human the person who eats poop with no qualms. Yeah,
(48:27):
I mean, you know, I guess again. It just comes
down to are you in a dire enough condition and iracous?
Is that is that environment? Now? Smith coming back to
sweating itself though, uh Smith has a real problem with
(48:48):
the idea that the suit would allow your normal sweat
process to to carry on because because as well discuss,
it's not just a matter of water leaving your audi
and and now you're cool, um, you need an evaporation
to take place, and he doubts that quote near normal
evaporation process would even be possible in a still suit
(49:10):
for UH. For organic cooling to take place, sweat must
go through a phase change from a liquid to vapor
in order to remove heat and cool the skin. So
it's an endothermic process. And moving sweat away just whisk
wicking it away, as with specially designed workout garments, that
just merely makes your skin drier, not cooler. That's why
(49:32):
so called wicking fabrics UM, which use a passive capillary
action to move sweat from your skin to the outer
surface of your workout garment. They help you stay warm
during cold weather workouts. You're interfering in the natural cooling process,
not not level because it's not skin tight, not completely,
(49:52):
but it's still preventing sweat from doing what it does.
And I think anybody who's ever worn a scuba suit
i'll side of the water in the sun for any
amount of time can probably attest to that. You can
you can overheat really quickly in that environment because it's
making such close contact with the skin. When I was
watching the David Lynch Dune movie, I was looking at
those actors and thinking like, wow, that looks really hot. Yeah.
(50:16):
I mean apparently these were these were thin latex bodysuits,
and of course they were not functional still suits, so
they were having to deal with without with overheating, you know,
falling out from the heat. Uh. And interestingly enough, Patrick
Stewart has apparently gone on record saying it's the least
comfortable thing he ever wore for for any kind of
(50:37):
a film or TV project. And this is from the
guy who you know who had to wear that awful
Starfleet uniform. Um. I was not aware of this, but
apparently they call it the the Picard maneuver. If you
watch it enough, you'll see that he's always tugging down
on the garment to keep it from riding up. So anyway,
the bottom line here um is that the skin level
(51:00):
layer of the steel suit would need to be a
highly thermally conductive layer that allowed evaporated cooling to take
place um again perhaps via some as yet uninvented meta material.
And yet even then, the humidity in the skin level
porous layer would need to be high humidity, which could
in theory, merely just escalate the whole situation more perspiration,
(51:23):
more heat, and according to John C. Smith, the suit
would have to self dehumidify as well. So and in
order for that all that water vapor to become liquid
again so that you could drink it, you'd have to
have condensation occur. And for this phase change to happen,
which is an exothermic process, you need to have a
cool layer, such as you know, a cold glass on
a hot day, and you see that, you know, the
(51:43):
moisture form on it, and there's no mention of refrigeration
in the suit, but it would be necessary as far
as we understand the process, for that phase shift to happen. Man,
that just sounds like a mess. Yeah, that's the thing.
It seems like it would be if you don't have
a clear understanding of how sweat works and how how
how cooling works, and indeed how cooling systems work. It
(52:03):
seems like it would be a simpler mechanism, but it's not. Yeah. Now,
of course refrigeration does exist. So perhaps it's just a
question of how much bulk do you want to incorporate
into your suit? Yeah, I mean, can you fit some
manner of heat pump in there? A free incompressor? Um?
You know we have we have firefighters that use like
blue ice packs near the skin to keep their body
(52:25):
from overheating. But would that make sense at all in
a water scarce environment? And then uh, and then you
also have to any of these systems would also involve
more power. Uh. And all we have to go on
is that it's powered by motions of the body, especially breathing,
and according to Smith here, that would not be sufficient
to power the suit given our current progress on motion
(52:46):
generated power, even if we augmented it with solar power,
which again is if he because you want to travel
by night on a racus um, we you just end
up again not being able to keep up with with
the energy requirements for the suit. So that's what Smith
has to say more recent commentary, But if we look
to the Dune Encyclopedia and the entry written by Christine Watson,
(53:09):
she stresses the use of still cloth based on the
principles of cryogenics of a cryogenics separator, that's she says,
used on a number of worlds to draw oxygen and
other gases from the planet's happens here. So here we
see a you know, a futuristic meta material explanation. And
as for cooling, she says that the the tubes contained air.
(53:30):
At the beginning of the suit cycle, the air pressure
built up by the pumping action of the wearer's breathing
and by heel pumps. At a preset pressure, the air
was released into a holding chamber in the suit's hood.
This sudden release cool the air by the jewel Thompson effect,
and the cooled air was drawn back into the system
and again through the suit, dropping the temperature of the
separating layers. And that jewel Thompson effect, by the way,
(53:52):
that's the temperature exchange of a gas or liquid when
it is forth through a valve or porous plug while
kept insulat it did so that no heat is exchanged
with the environment. I gotta be honest, I didn't follow that.
I mean I had I had to go at it
a couple of times. But basically it comes down to
the fact that the hood would be kind of an
essential air bladder for the suits cooling systems. So imagine
(54:16):
the steel suit. Imagine com McLaughlin in the steel suit,
but with kind of a balloon hood portion. Man that
makes mud deep a little less a little less cool
looking if he's got a balloon head. Yeah, I would
think so. So again, you have to kind of talk
it up to say, however, the steel suit works. It
evidently involves some materials and technologies that we haven't quite
(54:39):
have figured out in this ancient day and age. Now,
another interesting technology that you see on a rackets and
also elsewhere in the worlds of done the use of
ornithopters of aircraft that fly via flapping wings. Yeah. So
we are told that the power of House of tradees
(55:00):
their home planet of Caladan before they move to the
desert planet of Irakus. Is air power there? An air
force power kind of like you might think of the
United States on the sort of military geopolitical world stage
that the power is concentrated in the ability to strike
from above. But their way of striking from above is
(55:21):
not much like anything we would commonly use on on
Earth technology today. It is like something we would commonly
see in the biological world. So of course birds fly
by flapping their wings, insects fly by flapping their wings.
It seems like a perfectly normal way to get around.
But there's a reason our airplanes don't do this. Ornithopters
(55:44):
can be built. You can make a machine that stays
in the air by flapping wings, but it is not
a very practical way to move heavy cargo or passengers.
That's right, and and certainly that's what you see utilized
in the dune universe, like sweeping down, swooping down to
pick up you know, mobile spice factory off of the
sands before a worm can get to it. Yeah, according
(56:04):
to Dr James Usherwood of the University of London's RBC
Structure and Motion Laboratory, uh, this is one area of design,
you know, where nature doesn't quite nail it. And this
is a kind of ironic because in the field of
biomimicry we see In a lot of cases, we can
turn to nature and say, well, how did nature evolve
to solve this design problem? And oftentimes they're they have
(56:24):
a really elegant Nature has a really elegant solution. I'd
say that's especially true on the very small scale. Biomimicry
becomes more and more powerful the smaller you go in
uh In an essay titled a Flying and Walking Learning
from Nature, and this was published in the book seventy
Great Mysteries of the Natural World, which I highly recommend.
Um Usherwood points out that a slow flying pigeon requires
(56:47):
up to four times the power an equivalent helicopter would need,
and hovering is even worse, resulting in pitiful amounts of
lift for the amount of energy exerted. Each pump of
the wings requires yet another burst of energy, and it
all adds up pretty quickly. That's why hummingbirds have the
highest energy expenditure of any warm blooded animal, ten times
(57:07):
that of a human. They're perpetually on the verge of starvation.
Uh and and and sometimes I have to actually go
into kind of suspended animation to deal with these these
energy costs. Uh and all the time, you know, consuming
colossal amounts of nectar to keep up their little sugar
water vampires that cannot be sated. Yeah, so you know,
we you know, looking back, you see early aviation pioneers
(57:29):
who toyed around with flapping wings, generally with the disastrous results.
But you do see scientists that have been looking into
it's used for micro air vehicles or m a v s.
And these are tiny robotic aircraft that depend on bio
mechanical flight designs. Uh. And the funding typically comes into play, um,
(57:49):
you know, for obvious surveillance purposes. Right, some sort of
tiny robot with buzzing, flapping wings that you can use
to spy on somebody. Now, what is the appeal of
that over just like a tiny quad rotor drone or
something like that. Is it just that it would look
like an insect? I think so. And I think also
there is that that bio mimicry attraction saying if it's
(58:11):
if it's flight at a small scale, then perhaps, uh,
perhaps there is an advantage in drawing on real world comparisons,
but overall, we are not going to see passenger planes
with flapping wings. And uh. I was looking at a
US Army Research Office report from two thousand five. Uh
that alt was weighing in and saying that when it
(58:31):
comes to M A v S, you're looking at enormous
manufacturing challenges, inefficient energy usage, and dependence on less under
good understood small scale physics. So at this point in time,
even small ornithopters the amount of reach. Yeah. Now, if
you want to just cheat and invoke some science fiction magic,
you might say that the ornithopters have something to do
(58:54):
with other technology present in the Dune universe, like like suspensers.
I noticed you putt in a note here, right, yeah, yeah,
and this draws us right into another important technology they
we're going to spend less time on because there's there
are a fewer answers, and that is the Haltzman effect
that enables faster than light travel, It enables personal shields,
and enables just ubiquitous use of anti gravity suspensers. That
(59:19):
I mean, you know, the main character of one of
the main characters, Vladimir Harcon and uses it to float
around and suspend his bulk. But you also see mentions
of just you know, here's a suspenser enabled chair in
a room. If you watch any scene from the movie
and not the whole movie, not the whole David Lynch movie.
Go watch the scene where where Vladimir harcon and floats
up in the screams I will have the spice. That's
(59:41):
pretty good. But anyway, I thought this is also a
really cool technology as imagined in the books, specifically with
application to the shields. Now, there are personal energy shields imagined,
uh in the Dune universe, and you've probably seen all
kinds of science fiction that has shields, you know, like
a shields up, you know, you put them up around
(01:00:02):
the spaceship and they deflect incoming weaponry, projectiles, energy beams.
But these are personal shields that are often imagined. Well,
actually they're There are large scale shields, and there are
personal shields, but you might like click a button on
your belt and suddenly a shield comes up around your body.
Somebody tries to run and stab you with a knife,
they will be deflected by the shield. And so the
(01:00:25):
solution to this creates a very interesting combat dynamic that
people talk about in the book, where people engaging in
knife fights with shields activated have to come up with
ways of trying to move their knife very slowly toward
the enemy because a quickly incoming knife will be deflected
by the shield. But if you can stab ever so slowly,
(01:00:48):
you can go through the shield gently, and then you
can you can penetrate the person's skin and make them bleed. Yeah.
So the defensive technology requires an entirely well not entirely,
but at different isle of martial arts. So we we
don't know a lot about the Holtzman effect. In the
books UH, it's described as the negative repelling effect of
a shield generator. UH. And a suspenser is the secondary
(01:01:10):
low drain phase of the Haltzman field generator, and it
nullifies gravity. It nullifies gravity within certain limits prescribed by
relative mass and energy consumption. So in this we we
have no choice but to turn to the science of
doone and UH the writings there of planetary scientist Kevin R. Grazier,
(01:01:32):
who also edited and along he also worked with physicist
Jess Seeger on some of this and UH. As they
point out, much of the whole Haltzman situation is unexplained.
In the later books, we do learn that that guild
highliners the big spaceships travel the stars by the quote
compression or warping of space time in conjunction with mass neutralization,
(01:01:58):
and as a planetary scientist. Again, Kevin R. A. Grazier
points out UH in cosmic oregonomy, that's the piece in
the science of doone. UH. If the mass of a
spaceship could be nullified, then the relativistic effects of high
speed space travel could be reduced. So essentially it's talking
about all right, if you could turn, if you could
simply dampen or nullify the mass of an object, then
(01:02:22):
that would enable you to to cheat in various respects
in terms of acceleration in spacetime. UH. Also Grazier and
Uh and Seeger opposit that the Holsman field is an
energy screening shield. Perhaps it screens the mass of an
object from the rest of the universe. Lowering the mass
of an object would also lower the force of gravity
on it. Lowered enough and you just float around up
(01:02:44):
in the air. And as for space travel, theory and
observations of general relativity indicate that spacetime can be curved
and warped, and perhaps it can even be folded and compressed.
So again the classic examples, you have a map, right,
and you fold the map, and then you just poke
a hole through point A and point B, and now
you have the whole right right, the Tessaract Tessaract example,
(01:03:05):
the even arise an example. Um, do you thus shorten
the distance between two points, meaning that faster than light
acceleration and all the problems they're in might not even
be necessary? In the Dune books, we don't know much
more beyond that, other than the process is dangerous and costly.
You really need a number crunching power of an advanced
(01:03:26):
computer to handle it all. But in the Dune universe
it all falls to human minds enhanced by spice. Alright,
So that's pretty out there science fiction. I think I'd
have to say the same thing about the energy shields
as that relates to the whole Simon effect. I I
can't think of any example, uh, And I wasn't able
to find any example of a real energy shield in
(01:03:47):
the world that would successfully deflect incoming matter like that,
especially not without harming the person who was wearing it.
I mean, you can imagine wearing a huge magnet of
some kind that, you know, if somebody tries to shoot
a bull it at you or something like that, might
be able to deflect it if it's powerful enough. But
I mean, at certain points you're getting into levels of
(01:04:08):
energy that makes the proposition ridiculous. And so if you're
imagining an energy shield like they have, maybe the closest
thing I've seen would be propositions of energy shields like
ion shields around spaceships to prevent incoming radiation. But I
don't even know if that's really viable. Yeah, it's definitely
less down to Earth compared to the still sit So
(01:04:32):
there you have it, some of the technology to do,
not all of it by any means. We just decided
to draw in a few examples that we could discuss
here in the podcast. Uh. And again, we're gonna do
a second episode and we'll get into the biology of
doing a bit where we're definitely going to discuss sandworms
in detail. So UH, as we lead out here, we're
gonna enjoy another track from Raleigh Porter. This is X
(01:04:54):
again off the two thousand eleven album Aftertime, released by
Subtext Recordings. There's a link on the landing p age,
but you can learn more about his work at Raleigh
Porter dot com. Uh. In the meantime, checkout stuff to
Blow your Mind dot com. That is the mothership. That's
where you will find all of our podcast videos. And
blog post, as well as the links out to our
social media accounts. And if you want to get in
(01:05:14):
touch with us about your favorite fact about the June
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