Redesign of The Atlantic Magazine

The Touch-ScreenGenerationWhat’s this tecnology doing to toddlers’ brains?

monarch in the middle The Touch-Screen GenerationYoung children-- even toddlers-- are spending more and more time with digital technology. Should parents recoil or rejoice?

The stessful life of a pro-American ruler in the midst of the Arab Spring.

The Conversation

THE BIG QUESTION

ANCIENT SCRIPT

A DEMOCRATIC AGE?

FOR WHOM THE BELL TOLLS

CASINO JACK’S NEW GAME

THE QUEEN BEE’S GUIDE TO PARENTING

THE THINGS THEY CARRY

MISS EDUCATION

LIFE ON MARS

OUR MONOPOLY ECONOMY

Young Obama voters are unlikely to turn into conservatives as they grow older and that's a big problem for an increasingly geriatric GOP

The inexorable decline of America’s least favorite pronoun.

After more than three years in prsion, and an implausible make-over as a good-government reformer, Abramo� is still Abramo�.

By Lindsay Abrams

Will robotic “mules” populated the battle-�elds of the future?

Why women’s success in higher education hasn’t led to more femal leaders.

James Fallows talks with the space entrepreneur Eric Anderson about the next wave of space exploration.

By Jordan Weissmann

Norman Rockwell never painted Boy Swiping Finger on Screen, and our own vision of a perfect childhood has never adjusted to fit that now-common tableau.

By age 3, Gideon would tune in to what was cool in toddler world, then drop the iPad in my lap and ask for certain games by their approximate description.

James Fallows: Space exploration seems to have lost its hold on the public imagination, compared with a generation ago. Why should people be excited about what lies ahead?

Eric Anderson: In the next generation or two—say the next 30 to 60 years—there will be an irreversible human migration to a permanent space colony. Some people will tell you that this new colony will be on the moon, or an asteroid. In my opinion asteroids are a great place to go, but mostly for mining. I think the location is likely to be Mars. This Mars colony will start off with a few thousand people, and then it may grow over 100 years to a few million people, but it will be there permanently. That should be really exciting, to be alive during that stage of humanity’s history.

BY JAMES FALLOWSJF: I have to ask—really? This will really

EA: I really do believe it will. First of all, the key to making it happen is to reduce the cost of transportation into space. My colleague Elon Musk is aiming to get the cost of a flight to Mars down to half a million dollars a person. I think that even if it costs maybe a few million dollars a person to launch to Mars, a colony could be feasible. To me the question is, does it happen in the next 30 years, or does it happen in the next 60 to 70 years? There’s no question it’s going to happen in this century, and that’s a pretty exciting thing.

JF: Apart from the cost of transport, what are the challenges in making that a reality? Are

they cost and engineering challenges, or are they basic science problems?

EA: I think it’s all about the economics. There is no technological or engineering challenge.

One key to making all this happen is that we need to use the resources of space to help us colonize space. It would have been pretty tough for the settlers who went to California if they’d had to bring every supply they would ever need along with them from the East Coast.

That’s why Planetary Resources exists. The near-Earth asteroids, which are very, very close to the Earth, are filled with resources that would be useful for people wanting to go to Mars, or anywhere else in the solar system. They contain precious resources like water, rocket fuel, strategic metals. So first there needs to be a reduction in the cost of getting off the Earth’s surface, and then there needs to be the ability to “live off the land” by using the resources in space.

JF: Again—really? To the general public, asteroid mining just has a fantas-tic-slash-wacky connotation. How practical is this?

EA: When [co-founder] Peter Diamandis and I conceived of the company, we knew it would be a multi-decade effort. From history, we knew that frontiers are opened by access to resources. We would like to see a future where humans are expanding the sphere of influence of humanity into space.

To make asteroid mining viable, we need spacecraft that can launch and operate in space considerably less expensively than has traditionally been the case. If we are able to do that, then asteroid mining can be profitable—very much so. When you ask “Is it viable?,” I’ll be the first one to tell you how risky this proposition is, and how there is a significant possibility that we could fail in a particular mission or technology, or fall short of our goals.

But we have found ways to reduce the cost of space exploration already. For example, our prospecting mission to a set of targeted asteroids will use the Arkyd line of spacecraft. The first of that series, the Arkyd-100, would have cost $100 million, minimum, in the traditional aerospace way of business and operation. But with the engineering talent we

LIFEON MARS



JF: I have to ask—really? This will really

























That’s why Planetary Resources exists. The near-Earth asteroids, which are very, very close to the Earth, are filled with resources that would be useful for people wanting to go to Mars, or anywhere else in the solar system. They contain precious resources like water, rocket fuel, strate-gic metals. So first there needs to be a reduction in the cost of getting off the Earth’s surface, and then there needs to be the ability to “live off the land” by using the resources in space.

JF: Again—really? To the general public, asteroid mining just has a fantastic-slash-wacky connotation. How practical is this?


To make asteroid mining viable, we need spacecraft that can launch and operate in space considerably less expensively than has traditionally been the case. If we are able to do that, then asteroid mining can be profitable—very much so. When you ask “Is it viable?,” I’ll be the first one to tell you how risky this propo-sition is, and how there is a significant possibility that we could fail in a particular mission or technology, or fall short of our goals.

But we have found ways to reduce the cost of space explora-tion already. For example, our prospecting mission to a set of targeted asteroids will use the Arkyd line of spacecraft. The first of that series, the Arkyd-100, would have cost $100 million, minimum, in the traditional aerospace way of business and operation. But with the engineering talent we have, and by using commercially available parts and allowing ourselves to take appropriate risks, we’ve been able to bring that cost down to $4 million or $5 million.

In 10 years or so, what we’d really like to do is get robotic exploration of space in line with Moore’s Law [the tech-world maxim that the price for computing power falls by half every 18 months]. Remember, asteroid mining doesn’t involve people. We want to transition space exploration from a linear-growth technology to one with exponential growth, and create an industry that can flourish off of exponential technologies such as artificial intelligence and machine learning.

Our first missions, for asteroid reconnaissance, will be launching in the next two to three years. For these missions, we’re going


That’s why Planetary Resources exists. The near-Earth asteroids, which are very, very close to the Earth, are filled with resources that would be useful for people wanting to go to Mars, or anywhere else in the solar system. They contain precious resources like water, rocket fuel, strategic metals. So first there needs to be a reduction in the cost of getting off the Earth’s surface, and














then there needs to be the ability to “live off the land” by using the resources in space.



To make asteroid mining viable, we need space-craft that can launch and operate in space consid-erably less expensively than has traditionally been the case. If we are able to do that, then asteroid mining can be profitable—very much so. When you ask “Is it viable?,” I’ll be the first one to tell you how risky this proposition is, and how there is a significant possibility that we could fail in a particular mission or technology, or fall short of our goals.

But we have found ways to reduce the cost of space exploration already. For example, our prospecting mission to a set of targeted asteroids will use the Arkyd line of spacecraft. The first of that series, the Arkyd-100, would have cost $100 million, minimum, in the traditional aerospace way of business and operation. But with the engineering talent we have, and by using commercially available parts and allowing ourselves to take appropriate risks, we’ve been able to bring that cost down to $4 million or $5 million.

In 10 years or so, what we’d really like to do is get robotic exploration of space in line with Moore’s Law [the tech-world maxim that the price for computing power falls by half every 18 months]. Remember, asteroid mining doesn’t involve people. We want to transition space exploration from a linear-growth technology to one with exponential growth, and create an indus-try that can flourish off of exponential technologies such as artificial intelligence and machine learning.

Our first missions, for asteroid reconnaissance, will be launching in the next two to three years. For these missions, we’re going to launch small swarms of spacecraft. When I say small, I mean we’ll send three or four spacecraft, and each one of those spacecraft may weigh only 30 pounds. But they will have optical sensors that are better than any camera available today. They will send back imagery, they’ll map the gravity field, they’ll use telescopic remote sensing and spectroscopy to tell us exactly what materials are in the asteroid. It will be possible to know more about an ore body that’s 10 million miles away from us in space than it would be to know about an ore body 10 miles below the Earth’s surface.

We’re really not talking about if; we’re talking about when.

JF: Apart from the practicalities of asteroid mining, what is it going to mean in spiritual and philosophical ways for people to leave the Earth? I guess this is taking us back to the science fiction of the ’50s and ’60s, but what do you think?

EA: I’ve thought a lot about that. The interesting thing will be to see why the people who go to Mars, or to a colony on the moon, or to an asteroid, decide to go there. Will they go there because they’re escaping something? Will they go there because they’re curious? Will they go to make money?

Throughout history, most of the frontiers that we have had on the Earth have been opened up because people were seeking land—new hunting grounds, or fertile locations for cattle—or mining for gold or precious metals. But occasionally they would go somewhere new because they were seeking religious freedom or some other kind of freedom.

So I don’t actually know why people will go. Will the Earth be so ravaged by war, or catastrophic climate change, or whatever else, that people will want to leave?

JF: About the environment: Are you thinking space could be not just an escape from a ravaged Earth but a way to save the Earth?

EA: There’s a huge environmental cost to mining on Earth. But there are lots of strate-gic materials and metals that we can get in space and that will be necessary for us if we want to create abundance and prosperity generations from now on Earth. We sort of had a freebie over the past couple hundred years—we figured out that you can burn coal and fossil fuels and give all the econo-mies of the world a big boost. But that’s about to end. Not only do we have to transi-tion to a new form of energy, we also have to transition to a new form of resources. And the resources of the nearest asteroids make the resources on Earth pale by comparison. There are enough resources in the nearest asteroids to support human society and civilization for thousands of years.

I’m not suggesting that we’re going to start using resources from space next year. But over the next 20 years, resources in space will most likely be used to explore our solar system. And eventually we’ll start bringing them back to Earth. Wouldn’t it be great if one day, all of the heavy industries of the Earth—mining and energy production and manufacturing—were done somewhere else, and the Earth could be used for living, keeping it as it should be, which is a bright-blue planet with lots of green?


That’s why Planetary Resources exists. The near-Earth asteroids, which are very, very close to the Earth, are filled with resources that would be useful for people wanting to go to Mars, or anywhere else in the solar system. They contain precious resources like water, rocket fuel, strate-gic metals. So first there needs to be a reduction in the cost of getting off the Earth’s surface, and then there needs to be the ability to “live off the land” by using the resources in space.

JF: Again—really? To the general public, asteroid mining just has a fantastic-slash-wacky connotation. How practical is this?


To make asteroid mining viable, we need spacecraft that can launch and operate in space considerably less expensively than has traditionally been the case. If we are able to do that, then asteroid mining can be profitable—very much so. When you ask “Is it viable?,” I’ll be the first one to tell you how risky this propo-sition is, and how there is a significant possibility that we could fail in a particular mission or technology, or fall short of our goals.

But we have found ways to reduce the cost of space explora-tion already. For example, our prospecting mission to a set of targeted asteroids will use the Arkyd line of spacecraft. The first of that series, the Arkyd-100, would have cost $100 million, minimum, in the traditional aerospace way of business and operation. But with the engineering talent we have, and by using commercially available parts and allowing ourselves to take appropriate risks, we’ve been able to bring that cost down to $4 million or $5 million.

In 10 years or so, what we’d really like to do is get robotic exploration of space in line with Moore’s Law [the tech-world maxim that the price for computing power falls by half every 18 months]. Remember, asteroid mining doesn’t involve people. We want to transition space exploration from a linear-growth technology to one with exponential growth, and create an industry that can flourish off of exponential technologies such as artificial intelligence and machine learning.

Our first missions, for asteroid reconnaissance, will be launching in the next two to three years. For these missions, we’re going


That’s why Planetary Resources exists. The near-Earth asteroids, which are very, very close to the Earth, are filled with resources that would be useful for people wanting to go to Mars, or anywhere else in the solar system. They contain precious resources like water, rocket fuel, strategic metals. So first there needs to be a reduction in the cost of getting off the Earth’s surface, and

MONARCHIN THE MIDDLE

MONARCHIN THE MIDDLE

Amid the social and political transformations reshaping the Middle East, can Jordan's Ab-dullah II, the region's most pro-American Arab leader, liberalize his kingdom, modern-ize its economy, and save the country from capture by Islamist radicals?

BY JEFFREY GOLDBERG


Eric Anderson: In the next generation or two—say the next 30 to 60 years—there will be an irrevers-ible human migration to a permanent space colony. Some people will tell you that this new colony will be on the moon, or an asteroid. In my opinion asteroids are a great place to go, but mostly for mining. I think the location is likely to be Mars. This Mars colony will start o� with a few thousand people, and then it may grow over 100 years to a few million people, but it will be there permanently. That should be really exciting, to be alive during that stage of humanity’s history.

JF: I have to ask—really? This will really happen?

EA: I really do believe it will. First of all, the key to making it happen is to reduce the cost of transpor-tation into space. My colleague Elon Musk is aiming to get the cost of a �ight to Mars down to half a million dollars a person. I think that even if it costs maybe a few million dollars a person to launch to Mars, a colony could be feasible. To me the question is, does it happen in the next 30 years, or does it happen in the next 60 to 70 years? There’s no question it’s going to happen in this century, and that’s a pretty exciting thing.

JF: Apart from the cost of transport, what are the challenges in making that a reality? Are they cost and engineering challenges, or are they basic science problems?



That’s why Planetary Resources exists. The near-Earth asteroids, which are very, very close to the Earth, are �lled with resources that would be useful for people wanting to go to Mars, or anywhere else in the solar system. They contain precious resources like water, rocket fuel, strategic








That’s why Planetary Resources exists. The near-Earth asteroids, which are very, very close to the Earth, are �lled with resources that would be useful for people wanting to go to Mars, or anywhere else in the solar system. They contain precious resources like water, rocket fuel, strategic

“That Herod,” Abdullah

said as we flew over

the ruins of the an-

cient king’s fortress.

“Quite a character.”

“Not a role model for

you?,” I asked. “No,” he

said. “I have different

role models.”

IT IS STILL,

GOOD TO BE

ON OCCASSION,

a king.







One key to making all this happen is that we need to use the resources of space to help us colonize space. It would have been pretty tough for the settlers who went to California if they’d had to















When Abdullah reached

his 10th year on the

throne, he told his

family and friends he

was tired of being king.

“You can’t just quit,” I

said. “That’s what they

said,” he responded.

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Redesign of The Atlantic Magazine