Selenian Boondocks

In January, Elon Musk mused that the design goal for Starship was 3 flights per day, for about 1000 flights per year per Starship (assuming for the sake of simplicity he’s talking about a whole stack) with a payload of about 100 tons to LEO. That’s 10 Starships flying a total of 10,000 flights per year to reach 1 megaton in orbit. He points to 100 megatons annually to orbit (100 Starships per year for 10 years… 1 million Starship flights per year) as the goal.

” Building 100 Starships/year gets to 1000 in 10 years or 100 megatons/year or maybe around 100k people per Earth-Mars orbital sync “

Just how big is that? Is it realistic?

Note: I decided to make a couple images to illustrate the difference between 1 Megaton IMLEO/year (corresponding to roughly 1000 larger Starships heading off to Mars each synod) and 100 Megaton IMLEO/year (roughly 100,000 larger Starships heading off to Mars each synod). There are no stars in these images, just Starships:
1000 Starships doing trans-Mars-insertion simultaneously:

(alternately, for 100,000 Starships, they might do this once per orbit for a week straight)

Going by rough figures, there’s about 3 billion tons of methane (in the form of 4 trillion cubic meters of natural gas) produced every year. Each Starship takes about 1000 tons of methane (very rough numbers…). So you’d need 1 billion tons of methane every year to reach Elon’s 100 Megaton-to-orbit goal.

1 billion tons of methane is approximately 0.75 billion tons of carbon. About 5 billion tons of carbon is absorbed total by land and sea every year (Candela and Carlson 2017), so if all the world was doing as far as carbon emissions was launching SpaceX’s rockets, this wouldn’t be a problem. 1 gigaton of payload to LEO (so about 7.5 billion tons of carbon), however, WOULD be beyond the current ability of the land and sea to absorb carbon, slightly less than the current global carbon emissions from human civilization.

That puts current Starship launch efficiency to about 580MJ/kg, compared to the absolute minimum of ~32MJ/kg, or about 5% efficient. This is remarkably efficient if you think about it, but it’s nowhere near the efficiency that’s *possible*. Stretch estimates for what SpaceX hopes to eventually achieve with Starship might be 2320 tons of methane for 380 tons of payload (propellant in this case), given the 2016 ITS tanker figures (from “making_life_multiplanetary_2016.pdf“). They had a higher O:F mixture ratio (3.8), higher Isp, and lower dry masses. That’s just under 10% efficiency. Significantly better. That would mean half as much methane would be needed, perhaps lowering the carbon emissions to 4 or so gigatons of carbon for 1 gigaton to orbit, below the 5 gigatons the land and sea can absorb… Back to the 100 megaton goal, that’s 340MJ/kg times 100 billion kilograms… divided by about 31 billion seconds in a year, and you’re talking about a terawatt of methane per year.

Of course, you could switch from fossil methane to CO2-direct-air-captured methane. That’s about 50% efficient, so it’d take about 2 terawatts average per to produce. Or, given about a 20% capacity factor, about 10 terawatts of solar nameplate capacity.

But I think they’re potentially still leaving energy on their payload. (See previous posts) If they operate at yet higher O:F, even deeply oxygen-rich, for the first stage, they can get closer to an optimum Isp for early in flight. They can switch to a near-stoich hydrolox upper stage. Maybe we continue making advances in structural materials. Maybe there’s a small launch assist in the beginning (at least getting the vehicle to an altitude where vacuum-optimized first stage engines are feasible). Or they use gigantic expansion nozzles on the upper stage; higher chamber pressures; adjustable Isp. I can imagine achieving 20% or even 30% efficiency. Perhaps 100MJ/kg could be achieved without miracles. That lowers to about 300Gigawatts of chemical energy per year. Hydrogen may be more efficient to make (75%?), so maybe 400Gigawatts of average electricity per year… The US electric grid produces about 475Gigawatts average, so for the first time we’re below the US’s electrical output to power Elon’s 100 megaton/year dream.

However… Pumping all that water vapor up in the atmosphere could cause problems, too. But let’s say we avoid that somehow. There are other problems:

NOx emissions (nitrous oxide and similar) in the high atmosphere cause several problems. One is breaking down the ozone layer. Another is acid rain (although this is also part of the normal nitrate cycle on Earth, where lightning fixes nitrogen into the soil). Another is greenhouse effects… NOx emissions are approximately 250 times worse than CO2, pound-for-pound. It’s estimated that the Space Shuttle produced about 5% (but perhaps up to like 15%) of its reentering mass in NOx emissions (see: Global atmospheric response to emissions from a proposed reusable space launch system). Air-breathing rockets would make this worse by also producing NOx on the way up (see Skylon). We currently emit about 13 megatons of NOx every year from burning fossil fuels (compared to another 8 megatons annually from lightning). Considering the current fairly high dry mass of Starship, there’s basically about a 1-to-1 ratio of Starship mass reentered to payload delivered. So 1 megaton of payload would produce about 50,000kg of NOx. Not nothing, but not a showstopper. 100megatons, however, would produce about 5 megatons of NOx emissions… almost half of what we already make, but could be even higher, if the higher estimates of reentry NOx production are accurate (I don’t think they are).

However, I think we can do much better. The 2016 ITS tanker had a propellant payload to reentry mass ratio of about 4, reducing the amount of NOx production for 100 Megatons by a factor of 4 again. And we can maybe do better by changing the staging situation… Because NOx production and reentry temperature are really non-linear, there would be very little NOx production from a reentering 1st or 2nd stage in a 3-stage-to-LEO rocket. Falcon Heavy, in expendable mode, has an upper stage dry mass of around 4.5 tons (guesstimate from spacelaunchreport.com), and a payload of about 63.8 tons. That puts the ratio at about 14! Over an order of magnitude better than first-generation-Starship. Maybe knock that back to 10:1 for a reusable upper stage (but still using really advanced structures) for a launch vehicle optimized for this constraint, and we could be talking only 500,000tons of NOx per year. MUCH more manageable. To equal the current 20 megatons tons (combined human and lightning) NOx per year, we can reenter about 400 megatons of material, or launch (with an upper stage empty mass to payload ratio of 10) about 4 gigatons.

It may also be possible to scrub NOx from the atmosphere. This concept (backup link: https://doi.org/10.1007/s11356-016-6103-9 by Ming et al) suggests using a solar tower to help scrub NOx from the atmosphere and generate solar electricity at the same time. At really high launch rates, that might be necessary. In fact, any plan to use space resources to “deindustrialize” Earth (like Bezos and O’Neillians like to mention) would have to deal with the problem of (re)entry of massive amounts of material to Earth and the NOx emissions that causes.

It is also possible to pump Ozone into the stratosphere or maybe even suppress lightning to compensate.

Thinking long-term, what is the ultimate limit to ability to launch stuff with rockets, of any type? Current anthropogenic global warming from the greenhouse effect from fossil fuel emissions is much larger than, say, fundamental waste heat from any energy usage whatsover. Waste heat is on the order of 18 TW (same as primary energy usage), with global warming effect from fossil gas emissions (and land use changes) about 100 times that, so about 1-2 Petawatts. If we take current global warming level to be the ultimate limit that we could safely pursue long-term, then human society could grow to use approximately 100 times as much energy as it does right now relying on fossil fuels, or about 1-2 Petawatts. If all of that was used for chemical rockets with each kg of payload into LEO requiring 100MJ/kg, then we could get about 300 gigatons of payload into LEO per year before producing too much waste heat. Maybe with perfect launch systems, about 1 trillion tons per year.

So there are a lot of constraints. We, long-term, probably want to off-load much of that into space. That means maybe using solar-electric propulsion eventually. Before we get much beyond 1 megaton per year, I hope we’re looking seriously at scaling up solar electric propulsion, asteroid mining for propellant, and tethers. Using rotovators (discussed elsewhere on this blog), we could drastically reduce the amount of energy needed to be expended on Earth to launch payloads. And maybe just important (at that scale), we don’t need to use the atmosphere to slow down payloads to the surface of the Earth, either. Tethers combined with megastructures ~100km tall would allow payloads to be launched at higher efficiency and returned to Earth without massive aerobraking… in fact, even reducing reentry from 7.8km/s to 5.5km/s using a modest rotovator would halve the orbital energy input into the atmosphere and probably would non-linearly reduce NOx emissions as well.

Humans move on the order of 50-100 gigatons of material per year (with trucks, bulldozers, etc). See: https://www.sciencedaily.com/releases/2004/07/040709083319.htm#:~:text=In%201994%2C%20Hooke%20published%20the,%2C%20glaciers%2C%20oceans%20or%20wind.
That’s more than all the sediment moved by all the rivers of the world every year.
To move that much of material *to space* every year would require some clever thinking, but wouldn’t be impossible. It’d just take on the order of 100 Terawatts. Current solar cell prices are just 5.5 cents per watt… if they were illuminated constantly, that’s less than $10 trillion dollars worth of solar cells to move more material into space than all the material that all of humanity moves anywhere every year. And we might not even have to cook ourselves to do it.

However, Musk’s 100 Megatons to LEO every year would use up about a third of the world’s annual natural gas production. Might want to move beyond fossil fuels (and maybe optimize launch vehicle efficiency) if we’re going to really launch that much stuff…

And to continue the crude visual thought experiment from earlier, this is what it might look like if those 100 Megatons IMLEO were used to send 100,000 Starships to Mars at once each synod, with a total power output of approximately 2 Petawatts for 8 minutes, maybe even regionally outshining the Sun for a few minutes:

Mars has only the ancient remnants of a magnetic field. What little chunks of field it does have (imprinted into magnetic rocks) are regional in scale and do nothing at all for radiation shielding (I once calculated this). Additionally, over a long enough timescale (tens of millions of years), the solar wind will erode the atmosphere of a terraformed Mars. So, let’s just get on with replacing the lost magnetic field.

To do this, we aren’t going to do something silly like restart the core. We’re going to rely on a tried and true existing technology: cryogenic superconductors. Just put a superconducting ring around the equator of Mars. Turns out, this wouldn’t even cost that much to build. I will be using Magnesium Diboride (MgB₂) because it’s cheap, has pretty good performance (critical temperature of 39K, critical current of like 10⁵ A/cm² at 5K), and both Boron and Magnesium are known to exist fairly commonly on Mars. (Magnesium is super common, and Boron has been found in clays at >150ppm concentrations–according to this paper–and probably exists in far higher concentrations somewhere since Mars once had a quite active water cycle. I’ll assume that by the time the residents of Mars want to do this sort of thing, the costs of extracting these minerals will be similar to that of Earth (maybe a poor assumption, but why would you do this unless there are like millions of people on Mars, at a minimum?). We’ll also assume that because of the ridiculous scale being operated at, and because MgB₂ is a pretty easy superconductor to make (just need to heat the mixture of Magnesium and Boron powders), the cost of actually building the ring will be some single-digit multiple of the raw costs of the material.

Okay. So just how big is the Earth’s magnetic field? We’ll use its total energy (when approximated as current on a sphere) to estimate what we’ll need as far as current in the ring. According to this, the Earth’s magnetic field stores about 10²⁶ erg, or 10¹⁹J (roughly half the energy the world uses in a year). The energy stored in an inductor is just:

(according to Wikipedia)
Where L is inductance and I is the current in the ring.

To calculate the inductance L of a ring of radius R with wire radius a and number of turns N, we use the approximation:

(from here)

Since N=1 and we’ll conservatively (very conservatively) say the relative permeability  , and since the current I is related to the critical current density J_c such that: , we can write the equation as:

If we let a=.42m, R=r_Mars, and J_c = 10⁵ A/cm²:
https://www.google.com/webhp?#q=.5*r_Mars*(mu_0)*(ln(8*r_Mars/(.42m))-2)*(10^5A/cm^2*pi*(.42m)^2)^2 = 1.047*10^19 Joules, when we only needed 10^19 J to equal the same energy as Earth’s magnetic field.

Given the density of MgB₂ is 2.57g/cc (source), the mass of the superconductor is:
https://www.google.com/search?q=2*pi*r_Mars*pi*(42cm)^2*2.57g/cc or about 3*10¹⁰kg, 30 million tons, almost have of which is boron. The Earth mines about 4 million tons of Boron a year, so the Earth produces enough boron to build that thing in about 4 years (we’ll mine this on Mars, of course). Pretty reasonable, considering we’re doing some pretty hardcore terraforming, here.

Given a price of about 10USD/kg for Boron (just spitballing here, since Ferroboron is half boron by molarity and 15-20% boron by mass and is 1-2USD/kg… of course, boron ore is much cheaper) and like 2USD/kg for magnesium metal (just look up the spot prices for Mg and Ferroboron), so about USD6/kg of bulk MgB₂.

This whole thing would cost about 180B USD in raw materials but would store about 3 trillion kWh for a ridiculously low price per kWh of storage (like 6 cents/kWh! For storage that can be reused!). Of course, there is also insulation and cooling, plus some method to inject power into the ring.

 

NOTE: Some Japanese researchers recently (last 2-3 years I think?) published a paper about the thing I am proposing here. I can’t find the paper now, but I assume they did I better job than I did. Also, I don’t really buy into Jim Greene’s L1 magnetosphere, since the solar wind does actually shoot straight out from the sun but actually follows the spirals of the Interplanetary Magnetic Field, so I’m pretty sure solar wind would hit Mars because the shadow of a big magnetosphere at L1 would miss Mars.

After thinking a while about why self-replicating robots do not exist (thanks, Casey: https://caseyhandmer.wordpress.com/2019/09/02/self-replicating-robots-do-not-exist/ ), we’re reminded that living things do this regularly. I’m tempted to write “a human is a von Neumann probe,” but that wouldn’t be accurate. A single human cannot reproduce, and even a pair would quickly run into survival problems unless they got lucky (and there’s some amount of genetic variety needed, with the minimum number of individuals being somewhere between 50 and 5,000 to ensure enough genetic diversity). The human is by default in society, usually a band or tribe in the past and now in cities. Our survival depends on it. This has enabled us to span from pole to pole with a vast array of lifestyles.

Even a band (10-50 people) enables specialization and folklore. A full tribe (made of several bands, enough for genetic diversity) is a self-contained unit of humanity. Enough to replicate and perpetuate neolithic technology, which includes domesticated animals, plants, spoken language, and perhaps even written language. An individual or family would have difficulty maintaining this, but a tribe should be capable of it. And with the tools of written technology, could maintain knowledge and learn between generations.

What’s interesting about neolithic technology versus later developments is that this is before humanity became dependent on vast trade routes and city-state social structures (although those did develop in that time). Still small enough to be self-contained within a tribe and replicated most places on Earth (with adaption). Other than biological materials (seeds, animals… which are reproducible and not a fundamentally limited geological resource), it is still really easy to bootstrap neolithic technology and could be done by a small group of people. The Bronze Age requires tin and bronze, which are very limited in geologic availability (requiring vast trade networks) and require more sophisticated processing.

My favorite exploration of Neolithic technology is the Primitive Technology Youtube channel. He bootstraps from nothing (no knives, etc, just himself in shorts) and has gotten extremely far in technology development. https://www.youtube.com/watch?v=P73REgj-3UE

No doubt his efforts rely on a lot of free time enabled by modern food distribution systems, but they all could be replicated by a tribe. He has made some interesting advances, such as a sort of centrifugal blower and the beginnings of a bootstrapping of iron technology using iron bacteria (found all over) instead of geographically limited iron ore. He also makes use of domesticated yams.

Now I’ve been thinking a lot about potatoes. They’re remarkably easy to grow and extremely efficient in area, store reasonably well, easy to propagate, etc. It really is a good choice if you had to pick one staple to survive on Mars with (hello, Matt Damon). But they were not introduced into the New World until the 1500s. Same with corn (maize), and a bunch of other things. Corn is a particularly efficient way of growing calories. A similar thing is true of other domesticated crops. …and animals, such as donkeys, horse, oxen, etc. Any neolithic tribe could’ve utilized these resources, but these resources weren’t all available until the modern era (i.e. starting in the 1500s). There’s some evidence that domestication of, say, potatoes, helped speed the industrial revolution due to their efficiency. You could say that it was these domestic plants and animals that enabled the industrial revolution as much as any other particular scientific, economic, etc advance.

Any of these could’ve been introduced to neolithic tribes 10,000 years ago or even earlier. Maybe 100,000 years ago. One could have taught them writing. A single tribe had enough resources to bootstrap these “technologies,” and their productivity would’ve been vastly improved. Unlike our heavy industry today, they do not require a vast, globe-spanning economy to replicate. They can be planted and replicated by a single, neolithic tribe to their great benefit. Self-contained, self-replicating… (or requiring just some assistance from people to replicate).

Domestic plants and animals are remarkable technologies. Seeds in particular… little, unassuming von Neumann machines. Iron bacteria could’ve bootstrapped the Iron Age 100,000 years earlier. Give a tractor to a neolithic tribe, and it would stop as soon as it ran out of gas. A steam tractor maybe could’ve lasted longer and maybe animal grease could serve as oil, but the industrial toolchain in order to maintain any such engine would be beyond a single tribe’s ability. But oxen or other beasts of burden? Easy to maintain and replicate in comparison. Even with some amount of semi-autonomous intelligence. There are your self-replicating robots!

This is the potential of biology in simplifying the technology bootstrap process. It’s unfortunate that biological processes tend to be so inefficient. Their relevance to bootstrapping a Mars civilization may be difficult to gauge relative to the more energy-efficient heavy machinery approach… Also, not only is it inefficient, it’s also only viable in a relatively narrow temperature and pressure range which mostly makes it irrelevant to space settlement…

…but perhaps this is worth another look. I think the fact that biology can play a part in bootstrapping is one of the most important arguments for (at least partial) terrraforming… if you can make Mars Earth-like enough for at least SOMETHING to grow, maybe we can use biology to help bootstrap human civilization there. If Mars is terraformed, then the basic human unit, the tribe, would be sufficient to replicate civilization given a continuity of knowledge of written language.

…but maybe something smaller than full terraforming is sufficient? Humans, even with just neolithic technology, are remarkably adaptable (if we can find an energy source). We can live indefinitely in the Arctic by harvesting animals (including fish, etc) using neolithic technology. Some humans live nearly their whole lives on the water using pre-modern tech. Perhaps with some clever new inventions that could be bootstrapped with neolithic-level-tech, there may be some future domesticated plants or animals (or other?) that enable humans to live on a partially terraformed Mars with something as small as a tribe. After all, we used animal intestines to produce the impermeable gas bags of the mighty zeppelins. What new domesticated life form might enable us to live on Mars with a much simpler bootstrap chain?

Can we harden living things for the Martian environment? I’m reminded that the Armstrong Limit of pressure is dictated by the boiling point of water at the human body temperature. Other living things, such as lizards (not to mention hardy plants), can still live and move with body temperatures low enough that Mars’ pressure at Hellas Basin would be high that water would not boil. There’s also the possibility of some sort of toughened skin designed to maintain internal pressure and temperature. Lichen or similar lifeforms may even be able to photosynthesize under Martian conditions: https://pubmed.ncbi.nlm.nih.gov/20402583/

…so what is the REAL Martian potato? Could some domesticated lichen produce food and important chemicals for a growing Martian civilization? Maybe some sort of domesticated lichen that produces hydrogen peroxide? Could some sort of genetically modified reptile beasts of burden serve as our self-replicating robots? Could we grow tough membranes (with built-in molecular pressure pumps powered by photosynthesis) to make our pressurized cities? How can we simplify the industrial tool-chain so self-sufficiency becomes tractable?