Sustainable Biosphere For Maximal Carrying Capacity At Current US Standard of Living

Posted by James Bowery on Tuesday, 01 May 2007 09:33.

If it were possible to sustainably support people at the current US standard of living with an ecological footprint (as little as 1/100 gha percapita) quite conceivably less than 1/10,000 of the current US ecological footprint (109 gha percapita)—and do so using reasonably low risk technologies at a capital cost (fitting the US’s entire footprint in a desert area the size of South Carolina) equal to one year’s GDP, you’d think some of the geniuses running our lives would come up with the solution.  Well, maybe they just haven’t thought of this yet:
Read on for the details.image

There is a great need to increase world-wide carrying capacity without impacting high biodiversity ecosystems such as the Brazilian rainforests or continental shelf fisheries, without adding to global warming.  There may be an economic option that uses sea water pumped to desert areas powered by the fact that ground level temperatures are much higher than temperatures at high altitudes.  Indeed, it would dump greenhouse heat to space for its power while producing biodiesel, electricity, fish, fresh water, salt and real estate—all in quantities demanded by developed-world populations—without adding to, and possibly even sequestering, greenhouse gases.

Proposals for

solar updraft towers have typically assumed that they would be single use structures: solar to electricity via heat differentials between high altitude air and ground level greenhouse-enclosed air.  The resulting system has marginal economic value.

Something which would further enhance the value of the solar updraft tower power structure is to use the greenhouse area for algae ponds to add biodiesel, water, fish and salt production to the production of electricity normally envisioned.

Doing so brings the proposal from marginally viable to viable, with a net present value, primarily from live fish production, of $3.5 billion per system, thereby allowing for far higher capitalization and/or return on investment.

Let’s start with just the value of algae biodiesel:

The greenhouse area required per solar updraft tower of is huge:

(pi * (5km/2)^2) ? hectares
= 1963.49 hectares

producing peak at peak 200MW via a 1km tall tower.

We now add to this the production of algae biodiesel:

The UNH estimate for algae biodiesel production is 1 quad per 200,000 hectares. Let’s assume only half of the area of the solar updraft tower greenhouse would be available for production at any time (the other half would be used for ponds that buffered heat for the inner ponds, produce fish, provide additional evaporative surface for desalination and provide recreation for residential areas at the outer rim).

That gives us:

(1963.49/2)hectares/tower;200000hectares/quad ? towers/quad
= 203.719 towers/quad

Or about 200 towers per quad of biodiesel.

We can now calculate the biodiesel per tower:

7.2gallon/1e6btu;200tower/quad ? gallon/tower
= 3.5998E+07 gallon/tower

or about 35M gallons of biodiesel per year per tower.

At $2/gallon for wholesale diesel, this yields $70M biodiesel revenue per year.

Now for electrical revenue:

At an average rate of sold production only 1/2 (100MW) of peak capacity (200MW), electrical production per tower per year, is:

100MW;year ? GWh
= 876 GWh

At $30/MWh wholesale:

100MW;year;30$/MWh ? $
= 2.628E+07 $

or about $25M electrical revenue per year.

Interestingly, the biodiesel revenue is nearly 3 times the electrical revenue of a solar updraft tower!

200*200MW or 40GW electrical peak capacity is produced per quad of biodiesel.

Further that same UNH document estimates 19 quads to replace all transportation fuel in the US or 3800 towers, which would also produce 3800*200MW or 760GW or .76TW of electricity.

Current winter capacity in the US is about 1TW. So this cannot replace the entire US peak capacity but peak loads would probably be reduced under this system.  Moreover, 3/4 is very close to 4/4 by engineering standards, so we can afford the luxury, in this instance, of assuming some innovation in electrical conservation technologies targeting reduction of peak load.

For reference, 3800towers at 1963.49hectares/tower would require:

3800towers;1963.49hectares/tower ? hectares
= 7.46126E+06 hectares

or about 8 million hectares or close to 30,000 square miles—a figure that cross checks with the UNH figure of 15,000 square miles of optimally productive algae ponds which we are assuming are only half of our land area due to needed additional greenhouse warming area.

An additional advantage of this approach is that the relatively constant wind velocity and direction through the greenhouse disk would allow for the efficient use of wind for driving the algae raceways.

Now for desalination:

We’re going to assume the algae ponds are saline, growing a marine species like CCMP647, and that about half of them are not producing biodiesel. These ponds would be out of algae production but would still be providing water for desalination, a market for the residual salts, live fish, climate control and residential real estate value.

Let’s assume that out of the 8 million hectares, half of which is growing algae at reasonable efficiency and therefore providing 4 million hectares of evaporative surface, an additional 2 million hectares are in reasonably efficient production as evaporative ponds, some of which is salt production and some of which is fish production, for a total of 6 million hectares of evaporative surface. Then let’s assume the additional difficulty of evaporating from saline cancels that gain out leaving us back at 4 million hectares equivalent fresh water evaporative surface. Using “Open water bodies in the Phoenix area evaporate at about 6.2 acre-feet per year (about two million gallons) per year for each acre of surface area.

We get:

2*10^6gal/acre;4000000hectares ? gallons
= 1.97684E+13 gallons

or about 20Tgal per year.

Estimating total US demand:

132gal/person/day;300Mperson ? gallon/year
= 1.4454E+13 gallon/year

or about 14Tgal per year.

The entire US requirement for fresh water can be approximately replaced with the desalinated water from the solar updraft towers.

(An objection to this combined use of the solar updraft tower is that the heat of vaporization lost during evaporation will translate into a lower temperature differential between ground and exhaust at the tower head. However, this ignores the recapture of that heat upon condensation—a phenomenon that drives powerful natural phenomena such as thunderheads.  The main problem is constructing an appropriate condensor at the top of the updraft tower.)

Each tower’s water output:

1.97684E+13 gallons/3800 ? gallons
= 5.20221E+09 gallons

and at a penny a gallon (remember this is high quality, nearly distilled, water):

1.97684E+13 gallons/3800;.01$/gallon ? $
= 5.20221E+07$

or about $50 million/year in water revenue. In all likelihood this would be much higher given markets for the distilled water could be found.

Salt is about $25/ton at the mine mouth.

And the ratio of sea water to salt mass is about 65:1 so the revenue from sea salt is:

25$/ton_salt;65ton/ton_salt;tonm/m^3;5.20221E+09 gallons ?
= 7.57404E+06 $

Or about $8 million/year in salt revenue. Perhaps this can be brought up by arranging radial evaporative ponds to fractionally crystallize higher value salts and accounting for the elimination of a return pipe for waste brine, but from salt value alone it seems barely worth the investment.

Now to live fish:

If the algae is 50% oil, and extraction of the oil isn’t total, we can conservatively assume the mass of oil-depleted algae will approximate the mass of biodiesel:

0.827 g/ml;3.5998E+07 gallon ? tonm
= 124223 tonm

Trophic losses in acquaculture algae grazers are about 1/3 and the price per kg of live fish at the producer is conservatively $2/kg:

124223 tonm*.67;2$/kg ?
= 1.51009E+08 $

Or about $150 million/year in wholesale live fish revenue. This is a really big deal! Its as much as the electricity, biodiesel, water and salt production combined!

Totaling up yearly revenues:

$150M for live fish
$ 70M for biodiesel
$ 50M for fresh water
$ 25M for electricity
$ 8M for salt

$303M TOTAL REVENUE

Discount 20% for operation costs ($60M) and the yearly profit available is $240M/year or $20M/month.

A profit stream of $20M/month at 6% interest over 30 years has a net present value of $3.5 billion.

This compares very favorably with the estimated construction cost of the reference tower of $500M to $700M, which, of course, will have to be increased to account for the addition of a condenser to the tower, pond construction, centrifugal algae harvesters, boidiesel equipment, aquaculture equipment and brine transport systems. Indeed, the construction estimate for the reference system can be quintupled and still be financially sound if the already moderate technical risks are reduced.

Thus we have a system that is potentially profitable in the early stages of deployment, and that provides self-sufficiency in terms of high quality protein and water, with industrialized-nation levels of energy in the form of electricity and biodiesel—all in an ecological footprint of 1/100 gha percapita.  The primary remaining barriers to providing a standard of living comparable to the current US level are in secondary nutrition sources such as produce (fruits, vegetables, etc.).  As it turns out, the waste product from fish processing is a high grade fish emulsion fertilizer for such produce, and can support high density hydroponic gardens grown in the aquatic recreation areas and even residential areas at the outer rim.  If this proves insufficient, the expanded ecological footprint to support a wider variety of produce is unlikely to more than double the total footprint, and we are still looking at a 1/50 gha percapita—resulting in the entire ecological footprint of the US population being something like the size of Florida (rather than half its size as is South Carolina).  Of course, this ignores the potential to let people harvest naturally occurring produce from the greatly expanded wilderness areas resulting from the contracting ecological footprint.  From a tourism and recreation standpoint it is precisely such wilderness areas that provide expanded opportunities for people to live-out hunter-gatherer behaviors that seems to drive so much of the tourism and recreation industry.

So the question is, why is civilization, headed by Davos Men—so furrowed of brow over global crises and all—incapable of building carrying capacity maximizing systems like this?

Tags:



Comments:


1

Posted by melba peachtoast on Tue, 01 May 2007 14:54 | #

Algy met a bear
The bear was bulgy
The bulge was Algy.


2

Posted by Desmond Jones on Wed, 02 May 2007 00:06 | #

How do you see this type of structure overcoming efficiency problems in high latitudes like the northen US or Canada? Are they not also much less efficient than CSPs or photovoltaic power plants?


3

Posted by Lurker on Wed, 02 May 2007 00:24 | #

Melba, loved your rhyme and will certainly use myself wherever possible but, from my deeply entrenched position over here on the far left of the bell curve, I find cant quite see the relevence to the topic under discussion.


4

Posted by James Bowery on Wed, 02 May 2007 00:38 | #

First, the primary point is that the powers that be—the guys who have the capital to make things like this happen and cannot bring themselves to do so—are telling us we must accept lower fertility because we’re so profligate in our ecological footprint and then turn around saying that we should be race replaced so as to keep our population high with immigration as the top priority—lowering natural resource consumption then gets lots of lip service.  In other words, they aren’t really concerned about anything but rationalizing their genocidal policies.

Second, don’t get hung up on energy generation.  Energy is only 1/3 of the value of these biospheres and that is monetary value alone.

Third, the reality is that even in climates with lower solar incidence, the primary energy generation comes from temperature differences.  <a href=“http://www.sciencedirect.com/science?_ob=ArticleURL&_udi=B6V50-4FHKC05-2&_user=10&_coverDate=11/30/2005&_rdoc=1&_fmt=&_orig=search&_sort=d&view=c&_acct=C000050221&_versi>Projected energy production in northern climates is only 15% lower than in more sunny climates</a>.  Moreover, the highest value, for humans, plant growth and animals, comes from warming within the greenhouse, so the most likely scenario is one in which low-grade geothermal sources heat the greenhouse—thereby giving rise to higher temperature differences.



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