>> Neil deGrasse Tyson: Welcome back. This is the 16th Isaac Asimov Memorial Panel
Debate. It’s in its 15th year. There was one year where we had two. There was so much going on. I like learning—just briefly—for how many
people is this their first occasion to attend the Asimov Panel? Welcome. Where have you been the past 15 years? That’s the real question. I’m Neil deGrasse Tyson. I’m the Frederick P. Rose director of the
Hayden Planetarium. And we do this once a year in the spring. We find a topic of particular scientific vitality
that might have some controversy, but it’s more a topic that is on the frontier. And we bring it to you through a panel, and
that would be the Isaac Asimov Memorial Debate Panel. This event was started by a bequest of the
friends and family of Isaac Asimov, who’s was a friend of this institution. He did much of the research for his countless
books in the libraries and halls of this institution. And Janet Asimov, his widow, as well as friends
and family, came together to provide an endowment to sustain
this in perpetuity. So, I want to just publically thank the friends
and relatives of Isaac Asimov. Two other quick people I’d like to thank: Laura Jean Checki, who helped manage this
event, as well as my executive assistant Elizabeth
Stachow. Today happens to be her 60th birthday. And she’s working on her birthday because
that’s how devoted we are. Yes, she’s been 60 times around the sun. That’s how we talk about it here. That’s how we roll at the planetarium. Tonight’s topic is all about water. If you’re from the Midwest, that would be
water. And water is really all over the place. The real question is: Is it the kind of water
we can use? Water, water, all around. Not a drop to drink. Famously quoted from, I believe, The Rime
of the Ancient Mariner. And so we thought we would put together a
panel to discuss all facets of what water is, where it comes from, what its future will
be. And we have a crack team of water experts
to take us there, and let me introduce them for you. We will begin with—by the way, their bios
are in the programs, so I will not spend time reading the entirety
of their bio because I want to get straight to this panel. Oh, by the way, the way we’re going to conduct
this—it’s not a point/counterpoint debate style. It’s really a conversation. It’s as though you walked into a bar and the six of us are there talking about
water. And you’re eavesdropping on our discourse. That’s what’s going to happen tonight. There’ll be no PowerPoint slides, no polished
deliveries. We’re just having a conversation, and you’re
eavesdropping on it. At the end there’ll be time for questions
and answers. I’d like to first introduce a retired general
from the U.S. Air Force, who specializes in —among other things—the protection of
strategic assets. Join me in giving a warm welcome for General
Chuck Wald. The next it’s an honor and a privilege for
me to introduce a long-time friend of mine. We’ve served on boards together. She is the administrator—the chief person
of NOAA, the National Oceanic and Atmospheric Administration. Give me a warm welcome for Kathy Sullivan. We need some geology discussion here, and
so we combed the world to find who is some good geologists that specialize
in water. And we call those folks hydrologists. And I found one who’s actually appeared
as a guest on my radio show StarTalk. She’s an assistant professor in geosciences
at Penn State University. Give a warm welcome to Tess Russo. A lot of our understanding of water comes
to us—water in the universe comes to us from space, so we needed some
kind of representation from NASA here. And we found just that person; the chief scientist
of NASA. Give a warm welcome for Ellen Stofan:. And finally here there’s a long-time friend
and colleague of mine. We came up in graduate school around the same
time. She parted into the solar system. Into the rest of the universe. But she’s one of the—so, she stayed like
parked in the neighborhood. She is one of the world’s experts on comets
and other presence of water in the solar system. Give a warm welcome for Heidi Hammel. So, what I’d like to do is—just so you
can hear their voices and get a sense of where they’re coming
from in the universe—if you just spend two minutes— let me hear your name again and just what
your official titles are and where you’re coming from. General? >>Charles Wald: Thanks, Neil. I’m Chuck Wald. I live in Washington, D.C. I was with the United States Air Force for
35 years before I retired. The last assignment was deputy commander for
European command, U.S. European command. We had 92 countries in that command that we
were responsible for. And previous to that, I led the first three
months of the Afghan air war. Currently, I’m with Deloitte as a vice chairman
for our Federal practice in global defense issues. >>Neil deGrasse Tyson: Excellent. Thank you. Just a mic check; is that loud enough for
people? Do you want it a little louder? Can we get a little louder on that if we could,
please? Thanks. Kathy, go ahead. >>Kathryn Sullivan: Kathy Sullivan. I’m currently the undersecretary of commerce
for oceans and atmosphere and NOAA administrator,
as Neil said. I actually started my life as a solid rock
geologist, specializing in the deep sea floor. Then got a magical opportunity to go fly in
space and look at this little planet with my own eyes, and that’s really where the passion to take
the science and knowledge of our planet and bring it back to Earth and really make
a connect to the challenges and decisions that we all face every day, was struck in
me. So, hence the loopback to NOAA. That’s what we do. We’re America’s… >>Neil deGrasse Tyson: We’ll check in the
microphone here. Hold on. >>Kathryn Sullivan: Oops. Funny. >>Neil deGrasse Tyson: What’s he doing there? >>Kathryn Sullivan: No, really that was just
the light switch. Are you sure it’s on at the board? It worked in the mic check. >>Neil deGrasse Tyson: Yeah, we did actually
have a mic check earlier. While they’re fixing her mic allow me to
announce that this day is the 25th anniversary of Kathy Sullivan deploying
the Hubble Space Telescope in space. >>Kathryn Sullivan: So, small inside baseball
story. I did not actually get to pull the trigger
that released it. Steve Hawley did that. And Bruce McCandless and I were locked in
the airlock where we had almost had to race outside to
crank open the solar ray that hung up for a while. So, I only worked on the telescope five years. I never got to see it deploy. >>Neil deGrasse Tyson: Okay. Aw. But last week and this week were big weeks. It was the 25th anniversary of the launch
of the space shuttle mission to repair the Hubble. Kathy was on that mission, and we’re all
grateful for your efforts there and the rest of your team to make that happen. Hubble is an important piece of American history
of scientific history, and it’ll be remembered forever. So, I don’t know if your microphone is still
fixed. >>Kathryn Sullivan: No. >>Neil deGrasse Tyson: Oh, it’s not. Let’s move on and we’ll come back. So, yes, Tess? >>Tess Russo: Sure. My name is Tess Russo. I’m an assistant professor at Penn State
in the Department of Geosciences. And I study how water moves between the surface
of the Earth and the ground water. I study the physical dynamics of those processes. Most of my work is in the context of agricultural
water management. I do a lot of work in developing countries,
trying to figure out how much water they have, what the extent of their resources are, how they can use them in sustainable ways
to feed themselves and make sure they have enough water to feed
the next generations. >>Neil deGrasse Tyson: Were hydrologists always
around? I mean, is that a forever thing in the world
of geologists? >>Tess Russo: No, I don’t think so. I think one of the earliest hydrologist was
a British fellow. But I can’t remember— >>Neil deGrasse Tyson: How long ago? >>Tess Russo: Like late 1800s maybe. >>Neil deGrasse Tyson: Oh, okay. >>Tess Russo: Or, no, mid-1800s because that’s
when Darcy was. >>Neil deGrasse Tyson: Okay. It’s older than the century. I was just wondering— >>Tess Russo: Oh, yeah. >>Neil deGrasse Tyson: The thought of what
water is doing in its cycle might have been an emergent thought, but it’s
not. >>Tess Russo: No, no. They were trying to figure out how it moves through sand and clay differently. >>Neil deGrasse Tyson: Okay. Cool. Ellen? >>Ellen Stofan: I’m Ellen Stofan. I’m the chief scientist of NASA. I’m actually a planetary geologist. I study volcanoes around the solar system. But as chief scientist of NASA, I get to look
across all the science we do at NASA, from the work we do up on the International
Space Station every day, getting with our astronauts, getting humans ready to go to Mars, hopefully,
in the 2030s, to astrophysics, the great Hubble mission, which my boss Charlie Bolden was up with Kathy
and helped to deploy. >>Neil deGrasse Tyson: Her boss is the head
of NASA, just to make that clear. >>Ellen Stofan: Studying the suns, studying
the planets of our solar system and, of course, studying our favorite planet:
Earth. >>Neil deGrasse Tyson: Nice. Yeah, Heidi? >>Heidi Hammel: My name is Heidi Hammel. >>Neil deGrasse Tyson: Uh-oh. Are you on? >>Heidi Hammel: My name is Heidi Hammel. I am currently executive vice president of
a group called AURA that runs very large telescopes, including the Hubble Space Telescope. So, we have been celebrating this past week. My background is as a planetary astronomer,
but I also do astrophysics. I’ve looked at water on comets. I’ve looked for water on Jupiter. I’ve looked extensively at planets that have water inside them. And I recently participated in a NASA press
conference talking about the water inside Jupiter’s moon Ganymede. So, there’s water all over the solar system
and on planets around other stars as well. And we can talk about that as we move forward. >>Neil deGrasse Tyson: If water’s everywhere,
why are we having a problem here on Earth? Yeah, it’s all your fault. Also, we hear that comets are mostly water. Do we know where Earth’s water came from? Let’s start there. Presumably, you would have the answer to that. Did it come from space? Did it come from volcanoes? Who brought the water here? >>Heidi Hammel: Well, that’s a topic that
we discuss quite a bit in planetary astronomy. Certainly, some of the water just came from
the solar nebular as it formed. There were little bits of dust and ice throughout
our solar system as it was forming initially. And some of that water is intrinsic to our
planet. But at the same time, we really expect that
a lot of water was delivered to our planet as our solar system got stirred up. There’s some theories that say at one point
in time Jupiter, Saturn, Neptune and Uranus were the order of the planets. And there was a whole lot of icy planetesimals
out there filled with water. And at some point when Jupiter, Saturn, Uranus
and Neptune interacted with one another, Uranus and Neptune switched places. And when Neptune did that— when it swooped out into that cloud of debris—a
lot of material was delivered into the inner solar system. And that could be where some of the water’s
come from. So, there’s many different places that water
could come from. >>Neil deGrasse Tyson: So, you’re saying
that the debris in the outer solar system went unstable in the presence of this new
gravitational configuration. And when you go unstable, you lose your orbit. You descend into the inner solar system, and
it’s raining rain. >>Heidi Hammel: It’s raining rain and rocks
like when the dinosaurs— I mean, when the comets or asteroids were
delivering death to the dinosaurs. They were delivering water as well probably. >>Neil deGrasse Tyson: Water as well. So, wasn’t it a point of controversy where whether we use the water from the birth material
of the solar system versus whether it came later? Not that I know anything about it, but I remember
reading about that. >>Kathryn Sullivan: Will my mic ever come
on, do you think? >>Neil deGrasse Tyson: I don’t know. We’ll just stand here. And we’ll just—we can do this. >>Kathryn Sullivan: Well, yeah. I mean, that’s the whole point of science. It’s just constant controversy. >>Neil deGrasse Tyson: So, Ellen, what are
some other hot places—I mean, hot as in scientifically interesting places —you have to be careful with lingo here—in
the solar system where—because NASA has a mantra, I remember. And it’s “follow the water.” Is that still the mantra? And presumably it’s not just because we want a drink of water, but there’s
more going on there. So, could you highlight that or us? >>Ellen Stofan: Well, and I think that’s
important. You really have to step back and say why do we care so much about water. Well, let’s go back to the fact that we
are mostly made of water. We rely on water. Here on Earth, life evolved in water. And we actually remained in the oceans for billions of years before we managed to become
as complex as us. So, we think that water is key to life. And it’s not just— >>Neil deGrasse Tyson: Well, to life as we
know it. >>Ellen Stofan: To life as we know it. But it’s not— >>Neil deGrasse Tyson: Just trying to loosen
that up. >>Ellen Stofan: This isn’t completely an
Earth bias, though, Neil, because water has really unusual properties. It’s a solvent. It’s a bipolar molecule that we think has
really unique properties. >>Neil deGrasse Tyson: People are bipolar,
but that’s a different use of the term. >>Ellen Stofan: That’s a different use of
the term. >>Neil deGrasse Tyson: Yeah, just to clarify. >>Ellen Stofan: Positive and negative charge. >>Neil deGrasse Tyson: Yes. >>Ellen Stofan: So, because of those unique
properties of the water molecule, we think that contributed to the formation
of life. So, when we go out and follow the water in the solar system, out into the
galaxy, out into the universe, we’re following that ingredient—liquid
water—that we think is critical for the formation of life. So, where do we look? On Mars we know there was water on the surface
of Mars several billion years ago, flowing on the
surface maybe for as long as a billion years. Now, that time period is important because
it takes time for life to evolve. It takes time for life to get complex. So, many of us in the scientific community
have a pretty strong belief based on science that at some point life was likely to have
evolved on the surface of Mars. The hard point is going to be finding it. And don’t even get me started on the outer
solar system. Heidi mentioned the fact that Ganymede, one
of the moons of Jupiter, has liquid water in its interior. So does Europa. So does Enceladus, which is a moon of Saturn. All of these places are rich environments for us to go search for extraterrestrial life. Microbes, again. Not little green men. >>Neil deGrasse Tyson: Or little green women. Yes, okay. Tess? So, Tess, there’s water everywhere. And here on Earth, yes, we have water, but now we’re getting picky about our water
because some of it is salinated. Some of it is not. And we can’t really use the salinated water,
and we don’t know how to convert it efficiently yet. And so this creates your profession basically,
right? The cottage industry that is the hydrologists. >>Tess Russo: Yeah. We’re doing quite well. >>Neil deGrasse Tyson: Is that right? Eternal work for you. Yeah, so we take a lot for granted here. I go to the bathroom and just turn the knob and water comes out of the wall. And my parents, who are actually here this
evening, growing up—I mean, they’ve seen a lot
and they were born in the 1920s. I remember we complain about something or
other in the apartment, and they say, “You’re complaining and you have water
coming out of the wall?” And I’m thinking where did they get their
water from when they grew up. I don’t know. But it apparently didn’t come out of the
wall. So, we take so much for granted here in the
United States. What is it we should know about in these developing
worlds where access to potable water is scarce or nonexistent? >>Tess Russo: Well, so in most of the areas
that I’m working in people are either collecting their water by hand from
a nearby resource, or digging a shallow well, or collecting rainwater. And the challenge is that none of those are
very reliable. I mean, the fact that water comes out of the
wall reliably is the key part. And so most of my work has to do with agricultural
water use. So, how much water do people have for irrigation? And that’s becoming increasingly important
as the climate is changing and precipitation patterns are changing and
people can no longer rely on the natural rain patterns to irrigate their
crops. >>Neil deGrasse Tyson: What you mean by natural
is what they had grown accustomed to in their previous traditions. >>Tess Russo: Right. >>Neil deGrasse Tyson: Okay. And so what’s the future of this? >>Tess Russo: It’s uncertain. I think the future is— >>Neil deGrasse Tyson: Just so you know, you’re
speaking to a scientist. When they don’t know something, they’ll
say it’s uncertain. Everyone else says I have the answer, whether
or not they actually do. Yeah. >>Tess Russo: So, the future is working with
people from NASA and NOAA to get a better understanding of how we as
humans are affecting the climate and how it’s changing natural. How those two are working together, so that we can make smarter choices about
how we use water. And so choosing what crops to grow, when to
grow them, those are the decisions that are made. >>Neil deGrasse Tyson: Glaciers are fresh
water, aren’t they? >>Tess Russo: Yeah. >>Neil deGrasse Tyson: So, we are already
melting the glaciers, so doesn’t this help out? >>Tess Russo: That’s true. It is helpful, I guess, in some respect. But it’s not a long-term solution. >>Neil deGrasse Tyson: Kathy, NOAA, they don’t
have their own satellites. Is that correct? >>Kathryn Sullivan: We do have our own satellites. Are you kidding? I’m oh for two. >>Neil deGrasse Tyson: If we can up the gain
on that maybe. Okay. >>Kathryn Sullivan: We do have our own satellites. >>Neil deGrasse Tyson: But NASA launches them
for you. >>Kathryn Sullivan: Yeah. So, what we don’t have is we don’t have our own satellite design development acquisition
engineering cadre of people because the country’s got a fabulous one
in NASA. >>Neil deGrasse Tyson: Called NASA. >>Kathryn Sullivan: Called NASA. So, why build a second one? Agencies actually, believe it or not—government
agencies actually do do things together to make some efficiencies happen. So, this only goes back to the very first
time the United States had weather satellites. NASA—we set the requirements now. NASA builds them for us. They contract to do the launch, and then it
cuts back over to NOAA. >>Neil deGrasse Tyson: Okay. And so there’s ocean and atmosphere in your
acronym, and so what are you trying to do for us? >>Kathryn Sullivan: Yeah. So, this planet is actually a system of systems. When I was in school, you could look at a
cartoon of the Earth with brown mountains the green fields and light blue
sky and dark blue water. And you could pick a color and you could spend
your whole career just doing that. And around the ‘60s— >>Neil deGrasse Tyson: Your whole career working
in one of those colors. >>Kathryn Sullivan: Yeah. I’ll just do the brown dirt, or I’ll just
do the deep-blue ocean. And there was so much still to know and understand
about each of those domains, you could spend— and people for generations had—a whole career
just looking at how one domain works. Around the middle of the last century—in
the ‘60s particularly—we realized it’s actually the links between them that
are really critical. The oceans drive our weather and our climate. The atmosphere produces the input to the hydrological
cycle on the freshwater side. >>Neil deGrasse Tyson: Hydrologic, that’s
the water cycle. >>Kathryn Sullivan: As the water cycle. >>Neil deGrasse Tyson: Why don’t you say
water cycle? >>Kathryn Sullivan: We can say water cycle. They knew what I meant. >>Neil deGrasse Tyson: No, just in my field—in
astrophysics we have simple vocabulary. I’m amazed— >>Kathryn Sullivan: Sure you do. >>Neil deGrasse Tyson: Hydrologic cycle. Its’ the water cycle, right? >>Kathryn Sullivan: It’s the water cycle. >>Neil deGrasse Tyson: It’s the water cycle. >>Kathryn Sullivan: Yeah. >>Neil deGrasse Tyson: Okay. >>Kathryn Sullivan: So, it’s the connections
that matter. And NOAA was created in 1970 out of existing
pieces to do that integration, number one, make the science actually connect
across those fields. And, number two—and more importantly—make
that knowledge connect back to society. So, our roots always have been about making
the nautical charts not for the sake of maps, but so that commerce could go smoothly and
safely along our shores. Do the weather not just because it’s cool
stuff, but because ranchers and farmers out in the Midwest of the United States in
the 1870s critically needed to know when the blue norther is coming in. >>Neil deGrasse Tyson: I hadn’t fully appreciated
that until just this minute. So, I had always known—I knew, but never
understood that NOAA, in fact, ultimately reports to the Secretary
of Commerce. >>Kathryn Sullivan: That’s true. >>Neil deGrasse Tyson: And so it wasn’t
conceived as a science agency for the sake of science. It was conceived as a science agency to serve
oceanic commerce. >>Kathryn Sullivan: It was conceived—by
the 1970s when NOAA was put together, it was conceived as a science-based services
agency to serve the American people and the American economy. >>Neil deGrasse Tyson: But I’m just saying
because if you serve the economy and there’s money involved, it means you’ll
have a real budget. >>Kathryn Sullivan: So, we are as a country
more fond of new toys than of the ongoing maintenance of things. >>Neil deGrasse Tyson: Right, of course. Of course. So, General, there are regions of the world— we think of conflict typically as political,
as maybe even economic, but I don’t know that we much think of conflict
in terms of terrain or water or— can you share with us what your tea leaves
tell you about the future of water as a resource or as a strategic asset? >>Charles Wald: Yeah. I mean, first of all, it’s interesting to
be with all these scientists here that are doing good things for us. Some may be far out, but—so, my sphere of
concern is a little bit more near term and probably a little more focused on the
Earth. The issue about natural resource— >>Neil deGrasse Tyson: I’m sorry. Just the way you said it. It was so casual. Yeah, I focus on near term and the Earth. >>Charles Wald: Well, we had a good discussion
before we came on stage about some of this. And the issue that in the military I think
the big thing we’re looking at today is that the world is changing significantly
in a lot of ways. Some areas that we don’t— in the military—think of directly like those
things you were talking about, which are critical. But we do have a different world of threats, and those threats are, I would say, hybrid
in some says. And some of those threats have to do with
natural resources. We’ve always had a little bit of a problem
with that. We talked about oil earlier, but water becomes
very critical. And if you look at—we talked about it a
minute ago in the Darfur, which is in the Sudan, have had a terrible conflict there: tribal
versus farming people in the Darfur, all caused by conflict over land use for either
grazing or for farming. And that’s not going to be unique. That will become more and more common. And from a U.S. perspective, the U.S. military
plans for things that could happen. Not 100 percent would happen, but if it’s
50/50 shot, I mean, it makes sense for us to be— particularly if there’s high risk involved
with it. So, you look at the Artic, for example, which you all work on. The U.S. military now is paying attention
to the Artic because it’s an open area of conflict potentially. Hopefully, it’ll be a peaceful use of the
area. But when we do procurement of systems: boats, ships, icebreakers, it’s a 30-year
proposition. And you have to guess out into those areas. We also have to be ready for things we just
didn’t predict. My contention is U.S. military’s never predicted
one conflict right in the history of the world. So, you never get it right. And so you got to plan across the spectrum. And the other thing that’s probably a constant is the fact that you’re
going to respond to things you never guessed you would have. You look at the tsunami in the Pacific a few
years ago, or even now— >>Neil deGrasse Tyson: Indonesia. >>Charles Wald: Indonesia, right. And even now with Nepal. I mean, the United States military is responding
in a large way because we can, because we have huge mobility. And those natural disasters—and water could
be part of that— >>Neil deGrasse Tyson: You okay? Good. >>Charles Wald: But I’ll just finish with
this; the U.S., we’re going to face a lot different threats in the near future. Our concern, I think, about water is that
we’re about 2030 away from probably a really serious crisis in the world on water. >>Neil deGrasse Tyson: Twenty, 30, you mean
the year 2030? >>Charles Wald: Twenty-thirty. And if you look at the perspective of what
that 2030 means, right now it seems like it’s a ways off. We can probably figure it out. Nine-eleven was about 14 years ago, and I think that just went like that. So, anyway, yes, we have a lot of issues that
we have to start preparing for. And probably we’re the only military in
the world that can do it because of size. We do spend a lot of money on the U.S. military. >>Neil deGrasse Tyson: Kathy, aren’t we
just one widget away from solving these water problems? It’s just some spigot. The salt water goes in one side, fresh water
comes out the other. So, you say there’ll be a catastrophe in
15 years. Why don’t any of us have any hope or expectation
that a clever person will show up and solve this problem, so that water’s no longer
a strategic asset? >>Kathryn Sullivan: Well, there might be one
widget, but there’ll be nine billion people by the year 2030 that Chuck’s talking about. And so there are a number of factors. One is that widget takes electricity to run. And with the technology we currently have
to do— >>Neil deGrasse Tyson: Or sunlight. >>Kathryn Sullivan: Or sunlight. But you got to make water for nine billion
people. You got to make water to irrigate it in an
area the size of the Central Valley or some of the areas where Tess works. You’re going to need some serious power
density to make that all happen. So, our widgets today that can take the salt
out of seawater consume a lot of electricity to do that. And, guess what, it takes a lot of water to
produce a lot of electricity. So, getting the economics to work where you’re
really making some economic sense and getting the water cycle to where it’s
making some sense to suck in seawater to turn out a gallon of fresh water. And then, oh, by the way, since I do have
that ocean word in our agency title, what’s left when you’ve sucked the salt
out of seawater is a really dense salty brine. Okay, that just became your waste stream. What do you do with that? Well, you could put it back in the big ocean
where it came from, except all the things that live in the big
ocean that 20 percent of the people depend on for food globally, they don’t like really
salty water like that. So, there’s the power density. There’s the competing use of water for electricity, and electricity to make water. There’s the waste problem, and then there’s
just getting started improving some things to the appropriate scale
and moving out on it. So, one widget against nine billion people
is still a pretty tough proposition to scale. >>Neil deGrasse Tyson: Offline we were talking
about how much water it takes to make a bottle of water. Could you just share with us that? >>Kathryn Sullivan: Yeah. So, when you buy a bottle of water—little
PET bottle of water, it took twice as much water to make the bottle
as you have in the bottle. And depending how the water was filtered—assuming
it actually was filtered and it’s not just a fake label—depending
how the filtering was done it took three to nine gallons of water to make one gallon of that bottled water,
which then goes into plastic bottles that took twice as much water to make as they hold. So, you got to get those scales and those efficiencies. And did any of you know that before right
now? I didn’t know it before. >>Neil deGrasse Tyson: Kathy, I’m never
drinking water ever again in my life now that you tell me this. >>Kathryn Sullivan: Municipal water is really
fine. >>Neil deGrasse Tyson: New York, yeah. >>Kathryn Sullivan: And we’re in the United
States. It’s really fine. >>Neil deGrasse Tyson: It’s really good;
New York water. And, of course, even in New York restaurants they keep pushing bottled water on my when
I sit. I said, no, whatever comes out of the wall, that’s what
I’m drinking today. >>Kathryn Sullivan: Penn & Teller did a social
experiment one time where they created a wine bar. I think it was in Manhattan actually. But it was a water bar. And they did a menu with all the different
tasting things, and they wrote up all these fancy descriptions about the aroma from the one from the Artic. And, of course, it being a TV show they showed the waiters taking the empty water
bottles to the garden hose in the back and filling them again. But all the patrons were like lock, stock
and barrel bought in on it. “Oh, the nose is so good.” >>Neil deGrasse Tyson: Tess, what do you guys
use to clean water? You don’t have devices, right? You just have wells and regional clear water
lakes. Is that what’s going on? You don’t have technology helping you. >>Tess Russo: In the developing areas— >>Neil deGrasse Tyson: Yeah, in your places. >>Tess Russo: Yeah. They’re just pumping water right out of
the ground or catching what they can in a barrel off
their roof. Some places use some types of filters. You can build a clay filter that takes out
a lot of the particulates, but you’re left with biological activity
that could still be a problem. >>Neil deGrasse Tyson: I like that. Biological activity. It’s a euphemism for stuff that’ll kill
you. >>Tess Russo: Yeah. >>Neil deGrasse Tyson: NASA has a lot of scientists
working on a lot of projects. Is there anybody trying to desalinate things? If we’re going to go to another planet and
we want to live there— I’m told there’s water on the moon. How do you— >>Kathryn Sullivan: There is. >>Neil deGrasse Tyson: If you’re going to
go there, you want to clean it up so you can drink it. And, presumably, astronauts in the Space Station— is it not true that they recycle their own
urine and drink it? Is that correct? >>Ellen Stofan: We do. Right now on the Space Station we— >>Neil deGrasse Tyson: You’re on Earth. >>Ellen Stofan: Okay, I’m on—we NASA. >>Neil deGrasse Tyson: Don’t say we. >>Ellen Stofan: We NASA. >>Neil deGrasse Tyson: We NASA. Good, okay. Kathy drank her own pee. Is that right, Kathy? >>Kathryn Sullivan: That would be so not right. We made water from fuel cells on the Space— >>Neil deGrasse Tyson: From fuel cells, okay. All right. Damn, I thought I had that one. >>Ellen Stofan: Up on the ISS right now we
recycle about 85 percent of the water by purifying urine. To go to Mars—eight-month journey there,
eight-month journey back— we’re going to need to probably get to the
point where we’re recycling about 95 percent of the water. So, we’re not quite at the system that we’d
like to be. So, we’re still working on that. >>Neil deGrasse Tyson: Unless you find water
on Mars, and then you refill when you get there. Like a water filling station. >>Ellen Stofan: Right. And we know there’s water at the poles of
the moon. We know there’s water on Mars. So, we have whole programs of research right
now called In-Situ Resource Utilization, or ISRU, because we love acronyms. >>Neil deGrasse Tyson: We had an entire [unintelligible]
panel on that very subject. It was cool. >>Ellen Stofan: So, obviously, we need water
to drink. We can’t live very long without. So, that’s one possible use of the water. But even more importantly rocket fuel is basically made out of hydrogen and oxygen. So, we want the water for the astronauts to
drink potentially, but even more importantly especially at Mars
we want that water to be turned into rocket fuel to help launch them up off the
surface and get them home safely. >>Kathryn Sullivan: So, Ellen, as one of the
folks that once upon a time thought she might be on the list that got to go do
one of those things, the problem I had was there are not lakes on the moon that you just
dip a bucket into. You’ve got to extract it from huge volumes
of the surface material of the moon or Mars. So, I never heard anyone talk to intelligently
about what am I supposed to do from the time I land to the time that the other 700 rocket
ships with all the supplies arrive to build the thing that will extract the water to maybe make
water? And if that doesn’t work, then what are
we doing? >>Ellen Stofan: That’s a great question,
and something we’re actually working on right now. We are working on a whole thing called the
journey to Mars. How do you get humans to Mars in the 2030s, have them be
able to land there safely, return home safely and live for some period of time on the surface. So, the idea is— and while we’re working on these ISRU technologies
so hard right now— that you would preposition an ISRU plant,
say, in the surface of Mars somewhere near where the astronauts would be. You demonstrate that you can make rocket fuel. You demonstrate that you can do water before
you ever send humans. So, that’s one of the reasons it’s going
to take us to the 2030s at least to get humans to Mars, because we have a lot of technology development,
a lot of work to do, to make sure there’s resources on the surface of mars
by the time humans get there, or it wouldn’t be viable. Mars isn’t like sending humans to Antarctica
or even to the ISS, the International Space Station. It’s a pretty harsh place. It’s not a live-off-the-land kind of place. >>Charles Wald: You got to wonder if you can
make that practical to some of the work we need here on Earth. >>Neil deGrasse Tyson: Well, that’s what
I’m thinking the whole time. You get the smartest people to solve the space-borne problem, and then
you realize that has huge applications down here on Earth. >>Charles Wald: Absolutely. >>Neil deGrasse Tyson: That would be for people
who might not necessarily have humanitarian blood flowing through them,
but they like the really interesting engineering or science problem. Then they solve it for space, and then it
comes back. >>Charles Wald: One of the problems we had
in Afghanistan was that if you look at— most people probably paid a little attention
to this—there was this issue with IEDs, improvised explosive devices. They were all in convoys. >>Neil deGrasse Tyson: What are those again? >>Charles Wald: Improvised explosive devices. >>Neil deGrasse Tyson: IEDs. >>Charles Wald: Made-up bomb that hits a vehicle
and does bad things to it. Eighty-five percent of our casualties in Afghanistan
were in convoys. Those convoys were carrying water and fuel. The fuel to the battlefield is upwards of
$400 a gallon, and they’re using 22 gallons of fuel per
soldier. And the same thing with water issue. And some of that technology we’ll use it. It’ll just be natural. But they’ll be some things that are really
going to help the human race come out of these things, too. Bloom energy is one of them, for example. >>Heidi Hammel: But talking about some of
the things we discussed before this, NASA usually does things in a one-off way. I mean, they’ll come up with some great
ideas and they’ll do an amazing thing, but the
word scalability is the words that you were using— both of you—earlier today. And certainly in the military world, that’s something that you have to think
about. As you just described, you’re talking about supply lines. I think that’s one of the disconnects that
we might have if we tried to take a NASA thing and scale
it up. >>Kathryn Sullivan: But I’m with Neil. I don’t think you ask the guy who’s trying to figure out how do you sustain people
on Mars—I wouldn’t ask that person, that gal, to solve that problem, too. Ask them to change the equation radically and let the other smart folks say, oh, now
that only costs 1/1000th of what it used to, look what I can do with it. >>Ellen Stofan: Right. And that’s been the story of NASA. We estimate for about every dollar spent at
NASA, about $4 gets returned to the U.S. economy. And that’s through innovative— >>Neil deGrasse Tyson: In manna from Heaven
or something? What are you talking about? >>Ellen Stofan: Innovative new applications
of technology. >>Kathryn Sullivan: Tang. >>Neil deGrasse Tyson: The economic value
of the innovation. >>Ellen Stofan: Yeah. >>Neil deGrasse Tyson: I want to back up for
a minute. Heidi, the astronauts went to the moon. There was no water there. So, lately there’s been this talk about
water on—how did it get there and where is it and why? >>Heidi Hammel: The question of where’s
the water, what is everywhere, but the problem is that it’s in forms that
are not easily accessible. For example, on the moon—as we were talking
about—there is for sure water on the moon, but it’s tightly bound up in clathrates
and you can’t just get that water out. >>Neil deGrasse Tyson: Is clathrate some kind
of—is that a geo word for something? >>Heidi Hammel: Yeah. It’s a geo word for a mineral lattice, and then the water is trapped inside the lattice. >>Neil deGrasse Tyson: Oh, okay. So, it’s like a water bottle. >>Tess Russo: It’s like a cage. >>Heidi Hammel: On a microscopic scale. >>Neil deGrasse Tyson: Okay, all right. So, this is a point that was just made. The water may be there, but you need some
kind of device where you dump in the stuff with water in the lattice
and out comes a cup of water on the other side. >>Heidi Hammel: Yeah. Much like we’re talking about our desal
techniques when you’ve got the salt water going in
and the fresh water coming out. Except it’s soil instead of salt water. >>Neil deGrasse Tyson: Now, Ellen, there are
many people talking about the value of water in space. So, that if you could go to a comet, extract
water from it, and then deliver it to astronauts in space
then NASA doesn’t have to launch the [unintelligible] of water to get to them. Because that cost still how much a pound? >>Ellen Stofan: A lot. >>Neil deGrasse Tyson: To launch any amount
of weight into space, it’s like $10,000 a pound. >>Ellen Stofan: Yeah, it’s huge. Yeah, it’s a huge amount. So, for us we’re always trying to minimize
how much we have to launch off the surface of the Earth because we have
all this gravity. So, you need a big rocket to get things off
the surface. That’s why if you can find things out in the solar system
and utilize them, all the better. Now, catching a comet, mining it for water,
that’s a bit difficult. It’s a lot easier to go to Mars where unlike
the moon water on Mars is probably much more accessible. We think there’s probably ice under some
of the dust on Mars. There’s ice under the surface. There’s ice at the poles. >>Neil deGrasse Tyson: But I want to go to
a comet. What’s wrong with going to a comet? Why can’t we do that? >>Ellen Stofan: I love comets. >>Heidi Hammel: We’ve gone to comets. >>Neil deGrasse Tyson: No, but lasso it and
put it out in the thing and go get it when you need it and put it in the Sudan,
so there’s not a war going. >>Heidi Hammel: Yeah, that’d be great. I can imagine that. You target it and— they did that experiment in Russia not too
long ago when Chelyabinsk hit. >>Neil deGrasse Tyson: Oh, you’re talking
about the—in February 2013. >>Heidi Hammel: Exactly. >>Neil deGrasse Tyson: They unwittingly did
the experiment. Okay. >>Heidi Hammel: Yeah, nature did the experiment
delivering volatiles to us as comets or asteroids impacting our atmosphere. >>Neil deGrasse Tyson: There was an asteroid
basically the size of this stage that collided with Earth at 40,000 miles an
hour, exploded in air over the town of Chelyabinsk injuring 1,600 people
who all basically got cut by shattered glass because they saw this huge
burst of light and they all went running to the window to see what that was, forgetting
their physics 101 that light travels faster than sound. And so they go to the window, then the shockwave
hits, and then everyone gets cuts. It was like the Band-Aid collision. But that’s a collision with Earth. I’m talking about parking it somewhere,
and then drawing from it. Why is that so hard? >>Heidi Hammel: Well, I don’t know, Neil. It sounds like science fiction to me, but if we could think of a way to do that,
sure. But we’re just working on recycling urine
at this point. >>Ellen Stofan: Well, I must say— >>Neil deGrasse Tyson: Okay. Well, get back to work on that then. What, Ellen? >>Ellen Stofan: We do have a plan to go get
a piece of an asteroid and bring it back to the vicinity of the moon. It’s called the Asteroid Retrieval Mission that NASA’s working on right now to do in
the 2020s, which would go get a piece of an asteroid and bring it
back— >>Neil deGrasse Tyson: So, test of concept
then? >>Ellen Stofan: You could say that. And asteroids actually have a lot of water. In fact, some scientists think that it was
actually asteroids that delivered most of our water to the Earth, not comets. >>Neil deGrasse Tyson: This is that lattice
water that you’ve been talking about. >>Ellen Stofan: Yes. >>Neil deGrasse Tyson: I’ve always wondered. I look at an asteroid and it’s just like a dead rock to me. Then the geologists get all excited that it
has water— excuse me, [unintelligible]. >>Heidi Hammel: We’re actually finding asteroids
now in the main belt that have tails and comi like comets. And they call them main-belt comets, but they’re asteroids. So, let’s just get a little terminology
here straight. An asteroid is a dirt ball with some ice mixed
in. And a comet is an ice ball with some dirt
mixed in. >>Neil deGrasse Tyson: That’s the kind of
lingo I’m looking for here. Thank you, Heidi. >>Heidi Hammel: So, no, but there are some
challenges with comets that are a bit distinct from asteroids. And one of the challenges is that most of
the comets that we have visited now with NASA spacecraft with ESA spacecraft— >>Neil deGrasse Tyson: European Space Agency. >>Heidi Hammel: European Space Agency. They tend to be somewhat fluffier. They are icy, and so their tensile strength
is lower. So, it’s a little bit more challenging, I think, to think about towing
one back because comets often just fall apart on their own. I mean, just sunlight makes it fall apart. >>Neil deGrasse Tyson: So, they don’t have
much structural integrity to go reach out and grab it and put it in
one place or another? >>Heidi Hammel: That’s right. >>Neil deGrasse Tyson: This is the problem
you’re saying? >>Heidi Hammel: It could be a problem, yeah. >>Kathryn Sullivan: Towing your snow cone. >>Neil deGrasse Tyson: That would be hard. >>Kathryn Sullivan: Yeah. >>Neil deGrasse Tyson: To tow a snow cone. Okay. >>Heidi Hammel: So, why don’t we tow icebergs? I actually wanted to ask our water resource
person why don’t we just— we have Alaska. There’s a lot of ice up there. Can’t we get some big chunks of it and tow
them down to California? >>Neil deGrasse Tyson: Well, just a sec. Weren’t there plans in previous wars to
move icebergs around as a source of water? >>Charles Wald: Sure. We’ve already done it. >>Neil deGrasse Tyson: Oh, we’ve already
done it. Excuse me. I’m late in the coming here. >>Charles Wald: No, I’m learning more stuff
about comets and asteroids. This is amazing really. >>Neil deGrasse Tyson: Excuse me, I want to
know what the military did moving icebergs around. >>Charles Wald: No, I mean— >>Neil deGrasse Tyson: We’ll get back to
them in a minute. >>Charles Wald: I mean, Saudi Arabia purchased
an iceberg, and they were going to bring it to Saudi Arabia. They never did it, but— >>Neil deGrasse Tyson: Wait, wait, wait. Who sold them the iceberg? That’s what I want to know. I’ll get in on that one right here. >>Charles Wald: I think it was NOAA. >>Neil deGrasse Tyson: So, you attach an iceberg
to some ship and drag it somewhere? >>Charles Wald: Right. >>Neil deGrasse Tyson: And then what happens? >>Charles Wald: Melt it and use it. >>Neil deGrasse Tyson: Okay then. So, Tess, what? >>Tess Russo: Well, so the issue with that—and
the same with the desal—is that— >>Neil deGrasse Tyson: Desal is desalinization. >>Tess Russo: Desalinization. >>Neil deGrasse Tyson: So, you’re a nickname
basis with the technology. >>Tess Russo: Yeah. >>Neil deGrasse Tyson: Desal. Okay, go. >>Tess Russo: Is that you’re only providing
water right at the coast. And if you think about the U.S. where most
of our agriculture is— it would have to cross a mountain range to
get to central California, and have the country to get to the high plains. And so moving that water requires more energy
than it would take to desalinate, which is our initial problem. And so we need to think about more than how
do we provide drinking water to the people on the coast, but how do we provide water
for all the agriculture and building our clothes and electronics and all that stuff. >>Charles Wald: There is some semi-good news. >>Neil deGrasse Tyson: Okay. Let me hear it. >>Charles Wald: The bad news is that, again,
between now and 2050, the urbanization of the littoral of the coastlines
of the world is grow dramatically. That’s where people are going to move to. And so there is a transportation issue. I get it. But— >>Neil deGrasse Tyson: Just to be clear, you’re
saying this trend has been going on in fact for the entire 20th century
where cities are becoming more populated relative to rural and suburban communities. >>Charles Wald: Yeah, absolutely. Absolutely. And you’ve read all the size of the cities. The Marine Corp—as a matter of fact, their
major strategy for the future is urban warfare along the littoral. >>Neil deGrasse Tyson: Along the what? >>Charles Wald: The littoral. >>Neil deGrasse Tyson: What is that word? That’s a new word for me. >>Charles Wald: Really? >>Neil deGrasse Tyson: Say it again. >>Charles Wald: Is that military word. L-I-T-T-O-R-A-L. >>Heidi Hammel: No, that's a science word. >>Ellen Stofan: It’s a science word. >>Neil deGrasse Tyson: Am I the only one? A science word? >>Kathryn Sullivan: It’s a science word. >>Neil deGrasse Tyson: I’m sorry. Have you heard of this word before? Littoral. Or is it just me? I don’t know. >>Kathryn Sullivan: It’s an Earth science
word. >>Neil deGrasse Tyson: Earth science. So, tell me—I’ll get back to you in a
minute. Let me get this word defined. Go. >>Kathryn Sullivan: Coastal zones. The coastlines and shallow seas fringing the
coasts. >>Neil deGrasse Tyson: Would that include
being on a coast if you’re on a river? >>Kathryn Sullivan: It’s about being on
the coast of the sea. >>Neil deGrasse Tyson: Of the seas and the
oceans? >>Kathryn Sullivan: Yeah. >>Neil deGrasse Tyson: Okay, fine. Littoral. Thank you. >>Charles Wald: I thought that was a common-used— >>Neil deGrasse Tyson: No, I’m sorry. >>Charles Wald: But desalination or icebergs
it’s perhaps called it could be— so, this is more than a one-solution issue. I mean, I think. So, that could be part of it. And moving the water inland is very problematic. But talking to some friends I have that work
with U.S. water and other areas, the big push they say is a couple things in
the near term. Not long term. I think long term’s going to be some space
solution of some sort, no doubt about it, in a lot of ways. But I think in the near term it’s going
to be a realization that water is cost, which has always been kind of a moral issue. And number two is we’re going to have to
use wastewater and recycle everything we have. >>Kathryn Sullivan: No, Neil, we’re worried
about getting drinkable water. And in this country we use drinkable water
for our lawns and our laundry and our toilets. The biggest water treatment plant in southern
California pumps trillions of gallons of treated water that’s drinkable standards
except it would probably offend us all, pump it into the sea because it’s been treated,
and because we built our system to be one way. That could probably water all the lawns in
southern California. That could do all the laundry. That could power power plants, but we just
dump it into the ocean. So, before we go doing widgets and gadgets,
we might want to look at how we’re using what we got. >>Neil deGrasse Tyson: Okay. So, what comes first? Thinking of water as a strategic—potable
water as a strategic asset because we’re running low on it, or interfacing with the
different stages of cleanliness of the water in a more intelligent way. At what point do you say I don’t want to
do that? I don’t want to fight a war to get access
to clean water. Or do you turn the problem back inland and
say let’s fix how we’ve ever intersected with our own usage of water, be
it for watering plants, cleaning clothes, drinking or taking a shower. >>Charles Wald: I think you have to make water
a holistic issue. And right now businesses a lot of times it
has to do with just purely with a bottom line, which is a motivation. There’s no doubt about it, but I think it has to be much more sophisticated. It has to be more holistic and it has to be done fairly quickly. I mean, as we were talking earlier about the
Gaza, which last summer the Israelis— >>Neil deGrasse Tyson: By the way, when everyone
here has been saying we were talking earlier, we just had a mini
press conference with seven members of the press. And so a lot of this came up then. This is the referencing to earlier. It’s not something that you missed that
you’re wondering—so, continue. >>Charles Wald: But I like your questions
better than the press. But in the Gaza, as we all know, it’s the
size of Washington D.C. that’s very strict structured as people are closed in. And water is of the essence. They live on the water, but they don’t have
a desal plant there. They get their water from Israel. And they’re using so much water that in
two years the water— the aquafer is going to salinate and they
won’t have any water. Now, that's going to be a crisis in the making
right there. And we talk about what— >>Neil deGrasse Tyson: You see that coming
already. >>Charles Wald: WE see it coming. >>Neil deGrasse Tyson: So— >>Ellen Stofan: Well, and I’d like to bring
it back to California. And this is where I think the U.S.— >>Neil deGrasse Tyson: And you’re from California,
right? >>Ellen Stofan: I used to live in California
because I worked at the Jet Propulsion Laboratory out there for a while. >>Neil deGrasse Tyson: In Pasadena, California. >>Ellen Stofan: Right. And I guess to me the frustration I see is this is such an opportunity for us to lead
because we look at the situation in California right now— that it’s suffering a severe drought. They’re pumping out their aquafer to grow food for all of us in the Central
Valley of California that we all eat. So, if you think, oh, it’s California’s
problem. It’s not my problem. It’s all of our problem. That’s where our food comes from. And there’s a real issue. Reduce because of the drought, less snow pack, less water, it’s not recharging the aquafer,
it’s not refiling the reservoirs. So, we’re in a crisis right here, and it’s
consistent with climate change. These mega droughts like we’re seeing the
southwest is consistent with climate change. So, we have to start valuing water as a precious
finite commodity here. And, face it, we have the technology. We have the knowhow to lead the rest of the
world. But we need to do it. >>Heidi Hammel: How can we turn that [unintelligible]
around so that water’s not being thrown away, and who makes that
choice? Is it our choice? Could we write petitions? >>Neil deGrasse Tyson: Do you, as head of
NOAA, suggest that on TV to the rest of the world the way the Surgeon
General used to get up there and tell America how stuff went down? >>Kathryn Sullivan: Yeah. There’s a bully pulpits are the power of
the pulpit opportunity certainty. But water management in the United States
is one step up above the Surgeon General. It tends to be municipal and state controlled. So, it's not Federal controlled. It’s not Federal regulated, and it’s not
even really most of the data about water usage in the U.S. is actually state and local data. A lot of the many thousands of wells in the country are not listed anywhere. We don’t know what the real count is, and they’re not metered. So, you don’t really know the usage. So, that plant in southern California built
back when it was built is in the very southern part of the L.A. area mainly because you wanted
it out of your way. It’s an unsightly thing, so they put it
out where people didn’t live at the time. And that’s actually slightly downhill. Boy, you wish it wasn’t at this point because
now to turn that plumbing around and be able to reuse some of that water would
be tremendous. Vegas has had to do this for years. The big resorts with all their fountains are all closed-loop, not using any freshwater. They’ve got— >>Neil deGrasse Tyson: What’s that information
you gave us about the per capita consumption of water in Vegas compared with New Yorkers? >>Kathryn Sullivan: Yeah. The per capita consumption of water in Las
Vegas— the number is from a couple years ago. It’s probably still very close to true. Twice the per capita consumption of water
as you have here in New York, but it rains 10 times as much rain in New
York. Let me pick up on the point that both Tess
and Ellen have made, too, with another little piece. Agriculture’s the biggest use of water in
Nevada. It’s like 90 percent of Nevada’s water
use. The agricultural sector in Nevada employs
about 6,000 people. The Mirage Hotel singular in Vegas employs
more people than that. So, there are all these odd scale factors. >>Neil deGrasse Tyson: So, the Colorado River
I’ve read that— or any river consider it. The river has fresh water because it’s basically
rainwater collecting into a basin and finding its way
to the ocean where it’s salty there. And so I have a river adjacent to my town,
my county, my state, and I start taking water from the river. I can do it directly from the river, or from
my aquifer, which feeds the river. Isn’t that correct, if I understand the
little bit of geology that I know. If that’s the case, you’re downstream
from me. The river now has less water in it because I’ve sucked it out and used it for
my agriculture and you’re a different state. Is this the beginnings of state warfare? Eventually, what is the flow rate of that river 10 states down the line? And isn’t this actually happening? >>Heidi Hammel: Yeah. Why are you saying this in a hypothetical
way? >>Neil deGrasse Tyson: Okay. >>Kathryn Sullivan: So, the Des Moines, Iowa
Municipal Utility is in the process of suing three upstream
counties for failure to manage their feeder system off the farmlands that’s dumping too much
nitrate into the Raccoon River that feeds Des Moines Municipal Water. Think Darfur. Farmers up land, urban users down land. You’re doing something to the water that’s
affecting my ability to use the water. It’s happening in 35—35 states in this
country are fighting with each other over water today. >>Charles Wald: I mean, [unintelligible] Colorado
River, but I was just in Ethiopia a couple weeks ago, and they’re
building a huge dam on the Nile. The Nile actually flows toward the Mediterranean,
obviously, into Egypt. And it’s a big issues with Egypt. I mean, they’ve threatened war over this
thing because [unintelligible] accommodate how much
are they going to take out. But they’re going to keep it for electricity
actually. But they’re stopping the water. And that’s the future. I mean, that’s what Israel having an issue
with the Jordan River and all that for a long time. So, water wars are not—first of all, they’re
not new, but they could be exacerbated, I think. >>Neil deGrasse Tyson: Well, what’s going
on— is something in Syria going on related to
water as well? >>Charles Wald: Well, they had a dam there
in Syria at Mosul, or the dam that went from Mosul down into Iraq. And the ISIS folks took it over. They got it back. I used to fly over it. But, again, you’re talking about water distribution into Iraq, which, again, has a huge morality
issue to it, has a huge strategic issue; a lot of influence. And so those are—we’ve seen this in the
Middle East with some of the activity going there. There is not morality to the war there. I mean, in some cases. And water certainly is a target. >>Neil deGrasse Tyson: That’s just an interesting
sentence. There’s no morality in that war. It’s just interesting to me. >>Charles Wald: No, I said that war there. >>Neil deGrasse Tyson: Oh, war there. >>Charles Wald: Well, no, wait a second. >>Neil deGrasse Tyson: No, I was just— >>Charles Wald: No, you’re right. You’re right. Okay, Freudian slip. >>Neil deGrasse Tyson: No, no, no. That’s fine. >>Charles Wald: I’m a military guy. Everything’s the nail. I’m a hammer. >>Neil deGrasse Tyson: Yeah, I got you. I got you. And we expect that. This is why you exist. Tess, let me ask—I don’t really understand
aquifers. And I’m just wondering could you—I saw
a map that compared—was it 10 years ago or 20 years ago—the volume of aquifer water
in California relative to today. Was it lower or less or where did it go? Why isn’t it there? And could you just give me aquifer 101 because—plus, if we’re going
to find life on Mars, isn’t it going to be in an aquifer beneath the soils because on the surface you
wouldn’t expect that. So, could you just give me a 101 on this? >>Tess Russo: Sure. Aquifers are ground water. So, when you drill a well, you’re drilling into an aquifer. And an aquifer by definition means that it
can provide enough water to be useful. It’s basically—like if my cup were full
of sand, the part that the water goes up to is the
aquifer. It’s filling all the pore spaces in between
the sediments and the rock, fractures. >>Neil deGrasse Tyson: Okay. That’s aquafer 101. >>Tess Russo: Oh, the California. >>Neil deGrasse Tyson: Yeah. So, California—because my naïve thought
is there’s water in the ground. I take out the water. I water the plant, and the plant uses some of it, but the rest goes in the
soil. And doesn’t it go back to the aquifer? And I pull out of the well and I drink it
and I pee later and it goes back in. Where’s the water going? I thought it was all just one cycle. >>Tess Russo: So, that’s what the farmers
in India that I work with— they think it’s okay to overwater my field
because the rest of it just goes back to the aquifer. But we have to remember the other thing that’s
happening: evaporation— >>Neil deGrasse Tyson: But that goes to a
cloud that then rains later. >>Tess Russo: Right. But the time that it takes the water to go
back into the aquifer is longer than it takes you to
pump it. And so— >>Neil deGrasse Tyson: Oh, so it’s out of
equilibrium. >>Tess Russo: Yes. Yeah. >>Neil deGrasse Tyson: Oh, that’s different. >>Tess Russo: And so there are aquifers that
are in equilibrium and that we’re pumping at a reasonable, sustainable
rate. And those are fine. And then there’s ones that we’re pumping
faster than recharge goes back in. We’re actually pumping water that recharged
in a previous ice age. >>Neil deGrasse Tyson: Whoa. >>Tess Russo: Yeah. >>Neil deGrasse Tyson: Okay. So, why isn’t that causing earthquakes? >>Tess Russo: Why is it or— >>Neil deGrasse Tyson: Is it not. >>Tess Russo: Oh, it is in some places. >>Neil deGrasse Tyson: Oh, okay. That’s the answer. Good, all right. >>Kathryn Sullivan: It’s causing massive
land subsidence in some places. >>Tess Russo: Yeah. >>Kathryn Sullivan: You can find telephone
poles in the Imperial Valley in California where people would put a sign on the ground
and take a picture of it. And they come back 10 years later, and that
sign is here and it’s like 100 feet of subsidence from pulling the ground water
out. >>Neil deGrasse Tyson: Well, I missed the
sense of where the sign was. So, the sign was high, and then it was low. >>Kathryn Sullivan: You put a sign on the
ground. You come back 10 years later. Because the land sank, the sign is now 10 feet above the current ground level. >>Neil deGrasse Tyson: Oh, the land sank. >>Kathryn Sullivan: The land sank. So, you put another sign, you come back another 10 years and there’s
100 foot of subsidence from water [unintelligible]. >>Neil deGrasse Tyson: I was just in Venice
and they have really too much water there. Venice, Italy. And everything’s sinking. You’re walking on a floor and they said this is the floor of the last century. But four centuries ago the floor was five
feet below you. And so everything’s just sinking, returning
to the Earth. >>Tess Russo: But the other thing is in California
it’s sinking, but it’s also rising because they’re pumping all this water out
of the ground, which makes it lighter. And then so that crust material that’s floating
on our mantel is now lighter, and so it is more buoyant and it floats up a little
bit. And that’s what’s causing the earthquakes
that people have been talking about in California. >>Neil deGrasse Tyson: Oh, that’s complicated. >>Tess Russo: Yeah. It’s coming up and it’s releasing the
pressure on parts of the San Andreas, and so it makes
it easier to sink. >>Heidi Hammel: So, what I’m hearing is
the word disequilibrium, and that sounds like a pretty important word here
for water usage, for just how people are interacting with our planet right
now is that we are driving it into disequilibrium by where the people are
going and how much of the resources they’re using. But we’re not actively trying to mitigate
it yet. What will it take? >>Neil deGrasse Tyson: No one’s thinking
about equilibrium here. It’s not a thought. We don’t know. Now, but I’m still in the aquifer thing
here. Before I flesh that out some more, if we’re
going to find life on Mars it’s going to be in an aquifer. Why do you think there are aquifers on Mars? >>Heidi Hammel: Well, we have a lot of good
reasons for thinking that. When we take our rovers there and we look
at the geology, we can see— >>Neil deGrasse Tyson: Marsology. >>Heidi Hammel: Mars— >>Neil deGrasse Tyson: Geo means Earth. I’m just saying. >>Heidi Hammel: The Marology. >>Neil deGrasse Tyson: Marology, yeah. >>Heidi Hammel: Mar— >>Neil deGrasse Tyson: That word sucks. Okay, stick with geology. I got you. Okay, I’m with you. We look at rocks. And we look at the rocks and we see layers in the rocks, and the layers
in the rocks tell us that at times there could be standing water. It’s not just layers. There’s also structures that we see— small-scale structures—that we know from
analogies—studies to Earth that must have formed in standing water. There’s chemistry. There’s chemistry we see that we know is
indicative of water in the past. And so there are many lines of evidence from
the spacecraft we’ve sent there that tell us that water is there. But we know it’s not on the surface now. It’s dry on the surface now. Dry as a bone. However, we do know when some of the spacecraft
have scooped up soil and when they look at it initially, it’s
very white and reflective. And then it dissipates. It sublimes. It evaporates. It’s gone. So, it’s strong evidence that there is water
ice underneath the surface. >>Neil deGrasse Tyson: Okay, but it’s frozen. It’s not liquid then. >>Heidi Hammel: Oh, it’s probably not liquid,
no. >>Neil deGrasse Tyson: Okay. So, you wouldn’t expect life as we know
it to thriving in ice? >>Heidi Hammel: Not right now. Maybe in the past, though. I think as Ellen said, we aren’t looking
for plants and little green men and women. We’re looking for the traces of biological
activity in the past. >>Ellen Stofan: Yeah. So, we’re mostly looking for fossilized
life, fossil evidence of life. >>Neil deGrasse Tyson: Evidence of life having
once thrived. >>Ellen Stofan: Exactly. Though, there are people who believe that scientists who think that life could have
gone underground. So, that if you did pump water from deep enough—because
if you go deep enough down, it actually gets warmer as you go deeper into
a planet. >>Neil deGrasse Tyson: Is that true in Mars
as well. >>Ellen Stofan: Yeah. >>Neil deGrasse Tyson: Oh, so there’d be
a point where you’ve liquefied— >>Ellen Stofan: Yeah. There should be actually a water table deep
in Mars. >>Neil deGrasse Tyson: I didn’t know that. >>Ellen Stofan: If you drilled down to that
and pumped out— >>Neil deGrasse Tyson: About how far? >>Ellen Stofan: Couple kilometers down. >>Neil deGrasse Tyson: Oh, that’s all? >>Ellen Stofan: So, it’s—yeah. We don’t have the technology right now to
drill that deep. But you actually have to get a couple meters
below the surface on Mars to get away from the radiation. There’s solar radiation and cosmic radiation because Mars doesn’t have a protective magnetic
field anymore. It used to in the past. It doesn’t now. And so the surface of Mars— >>Neil deGrasse Tyson: This would be radiation
that’s hostile to life. >>Ellen Stofan: Yeah. >>Neil deGrasse Tyson: To molecules that comprise
life. >>Ellen Stofan: As we know it. But on the other hand, we— >>Neil deGrasse Tyson: If we were all tardigrades
this would not be a problem. >>Ellen Stofan: Exactly. >>Neil deGrasse Tyson: The little water bears. >>Ellen Stofan: The little water bears. >>Neil deGrasse Tyson: The cutie little— >>Ellen Stofan: Cute. >>Neil deGrasse Tyson: You ever see the tardigrades? They’re like this big, and you could step on them and they’ll survive. Like radiate them, squeeze them, heat them, freeze them, freeze dry, microwave
them. Did I leave anything out? >>Ellen Stofan:
Pretty much you can—they’ll live through anything. Take them into space. They live. >>Neil deGrasse Tyson: Yeah. >>Ellen Stofan: And that’s one of the things—that’s
what makes us so optimistic about finding life off the Earth because what
we’ve learned over the last 10 to 20 years is life— we’ve found life in the oddest places here
on Earth: extreme cold, extreme hot. Life lives in—there’s bacteria that live
in radioactive waste. So, life is very tenacious, and that’s why
we wonder could that life on Mars have migrated to a point where there is still—and
that’s something we worry about for exploring Mars because certainly we wouldn’t
want to bring that back to Earth. >>Charles Wald: Get a little trifled mixed
up here a little bit. >>Neil deGrasse Tyson: What’s that? Tell me. Straighten me out. >>Charles Wald: Well, I mean, first of all
I love what you guys are doing. And I think that's what America should do
and the world should do. We should explore and find out. And who knows? We may have to go live there someday, is the point, I guess. In the near term, you’re talking about why
don’t we do something in Earth. It’s amazing thing because you just can’t
get people to have consensus around the world. I mean, it’s like in America. Okay, well, we’ll give up half our water
for somebody else. I don’t think so. And so you have this really interesting dynamic
in the world right now. And we talked again, previously with the—sorry. But this dynamic where you almost have to
have, unfortunately, a crisis, I think. >>Heidi Hammel: The crisis would have to be
I’d turn on my tap and the water doesn’t come. >>Charles Wald: Yeah. Or you get real thirsty and you die. >>Neil deGrasse Tyson: Yeah. That would— >>Charles Wald: But there are places that
they spend their whole day trying to get water. I mean, and— >>Neil deGrasse Tyson: Just to be clear, you
can go a month without food, but you’re dead in 10 days without water. >>Charles Wald: Right. >>Neil deGrasse Tyson: Is that about fair? >>Charles Wald: If you’re lucky to go 10. >>Neil deGrasse Tyson: Yeah, if you’re lucky. Right. >>Charles Wald: So, I guess my real question
there since I— it was a question embedded. What are we doing about all the cool things
you guys are doing? I mean, really tremendously cool. I get fired up hearing about it, to make life here on Earth better. >>Ellen Stofan: Well, everything we do at
NASA we feel comes back to the Earth, whether it’s through technology, whether
it’s through the direct research we do with our 19 satellites that we do with our
partners at NOAA and our international partners to measure
all these things to try to figure out what’s happening on the Earth right now
because climate change is happening right now. There are streets in Florida that flood at
high tide. Mega drought in California. The Arctic ice is melting. Come on, people, what more do you need? Climate change is happening. >>Neil deGrasse Tyson: You’re in New York
here. That’s fine. We already get it. We got that. All right. >>Ellen Stofan: So, certainly we’re working
on that, but the amazing thing is all of this research we do, whether it’s the
health research we do on the astronauts up on the International Space Station, a lot
of that we bring back to help people right here on Earth. All this technology ultimately helps our own
planet. >>Kathryn Sullivan: So, the trick is—this
has been principally a scientific conversation. It’s as you know, Chuck, just within the
last not that many years it began to be a national security conversation. And it’s really only just starting to become an economic conversation, I remarked
in our earlier session. The great line that characterized this part
of the issue to me was—guess who— Stephen Colbert, who said, “Hey, if my body’s
60 percent water, how come I’m only 2 percent interested?” And you know what, the reason is because it comes out of the
wall and it’s essentially free to you right now. >>Neil deGrasse Tyson: Comes out of the wall. >>Kathryn Sullivan: So, it’s just the taken
for granted routine. And since you only have 10 days to get seriously
worried about it when you hit a wall, it’s going to get really ugly when you hit
a wall. This is not going to be sitting quietly in
your living room until you pass away. This is going to phrase society incredibly— >>Neil deGrasse Tyson: But strategically here
suppose there’s water elsewhere in the world and somehow we run
out of water here. That becomes a strategic asset presumably
no different than oil. We’ll start having Federal governmental
policy related to the acquisition and the protection of that asset. My question to you is, as was discussed earlier,
you could bring some fresh water to— now, you have to bring it inland and take
it to the crops. And the distribution of it is a whole other
frontier than just simply getting access to it in the first place. >>Charles Wald: I think there’s a dynamic
about water that it’s hard to even imagine the emotion
of it. But I think all of us here would probably do something pretty drastic
if we didn’t have water and somebody else did. That’s a terrible thing to think about. I mean, and that would— >>Neil deGrasse Tyson: Yeah, but you’re
paid to think about that. >>Charles Wald: Well, and I think people do
horrible things when they’re pressured. So, again, I mean, this is one of those things
where we talked about energy a little bit and oil. You could probably work around that somehow. You could probably live— if it was totally cut off, it wouldn’t work
very good. But if you start cutting off water, this is like Maslow’s theory here. I want my air. I want my water. And everything else after that is gravy. >>Neil deGrasse Tyson: Who— >>Charles Wald: Maslow’s. The Maslow’s theory of hierarchy needs. >>Neil deGrasse Tyson: I’m sorry, I didn’t—we
must be reading different books. But that’s a very sensible philosophy. I need my air. I need my water. After that, life is gravy. >>Charles Wald: Air, water, food, clothing,
shelter, those are the priorities. >>Neil deGrasse Tyson: Okay. >>Charles Wald: And we’re all living pretty
good. >>Neil deGrasse Tyson: Sex is in there, too,
for the species. >>Charles Wald: It’s there. But you talk about these problems where in times we’ve got plenty of water here. Life is good for us mostly, and we’re not really—I mean, we can gripe
about things that are happening in America, but you go around the world and
there’s some problems out there. And water will be an exacerbator, no doubt
about it, in a big way. >>Neil deGrasse Tyson: So, you don’t really
have any hope for the situation. >>Charles Wald: No, I absolutely have hope
because— >>Neil deGrasse Tyson: Where you—in fact— >>Charles Wald: Here’s where you have hope— >>Neil deGrasse Tyson: We have to bring this
to closure. I want to hear where everyone’s got some
hope. By the way, I try not to have hope because it implies that I want an outcome
for which I have no control over it. And so I’d rather think about things I can
affect, and then you don’t have to hope for it. You can make the change. So, that’s just my relationship to the word
hope. >>Charles Wald: I love Churchill’s line. You’ve heard it, right? >>Neil deGrasse Tyson: What’s that? >>Charles Wald: “America gets it right every
time after eliminating every other possible solution.” So, I think it’s going to be— it’ll be a pressure issue. >>Neil deGrasse Tyson: Okay. So, this came up earlier. We’re going to have to be up against the
wall, hitting bottom, whatever is the metaphor. Then we’ll respond in some way that will
sensibly solve this problem. That’s what you’re thinking. >>Charles Wald: Yes. >>Neil deGrasse Tyson: Okay. >>Charles Wald: I hate to say it. >>Neil deGrasse Tyson: No, no. We pay you to be real. That’s what that is. >>Charles Wald: That’s a good point. >>Neil deGrasse Tyson: Yeah, okay. Kathy, as head of NOAA don’t just tell us what’s going wrong, fix it. Are you in the solution business or telling-us-what’s-wrong business? >>Kathryn Sullivan: I think we’re in the
solution business. We certainly have the science data that paints the landscape
that describes the issue. But going back to our roots to make this information
matter and make it connect to real-world decisions. So, I get some hope because I think these kinds of issues and the sensitivities
and the risks they pose to society and to human kind are beginning to connect
to the economic world that we live in. And I think—I agree with Chuck. Pressure points that become really demanding is one way this gets solved. Economic signals is another way to change
the equation on with what speed are we acting
about this. So, the Bloomberg trading terminal—my meeting before this event was
with guys from Bloomberg today. They’ve incorporated water scarcity into
Bloomberg— >>Neil deGrasse Tyson: This is Bloomberg Financial
Markets. >>Kathryn Sullivan: The Bloomberg Financial
Markets and their business information circuit. So, folks that are in investment banking or
they’re doing big construction projects or they’re doing mining or they’re citing
another business. You can now overlay and say, hey, this takes X gallons of water
to do your business process. And you think you’re putting it there. That’s nuts. It’s too risky for your business decision. It’s too risky for me to finance you. It’s too risky for me to insure you. >>Neil deGrasse Tyson: Because the data contains
the content in the aquifer from which it’s drawing water. >>Kathryn Sullivan: It contains a total picture
of total water scarcity and water— look, water stress can be the availability
of the resource. It can be political instability. It can be regulatory uncertainty. All those things go to how reliable is that water supply that you’re— >>Neil deGrasse Tyson: That’s a new feature
in your capacity to make a business decision on the Bloomberg terminal. >>Kathryn Sullivan: It starts to change how
the big economic drivers of our world are shaping their decisions,
I think, is a second pathway to start entering social decision making and
policy decisions. >>Neil deGrasse Tyson: So, my wife told me
earlier that she thinks just the way to solve this is make sure everything costs exactly what
it actually cost. >>Kathryn Sullivan: Make sure it cost anything
close. Anything above zero would be a good thing
in water. >>Neil deGrasse Tyson: And then people will
think about how they’re using water. >>Kathryn Sullivan: Yes. You’ll start weighing that against other
things that are important to you. When you find out that, hey, if I use this
water twice—once for my dishes and once through a filter to put it on my
lawn—it saves me $10,000 a year. >>Neil deGrasse Tyson: People would do it
like that. >>Kathryn Sullivan: Yeah. And they can do the equation that says, hey, that’s worth the $500 water filter
that otherwise I probably wouldn’t bother with. >>Neil deGrasse Tyson: The key phrase there
is they can do the equation. Is that what you’re assuming? >>Kathryn Sullivan: People could do— >>Neil deGrasse Tyson: This is America we’re
talking about. >>Kathryn Sullivan: Yeah, they can do their
household consumer budget. >>Neil deGrasse Tyson: Okay. If they could do the equation with home mortgages, we wouldn’t have—they can do the equation
is a big step, I think. Tess, you study these problems, but what are
your solutions? >>Tess Russo: Well, so I’m working on a
number of solutions, but I agree with Chuck that we’re going to have to hit the wall
before people are taking action on this. But the good thing about that is that hydrology
is really local, so that people are hitting the wall already
in certain places. And it’s not catastrophic, but farmers in
certain parts of Texas and certain parts of Kansas are already making decisions about
how to better manage their farms and what technology they should be adopting. It’s just going to spread. >>Neil deGrasse Tyson: So, not everyone is
hitting the wall at the same time. >>Tess Russo: Exactly. So, you have a little bit of time. It’s not just 10 days to die. It’s like your neighbor is going to start
adopting something because his well goes dry first, and then it’ll spread. Or that’s what I think. So, there’s a bit of hope. >>Neil deGrasse Tyson: Okay. And what is the—we can say it and we want
it to be true, but we kind of have to wait until we see it
to then agree with you that all this investment in high technology made by
NASA applies back to Earth eventually. So, is there any focusing of this expenditure
where we can then say, yeah, I’m going to wait? That's going to be a good one that’s going
to help—let’s keep an eye on that one. >>Ellen Stofan: You don’t have to wait. That’s the good news. Because, for example, just a couple months
ago we launched a satellite called the Soil Moisture Active Passive Mission. That’s getting data on what fields are wet, what fields are dry, what regions
are wet, what regions are dry. That’s just one of the many sensors we have— >>Neil deGrasse Tyson: Wait, this is satellite
that’s monitoring crops. >>Ellen Stofan: It’s monitoring the ground
to help understand not just weather and climate, but to help
farmers make decisions about crops. That’s just one of the many satellites that
we have working, again, with NOAA with USGS. >>Neil deGrasse Tyson: Is that because farmers
have been overwatering crops, for example? Is that a problem? >>Ellen Stofan: Yeah. Because if they don’t know—if they think, well, I don’t know if the field— >>Neil deGrasse Tyson: Doesn’t the farmer
know when the corn needs water? >>Ellen Stofan: They know, but they can get
it to a much more precise level. There’s an incredible amount of water in
agriculture that’s actually wasted. And so if you can fine-tune the amount of
water you make, you actually make a huge difference. We have that technology. Working with all our partner agencies, we’re
gathering it. And I think what Kathy was alluding to, even
more importantly, there’s people who now see economic value. This isn’t just data for scientists. It’s information that a company says, well,
I can work with farmers and actually make money off of this. And that’s what I hope is going to drive
a lot of the change, is when the private sector says, ah, there’s money to be made in that data. It helps all of us. It becomes a virtuous circle. We start using less water. We still are growing crops to feed the world, and we’re all better off. And we’re not just doing this. We’re not just providing this in the U.S.
to our own farmers. We’re doing it for farmers around the world. Kathy’s agency and NASA work together through multiple programs to help farmers,
to help scientists around the world use this data. So, it’s not just the U.S. benefiting from
it. >>Neil deGrasse Tyson: Just to cap before
I get back to Heidi here, Kathy, what percent of all freshwater is used for
crops? >>Kathryn Sullivan: So, the total freshwater
on the planet it about 2.5 percent of the total water. The rest is salt and other things. >>Neil deGrasse Tyson: It’s only 2.5 percent? >>Kathryn Sullivan: It’s only about 2.5
percent and only about .4 percent of the total water on Earth is the drinkable, usable water. And 90 percent roughly globally of that is
used for agriculture. >>Neil deGrasse Tyson: Okay, so— >>Kathryn Sullivan: So, we’re living on
less than half a percent of the total water on the planet. >>Neil deGrasse Tyson: Okay. Let me just get your percentages in the right
sequence here. So, 2.5 percent is the total amount of water
we’re talking about right now. >>Kathryn Sullivan: Freshwater. >>Neil deGrasse Tyson: Of the 2.5 percent
that is freshwater, 90 percent of that is used for agriculture. >>Kathryn Sullivan: Basically, yes. >>Neil deGrasse Tyson: So, the remaining 10
percent of 2.5 percent— >>Kathryn Sullivan: Wait, wait. Correction. >>Neil deGrasse Tyson: Busted. All right, Tess, what do you have? >>Kathryn Sullivan: Get it right, Tess. >>Tess Russo: No, so the 2.5 percent is the
freshwater. Two-thirds of that is in icecaps. A third is underground. >>Neil deGrasse Tyson: Busted, okay. Icecaps, all right. >>Kathryn Sullivan: What she said. >>Neil deGrasse Tyson: Okay. I was asking the wrong person. Tess. >>Tess Russo: No, but Kathy’s right. It’s 70 to 90 percent of the freshwater consumed in the world goes to agriculture. >>Neil deGrasse Tyson: Okay, could there be
a day—if it all goes to agriculture, could there be a day where we no longer drink
water? That our water is completely consumed via
the water content of our food. >>Kathryn Sullivan: Oh, now you’re asking
physiology questions? >>Neil deGrasse Tyson: Yeah. I don’t know. >>Heidi Hammel: You don’t have the right
people on this panel. >>Neil deGrasse Tyson: Okay, sorry. All right. I was just wondering. Just wondering. >>Tess Russo: Oranges, coconut water? >>Neil deGrasse Tyson: Yeah, I don’t know. >>Heidi Hammel: Watermelon has a lot of water. >>Neil deGrasse Tyson: Yeah. It does. All right, coconut water. Yeah. We’ll solve this problem. >>Tess Russo: Coconut water’s— >>Neil deGrasse Tyson: Before the night’s
over. So, Heidi, I know you don’t build machines such as
this, and you think about water in the solar system. Do you have any really long-term thoughts
about how we might use the water that’s out there? Or is it really just an exploratory frontier
for you without the practical application? >>Heidi Hammel: So, the exploration of the
solar system I see as science and engineering. That’s what we do at NASA. We do science and engineering. And I ask the question: What do you need to
solve these problems that you’re talking about? You need young people who are educated in
science and engineering. And so it seems to me that there is a natural
connection. And I don’t mean that just because I get
a lot of my funding from NASA. There’s actually economic studies of engineers. Forbes had a survey of engineers— thousands of engineers. And they asked: What’s your dream job? And they all said— many. I think it was something like 70 percent said
working for NASA. Now, these are not engineers that actually
build spacecraft, these petroleum engineers and engineers who are developing automotive
systems and all kinds of engineers. But NASA’s what’s inspiring them. So, I view what we do as bringing that into
the equation. Somewhere out there right now there is a little
girl, and in about 20 years— right about the timescale we’re talking
about that we need someone to help solve these problems— she’s going to be there. She’s going to her school library right
now and I guarantee you she is not getting a book
about desal. She isn’t. >>Neil deGrasse Tyson: Yeah, I’m with you
on that. >>Heidi Hammel: And she’s probably not going
to be studying aquifers. She’s not looking at resource utilization. And I know these things because I have kids and I’ve worked in their libraries. They’re getting out books about black holes, which are just as esoteric as those other
things, but kids love that. So, NASA plays a very important role for our
country, inspiring people, inspiring kids. I mean, the kind of stuff— >>Neil deGrasse Tyson: This is where the music
comes in as you— >>Heidi Hammel: So, sorry I don’t have the
answers, but I’m trying to get the people out there who will have the answers. >>Neil deGrasse Tyson: Yeah, I got to agree
entirely with Heidi on that because the universe is quite the force of
attraction for kids in middle school and high school—a gateway science, if you
will, to think—you know I’m right. You just know— >>Kathryn Sullivan: Hey, I was one. >>Neil deGrasse Tyson: Right. We only have a couple more minutes here. General, let me ask you a question. Do you really foresee wars over water going
forward? I mean, are your people who are still at the
Pentagon—are there whole situation rooms where they’re plotting what kind of war
would occur in the presence of scarcity of water? >>Charles Wald: Yeah. >>Neil deGrasse Tyson: Okay. >>Charles Wald: No, so it isn’t the type
of war it would be. It is a war. >>Neil deGrasse Tyson: So, what you’re saying
is it’s a strategic resource. >>Charles Wald: Absolutely. >>Neil deGrasse Tyson: Therefore— >>Charles Wald: So, I think there’s a high
likelihood—unless something changes— there will be serious conflict over water
in the not too distant future— 15, 30 years. Maybe before that. And I think there’s already been conflicts over water in different ways. >>Neil deGrasse Tyson: Yeah. >>Kathryn Sullivan: That’s what I was going
to say. There’s some convincing evidence that Libya
and Syria and the unrest there has got an underpinning of water stress and
disruption of livelihoods. >>Neil deGrasse Tyson: Okay, I know I’ve
asked that question, but I’m going to go back to Heidi for a happy thought to end the evening
on. I know I asked for that, but I’m going to try to get a happy thought
here. So, do you see this movement into attracting
kids into space sciences as—could it really be
the solution to all our problems? Especially since space has unlimited resources
and unlimited energy. Would you agree? >>Heidi Hammel: Well, yes. I don’t think the movement is to get kids
into space sciences. The movement is to get people thinking scientifically
and appreciating science, appreciating engineering. They don’t need to be astronomers. They don’t need to be space scientists. But they need to be educated people. That’s the goal. >>Neil deGrasse Tyson: Ladies and gentlemen,
let’s thank our panel. I think, Heidi, you could end any panel on
that we need to be educated. That’s what that is. If we bring up the lights a little bit and
we’re going to take some questions. I think we actually have the question microphone
up here on stage. So, if you walk up I can hand the mic there. We’ll take questions of the panel. Oh, we do have a microphone right here. Is it live? It’s going to be in a moment. So, you can come on up. I don’t know if we’ll have a second one
on this aisle. We’ll spend about 10 minutes in Q&A just
so we can hear what you’re thinking about what just unfolded. Why don’t we start here? Someone come on down, and I’ll hand you
my microphone. Come here. Okay, go. >>Question: Okay, so I just—a lot of the
panelists were saying how America has to lead the world. But how are we bringing these developing countries who don’t necessarily have the resources
to maybe follow in this technological path? How are we bringing them on board into something
that requires this long-term investment? >>Neil deGrasse Tyson: How old are you? >>Question: Thirteen, Mr. Tyson. >>Neil deGrasse Tyson: Whatever you’re doing,
keep doing it. All right? Yeah, sure, Ellen. >>Ellen Stofan: I just got back a couple weeks
ago from South Africa where I was speaking at a science festival for kids
that about 70,000 kids came through. And I was working with the Ministry of Science
and Technology in South Africa, and they said their principle focus right
now is human capital development. How can we get our citizens—we talk about
STEM education, the importance of having STEM education. >>Neil deGrasse Tyson: STEM, science, technology,
engineering and math. >>Ellen Stofan: Engineering and math. And countries that I visit around the world, that’s a huge focus. They love to have people from NASA come because we have a great brand and we
actually get kids excited not just in the U.S., but all around the world. So, countries understand this. And then we have programs— we work with NASA. We work with the U.S. Agency for International
Development. This one program we have called SERVIR where
we go and, again, we take our data. We help scientists, engineers in those countries— in countries that are really struggling how
to use this data. So, we’re not just throwing it over the transom and saying good
luck, world. We’re actually out there working with people. NOAA does this. NASA does it. It’s really important that we actually get
out there and help people use our data. >>Neil deGrasse Tyson: And led off with the
fact that a big piece of this is the intellectual capital as well. >>Charles Wald: Let me go back to the question
[unintelligible]. Why is it only the United States? Are we the only people that can lead? No. But we need to provide leadership. If you look at our foreign aid budget, for example, you’re talking about how do
you make other countries help themselves. Our theory when I was in the European committee
we had Africa in our area of responsibility was help them help themselves. Not lead for them. Not do it for them. Help them become self-sufficient. Our foreign aid budget is— most people take a guess. I mean, what do you think our foreign aid
budget is? >>Neil deGrasse Tyson: Every time I hear it,
it always was lower than I thought it would have been or should have
been. >>Charles Wald: It’s 1 percent. >>Neil deGrasse Tyson: One percent of the
Federal budget. >>Charles Wald: One percent of the Federal
budget. We put $40-some billion a year into foreign aid. And the amount of ability for countries to
take care of themselves to be more stable, which is
really what we’re looking for— I mean, our job in the military is get out
of the business. >>Neil deGrasse Tyson: Exactly. >>Charles Wald: And so, yes, 100 percent we
should do more and more of that. And, by the way, none of these problems are
ever going to be solved by the United States alone ever. I mean, it’s going to have to be a global
issue. So, that’s your job. >>Neil deGrasse Tyson: You’re [unintelligible]
into this. But you briefly mentioned something that’s
a famous—it’s an adage or an epithet. The ultimate task of a general is to lay down
his sword. >>Charles Wald: Absolutely. >>Neil deGrasse Tyson: Yeah. Put yourselves out of business. Yes, over here, go. >>Question: Okay. You’re talking about—is this coming through? >>Neil deGrasse Tyson: Yeah. >>Question: Okay. You’re talking about the water shortage,
which is really aggravated by global warming. Most scientists agree—or actually nearly
all of them agree— that it’s real. That you get politicians who are ignoring
it and actively denying it. It’s like they were being paid off by the
fossil fuel industries. Why is there such a controversy about the
occurrence of global warming? What is preventing people from realizing how
real it is? >>Kathryn Sullivan: I’ll take a shot at
that one. >>Neil deGrasse Tyson: Okay, go. >>Kathryn Sullivan: Two-prong answer. One is it is such a massive disrupter that human inclination to really want proof,
proof, proof positive, which means you’re going to wait too long. But there’s another dimension to this question. Change is happening. It’s clear in the data. It’s clear on the ground. NOAA has an agreement, for example, with the
Western Governors Association centered on water and water data. So, these same folks will ask me when I come
talk with them to please not say the C word, but they also know their ranchers and their
farmers and their municipal water managers are seeing
changes now. They know that they can’t—the statistics, as Neil said
before, the patterns they were used to that worked for decades when they built their
businesses or built their water system, those patterns are falling apart because the
patterns are changing. That’s real. It’s being seen. That’s becoming part of what’s undoing
slowly the political backlash against accepting human
forcing. Look— >>Neil deGrasse Tyson: The Pope just talked
about climate change today, I think. Is that right? >>Kathryn Sullivan: Well, and look whether
it’s the planet itself or I did it or you did it or God did it or whatever, if
the patterns are changing underneath a country of 300 million people and the economy that
we have, that is all at risk. At some level it doesn’t matter what the
underlying cause it. The society as we know it, the economy as
we count on it, is at risk from these pattern changes. No business, if they saw their forward prospect
shifting this much, would ban the word price change. They’d go try to get information about what the nature of the risk might be and how
to prepare for what’s coming. And that’s slowly—too slowly—beginning
to happen. >>Neil deGrasse Tyson: So, what you’re saying
is they’ll catch up once further evidence of this affects their pocketbook. >>Kathryn Sullivan: They’re responding to
the symptoms now. The resistance to shift the energy economy
is just so disruptive economically that’s a tougher pill to swallow. >>Charles Wald: Probably got to worry about
climate change is there’s a zipper effect. If you get down the road too far you can’t
recover. And so for anybody in the world that thinks climate change is a hoax or something
like a couple of our people in Washington do, it’s almost immoral. >>Question: But they keep doing it because
they’re getting paid off. >>Neil deGrasse Tyson: Yes. Question right here. >>Question: I was wondering if in terms of
the negative of the economic cost, if that outweighed the small abundance of
water that you receive from the planets and having to build the tools
and the crafts to actually get up to the planets and if the economic cost outweighed the abundance
of water you actually received and had brought back
to Earth? >>Neil deGrasse Tyson: How old are you? >>Question: Thirteen, Mr. Tyson. >>Neil deGrasse Tyson: Man. >>Kathryn Sullivan: Are these guys all from
the same school? >>Neil deGrasse Tyson: What’s in the water
supply? Is that what we’re talking about here? Heidi, why don’t you take that? >>Heidi Hammel: Yeah, sure. So, to make sure I understand your questions— I’m paraphrasing it—you’re asking is
it cost effective to go and get water and bring it back here because it cost so
much to get out there? >>Question: Yeah. I mean, it cost so much to build the crafts
to actually mine the water and build so much to build the crafts
to get up on to the planets to retrieve the water. I was wondering if the— >>Heidi Hammel: You’re coming back to the
scalability question. Does it even make sense to do that? And, yes, it does cost a lot, but the goal is to—I would imagine—here’s
long-term thinking. Not 20 years. Not 30 years, but maybe 50 or 100 years. If there was a way that we could develop an
infrastructure— >>Neil deGrasse Tyson: Okay, this is when
you’re 63. This is what she’s talking about. All right, go. >>Heidi Hammel: But life expectancy will be
much longer 30 and 40 years from now. So, build an infrastructure where we don’t
have to rely on one-offs. And then you could think more reliably about
getting some of this water back to us. Or maybe by that time—I’ll pass this over
to Ellen—NASA will have a system that we can actually be exploring some of
these places and going to places we know there’s lots of water like Europa, for example. Then we don’t have to worry about bringing
it back here. But we will, I think— to address the concerns at the other end of
the panel, we will have to be solving problems right
here on Earth. I don’t think that NASA is going to be able to solve Earth’s water
problems by bringing water to Earth. I think we need to change. We need to adopt mitigation strategies here
on Earth on how we’re currently using water, and
make sure that the cycles that we have are robust. >>Neil deGrasse Tyson: I can tell you this,
if you go to Europa and bring water back— whatever it cost—you could probably sell
it for a lot of money. Imagine bottle water from Europa. Oh, my gosh, that would totally rock. >>Heidi Hammel: Awesome. >>Neil deGrasse Tyson: I’d— >>Kathryn Sullivan: You’d buy that one. >>Neil deGrasse Tyson: I think I’d buy. I want to say if you ever find life on Europa, they would be called Europeans, right? Is that what that— life on Europa. It’s Europeans. >>Heidi Hammel: I think that was already used
somewhere. >>Neil deGrasse Tyson: Oh. Time for just a couple more questions. Sir, yes? Get up nice and close to the microphone there. >>Question: Al right. This question’s actually for Dr.— >>Neil deGrasse Tyson: Closer to the mic,
yeah. >>Question: This question’s for Dr. Russo. I guess it’s more of an idea-based thinking. You were talking a lot about how it’s about
700 million people who don’t have access to clean water now, which means— >>Neil deGrasse Tyson: Is that right? >>Tess Russo: It’s way more. >>Question: It’s more than that by now,
right? >>Neil deGrasse Tyson:
Try keeping it in front of your face. >>Question: Just trying to get an understanding
of if there was a product or a widget or an infrastructure that was
based solely to fix that issue, where would it start? Would it be the transportation of the water
because of the amount of time it takes— the amount of time they spend getting to that
water source and bringing it back home? Would it be in the filtration process, using
low-end, low-budget options to make that happen? Something like that would be pretty effective
as a product. >>Tess Russo: Right. So, most of the places that I’ve been— >>Neil deGrasse Tyson: Thank you. >>Tess Russo: —people are walking far to
get to clean water. So, they’re walking past dirty water to
get to the clean water source. So, I wouldn’t say it’s in the transportation
of clean water from that. It’s in some method of filtering that dirty
water, treating that local dirty water source. And there’s a lot of really neat technologies. There are little straws that you can put in the dirty water and drink through and low
cost technologies for filtering. So, I think there are a lot of people working
on that, and they’ll be making progress. >>Neil deGrasse Tyson: I’m surprised every
day I walk into a grocery store and there’s a kiwi there for $.50 that came
from New Zealand. If you can bring me a kiwi for $.50 from New
Zealand, why can’t you move water around? >>Tess Russo: I don’t know. >>Neil deGrasse Tyson: I’m sorry. We have time for only two more questions. I’ll take one from this aisle and one from
that one. Sorry for the rest of you. Yes, go ahead. >>Question: So, you were talking before about
grabbing a comet and taking the water from that comet. But you said parking it somewhere. How would you—if you somehow managed to
grab ahold of the comet, how would you manage to stop it? Because there’s not a lot of friction in
space. >>Neil deGrasse Tyson: You’re not supposed
to ask that kind of question. I was just coming up with an idea. I was just trying to solve it. Now, you got to get all technical on me. How old are you? >>Question: Thirteen. >>Neil deGrasse Tyson: You’re how much? >>Question: Thirteen. >>Neil deGrasse Tyson: Thirteen. Where did all these 13-year-olds come from? Damn. What’s going to—what are we going to—what? Why am I walking that way I have no idea. So, is there an orbital thing we can solve here, Ellen? >>Ellen Stofan: Yeah. So, when we were first looking at the Asteroid
Retrieval Mission, the option we’ve gone to is one that would
grab a boulder off a large asteroid and bring it back. But the first concept we looked at—fasten
your seatbelt—was to go and bag an asteroid. >>Heidi Hammel: A big bag. >>Ellen Stofan: A big bag. No, small asteroid, big bag. But the cool thing is, first of all, you have to match—the asteroid’s
moving and tumbling, so you take your spacecraft there and you
get your spacecraft to be doing the same thing the asteroid is doing. >>Neil deGrasse Tyson: Well, you have to catch
up with the asteroid first. >>Ellen Stofan: You catch up with it. >>Neil deGrasse Tyson: It’s got its own
orbit around the sun. >>Ellen Stofan: Right. And then you get into orbit around it, and you synchronize your motion with its using
your retro-rockets. Then you bag it, and then you slowly, slowly—so,
that you don’t rip your spacecraft or the asteroid apart—start firing your
rockets to get it to start doing what you want it to do. And they actually did all the physics and
math to work all this out. And they actually said we could actually do
this. It was really cool physics, angular momentum, all kinds of cool math that you might think
is not so fun. Really cool stuff. >>Heidi Hammel: And I just want to mention,
too, that we’ve actually done something— we humanity. I’m using we in a very large sense here. We have done something like this. The Europeans actually sent a spacecraft Rosetta
to a comet, went into orbit around it, deployed the little lander. How many of you watched that little Philae
lander? I mean, how cool is that? So, we do have the technologies, as Ellen
said. Your question like where would we bring it
to, well, that’s the part of the equation we haven’t
solved yet. >>Neil deGrasse Tyson: Okay. But you have to orbit it around Earth in some
near distance. >>Heidi Hammel: Maybe. >>Ellen Stofan: You could put it around the
moon. You could put it in orbit around the moon,
or you could put it at a Lagrange Points. >>Heidi Hammel: You could put it Lagrange
Point. >>Neil deGrasse Tyson: The Lagrange Point. There are five Lagrange Points. You want to tell us what they are? >>Heidi Hammel: Sure. L-1, Lagrange Point one is the easiest to
understand. We’re just talking about the Earth and the
moon. >>Neil deGrasse Tyson: Yeah. So, here we are. >>Heidi Hammel: Yeah. So, you’ve got the Earth here and the moon
there, and you could imagine that there is a point
in here where the pull from the moon— the gravitational pull from the moon—is
the same as the gravitational pull from the Earth. So, if you put a little bead there or a spacecraft
or a comet, it would just sit there. That’s a gravitational stable point, Lagrange
1. Lagrange 2 is on the other side. Yeah. Did you hear any of it? >>Neil deGrasse Tyson: Yeah. >>Heidi Hammel: Lagrange 1 is here. Lagrange 2 is here. And I can’t remember which are three, four
and five. They’re scattered [unintelligible]. >>Kathryn Sullivan: Three is a million miles
away from the Earth on a line to the sun. We have a spacecraft on its way there that
will arrive in June. >>Neil deGrasse Tyson: So, these are gravitationally
stable points where you can put stuff and it’ll just stay there. And in fact we are exploiting this fact with
our spacecraft. James Webb Space Telescope, the follow-on
from the Hubble, is going to L2. That’s the Earth’s sun L2, I think. >>Kathryn Sullivan: Yes, that’s correct. >>Neil deGrasse Tyson: Not the Earth/moon
L2. So, you put it there and it hangs and it doesn’t fall anywhere. So, if we’re going to lasso a comet— if we’re going to bag a comet, you stick
it there. You go up, scoop out some water, go back as often as you want. >>Heidi Hammel: Earth/moon L1. We didn’t answer the gentleman’s question about accomplishing the orbit change. >>Neil deGrasse Tyson: He’s 13. >>Heidi Hammel: Kind of put his finger right
on those [unintelligible] spot. >>Neil deGrasse Tyson: Okay. How do you accomplish it? And, by the way, the bagging part—not to speak for you, but
I want to get this out there— remember we said earlier the structural integrity
for many of these objects, first, is unknown to the precision we need, but also
the ones we do know about it doesn’t take much to break them apart. So, you can’t just start tugging these things
around and expect them to stay as some solid piece
wherever you put them. So, that’s a big issue here about how you’re
going to move around stuff in the solar system these smaller rocky bodies. >>Ellen Stofan: But once you control its spin
and its orbit, then you fire your rockets and you change its orbit. So, it’s all in bringing a lot of fuel with
you. >>Neil deGrasse Tyson: You are the last question,
so it better be awesome. The pressure’s on. Okay, go. >>Question: Okay. So, I don’t know if any of you are fans
of musical theater, but there is this— >>Neil deGrasse Tyson: That’s a segue for
you. I’ve heard that one. Whoa. >>Question: There’s this musical called
Urine Town, and basically it’s about a severe water shortage in this
town— >>Neil deGrasse Tyson: Urine spelt U-R-I-N-E? >>Question: Yes. >>Neil deGrasse Tyson: Yes, okay. >>Question: Yes, pee town. And basically there’s this class system based off of who can afford water and who
can’t. And it’s like there’s this whole song dedicated about how it’s a privilege to
pee and you have to pay to go to the bathroom. And then there’s riots about it. So, do you think that system like that where water will become so scarce and valuable that
even if you had access to it, it would be only in the higher echelons of
society? And then the lower echelons would just be peeing in bushes and not—drinking
their pee and stuff like that? >>Neil deGrasse Tyson: So, the new class system. The rich people get water. The poor people don’t. The reason why that’s unstable is because
the rich people need the poor people to mow their lawns. They’ll have to keep them alive. That’s my solution to that. What do you say? >>Kathryn Sullivan: Well, you touched on a
great point because a premise of water globally has been there’s a public
good, there’s a moral public good dimension to even if you start putting price on the
water, somehow we have to make sure that even the least of us have the water needed
to survive. So, Chuck and I have talked and alluded to a bit, it’s a penny a gallon. That’s nonsense. It’s more precious to us than that. How do you put a price signal on it that starts to change behavior and incentivize the kind
of technology investments we’ve been talking about without creating the moral and
social problem that you’re talking about? No one knows that answer yet. But it’s one of the real tension points
on the decision about do you price water. Do you turn all the municipal, publically
funded water systems and let them all become private sector operated, which will
just be pricing tiers and subscription services? And too bad if you can’t afford it. or can you somehow build into that a public obligation even for the private sector
company to make sure that everyone’s got some key needs met? And then who gets to define what the some
key needs are? >>Charles Wald: I’ll just tell you that
we have got—never get even close to that because human nature is such that
people can be really ugly when they get to that point. That would be awful. >>Neil deGrasse Tyson: Quick reminders of
our jungle roots, our caveman roots like that. What we call civilization is in fact fragile. What I’d like to do—if I have the whole
panel toast you, the audience, with a sip of water. I don’t have a glass, so I got to use the
thing. All of you thank you for coming for this, the 16th Isaac Asimov Panel Debate. We toast to you all. We’ll see you again next year. Thank you. 90
