Engineering a Solution to Global Warming

24 Replies Jonny Hankins

Most scientists agree that the Earth is warming, whether due to the effects of human habitation and lifestyle or as part of a cycle that is as natural as the rotation of the Earth itself. Whatever the cause it looks as if sea levels are going to continue to rise, weather patterns are changing and this is going to cause serious problems for millions of people across the globe. But what can be done about it?

Firstly I should define the terms used both here and elsewhere a little better. Climate Change and Global Warming are the two main terms we hear in both the scientific and popular press. They are not however interchangeable. Climate change represents changes in the climate (obviously), increased or decreased rainfall for example as well as temperature change, but from a geographical point of view. Global warming specifically represents the increase in the Earth’s surface temperature in general as provoked by the increase in so called ‘greenhouse gas’ emissions, it is not geographical but global. This article on the NASA website describes the development of the terminology.

Global warming is therefore the tricky term. Recently however a group of scientists that included global warming skeptics agreed that the planet is in fact warming, although there is still some debate as to why. The results were a surprise as the research was carried out by a long time global warming skeptic at the University of Berkley, and reported to Congress last year. Read the article in the Los Angeles Times.

Those scientists that have accepted the definition of the problem have offered various engineering solutions to the problem, some seem a little absurd and others foolishly simple, so I would like to have a look at a few of them.

The following describes the problem of the ‘greenhouse effect’ that is believed to cause global warming, and the two main variables that could be manipulated, heat coming in and heat leaving the atmosphere.

Major variables in the ‘greenhouse effect’

Those in the know call it Geo-engineering, and its intentions and goals can be grouped into 2 basic classes, carbon dioxide removal techniques and solar radiation management techniques. The first involves the removal of carbon dioxide from the atmosphere through means such as ocean fertilization, changes in land use, afforestation, bio-energy, enhanced weathering and direct mechanical air capture techniques. This should let more heat out. The second involves surface albedo, cloud enhancement, stratospheric aerosol and space based methods. The first addresses the perceived cause of the problem, carbon and other pollutants in the atmosphere, while the second attempts to alleviate the problem by reflecting some of the heat from the sun back into space.

In terms of removing the carbon dioxide from the atmosphere they have a couple of large scale proposals, either land or sea based. Land based involve the obvious stuff like reforestation and stopping deforestation, also enhanced weathering techniques that involve spreading minerals on agricultural land to help the earth absorb the carbon as it is washed down by the rain, but also some interesting large scale engineering projects. One is to build lots of huge carbon alkali filters, probably above disused mines or in a desert somewhere and filter out the carbon as the air passes through them, before storing it in the chambers left by the mining. This technique is touted as interesting because the facilities can be built anywhere, and so cheap unpopulated zones can be used.

Ocean fertilization is another option being looked into, the oceans are fertilized with algae that soak up the carbon and sink down into the sea where the water then breaks it down. From a personal point of view I think the possibility of forever changing the oceans’ ecosystem is clear for all to see however (there is also a possibility that the volume of the seas might expand, not a desired side effect by any stretch of the imagination).

The second options are more interesting, they involve reflecting the sun’s rays back before they arrive, or reflecting more as they hit the Earth.

I like the simple ideas. Seeing as black soaks in more heat and white reflects it back into space, painting all rooves white and making all the roads white would do a great deal. As would growing light coloured plants in large numbers. Suggestions include planting huge areas of light coulored trees, a doubly productive approach. These ideas seem more reasonable to me as at least they can be managed relatively easily, something that cannot be said for ocean fertilization or some of the following suggestions.

One of which is to disperse millions of tiny pieces of reflective paper into the outer atmosphere so that less sun physically arrives. This seems a bit risky to me though as you can’t get rid of them once they are up there and the effect may be disastrous for some regions that could experience dramatic weather changes. Irreversibility is a big no as far as I am concerned, as is complete lack of control. In the event of the Earth starting to cool how could you get them down?

Artificial cloud production or whitening is also on the table, but also has the problem of control, you cannot determine where the clouds will go, and their very existence in one area can have huge impacts on others. If it rains too much in one place it may well cause drought in others. Stratospheric aerosol use poses similar risks and problems.  Placing huge seas of mirrors in the desert to reflect the sun back up seems a bit less risky to me, maybe they could even produce some electricity while they were at it!

The solutions above do not address the problem of carbon emissions, and many seem to be rather haphazard operations. Many of them will be outside human control even during testing operations, and I can’t help but feel that they are talking about point of no return.

If you were wondering, I promise you that I did not make any of this stuff up, and if you would like to read an in depth report about the proposals outlined above you can download one here from the Royal Society of Engineering for free. More of my writing on this subject as well as many related issues can be found as ever on the Bassetti Foundation website.

If anybody else has any ideas I would love to hear them. Next week I look at the Holy Grail, pollution free, cost free energy, patented, on sale, and for you to behold from the comfort of your own computer.

Are you doing your bit for the blog?

17 Replies Christopher Roberts

Yesterday Jonny, one of our authors, emailed me to let me know about the post he had written on the site he writes for (the Bassetti Foundation) where he wrote about the community awards he picked up, praised the blog and talked about and linked to the posts he has written for us.

Jonny asked that I promoted the idea of the community a little bit more through an article, which is exactly what I am going to do!

It is time for the poster again 😉

Technology Bloggers needs your help!The idea of a community blog is that everyone benefits. It’s in our slogan:

“Read | Contribute | Benefit
A whole community of technology bloggers”

The three keywords there are contribute, benefit and community. We are a community blog, designed in such a way that everyone is able to benefit.

If everyone is helping to improve the blog, the better the blog is, therefore the more we all benefit. Basically the more we all put in the more we all get out.

I really do try hard with this blog, I give it my all, and I feel that if we all did a tiny bit more (like Jonny has) we could make this blog so much better – and it is already really good! A better blog means more benefit for all!

Let me explain.

PageRank

If all of our readers, writers and commenters (I know some of you are all three!) were to write a post like Jonny’s, more PageRank/link juice would be flowing into the blog. This would increase the blogs PageRank overall – not that a high PageRank is anything to really fantasise about.

If the blog is of a higher PageRank, more flows back to all those commenters and writers who have links on the blog, therefore they get an increase in PageRank too – a benefit directly derived from Technology Bloggers.

Traffic

PageRank is maybe not the best of examples, so let me give you another example, using traffic. If you write about the blog, include it in your bio, tweet about it, post about it on Facebook and generally share it via all your social internet channels, then the blog’s traffic will increase.

More people (traffic) means more people reading the content, more people commenting, a bigger, better and stronger community, more opportunities, more articles etc. it also means that for those writers who are adding AdSense to their posts (like Alan) the chance of making more money increases.

More people means more articles getting read, so writers are getting better exposure/greater publicity. Commenters links are more likely to be followed etc.

Brand

Having a bigger, better blog and community, make Technology Bloggers a stronger brand. This means that your association with the blog is a greater benefit for you. Saying you are a writer for TechCrunch brings you a lot of credibility, due to your association with the strong brand, we can make Technology Bloggers like that too!

The bigger we get, the more everyone involved gets out of the blog!

You

So what can you do to help your blog? The answer? Help us by promoting the blog further. We have a great community here, loads of fantastic writers, writing brilliant content daily, so what we really want to do now is expand, and to do that, we need to help more people find out about us.

Why not tweet if you read an interesting article here, also, if you can +1 it, share it via Facebook etc. please do!

Why not tweet or post a comment like:
I am part of the great dofollow community over at Technology Bloggers (www.technologybloggers.org) why don’t you come and join me?
or how about
Why not check out the great dofollow community over at Technology Bloggers – www.technologybloggers.org?

Like us on Facebook, follow us on Twitter, share our articles!

If you are a blogger why not add us to your blogroll, or page of favourite sites? Why not add a link to us into your bio? You could even write a post like Jonny has done.

Here are some images you could add to your blog, or post via social media to help promote us:
Technology Bloggers - A Dofollow Community Blog a smaller version – more are available, just contact me 🙂Technology Bloggers - A Dofollow Community Blogshow off that you are part of the community!
I Am Part Of The Technology Bloggers Dofollow Community! www.TechnologyBloggers.orgIf I was a normal blogger, that might have seemed like a very needy plea for help to improve our traffic (which is already very respectable) however I am not, I am a member of a community blog. That is the difference, I am doing this on your behalf. You reading this are going to benefit (hopefully!) from this article, through the communities (that includes you!) response.

What are you going to do to help the blog? Let us all know below! If we get enough people writing about what they have done, I might write a post promoting those people!

Technology Bloggers – a community blog from which we can all benefit!

Nanobots – The future in Nanotechnology

5 Replies Hayley

This is Technology Bloggers 150th article 🙂
Well done and thank you to all our brilliant writers (Hayley included), as well as readers and commenters who have helped us get here!

A fraction of the ever-expanding field of nano-technology, nano-robots, a.k.a. nanobots, hold some of the most promising possibilities in the fields of technology, engineering and medicine. They also pose some of the most complex hurdles, such as automation, replication, control and finding viable energy sources to enable movement.

The Nano-Scale

Nanotechnology involves the study and micromanipulation of anatomic particles up to 1 nanometer, with scientists working to develop nanobots in fields less than 100 nanometers in size. Transmission electron (TEM), scanning electron (SEM), scanning tunneling (STM) and Atomic Force (ATM) microscopes are large, powerful machines that make all aspects of nanotechnology, including nano-robotics, possible.

Nano-microscopes allow researchers to isolate and observe single molecules, including chemical reactions that occur upon moving, eliminating and rearranging molecular structures. This base knowledge is essential to understanding, creating and ultimately finding solutions so that nanobot technology will reach its full potential.

Bottoms Up

Up until recent years, the development of nanotechnologies maintained “top-down” construction. The advent of “bottom up” creations on the nano-scale provide scientists the ability to create smaller objects; in addition, components can be “grown” to allow greater adaptation to specific environments or inclusion of specific properties.

Scientists are literally able to “grow” carbon nanotubes and “string” together nanowires, creating desired properties such as hastening conduction or reducing heat output – properties that make for tiny, efficient particles. In theory, by building a nanobot from the bottom up, scientists begin to find solutions that allow for greater control mechanisms and possibly self-replication of the nanobot.

A carbon nanotube

Carbon nanotubes – building nanotechnology from the bottom up.

The greatest benefit of working bottom-up is that, rather than altering materials to work in a desired fashion, scientists build nanostructures and nanobots with proper compounds from the outset.

The Present

Although practical applications in medicine and technology have yet to be fully realized, nanobots are no longer figments of science-fiction imagination.

Lack of autonomy, largely associated with insufficient or unrealistic sources of energy, leaves a large barrier to the potential uses of nanobots. Batteries and solar sources are impractical due to size and, although a scientist can guide the nanobot with the use of magnets, they are not ideal. For example, a physician using a nanobot to treat a patient would need to maneuver the nanobot from outside the skin while also observing inner structures of the body.

Within the past year, scientists announced the creation of a nano “electric motor.” Utilizing principles of adsorption, a molecule attaches itself to the outside of a piece of copper; an STM probe focuses electrons onto the molecule, providing a source of energy and means to control direction. The large, cumbersome STM still makes this impractical in many ways; however, scientists are able to study this single motor and hypothesize ways to alter this and thus to apply it to nanobots.

In addition, micromanipulation made possible by electron microscopes allows for “DNA-walkers.” Essentially reprogramming a portion of a DNA strand, “molecular robots” or “spiders” walk autonomously; ultimately, scientists hope to further develop this technology, creating nanobots that fix genetic diseases.

The Future

Many scientists believe self-replication, most likely by programming the nanobot to micromanipulate surrounding atoms to create duplicates of its self, is essential to the realization of the many medical and technological applications.

In addition, a truly autonomous nanobot would be able to recognize, react and/or adjust to varying environmental conditions, including the presence of other nanobots; scientist could also program them for molecular assembly.

Many believe nanobots will allow for precise diagnostic capability and treatment of diseases such as cancer, as well as genetic disorders. Advances in communications, green energy, computer electronics and semi-conductors appear limitless.

Summary

Although still in its infancy, scientists across many fields hold much promise for nanobot technology. An autonomous nanobot, able to adapt its environment and self-replicate, could be the key to early detection and the cure of many diseases; in addition, nanobots will play an important role in sustainable or renewable energy sources, engineering and advancing computer technology. What do you think?

For further information check out the article on nanobots over at MicroscopeMaster. Links in my bio.