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I gave the following speech at the Space Elevator Conference.

——

“Waste anything but time.”

—Motto of the NASA Apollo missions

The consensus amongst those of us who think it is even possible to build a space elevator is that it will take more than 20 years. But how can you say how long it will take to do something until you specify how many resources it will require and how many people you’ve assigned to the task?

For the first part of this speech, let’s pretend we can make the nanotubes and focus on the remaining 99%. When analyzing a task you generally know how to do, it is best to take a top-down approach. If you are painting a room, you would divide this task into the prep, the actual painting, and the cleanup, and then organize the work in each one of those phases.

In my former life at Microsoft, I learned to appreciate the power of educated and focused large-scale teams as the best tool to beat the competition. With a 1,000 person team, 1 man-year of work is accomplished every 2 hours. Work is generally fungible so a 20 year project could definitely use more people and go faster.

The goal in a project is for everyone to always be moving ahead full speed and to finish on the same day. What slips schedules is when you have people with dependencies on each other. If one person needs something from another to do their work, you have the potential for that person to go idle and to slip the entire project.

You can prevent that from happening with strong leadership. In the recent BP oil spill, Louisiana tried to get permission to build berms, but the EPA and the other agencies took a long time to analyze the environmental impact. The federal bureaucracy with all of its technology moved slower than lifeless oil floating in the ocean. A good leader can cut through red tape and bring in outside assets to unblock a situation.

The various big pieces of the space elevator have clear boundaries. Those building the solar panels need work with the climber team only to come up with a way to attach the panels. The physical shape of the climber impacts little on the anchor station. The primary issues are the throughput of tons per day and the process to load a climber. Even mission control looks at pieces as black boxes. Mega-projects can be broken down into efforts with clear boundaries so this means that in general, once commenced, everyone should be able to work in parallel.

The robotic climber is one of the most complicated pieces of hardware that the space elevator needs, and it has many of the same requirements as one of Seattle’s Boeing airplanes: both will move a few hundred miles per hour, and have to deal with difficult changes in temperature, pressure, and radiation.

Boeing is at least on a 7 year timeframe with its 787, compared to NASA which seems to takes decades to do anything. The goal is to be the quality of NASA, but faster than the speed of Boeing. Engineering is about humans and their computers, and both can be improved.

At least some of the 787’s delays were not technically related, as the local papers documented months of labor disputes. Boeing is also working more closely with its suppliers over the Internet than ever before, and learning how to do this.

Man landed on the moon 7 years after Kennedy’s speech, exactly as he ordained, because dates can be self-fulfilling prophecies. It allows everyone to measure their work against their plan and determine if they need additional resources. If you give out a few years of work per person, and allow for time for ramp-up and test, then about 7 years is quite reasonable. Long timelines encourage procrastination. If you want something to happen more slowly, you can find always ways to succeed.

It is cheaper to get loans for shorter terms, so it is cheaper to build something in 7 years than in 20. A 20-year plan is almost a guaranteed way to get a “no” answer. Even the U.S. Congress doesn’t think more than a few months ahead.

Boeing has the requisite technical skills, and they have 160,000 employees, so we could use them as a baseline of an estimate on how many people it would take. Here is what those 160,000 people work on:

Boeing Projects

2018 Bomber

737 Airborne Early Warning and Control (AEW&C)

737 AEW&C Peace Eagle

737 AEW&C Wedgetail

767 Airborne Warning and Control System (AWACS)

A-10 Thunderbolt II

A160 Hummingbird

AC-130U Gunship

Aegis SM-3

Airborne Early Warning and Control

AGM 86-C Conventional Air-Launched Cruise Missile (CALCM)

AH-64 Apache

AV-8B Harrier II Plus

Airborne Battle Management (ABM)

Airborne Warning and Control System (AWACS)

Airlift and Tankers (A&T)

Advanced Global Services & Support

Advanced Tanker

Air Force One

Airborne Battle Management (ABM)

Airborne Laser Test Bed (ALTB)

Ares I Crew Launch Vehicle

Arrow Interceptor

Avenger

B-1B Lancer

B-2 Spirit

B-52 Stratofortress

BattleScape

Boeing 376 Fleet

Boeing 601 Fleet

Boeing 702 Fleet

Boeing 702MP Spacecraft

Boeing Australia

Boeing Launch Services

Boeing Military Aircraft

Boeing Satellites

Brigade Combat Team Modernization (BCTM)

Brimstone Precision Guided Missile

C-17 Globemaster III

C-130 Avionics Modernization Program

C-32A Executive Transport

C-40A Clipper Military Transport

C-40B Special-Mission Aircraft

C-40C Operational Support and Team Travel Aircraft

Canard Rotor/Wing

CH-46E Sea Knight

CH-47D/F Chinook

Cargo Mission Contract (CMC)

Checkout, Assembly & Payload Processing Services (CAPPS)

Combat Survivor Evader Locator (CSEL)

Commercial/Civil Satellite Programs

Constellation/Ares I Crew Launch Vehicle

Conventional Air-Launched Cruise Missile (CALCM)

Cyber and Information Solutions

DataMaster

Defense & Government Services

Delta II

Delta IV

Directed Energy Systems (DES)

DIRECTV 1, 2, 3

DIRECTV 10, 11, 12

DRT

E-3 AWACS

E-4B Advanced Airborne Command Post

E-6 Tacamo

EA-18G Airborne Electronic Attack Aircraft

Engineering & Logistics Services

F-15E Strike Eagle

F-15K — Republic of Korea

F/A-18 Hornet

F/A-18E/F Super Hornet

F-22 Raptor

F/A-18E/F Integrated Readiness Support Teaming (FIRST)

Family of Advanced Beyond Line-of-Sight Terminals (FAB-T)

Global Broadcast Service (GBS)

Global Services & Support

Global Positioning System

Global Positioning System (GPS) IIF

Global Security Systems

GSA

GOES N-P

Ground-based Midcourse Defense (GMD) System

Harpoon

Harrier

Hornet

I&SS Mission Systems

Insitu

Integrated Logistics

Integrated Weapons System Support Program

Intelligence and Security Systems

Intelsat

International Space Station (ISS)

Iridium

Intelligence, Surveillance, Reconnaissance (ISR) Services

Joint Direct Attack Munition (JDAM)

Joint Effects-Based Command and Control (JEBC2)

Joint Helmet-Mounted Cueing System (JHMCS)

Joint Recovery and Distribution System (JRaDS)

Joint Tactical Radio System Ground Mobile Radios (JTRS GMR)

KC-10 Extender

KC-135 Stratotanker

KC-767 Advanced Tanker

Lancer

Laser & Electro-Optical Systems (LEOS)

Laser Joint Direct Attack Munition (LJDAM)

Leasat

MH-47E/G Special Operations Chinook

Maintenance, Modifications & Upgrades

Measat-3

Military Satellite Systems

Milstar II

Mission Operations

Mission Systems

Military Satellite Systems

Network and Space Systems

Network and Tactical Systems

Network Centric Operations

NSS-8

Orbital Express

P-8

Patriot Advanced Capability-3 (PAC-3)

Peace Eagle

Phantom Works

Raptor

Rotorcraft Systems

SQS

ScanEagle

Sea Knight

Sea Launch

SBInet

SkyTerra

Small Diameter Bomb (SDB)

SoftPlotter

SOSCOE

Space and Intelligence Systems

Space Based Space Surveillance (SBSS) System

Space Exploration

Space Flight Awareness

Space Shuttle

SPACEWAY 1, 2 North

Special Operations Chinook

Spectrolab

Spirit

St. Louis Flight Operations

Standoff Land Attack Missile Expanded Response SLAM ER

Strategic Missile & Defense Systems

Strategic Missile Systems

Stratofortress

Super Hornet

Supply Chain Services

T-45 Training System

Tacamo

TACSAT I

Tanker

Thuraya-2, 3

Training Support Center

Training Systems and Services

Transformational Wideband Communication Capabilities for the Warfighter

UH-46D Sea Knight

UHF Follow-On

Unmanned Airborne Systems

Unmanned Little Bird

V-22 Osprey

VSOC Sentinel

Wedgetail

Wideband Global SATCOM (WGS)

X-37B Orbital Test Vehicle

X-51 WaveRider

XM Satellite Radio

XM-3, 4

XSS Micro-Satellite

The news in Seattle was how Boeing’s 787 was continually being delayed, but they are involved in so many military and space efforts, it is surprising they find any time at all to work on their Dreamliner!

Boeing is working on 150 projects, so they have 1,100 people per project. Averages are more prone to error, so we can assume a space elevator is 10 times bigger than average. This gives you 11,000 people. If you knew the size of the teams at Boeing, something which is not public information, you could better refine the estimates. A 11,000 person team would be a sight to behold.

If we landed on the moon 7 years after Kennedy told us we would, and if Boeing can build the 787 in 7 years, they we can build the rest of the space elevator in 7 years. It is just a matter of having enough of the right people. So 11,000 people in about 7 years is a first estimate. But this is the 21st century, and we landed on the moon 40 years ago.

Software

Software is my training, and what I will turn to now. Ford Motor Company made an ad that said before they build a car, they build it inside a computer. If you are satisfied with the design inside a computer, you are ready to start production. What is true for a car is even more true for an airplane, and there is a lot of software involved in designing, testing, running and maintaining an airplane, and I’ve had the chance to talk to some Boeing engineers in my years in Seattle. It would not be surprising if the majority of engineers at Boeing knew how to program, and that software is a large part of Boeing’s investments. On the Wikipedia page for the 787, their (proprietary) software is mentioned several times as being a reason for delays.

Setting aside the space elevator, the key to faster technological progress is the more widespread use of free software in all aspects of science. For example, I believe there are more than enough computer vision PhDs, but there are 200+ different codebases and countless proprietary ones. Simply put, there is no computer vision codebase with critical mass, and this problem exists for a number of problem domains. The lessons of Wikipedia have not been learned.

We are not lacking hardware. Computers today can do billions of additions per second. If you could do 32-bit addition in your head in one second, it would take you 30 years to do the billion that your computer can do in that second.

While a brain is different from a computer in that it does work in parallel, such parallelization only makes it happen faster, it does not change the result. Anything accomplished in our parallel brain could also be accomplished on computers of today, which can do only one thing at a time, but at the rate of billions per second. A 1-gigahertz processor can do 1,000 different operations on a million pieces of data in one second. With such speed, you don’t even need multiple processors. Even so, more parallelism is coming via GPUs.

I have written a book that has ideas on how to write better software faster. Today, too many programmers of this world have not adopted free software and modern programming languages. I cannot speak for the shortest amount of time it would take to build the hardware for the space elevator, but I can speak a little bit about the software. Software is interesting because it seems there is no limit on the number of people who can work together.

Linux’s first release in 1991 was built by one programmer and had 10,000 lines of code. It is now 1,000 times bigger and has 1,000 times as many people working on it. Software is something like Wikipedia, which started with a handful but now has millions of people who have made contributions. I grabbed a random article on Wikipedia: it was 5,000 words which is a decent hunk of intellectual property, about as long as this speech which is half-over. It had 1,500 revision and 923 contributors. Each person noticed something different; not every change is perfect, but newer changes can further polish the work, and it usually heads in the right direction evolving towards a good state. A corollary of the point is the line by Eric Raymond that with enough eyeballs, all bugs in software are shallow.

Leonardo Da Vinci said that: “Art is never finished, only abandoned.” This is true of software as well because both are perfectable to an arbitrary degree. Every software programmer has had a feeling in his gut that if he had more resources, he could do more things. Software is different than Wikipedia, but I have found generally that problems in software, assuming you have the right expertise, can be broken up into arbitrarily small tasks. Every interesting problem can be expressed as a functional interface and a graph of code that someone else can maintain.

Some think that the AI problems are so hard that it isn’t a matter of writing code, it is a matter of coming up with the breakthroughs on a chalkboard. But people can generally agree at a high level how the software for solving many problems will work and there has been code for all manner of interesting AI kicking around for decades.

What we never built, and still don’t have, are some places where lots of people have come together to hash out the details, which is a lot closer to Wikipedia than it first appears. Software advances in a steady, stepwise fashion, which is why we need free software licenses: to incorporate all the incremental advancements that each random scientist is making. Even if you believe we need more scientific breakthroughs, it should be clear that things like robust computer vision are complicated enough that you would want 100s of people working together on the vision pipeline. So, while we are waiting for those “breakthroughs, let’s just get the 100 people together.

A big part of the problem is that C and C++ have not been retired. These languages make it hard for programmers to work together, even if they wanted to. There are all sorts of inefficiencies of time, from learning the archane rules about these ungainly languages (especially C++), to the fact that libraries often use their own utility classes, synchronization primitives, error handling schemes, etc.

It is easier to write a specialized and custom computer vision library in C/C++ than to integrate OpenCV, the most popular free computer vision engine. OpenCV defines an entire world, down to the matrix class so it cannot just plug into whatever code you already have. It takes months to get familiar with everything. Most people just want to work. To facilitate cooperation, I recommend Python. Python is usable by PhDs and 8 year olds and it is a productive, free, reliable and rich language. Linux and Python are a big part of what we need. That gives a huge and growing baseline, but we have to choose to use it.

This is a screenshot of a fluid analysis of an internal combustion engine, and is built using a Python science library known as SciPy that can also do neural networks, and computer vision.

We might come up with a better language one day, but Python is good enough. The problem in software today is not a lack of hardware, or the technical challenge of writing code, it is the social challenge of making sure we are all working together productively. If we fix this, the future will arrive very fast. Another similarity between Wikipedia, free software, and the space elevator, is that all are cheaper than their alternatives.

So given all this technology at our disposal, we should be able to build this elevator in less than 7 years. Few would have predicted that it would take the unpaid volunteers of Wikipedia only 2.5 years to surpass Encyclopedia Britannica. Anything can happen in far less time than we think is possible if everyone steps up today to play their part. The way to be a part of the future is to invent it. We need to focus our scientific and creative energy towards big, shared goals. Wikipedia, as the world’s encyclopedia, is a useful and inspiring tool, and so people have come pouring in.

Future software advancements like cars that drive themselves will trigger a new perspective on whether we can build a space elevator. My backup plan to hitching a ride on the space elevator is to encourage people to build robot-driven cars first. Today, I’m trying the reverse approach.

The way to get help for a project is to create a vision that inspires others, but it would also be helpful if we got ten billion dollars. If the US can afford a $1.4 trillion dollar deficit, we can afford a space elevator.

There are already millions of people working in the free software movement today, so in a sense there already are millions of people working on the space elevator. If we had people with the right skills working, we could start writing the actual software for the space elevator. We could in principle write all of the software for the space elevator, just as Boeing and Ford do, which would further shrink the estimates.

Unfortunately, writing all the software now is theoretically possible but not practical. The problem is that a lot of what we need are device drivers. There are many ways to design the cargo door of the climber, and what the various steps of opening this door are. The software that controls the opening and closing of that door is a device driver, a state machine that coordinates all the littler pieces of hardware. You can even think of mission control as the software that orders all of the hardware pieces around. It is a meta-device-driver, so it can’t be written yet either. So, we are mostly stuck with our attempts to write too much software now, but there are a few things we can do.

We could use hardware designs. The hard part about us talking about a design aspect of a climber at a conference like this is that there is no canonical designs or team. Today, there is much interesting intellectual property locked up besides software.

Free data is also important however. Wikipedia has 2.6M lines of code to edit and display the encyclopedia, but it is gigabytes of data. Different projects have different ratios but software is useless without data. Everything Boeing does is proprietary today. We should fix that for the space elevator to encourage faster progress. If we all agree on free software and formats as baseline, it means people can work together. One big challenge is there is no free Solidworks replacement.

Even today, not everything that Boeing has locked up is innovative and strategic. They use standard military encryption algorithms which are public and free. Much of software is boring infrastructure code.

With free software and free formats, we can most quickly build the space elevator. So while it is bad news is that much of the required software efforts will be device drivers, the good news is that are some little software things we can work on today.

Dave Lang’s work on tethers is very useful, and it could use a team of people to work with him to port it from Fortran to Python. Dave started, but he didn’t know Python and the interop tools well enough to make progress. It would also be nice to get some people with supercomputers analyzing ribbon designs, and ways to bootstrap and repair a ribbon. NASA has people, but they don’t have this as their job.

I am hosting spaceelevatorwiki.com on my server and I plan on handing it over to ISEC, and it could serve as a place to coordinate various kinds of software or other R&D. If we could get some people to work, it would push others to get going. Nobody wants to be the only worker on a project. Even millions of dollars of money can be useful to jumpstart software efforts.

The 1% of the Carbon Nanotubes


Okay, so now on to the carbon nanotubes. This is not my area of expertise so it will be short. I am satisfied to make the case that a space elevator is 99% doable in less than 7 years and leave the resolution of the last 1% for another day. To adapt a line from Thomas Edison: success at building a space elevator is 99% perspiration and 1% inspiration.

Many futurists believe that nanotechnology is the next big challenge after information technology. When analyzing a system you know how to build, it is best to work top-down. But when trying to do something new, you work your way up. When learning to cook, you start with an egg, not filet mignon. A good way to attack a big problem like nanotechnology is to first attack a small part of it, like carbon nanotubes. A Manhattan Project on general nanotechnology is too big and unfocused of a problem. Protein folding is by itself a Manhattan project!

A carbon nanotube is a simple and useful nanoscale structure and could be a great way to launch atomically precise manufacturing. The ribbon needs some science related to the design of the ribbon, dealing with friction, damage, and decay, but that work can be done today on supercomputers. There are people at NASA that have the expertise and equipment, but they don’t have this as a goal. One of the points Kennedy made is that sending a man to the moon served as a goal to: “organize and measure.”

One concern is that there is a lot of money being spent on nanotube manufacturing research, but it is doled up in amounts of $100K. I am not convinced that such a small investment can bring any major new advancements.

Nanotubes might require the existing industrial expertise of a company like Intel. We all know that NASA has not seriously considered building a space elevator, and similarly, I think that no one at Intel has considered the benefits to creating the world’s best nanotube threads. They already experimenting with nanotubes inside computer chips because metal loses the ability to conduct electricity at very small diameter, but they aren’t producing them as an independent product for purchase now.

Intel is working in the 35 nm scale today which is a long way from the 2nm nanotube scale. But Intel’s only goal today is faster and cheaper. Intel can fit 11 of their Atom processors on the surface area of a penny. Such a powerful processor is small enough for iPhone sized devices, let alone laptops which is their actual market.

Size is just a side-battle in their goals of more speed and lower production cost. So perhaps Intel would build a nanotube fabrication plant that looks nothing like what they are trying to do today:


Intel Itanium Processor

The first nanotube threads will likely not be good enough for the space elevator, but Intel learns how to build a better and smaller chip in the process of designing and building their current chip. So after they build this manufacturing plant, they could sell their product while they build their next one. Who knows how many of these iterations it would take, or ways to speed the progress up.

Brad Edwards tells me that with one-inch fibers, you can spin arbitrarily long carbon nanotube threads, using the textile process we’ve been following for centuries. Carbon nanotube are the simplest interesting nanoscale structure. Carbon nanotubes were discovered in 1991, and growing fibers in an oven and spinning them into threads is something we could have done back then. Companies like Hexcel, one of the world’s leaders in carbon fiber, is afraid to invest in carbon nanotubes even though they are the company in the world closest to being able to produce them. They are afraid of failure. I have discovered in software that it is about constantly adding new features which enable the new scenarios. Software is therefore constantly about generalizing. From where I sit, carbon fiber and carbon nanotubes are nearly the same thing! Even if it required new investments, Hexcel should be able to do it faster, better, and cheaper than anyone else, and they should have the most customers lined up who might want their new product. Hexcel, the company that should be leading in this market, is paralyzed into inaction by fear of failure. There is a moral obligation to innovation.

In conclusion, there is a new generation of kids maturing known as the Millennials. Their perspective is unique because they’ve been using Youtube and Google for as long as they can remember. They expect to get an answer to any question they pose in 100 milliseconds on their phone. The fact that Social Security is bankrupt is not acceptable. E=mc2 is sufficient proof that nuclear power is a good idea. If you tell them you’ve got a 20-year plan, they will reply that you don’t know what you are doing yet, and you need to develop better plans. Waiting 20 years for a space elevator once makes as much sense as waiting 30 minutes at the gas station. And they are right — they don’t need to change their perspective, the rest of us need to change ours.

I’m not a Millennial, I’m a Generation X’er, and we are the ones building it. But I’m a software person. It would require 10,000 of my first computer to have the same capacity as an iPhone. I see today’s hardware as magic, so I believe someone can conjure up high quality nanotube rope if they invested enough resources. It might not be good enough for the elevator, but it could be a revenue-generating business. In Kennedy’s Rice speech, he mentioned that the Apollo program needed “new metal alloys” that hadn’t been invented. He didn’t think it would be a problem back then and we shouldn’t be 100% convinced now either.

The International Space Station is a tin can in space. We can do a lot better. A space elevator is a railway to space. Scramjets, space tethers, rockets, or reusable launch vehicles, none of them are the way. Perhaps the Europeans could build the station at GEO. Russia could build the shuttle craft to move cargo between the space elevator and the moon. The Middle East could provide an electrical grid for the moon. China could take on the problem of cleaning up the orbital space debris and build the first moon base. Africa could design the means to terraform Mars, etc. This could all be done completely in parallel with the space elevator construction. We went to the moon 40 years ago, and the space elevator is our generation’s moon mission. Let’s do as Kennedy exhorted and: “Be bold”.

There are legal issues to consider. But when this project commences, we need to tell the bureaucrats to get out of the way. We should also approach the global warming crowd and tell them that even better than living in rice patties, and driving electric rickshaws, the best way to help comrade mother earth is with a space elevator. Colonizing space will changes man’s perspective. When we feel crammed onto this pale blue dot, we forget that any resource we could possibly want is out there in incomparably big numbers. This simple understanding is a prerequisite for a more optimistic and charitable society, which has characterized eras of great progress.

We have given this program a high national priority — even though I realize that this is in some measure an act of faith and vision, for we do not now know what benefits await us. But if I were to say, my fellow citizens, that we shall send to the moon, 240,000 miles away from the control station in Houston, a giant rocket more than 300 feet tall, the length of this football field, made of new metal alloys, some of which have not yet been invented, capable of standing heat and stresses several times more than have ever been experienced, fitted together with a precision better than the finest watch, carrying all the equipment needed for propulsion, guidance, control, communications, food and survival, on an untried mission, to an unknown celestial body, and then return it safely to earth, re-entering the atmosphere at speeds of over 25,000 miles per hour, causing heat about half that of the temperature of the sun …, and do all this, and do it right, and do it first before this decade is out — then we must be bold.

John F Kennedy, 1962

I am a former Microsoft programmer who wrote a book (for a general audience) about the future of software called After the Software Wars. Eric Klien has invited me to post on this blog (Software and the Singularity, AI and Driverless cars) Here are the sections on the Space Elevator. I hope you find these pages food for thought and I appreciate any feedback.


A Space Elevator in 7

Midnight, July 20, 1969; a chiaroscuro of harsh contrasts appears on the television screen. One of the shadows moves. It is the leg of astronaut Edwin Aldrin, photographed by Neil Armstrong. Men are walking on the moon. We watch spellbound. The earth watches. Seven hundred million people are riveted to their radios and television screens on that July night in 1969. What can you do with the moon? No one knew. Still, a feeling in the gut told us that this was the greatest moment in the history of life. We were leaving the planet. Our feet had stirred the dust of an alien world.

—Robert Jastrow, Journey to the Stars

Management is doing things right, Leadership is doing the right things!

—Peter Drucker

SpaceShipOne was the first privately funded aircraft to go into space, and it set a number of important “firsts”, including being the first privately funded aircraft to exceed Mach 2 and Mach 3, the first privately funded manned spacecraft to exceed 100km altitude, and the first privately funded reusable spacecraft. The project is estimated to have cost $25 million dollars and was built by 25 people. It now hangs in the Smithsonian because it serves no commercial purpose, and because getting into space is no longer the challenge — it is the expense.

In the 21st century, more cooperation, better software, and nanotechnology will bring profound benefits to our world, and we will put the Baby Boomers to shame. I focus only on information technology in this book, but materials sciences will be one of the biggest tasks occupying our minds in the 21st century and many futurists say that nanotech is the next (and last?) big challenge after infotech.

I’d like to end this book with one more big idea: how we can jump-start the nanotechnology revolution and use it to colonize space. Space, perhaps more than any other endeavor, has the ability to harness our imagination and give everyone hope for the future. When man is exploring new horizons, there is a swagger in his step.

Colonizing space will change man’s perspective. Hoarding is a very natural instinct. If you give a well-fed dog a bone, he will bury it to save it for a leaner day. Every animal hoards. Humans hoard money, jewelry, clothes, friends, art, credit, books, music, movies, stamps, beer bottles, baseball statistics, etc. We become very attached to these hoards. Whether fighting over $5,000 or $5,000,000 the emotions have the exact same intensity.

When we feel crammed onto this pale blue dot, we forget that any resource we could possibly want is out there in incomparably big numbers. If we allocate the resources merely of our solar system to all 6 billion people equally, then this is what we each get:

Resource Amount
Hydrogen 34,000 billion Tons
Iron 834 billion Tons
Silicates (sand, glass) 834 billion Tons
Oxygen 34 billion Tons
Carbon 34 billion Tons
Energy production 64 trillion Kilowatts per hour

Even if we confine ourselves only to the resources of this planet, we have far more than we could ever need. This simple understanding is a prerequisite for a more optimistic and charitable society, which has characterized eras of great progress. Unfortunately, NASA’s current plans are far from adding that swagger.

If NASA follows through on its 2004 vision to retire the Space Shuttle and go back to rockets, and go to the moon again, this is NASA’s own imagery of what we will be looking at on DrudgeReport.com in 2020.

Our astronauts will still be pissing in their space suits in 2020.

According to NASA, the above is what we will see in 2020, but if you squint your eyes, it looks just like 1969:

All this was done without things we would call computers.

Only a government bureaucracy can make such little progress in 50 years and consider it business as usual. There are many documented cases of large government organizations plagued by failures of imagination, yet no one considers that the rocket-scientist-bureaucrats at NASA might also be plagued by this affliction. This is especially ironic because the current NASA Administrator, Michael Griffin, has admitted that many of its past efforts were failures:

  • The Space Shuttle, designed in the 1970s, is considered a failure because it is unreliable, expensive, and small. It costs $20,000 per pound of payload to put into low-earth orbit (LEO), a mere few hundred miles up.
  • The International Space Station (ISS) is small, and only 200 miles away, where gravity is 88% of that at sea-level. It is not self-sustaining and doesn’t get us any closer to putting people on the moon or Mars. (By moving at 17,000 miles per hour, it falls fast enough to stay in the same orbit.) America alone spent $100 billion on this boondoggle.

The key to any organization’s ultimate success, from NASA to any private enterprise, is that there are leaders at the top with vision. NASA’s mistakes were not that it was built by the government, but that the leaders placed the wrong bets. Microsoft, by contrast, succeeded because Bill Gates made many smart bets. NASA’s current goal is “flags and footprints”, but their goal should be to make it cheap to do those things, a completely different objective.1

I don’t support redesigning the Space Shuttle, but I also don’t believe that anyone at NASA has seriously considered building a next-generation reusable spacecraft. NASA is basing its decision to move back to rockets primarily on the failures of the first Space Shuttle, an idea similar to looking at the first car ever built and concluding that cars won’t work.

Unfortunately, NASA is now going back to technology even more primitive than the Space Shuttle. The “consensus” in the aerospace industry today is that rockets are the future. Rockets might be in our future, but they are also in the past. The state-of-the-art in rocket research is to make them 15% more efficient. Rocket research is incremental today because the fundamental chemistry and physics hasn’t changed since their first launches in the mid-20th century.

Chemical rockets are a mistake because the fuel which propels them upward is inefficient. They have a low “specific impulse”, which means it takes lots of fuel to accelerate the payload, and even more more fuel to accelerate that fuel! As you can see from the impressive scenes of shuttle launches, the current technology is not at all efficient; rockets typically contain 6% payload and 94% overhead. (Jet engines don’t work without oxygen but are 15 times more efficient than rockets.)

If you want to know why we have not been back to the moon for decades, here is an analogy:

What would taking delivery of this car cost you?
A Californian buys a car made in Japan.
The car is shipped in its own car carrier.
The car is off-loaded in the port of Los Angeles.
The freighter is then sunk.

The latest in propulsion technology is electrical ion drives which accelerate atoms 20 times faster than chemical rockets, which mean you need much less fuel. The inefficiency of our current chemical rockets is what is preventing man from colonizing space. Our simple modern rockets might be cheaper than our complicated old Space Shuttle, but it will still cost thousands of dollars per pound to get to LEO, a fancy acronym for 200 miles away. Working on chemical rockets today is the technological equivalent of polishing a dusty turd, yet this is what our esteemed NASA is doing.


The Space Elevator

When a distinguished but elderly scientist states that something is possible, he is almost certainly right. When he states that something is impossible, he is very probably wrong.

—Arthur C. Clarke RIP, 1962

The best way to predict the future is to invent it. The future is not laid out on a track. It is something that we can decide, and to the extent that we do not violate any known laws of the universe, we can probably make it work the way that we want to. —Alan Kay

A NASA depiction of the space elevator. A space elevator will make it hundreds of times cheaper to put a pound into space. It is an efficiency difference comparable to that between the horse and the locomotive.

One of the best ways to cheaply get back into space is kicking around NASA’s research labs:

Scale picture of the space elevator relative to the size of Earth. The moon is 30 Earth-diameters away, but once you are at GEO, it requires relatively little energy to get to the moon, or anywhere else.

A space elevator is a 65,000-mile tether upon which we can launch things into space in a slow, safe, and cheap way.

And these climbers don’t even need to carry their energy as you can use solar panels to provide the energy for the climbers. All this means you need much less fuel. Everything is fully reusable, so when you have built such a system, it is easy to have daily launches.

The first elevator’s climbers will travel into space at just a few hundred miles per hour — a very safe speed. Building a device which can survive the acceleration and jostling is a large part of the expense of putting things into space today. This technology will make it hundreds, and eventually thousands of times cheaper to put things, and eventually people, into space.

A space elevator might sound like science fiction, but like many of the ideas of science fiction, it is a fantasy that makes economic sense. While you needn’t trust my opinion on whether a space elevator is feasible, NASA has never officially weighed in on the topic — also a sign they haven’t given it serious consideration.

This all may sound like science fiction, but compared to the technology of the 1960s, when mankind first embarked on a trip to the moon, a space elevator is simple for our modern world to build. In fact, if you took a cellphone back to the Apollo scientists, they’d treat it like a supercomputer and have teams of engineers huddled over it 24 hours a day. With only the addition of the computing technology of one cellphone, we might have shaved a year off the date of the first moon landing.

Carbon Nanotubes

Nanotubes are Carbon atoms in the shape of a hexagon. Graphic created by Michael Ströck.

We have every technological capability necessary to build a space elevator with one exception: carbon nanotubes (CNT). To adapt a line from Thomas Edison, a space elevator is 1% inspiration, and 99% perspiration.

Carbon nanotubes are extremely strong and light, with a theoretical strength of three million kilograms per square centimeter; a bundle the size of a few hairs can lift a car. The theoretical strength of nanotubes is far greater than what we would need for our space elevator; current baseline designs specify a paper-thin, 3-foot-wide ribbon. These seemingly flimsy dimensions would be strong enough to support their own weight, and the 10-ton climbers using the elevator.

The nanotubes we need for our space elevator are the perfect place to start the nanotechnology revolution because, unlike biological nanotechnology research, which uses hundreds of different atoms in extremely complicated structures, nanotubes have a trivial design.

The best way to attack a big problem like nanotechnology is to first attack a small part of it, like carbon nanotubes. A “Manhattan Project” on general nanotechnology does not make sense because it is too unfocused a problem, but such an effort might make sense for nanotubes. Or, it might simply require the existing industrial expertise of a company like Intel. Intel is already experimenting with nanotubes inside computer chips because metal loses the ability to conduct electricity at very small diameters. But no one has asked them if they could build mile-long ropes.

The US government has increased investments in nanotechnology recently, but we aren’t seeing many results. From space elevator expert Brad Edwards:

There’s what’s called the National Nanotechnology Initiative. When I looked into it, the budget was a billion dollars. But when you look closer at it, it is split up between a dozen agencies, and within each agency it’s split again into a dozen different areas, much of it ends up as $100,000 grants. We looked into it with regards to carbon nanotube composites, and it appeared that about thirty million dollars was going into high-strength materials — and a lot of that was being spent internally in a lot of the agencies; in the end there’s only a couple of million dollars out of the billion-dollar budget going into something that would be useful to us. The money doesn’t have focus, and it’s spread out to include everything. You get a little bit of effort in a thousand different places. A lot of the budget is spent on one entity trying to play catch-up with whoever is leading. Instead of funding the leader, they’re funding someone else internally to catch up.

Again, here is a problem similar to the one we find in software today: people playing catchup rather than working together. I don’t know what nanotechnology scientists do every day, but it sounds like they would do well to follow in the footsteps of our free software pioneers and start cooperating.

The widespread production of nanotubes could be the start of a nanotechnology revolution. And the space elevator, the killer app of nanotubes, will enable the colonization of space.

Why?

William Bradford, speaking in 1630 of the founding of the Plymouth Bay Colony, said that all great and honorable actions are accompanied with great difficulties, and both must be enterprised and overcome with answerable courage.

There is no strife, no prejudice, no national conflict in outer space as yet. Its hazards are hostile to us all. Its conquest deserves the best of all mankind, and its opportunity for peaceful cooperation may never come again. But why, some say, the moon? Why choose this as our goal? And they may well ask why climb the highest mountain? Why, 35 years ago, fly the Atlantic? Why does Rice play Texas?

We choose to go to the moon. We choose to go to the moon in this decade and do the other things, not because they are easy, but because they are hard, because that goal will serve to organize and measure the best of our energies and skills, because that challenge is one that we are willing to accept, one we are unwilling to postpone, and one which we intend to win, and the others, too.

It is for these reasons that I regard the decision last year to shift our efforts in space from low to high gear as among the most important decisions that will be made during my incumbency in the office of the Presidency.

In the last 24 hours we have seen facilities now being created for the greatest and most complex exploration in man’s history. We have felt the ground shake and the air shattered by the testing of a Saturn C-1 booster rocket, many times as powerful as the Atlas which launched John Glenn, generating power equivalent to 10,000 automobiles with their accelerators on the floor. We have seen the site where five F-1 rocket engines, each one as powerful as all eight engines of the Saturn combined, will be clustered together to make the advanced Saturn missile, assembled in a new building to be built at Cape Canaveral as tall as a 48 story structure, as wide as a city block, and as long as two lengths of this field.

The growth of our science and education will be enriched by new knowledge of our universe and environment, by new techniques of learning and mapping and observation, by new tools and computers for industry, medicine, the home as well as the school.

I do not say that we should or will go unprotected against the hostile misuse of space any more than we go unprotected against the hostile use of land or sea, but I do say that space can be explored and mastered without feeding the fires of war, without repeating the mistakes that man has made in extending his writ around this globe of ours.

We have given this program a high national priority — even though I realize that this is in some measure an act of faith and vision, for we do not now know what benefits await us. But if I were to say, my fellow citizens, that we shall send to the moon, 240,000 miles away from the control station in Houston, a giant rocket more than 300 feet tall, the length of this football field, made of new metal alloys, some of which have not yet been invented, capable of standing heat and stresses several times more than have ever been experienced, fitted together with a precision better than the finest watch, carrying all the equipment needed for propulsion, guidance, control, communications, food and survival, on an untried mission, to an unknown celestial body, and then return it safely to earth, re-entering the atmosphere at speeds of over 25,000 miles per hour, causing heat about half that of the temperature of the sun — almost as hot as it is here today — and do all this, and do it right, and do it first before this decade is out — then we must be bold.

John F. Kennedy, September 12, 1962

Lunar Lander at the top of a rocket. Rockets are expensive and impose significant design constraints on space-faring cargo.

NASA has 18,000 employees and a $17-billion-dollar budget. Even with a fraction of those resources, their ability to oversee the design, handle mission control, and work with many partners is more than equal to this task.

If NASA doesn’t build the space elevator, someone else might, and it would change almost everything about how NASA does things today. NASA’s tiny (15-foot-wide) new Orion spacecraft, which was built to return us to the moon, was designed to fit atop a rocket and return the astronauts to Earth with a 25,000-mph thud, just like in the Apollo days. Without the constraints a rocket imposes, NASA’s spaceship to get us back to the moon would have a very different design. NASA would need to throw away a lot of the R&D they are now doing if a space elevator were built.

Another reason the space elevator makes sense is that it would get the various scientists at NASA to work together on a big, shared goal. NASA has recently sent robots to Mars to dig two-inch holes in the dirt. That type of experience is similar to the skills necessary to build the robotic climbers that would climb the elevator, putting those scientists to use on a greater purpose.

Space debris is a looming hazard, and a threat to the ribbon:

Map of space debris. The US Strategic Command monitors 10,000 large objects to prevent them from being misinterpreted as a hostile missile. China blew up a satellite in January, 2007 which created 35,000 pieces of debris larger than 1 centimeter.

The space elevator provides both a motive, and a means to launch things into space to remove the debris. (The first elevator will need to be designed with an ability to move around to avoid debris!)

Once you have built your first space elevator, the cost of building the second one drops dramatically. A space elevator will eventually make it $10 per pound to put something into space. This will open many doors for scientists and engineers around the globe: bigger and better observatories, a spaceport at GEO, and so forth.

Surprisingly, one of the biggest incentives for space exploration is likely to be tourism. From Hawaii to Africa to Las Vegas, the primary revenue in many exotic places is tourism. We will go to the stars because man is driven to explore and see new things.

Space is an extremely harsh place, which is why it is such a miracle that there is life on Earth to begin with. The moon is too small to have an atmosphere, but we can terraform Mars to create one, and make it safe from radiation and pleasant to visit. This will also teach us a lot about climate change, and in fact, until we have terraformed Mars, I am going to assume the global warming alarmists don’t really know what they are talking about yet.2 One of the lessons in engineering is that you don’t know how something works until you’ve done it once.

Terraforming Mars may sound like a silly idea today, but it is simply another engineering task.3 I worked in several different groups at Microsoft, and even though the set of algorithms surrounding databases are completely different from those for text engines, they are all engineering problems and the approach is the same: break a problem down and analyze each piece. (One of the interesting lessons I learned at Microsoft was the difference between real life and standardized tests. In a standardized test, if a question looks hard, you should skip it and move on so as not to waste precious time. At Microsoft, we would skip past the easy problems and focus our time on the hard ones.)

Engineering teaches you that there are an infinite number of ways to attack a problem, each with various trade-offs; it might take 1,000 years to terraform Mars if we were to send one ton of material, but only 20 years if we could send 1,000 tons of material. Whatever we finally end up doing, the first humans to visit Mars will be happy that we turned it green for them. This is another way our generation can make its mark.

A space elevator is a doable mega-project, but there is no progress beyond a few books and conferences because the very small number of people on this planet who are capable of initiating this project are not aware of the feasibility of the technology.

Brad Edwards, one of the world’s experts on the space elevator, has a PhD and a decade of experience designing satellites at Los Alamos National Labs, and yet he has told me that he is unable to get into the doors of leadership at NASA, or the Gates Foundation, etc. No one who has the authority to organize this understands that a space elevator is doable.

Glenn Reynolds has blogged about the space elevator on his very influential Instapundit.com, yet a national dialog about this topic has not yet happened, and NASA is just marching ahead with its expensive, dim ideas. My book is an additional plea: one more time, and with feeling!

How and When

It does not follow from the separation of planning and doing in the analysis of work that the planner and the doer should be two different people. It does not follow that the industrial world should be divided into two classes of people: a few who decide what is to be done, design the job, set the pace, rhythm and motions, and order others about; and the many who do what and as they are told.

—Peter Drucker

There are a many interesting details surrounding a space elevator, and for those interested in further details, I recommend The Space Elevator, co-authored by Brad Edwards.

The size of the first elevator is one of biggest questions to resolve. If you were going to lay fiber optic cables across the Atlantic ocean, you’d set aside a ton of bandwidth capacity. Likewise, the most important metric for our first space elevator is its size. I believe at least 100 tons / day is a worthy requirement, otherwise the humans will revert to form and start hoarding the cargo space.

The one other limitation with current designs is that they assume climbers which travel hundreds of miles per hour. This is a fine speed for cargo, but it means that it will take days to get into orbit. If we want to send humans into space in an elevator, we need to build climbers which can travel at least 10,000 miles per hour. While this seems ridiculously fast, if you accelerate to this speed over a period of minutes, it will not be jarring. Perhaps this should be the challenge for version two if they can’t get it done the first time.

The conventional wisdom amongst those who think it is even possible is that it will take between 20 and 50 years to build a space elevator. However, anyone who makes such predictions doesn’t understand that engineering is a fungible commodity. I can just presume they must never had the privilege of working with a team of 100 people who in 3 days accomplish as much as you will in a year. Two people will, in general, accomplish something twice as fast as one person.4 How can you say something will unequivocally take a certain amount of time when you don’t specify how many resources it will require or how many people you plan to assign to the task?

Furthermore, predictions are usually way off. If you asked someone how long it would take unpaid volunteers to make Wikipedia as big as the Encyclopedia Britannica, no one would have guessed the correct answer of two and a half years. From creating a space elevator to world domination by Linux, anything can happen in far less time than we think is possible if everyone simply steps up to play their part. The way to be a part of the future is to invent it, by unleashing our scientific and creative energy towards big, shared goals. Wikipedia, as our encyclopedia, was an inspiration to millions of people, and so the resources have come piling in. The way to get help is to create a vision that inspires people. In a period of 75 years, man went from using horses and wagons to landing on the moon. Why should it take 20 years to build something that is 99% doable today?

Many of the components of a space elevator are simple enough that college kids are building prototype elevators in their free time. The Elevator:2010 contest is sponsored by NASA, but while these contests have generated excitement and interest in the press, they are building toys, much like a radio-controlled airplane is a toy compared to a Boeing airliner.

I believe we could have a space elevator built in 7 years. If you divvy up five years of work per person, and add in a year to ramp up and test, you can see how seven years is quite reasonable. Man landed on the moon 7 years after Kennedy’s speech, exactly as he ordained, because dates can be self-fulfilling prophecies. It allows everyone to measure themselves against their goals, and determine if they need additional resources. If we decided we needed an elevator because our civilization had a threat of extermination, one could be built in a very short amount of time.

If the design of the hardware and the software were done in a public fashion, others could take the intermediate efforts and test them and improve them, therefore saving further engineering time. Perhaps NASA could come up with hundreds of truly useful research projects for college kids to help out on instead of encouraging them to build toys. There is a lot of software to be written and that can be started now.

The Unknown Unknown is the nanotubes, but nearly all the other pieces can be built without having any access to them. We will only need them wound into a big spool on the launch date.

I can imagine that any effort like this would get caught up in a tremendous amount of international political wrangling that could easily add years on to the project. We should not let this happen, and we should remind each other that the space elevator is just the railroad car to space — the exciting stuff is the cargo inside and the possibilities out there. A space elevator is not a zero sum endeavor: it would enable lots of other big projects that are totally unfeasible currently. A space elevator would enable various international space agencies that have money, but no great purpose, to work together on a large, shared goal. And as a side effect it would strengthen international relations.5


1 The Europeans aren’t providing great leadership either. One of the big investments of their Space agencies, besides the ISS, is to build a duplicate GPS satellite constellation, which they are doing primarily because of anti-Americanism! Too bad they don’t realize that their emotions are causing them to re-implement 35 year-old technology, instead of spending that $5 Billion on a truly new advancement. Cloning GPS in 2013: Quite an achievement, Europe!

2 Carbon is not a pollutant and is valuable. It is 18% of the mass of the human body, but only .03% of the mass of the Earth. If Carbon were more widespread, diamonds would be cheaper. Driving very fast cars is the best way to unlock the carbon we need. Anyone who thinks we are running out of energy doesn’t understand the algebra in E = mc2.

3 Mars’ moon, Phobos, is only 3,700 miles above Mars, and if we create an atmosphere, it will slow down and crash. We will need to find a place to crash the fragments, I suggest in one of the largest canyons we can find; we could put them next to a cross dipped in urine and call it the largest man-made art.

4 Fred Brooks’ The Mythical Man-Month argues that adding engineers late to a project makes a project later, but ramp-up time is just noise in the management of an engineering project. Also, wikis, search engines, and other technologies invented since his book have lowered the overhead of collaboration.

5 Perhaps the Europeans could build the station at GEO. Russia could build the shuttle craft to move cargo between the space elevator and the moon. The Middle East could provide an electrical grid for the moon. China could take on the problem of cleaning up the orbital space debris and build the first moon base. Africa could attack the problem of terraforming Mars, etc.

An obvious next step in the effort to dramatically lower the cost of access to low Earth orbit is to explore non-rocket options. A wide variety of ideas have been proposed, but it’s difficult to meaningfully compare them and to get a sense of what’s actually on the technology horizon. The best way to quantitatively assess these technologies is by using Technology Readiness Levels (TRLs). TRLs are used by NASA, the United States military, and many other agencies and companies worldwide. Typically there are nine levels, ranging from speculations on basic principles to full flight-tested status.

The system NASA uses can be summed up as follows:

TRL 1 Basic principles observed and reported
TRL 2 Technology concept and/or application formulated
TRL 3 Analytical and experimental critical function and/or characteristic proof-of concept
TRL 4 Component and/or breadboard validation in laboratory environment
TRL 5 Component and/or breadboard validation in relevant environment
TRL 6 System/subsystem model or prototype demonstration in a relevant environment (ground or space)
TRL 7 System prototype demonstration in a space environment
TRL 8 Actual system completed and “flight qualified” through test and demonstration (ground or space)
TRL 9 Actual system “flight proven” through successful mission operations.

Progress towards achieving a non-rocket space launch will be facilitated by popular understanding of each of these proposed technologies and their readiness level. This can serve to coordinate more work into those methods that are the most promising. I think it is important to distinguish between options with acceleration levels within the range human safety and those that would be useful only for cargo. Below I have listed some non-rocket space launch methods and my assessment of their technology readiness levels.

Spacegun: 6. The US Navy’s HARP Project launched a projectile to 180 km. With some level of rocket-powered assistance in reaching stable orbit, this method may be feasible for shipments of certain forms of freight.

Spaceplane: 6. Though a spaceplane prototype has been flown, this is not equivalent to an orbital flight. A spaceplane will need significantly more delta-v to reach orbit than a suborbital trajectory requires.

Orbital airship: 2. Though many subsystems have been flown, the problem of atmospheric drag on a full scale orbital airship appears to prevent this kind of architecture from reaching space.

Space Elevator: 3. The concept may be possible, albeit with major technological hurdles at the present time. A counterweight, such as an asteroid, needs to be positioned above geostationary orbit. The material of the elevator cable needs to have a very high tensile strength/mass ratio; no satisfactory material currently exists for this application. The problem of orbital collisions with the elevator has also not been resolved.

Electromagnetic catapult: 4. This structure could be built up the slope of a tall mountain to avoid much of the Earth’s atmosphere. Assuming a small amount of rocket power would be used after a vehicle exits the catapult, no insurmountable technological obstacles stand in the way of this method. The sheer scale of the project makes it difficult to develop the technology past level 4.

Are there any ideas we’re missing here?

It is interesting to note that the technical possibility to send interstellar Ark appeared in 1960th, and is based on the concept of “Blust-ship” of Ulam. This blast-ship uses the energy of nuclear explosions to move forward. Detailed calculations were carried out under the project “Orion”. http://en.wikipedia.org/wiki/Project_Orion_(nuclear_propulsion) In 1968 Dyson published an article “Interstellar Transport”, which shows the upper and lower bounds of the projects. In conservative (ie not imply any technical achievements) valuation it would cost 1 U.S. GDP (600 billion U.S. dollars at the time of writing) to launch the spaceship with mass of 40 million tonnes (of which 5 million tons of payload), and its time of flight to Alpha Centauri would be 1200 years. In a more advanced version the price is 0.1 U.S. GDP, the flight time is 120 years and starting weight 150 000 tons (of which 50 000 tons of payload). In principle, using a two-tier scheme, more advanced thermonuclear bombs and reflectors the flying time to the nearest star can reduce to 40 years.
Of course, the crew of the spaceship is doomed to extinction if they do not find a habitable and fit for human planet in the nearest star system. Another option is that it will colonize uninhabited planet. In 1980, R. Freitas proposed a lunar exploration using self-replicating factory, the original weight of 100 tons, but to control that requires artificial intelligence. “Advanced Automation for Space Missions” http://www.islandone.org/MMSG/aasm/ Artificial intelligence yet not exist, but the management of such a factory could be implemented by people. The main question is how much technology and equipment should be enough to throw at the moonlike uninhabited planet, so that people could build on it completely self-sustaining and growing civilization. It is about creating something like inhabited von Neumann probe. Modern self-sustaining state includes at least a few million people (like Israel), with hundreds of tons of equipment on each person, mainly in the form of houses, roads. Weight of machines is much smaller. This gives us the upper boundary of the able to replicate human colony in the 1 billion tons. The lower estimate is that there would be about 100 people, each of which accounts for approximately 100 tons (mainly food and shelter), ie 10 000 tons of mass. A realistic assessment should be somewhere in between, and probably in the tens of millions of tons. All this under the assumption that no miraculous nanotechnology is not yet open.
The advantage of a spaceship as Ark is that it is non-specific reaction to a host of different threats with indeterminate probabilities. If you have some specific threat (the asteroid, the epidemic), then there is better to spend money on its removal.
Thus, if such a decision in the 1960th years were taken, now such a ship could be on the road.
But if we ignore the technical side of the issue, there are several trade-offs on strategies for creating such a spaceship.
1. The sooner such a project is started, the lesser technically advanced it would be, the lesser would be its chances of success and higher would be cost. But if it will be initiated later, the greater would be chances that it will not be complete until global catastrophe.
2. The later the project starts, the greater are the chance that it will take “diseases” of mother civilization with it (e.g. ability to create dangerous viruses ).
3. The project to create a spaceship could lead to the development of technologies that threaten civilization itself. Blast-ship used as fuel hundreds of thousands of hydrogen bombs. Therefore, it can either be used as a weapon, or other party may be afraid of it and respond. In addition, the spaceship can turn around and hit the Earth, as star-hammer — or there maybe fear of it. During construction of the spaceship could happen man-made accidents with enormous consequences, equal as maximum to detonation of all bombs on board. If the project is implementing by one of the countries in time of war, other countries could try to shoot down the spaceship when it launched.
4. The spaceship is a means of protection against Doomsday machine as strategic response in Khan style. Therefore, the creators of such a Doomsday machine can perceive the Ark as a threat to their power.
5. Should we implement a more expensive project, or a few cheaper projects?
6. Is it sufficient to limit the colonization to the Moon, Mars, Jupiter’s moons or objects in the Kuiper belt? At least it can be fallback position at which you can check the technology of autonomous colonies.
7. The sooner the spaceship starts, the less we know about exoplanets. How far and how fast the Ark should fly in order to be in relative safety?
8. Could the spaceship hide itself so that the Earth did not know where it is, and should it do that? Should the spaceship communicate with Earth? Or there is a risk of attack of a hostile AI in this case?
9. Would not the creation of such projects exacerbate the arms race or lead to premature depletion of resources and other undesirable outcomes? Creating of pure hydrogen bombs would simplify the creation of such a spaceship, or at least reduce its costs. But at the same time it would increase global risks, because nuclear non-proliferation will suffer complete failure.
10. Will the Earth in the future compete with its independent colonies or will this lead to Star Wars?
11. If the ship goes off slowly enough, is it possible to destroy it from Earth, by self-propelling missile or with radiation beam?
12. Is this mission a real chance for survival of the mankind? Flown away are likely to be killed, because the chance of success of the mission is no more than 10 per cent. Remaining on the Earth may start to behave more risky, in logic: “Well, if we have protection against global risks, now we can start risky experiments.” As a result of the project total probability of survival decreases.
13. What are the chances that its computer network of the Ark will download the virus, if it will communicate with Earth? And if not, it will reduce the chances of success. It is possible competition for nearby stars, and faster machines would win it. Eventually there are not many nearby stars at distance of about 5 light years — Alpha Centauri, the Barnard star, and the competition can begin for them. It is also possible the existence of dark lonely planets or large asteroids without host-stars. Their density in the surrounding space should be 10 times greater than the density of stars, but to find them is extremely difficult. Also if nearest stars have not any planets or moons it would be a problem. Some stars, including Barnard, are inclined to extreme stellar flares, which could kill the expedition.
14. The spaceship will not protect people from hostile AI that finds a way to catch up. Also in case of war starships may be prestigious, and easily vulnerable targets — unmanned rocket will always be faster than a spaceship. If arks are sent to several nearby stars, it does not ensure their secrecy, as the destination will be known in advance. Phase transition of the vacuum, the explosion of the Sun or Jupiter or other extreme event can also destroy the spaceship. See e.g. A.Bolonkin “Artificial Explosion of Sun. AB-Criterion for Solar Detonation” http://www.scribd.com/doc/24541542/Artificial-Explosion-of-Sun-AB-Criterion-for-Solar-Detonation
15. However, the spaceship is too expensive protection from many other risks that do not require such far removal. People could hide from almost any pandemic in the well-isolated islands in the ocean. People can hide on the Moon from gray goo, collision with asteroid, supervolcano, irreversible global warming. The ark-spaceship will carry with it problems of genetic degradation, propensity for violence and self-destruction, as well as problems associated with limited human outlook and cognitive biases. Spaceship would only burden the problem of resource depletion, as well as of wars and of the arms race. Thus, the set of global risks from which the spaceship is the best protection, is quite narrow.
16. And most importantly: does it make sense now to begin this project? Anyway, there is no time to finish it before become real new risks and new ways to create spaceships using nanotech.
Of course it easy to envision nano and AI based Ark – it would be small as grain of sand, carry only one human egg or even DNA information, and could self-replicate. The main problem with it is that it could be created only ARTER the most dangerous period of human existence, which is the period just before Singularity.

For any assembly or structure, whether an isolated bunker or a self sustaining space colony, to be able to function perpetually, the ability to manufacture any of the parts necessary to maintain, or expand, the structure is an obvious necessity. Conventional metal working techniques, consisting of forming, cutting, casting or welding present extreme difficulties in size and complexity that would be difficult to integrate into a self sustaining structure.

Forming requires heavy high powered machinery to press metals into their final desired shapes. Cutting procedures, such as milling and lathing, also require large, heavy, complex machinery, but also waste tremendous amounts of material as large bulk shapes are cut away emerging the final part. Casting metal parts requires a complex mold construction and preparation procedures, not only does a negative mold of the final part need to be constructed, but the mold needs to be prepared, usually by coating in ceramic slurries, before the molten metal is applied. Unless thousands of parts are required, the molds are a waste of energy, resources, and effort. Joining is a flexible process, and usually achieved by welding or brazing and works by melting metal between two fixed parts in order to join them — but the fixed parts present the same manufacturing problems.

Ideally then, in any self sustaining structure, metal parts should be constructed only in the final desired shape but without the need of a mold and very limited need for cutting or joining. In a salient progressive step toward this necessary goal, NASA demonstrates the innovative Electron Beam Free Forming Fabrication (http://www.aeronautics.nasa.gov/electron_beam.htm) Process. A rapid metal fabrication process essentially it “prints” a complex three dimensional object by feeding a molten wire through a computer controlled gun, building the part, layer by layer, and adding metal only where you desire it. It requires no molds and little or no tooling, and material properties are similar to other forming techniques. The complexity of the part is limited only by the imagination of the programmer and the dexterity of the wire feed and heating device.

Electron beam freeform fabrication process in action
Electron beam freeform fabrication process in action

According to NASA materials research engineer Karen Taminger, who is involved in developing the EBF3 process, extensive simulations and modeling by NASA of long duration space flights found no discernable pattern to the types of parts which failed, but the mass of the failed parts remained remarkably consistent throughout the studies done. This is a favorable finding to in-situe parts manufacturing and because of this the EBF³ team at NASA has been developing a desktop version. Taminger writes:

“Electron beam freeform fabrication (EBF³) is a cross-cutting technology for producing structural metal parts…The promise of this technology extends far beyond its applicability to low-cost manufacturing and aircraft structural designs. EBF³ could provide a way for astronauts to fabricate structural spare parts and new tools aboard the International Space Station or on the surface of the moon or Mars”

NASA’s Langley group working on the EBF3 process took their prototype desktop model for a ride on the microgravity simulating NASA flight and found the process works just fine even in micro gravity, or even against gravity.

A structural metal part fabricated from EBF³
A structural metal part fabricated from EBF³

The advantages this system offers are significant. Near net shape parts can be manufactured, significantly reducing scrap parts. Unitized parts can be made — instead of multiple parts that need riveting or bolting, final complex integral structures can be made. An entire spacecraft frame could be ‘printed’ in one sitting. The process also creates minimal waste products and is highly energy and feed stock efficient, critical to self sustaining structures. Metals can be placed only where they are desired and the material and chemistry properties can be tailored through the structure. The technical seminar features a structure with a smooth transitional gradient from one alloy to another. Also, structures can be designed specifically for their intended purposes, without needing to be tailored to manufacturing process, for example, stiffening ridges can be curvilinear, in response to the applied forces, instead of typical grid patterns which facilitate easy conventional manufacturing techniques. Manufactures, such as Sciaky Inc, (http://www.sciaky.com/64.html) are all ready jumping on the process

In combination with similar 3D part ‘printing’ innovations in plastics and other materials, the required complexity for sustaining all the mechanical and structural components of a self sustaining structure is plummeting drastically. Isolated structures could survive on a feed stock of scrap that is perpetually recycled as worn parts are replaced by free form manufacturing and the old ones melted to make new feed stock. Space colonies could combine such manufacturing technologies and scrap feedstock with resource collection creating a viable minimal volume and energy consuming system that could perpetually repair the structure – or even build more. Technologies like these show that the atomic level control that nanotechnology manufacturing proposals offer are not necessary to create self sustaining structure, and that with minor developments of modern technology, self sustaining structures could be built and operated successfully.

Many years ago, in December 1993 to be approximate, I noticed a space-related poster on the wall of Eric Klien’s office in the headquarters of the Atlantis Project. We chatted for a bit about the possibilities for colonies in space. Later, Eric mentioned that this conversation was one of the formative moments in his conception of the Lifeboat Foundation.

Another friend, filmmaker Meg McLain has noticed that orbital hotels and space cruise liners are all vapor ware. Indeed, we’ve had few better depictions of realistic “how it would feel” space resorts since 1968’s Kubrick classic “2001: A Space Odyssey.” Remember the Pan Am flight to orbit, the huge hotel and mall complex, and the transfer to a lunar shuttle? To this day I know people who bought reservation certificates for whenever Pan Am would begin to fly to the Moon.

In 2004, after the X Prize victory, Richard Branson announced that Virgin Galactic would be flying tourists by 2007. So far, none.

A little later, Bigelow announced a fifty million dollar prize if only tourists could be launched to orbit by January 2010. I expect the prize money won’t be claimed in time.

Why? Could it be that the government is standing in the way? And if tourism in space can’t be “permitted” what of a lifeboat colony?

Meg has set out to make a documentary film about how the human race has arrived four decades after the Moon landing and still no tourist stuff. Two decades after Kitty Hawk, a person could fly across the country; three decades, across any ocean.

Where are the missing resorts?

Here is the link to her film project:
http://www.freewebs.com/11at40/

(Crossposted on the blog of Starship Reckless)

Eleven years ago, Random House published my book To Seek Out New Life: The Biology of Star Trek. With the occasion of the premiere of the Star Trek reboot film and with my mind still bruised from the turgid awfulness of Battlestar Galactica, I decided to post the epilogue of my book, very lightly updated — as an antidote to blasé pseudo-sophistication and a reminder that Prometheus is humanity’s best embodiment. My major hope for the new film is that Uhura does more than answer phones and/or smooch Kirk.

Coda: The Infinite Frontier

star-trekA younger science than physics, biology is more linear and less exotic than its older sibling. Whereas physics is (mostly) elegant and symmetric, biology is lunging and ungainly, bound to the material and macroscopic. Its predictions are more specific, its theories less sweeping. And yet, in the end, the exploration of life is the frontier that matters the most. Life gives meaning to all elegant theories and contraptions, life is where the worlds of cosmology and ethics intersect.

Our exploration of Star Trek biology has taken us through wide and distant fields — from the underpinnings of life to the purposeful chaos of our brains; from the precise minuets of our genes to the tangled webs of our societies.

How much of the Star Trek biology is feasible? I have to say that human immortality, psionic powers, the transporter and the universal translator are unlikely, if not impossible. On the other hand, I do envision human genetic engineering and cloning, organ and limb regeneration, intelligent robots and immersive virtual reality — quite possibly in the near future.

Furthermore, the limitations I’ve discussed in this book only apply to earth biology. Even within the confines of our own planet, isolated ecosystems have yielded extraordinary lifeforms — the marsupials of Australia; the flower-like tubeworms near the hot vents of the ocean depths; the bacteriophage particles which are uncannily similar to the planetary landers. It is certain that when we finally go into space, whatever we meet will exceed our wildest imaginings.

Going beyond strictly scientific matters, I think that the accuracy of scientific details in Star Trek is almost irrelevant. Of course, it puzzles me that a show which pays millions to principal actors and for special effects cannot hire a few grad students to vet their scripts for glaring factual errors (I bet they could even get them for free, they’d be that thrilled to participate). Nevertheless, much more vital is Star Trek’s stance toward science and the correctness of the scientific principles that it showcases. On the latter two counts, the series has been spectacularly successful and damaging at the same time.

The most crucial positive elements of Star Trek are its overall favorable attitude towards science and its strong endorsement of the idea of exploration. Equally important (despite frequent lapses) is the fact that the Enterprise is meant to be a large equivalent to Cousteau’s Calypso, not a space Stealth Bomber. However, some negative elements are so strong that they almost short-circuit the bright promise of the show.

I cannot be too harsh on Star Trek, because it’s science fiction — and TV science fiction, at that. Yet by choosing to highlight science, Star Trek has also taken on the responsibility of portraying scientific concepts and approaches accurately. Each time Star Trek mangles an important scientific concept (such as evolution or black hole event horizons), it misleads a disproportionately large number of people.

The other trouble with Star Trek is its reluctance to showcase truly imaginative or controversial ideas and viewpoints. Of course, the accepted wisdom of media executives who increasingly rely on repeating well-worn concepts is that controversial positions sink ratings. So Star Trek often ignores the agonies and ecstasies of real science and the excitement of true or projected scientific discoveries, replacing them with pseudo-scientific gobbledygook more appropriate for series like The X-Files, Star Wars and Battlestar Galactica. Exciting ideas (silicon lifeforms beyond robots, parallel universes) briefly appear on Star Trek, only to sink without a trace. This almost pathological timidity of Star Trek, which enjoys the good fortune of a dedicated following and so could easily afford to cut loose, does not bode well for its descendants or its genre.

trekmovie2w

On the other hand, technobabble and all, Star Trek fulfills a very imporant role. It shows and endorses the value of science and technology — the only popular TV series to do so, at a time when science has lost both appeal and prestige. With the increasing depth of each scientific field, and the burgeoning of specialized jargon, it is distressingly easy for us scientists to isolate ourselves within our small niches and forget to share the wonders of our discoveries with our fellow passengers on the starship Earth. Despite its errors, Star Trek’s greatest contribution is that it has made us dream of possibilities, and that it has made that dream accessible to people both inside and outside science.

Scientific understanding does not strip away the mystery and grandeur of the universe; the intricate patterns only become lovelier as more and more of them appear and come into focus. The sense of excitement and fulfillment that accompanies even the smallest scientific discovery is so great that it can only be communicated in embarrassingly emotional terms, even by Mr. Spock and Commander Data. In the end these glimpses of the whole, not fame or riches, are the real reason why the scientists never go into the suspended animation cocoons, but stay at the starship chart tables and observation posts, watching the great galaxy wheels slowly turn, the stars ignite and darken.

Star Trek’s greatest legacy is the communication of the urge to explore, to comprehend, with its accompanying excitement and wonder. Whatever else we find out there, beyond the shelter of our atmosphere, we may discover that thirst for knowledge may be the one characteristic common to any intelligent life we encounter in our travels. It is with the hope of such an encounter that people throng around the transmissions from Voyager, Sojourner, CoRoT, Kepler. And even now, contained in the sphere of expanding radio and television transmissions speeding away from Earth, Star Trek may be acting as our ambassador.

May 2: Many U.S. emergency rooms and hospitals crammed with people… ”Walking well” flood hospitals… Clinics double their traffic in major cities … ER rooms turn away EMT cases. — CNN

Update May 4: Confirmed cases of H1N1 virus now at 985 in 20 countries (Mexico: 590, 25 deaths) — WHO. In U.S.: 245 confirmed U.S. cases in 35 states. — CDC.

“We might be entering an Age of Pandemics… a broad array of dangerous emerging 21st-century diseases, man-made or natural, brand-new or old, newly resistant to our current vaccines and antiviral drugs…. Martin Rees bet $1,000 that bioterror or bioerror would unleash a catastrophic event claiming one million lives in the next two decades…. Why? Less forest, more contact with animals… more meat eating (Africans last year consumed nearly 700 million wild animals… numbers of chickens raised for food in China have increased 1,000-fold over the past few decades)… farmers cut down jungle, creating deforested areas that once served as barriers to the zoonotic viruses…” — Larry Brilliant, Wall Street Journal