Wednesday, May 4, 2011

I believe in Renewable Energy, and here's why

Renewable energy (RE) is a subjective and divisive topic, one that is influenced by many factors, including corruption, greed and purposeful ignorance, scientific and technological advances, and simple entrepreneurial spirit vs. entrenched interests.

Here are some of the reasons that I believe that we will see RE replace old energy by the midpoint of this century:

* It has been estimated that an area 55 miles by 55 miles dedicated to current solar technologies could replace all the electrical generating power of coal and oil (in the US). Or an area 80x80 miles to replace oil, coal and natural gas. (Here in the US we have over 100,000 square miles of desert, so space isn’t a problem)

* Regarding storage technologies (1) for when the sun is down: consider the advances taking place in fuel cells, batteries (LI, redox flow batteries, and 1300-ton battery modules used for grid stabilization), flywheels, compressed air, ultracapacitors and the likelihood that we will also use battery powered vehicles as storage.

* Regarding “getting the power from the solar installation to the people” – consider advances in superconducting wire and other advanced materials which are very likely to enable cheap and efficient transmission of power from where ever it is generated to where ever it is needed.

* Rooftop and local solar: My solar powered home won’t have to worry about darkness; we’ll tap into the battery reserve, as will all rooftop solar installations. A small percentage of our overall use to be sure, but significant none the less.

And as for explicit subsidies: on a per-energy-unit basis, then yes, solar has received more subsidies than fossil fuels in the very recent past. However, on the amount that each of us taxpayers has spent in a recent five-year period, fossil fuels subsidies far exceed solar.

Estimates range: (2)

Coal subsidies = somewhere between $17B and $72B
Solar subsidies = somewhere between $500M and $5B

And let us not forget that coal subsidizes also include intangible (and often purposefully left out) costs for cleaning up the ecosystem, and the public health expenses associated with all of the damage that the mining and use of coal causes. (3)

In my opinion, at the end of the day it all boils down to two simple facts: 1) technological change is on a double exponential growth curve (4) and 2) simple entrepreneurial spirit.

While we certainly need to wean society off finite, dangerous, polluting resources like coal and oil, the earth can and may go to hell in a handbasket. However, I think that entrepreneurial spirit and the certain fact that there is a barrel of money to be made in renewable energy solutions suggests that we will see RE replace old energy by the midpoint of this century. (5)

(1) "Of the ten advanced energy storage technologies, eight have applications in storage for electric power utilities at some level of development, aiming to provide reliable, economic, and energy-efficient power back-up options." Technical Insights Analyst Miriam Nagel

A123 Systems currently sells 2MW to 200MW grid stabilization systems (battery systems). Being used for large-scale energy storage deployment to support wind and solar integration. Small in comparison to the overall needs, but just one of many rapidly improving technologies.

“If investments in the smart grid infrastructure continue, electric vehicles may become ubiquitous — both because of the economic and environmental sense they make for consumers, and because of the vast store of batteries that will be available to grid operators to balance out the intermittency of wind and solar resources.”

“There are several major studies and research showing how the United States could reach 100 percent renewable electricity by 2050. Over the next two decades, the continually rising costs of fossil fuels will make it prohibitive to continue burning them, so we’ll witness the overdue transition to a largely renewable system. Smart grid upgrades will feature two-way communication to consumer appliances, real-time pricing information, more efficient transmission infrastructure, and advanced battery and flywheel technologies to balance the inherent fluctuations of wind and solar resources.”

http://www.mnn.com/earth-matters/energy/blogs/quayle-hodek-a-young-ceo-running-with-the-wind?hpt=Sbin

(2) “What if solar got the same subsidies as coal?” (Oct 21, 2010)
http://cleantechnica.com/2010/10/21/what-if-solar-got-the-same-subsidies-as-coal/

Coal subsidies: The U.S. coal industry enjoyed subsidies of around $17 billion between 2002 and 2008, including tax credits for production of "nonconventional" fuels ($14.1 billion), tax breaks on coal royalties ($986 million), exploration, and development breaks ($342 million), according to a study by the Environmental Law Institute.

http://sierraclub.typepad.com/mrgreen/2010/03/does-the-coal-industry-get-subsidies.html

Solar and wind subsidies: So far, the government has handed out about $5.4 billion, according to the Energy Department.

http://money.cnn.com/2010/11/18/news/economy/renewable_energy_tax_credit/index.htm

(3) Very informative investigative article http://wonkroom.thinkprogress.org/2011/02/03/manchin-coal-subsidies/


(4) “Most long range forecasts of technical feasibility in future time periods dramatically underestimate the power of future technology because they are based on what I call the “intuitive linear” view of technological progress rather than the “historical exponential view.” To express this another way, it is not the case that we will experience a hundred years of progress in the twenty-first century; rather we will witness on the order of twenty thousand years of progress (at today’s rate of progress, that is).” Ray Kurzweil http://www.kurzweilai.net/the-law-of-accelerating-returns

(5) During the past 11 years, as the editor of the leading nanoscale technologies web portal, I read and posted over 50,000 articles about advanced and frequently mind-blowing technologies. I have closely followed the very rapid progress in our understanding and utilization of the unique properties of the nanoscale (which greatly differ from the properties that we already understand). At the very least, we are headed for a future that not one of us can predict; what we can predict is that we will undoubtedly see old myths about technologies shattered and changes beyond our current level of comprehension.

6 comments:

datarimlens said...

Thank you for your post and your efforts runing your blog.

Nobody can argue with "I believe in Renewable Energy", as a belief that everyone is entitled to. However, the "and here's why", I believe can be argued with:

1. That science/technology progresses faster than a linear imagined extrapolation. This should be separated into science and engineering. Science defines the framework in which engineering of applications takes place. Progress speed in one may not match the other. An example: no engineering can put the MeV of energy of a nuclear reaction into a chemical (outer shell electrons) one. Even in the case of potential LENR reactions the nucleus has to be involved to reach high energy.

2. Energy storage is crucial for the viability of renewables. Too often this is, while acknowledged, dismissed as an easy engineering exercise as in this article. Given the energy amounts to be stored over a duration several days at least, the required infrastructure is huge, non-existent even in planning form. Most viable appear huge mechanical or thermal storage devices but their efficiency is limited. For a picture: the equivalent 1GW of a nuclear reactor requires the equivalent of a fairly large mountain to be used for a mechanical storage device. You can calculate the numbers, e.g., for 2 days for yourself. This means that when efficiencies and availability factor (wind ~30%) are included, you need to install double or triple the capacity you have for high availability sources. Some of these factors will not go away with any amount of engineering.
Some energy limits set for energy storage can be found here:
http://en.wikipedia.org/wiki/Energy_density

3. Maintenance: the fairly low energy density in case of wind and solar results in a relatively large bulk of the energy generation infrastructure. In turn this leads to a fairly large expenditure for construction and maintenance, often also neglected.

4. Cars:
electric/grid storage: what is more energy efficient, a 1-2 l/100km light fuel-based car or a heavy battery-driven car that has to transport a fairly large and bulky battery mass? How can moving around a low energy/high mass battery be more efficient overall? If, e.g., liquid fuel is created in a renewable fashion by algae or cellulose, how can it not beat the car based grid storage in efficiency?

hydrogen: Does a 700bar hydrogen tank make you feel good in your vehicle? That is proposed to match volume energy density of liquid fuels. Engineering does not improve hydrogen energy density by volume. What happens in an accident? Why do people still propose it?
5. Solar energy: It is a very thin source of energy to start with. It loses a typical factor 5 between orbit and ground, due to atmosphere, day/night cycles, latitude, etc. Even if the efficiency of the engineering ekes out 50 or 60% of the solar spectral energy, it would be a thin source, which requires a vast and vulnerable infrastructure to produce reasonable energy amounts.


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Remaining questions then are:
Why not put things in numbers, such as levelized energy costs, full up comparisons, apples to apples. For example:
- did your rooftop solar pay for itself? How long will it take when compared to the electricity price at your place? Does that factor in the pollution/waste by special materials in your solar cells and their production?
- how long can you store energy in flywheels, even if they are CNT based? What is the engineering limit? Currently batteris and flywheels are only used for stabilization as you write, not for multi-day storage. Why is that? What are the top three limitations?
- what are tradeoffs between storing energy in a car and driving it around vs. building a highly efficient car that carries as little fuel if possible? Bicycles, trikes, or Acabions anyone?

Full up comparisons are not popular because they are hard and have their limitations. But they can be critiqued and improved on in the best Kennedyesque effort to tackle the hard problems.

Anonymous said...

Hi - I am definitely delighted to discover this. great job!

Anonymous said...

Really good post!

Press Release Submission said...

What a lovely post, You are really a deep thinker and I am glad to see I am not the only one paying attention at this topic.

nano said...

I also love the renewable energy. The big problems on world of Global Warming could be reduced by cutting the use of coals , petrol and diesel. We should more use of electricity in our daily needs and this electricity should be come from the the solar energy systems. We should develop new energy sources with the help of nanotechnology related parts as nanoparticles and more.

Anonymous said...

Such a small think. ;-) But such a great idea