Rachel Armstrong  [  TED Oxford ] All buildings today have something in common. They’re made using Victorian technologies. This involves blueprints, industrial manufacturing and construction using teams of workers. All of this effort results in an inert object. And that means that there is a one-way transfer of energy from our environment into our homes and cities. This is not sustainable. I believe that the only way that it is possible for us to construct genuinely sustainable homes and cities is by connecting them to nature, not insulating them from it.

Now, in order to do this, we need the right kind of language.  Living systems are in constant conversation with the natural world , through sets of  chemical reactions called metabolism . And this is the conversion of one group of substances into another, either through the production or the absorption of energy. And this is the way in which living materials make the most of their local resources in a sustainable way. So, I’m interested in the use of metabolic materials for the practice of architecture. But they don’t exist. So I’m having to make them.

I’m working with architect  Neil Spiller at the Bartlett School of Architecture , and we’re collaborating with international scientists in order to generate these new materials from a bottom up approach. That means we’re generating them from scratch. One of our collaborators is  chemist Martin Hanczyc, and he’s really interested in the transition from inert to living matter . Now, that’s exactly the kind of process that I’m interested in, when we’re thinking about sustainable materials.

So, Martin, he works with a system called the  protocell . Now all this is — and it’s magic — is a little fatty bag. And it’s got a  chemical battery  in it. And it has  no DNA . This little bag is able to conduct itself in a way that can only be described as living. It is able to move around its environment. It can follow chemical gradients. It can undergo complex reactions, some of which are happily architectural. So here we are. These are protocells, patterning their environment. We don’t know how they do that yet. Here, this is a protocell, and it’s  vigorously shedding this skin . Now, this looks like a chemical kind of birth. This is a violent process.

Here, we’ve got a protocell to extract carbon dioxide out of the atmosphere and turn it into carbonate. And that’s the shell around that globular fat. They are quite brittle. So you’ve only got a part of one there. So what we’re trying to do is, we’re trying to push these technologies towards creating bottom-up construction approaches for architecture, which contrast the current, Victorian, top-down methods which impose structure upon matter. That can’t be  energetically sensible .

So, bottom-up materials actually exist today. They’ve been in use, in architecture, since ancient times. If you walk around the city of Oxford, where we are today, and have a look at the brickwork, which I’ve enjoyed doing in the last couple of days, you’ll actually see that a lot of it is made of limestone. And if you look even closer, you’ll see, in that limestone, there are little shells and little skeletons that are piled upon each other. And then they are fossilized over millions of years.

Now a block of limestone, in itself, isn’t particularly that interesting. It looks beautiful. But imagine what the properties of this limestone block might be  if the surfaces were actually in conversation with the atmosphere . Maybe they could extract carbon dioxide. Would it give this block of limestone new properties? Well, most likely it would. It might be able to grow. It might be able to  self-repair , and even respond to dramatic changes in the immediate environment.

So, architects are never happy with just one block of an interesting material. They think big. Okay? So when we think about  scaling up metabolic materials , we can start thinking about  ecological interventions  like repair of atolls, or reclamation of parts of a city that are damaged by water. So, one of these examples would of course be the historic city of Venice. Now, Venice, as you know, has a tempestuous relationship with the sea, and is  built upon wooden piles . So we’ve devised a way by which it may be possible for the protocell technology that we’re working with to sustainably reclaim Venice. And architect Christian Kerrigan has come up with a series of designs that show us how it may be possible to actually  grow a limestone reef underneath the city .

So, here is the technology we have today. This is our protocell technology, effectively making a shell, like its limestone forefathers, and depositing it in a very complex environment, against natural materials. We’re looking at  crystal lattices  to seed the bonding process in this. Now, this is the very interesting part. We don’t just want limestone dumped everywhere in all the pretty canals. What we need it to do is to be  creatively crafted around  the wooden piles.

So, you can see from these diagrams that  the protocell is actually moving away from the light, toward the dark foundations . We’ve observed this in the laboratory. The protocells can actually move away from the light. They can actually also move towards the light. You have to just  choose your species . So that these don’t just exist as one entity, we kind of  chemically engineer  them. And so here the protocells are depositing their limestone very specifically, around the foundations of Venice, effectively petrifying it.

Now, this isn’t going to happen tomorrow. It’s going to take a while. It’s going to take years of tuning and monitoring this technology in order for us to become ready to  test it out in a case-by-case basis on the most damaged and stressed buildings within the city of Venice . But gradually, as the buildings are repaired, we will see the accretion of a limestone reef beneath the city. An accretion itself is a  huge sink of carbon dioxide . Also it will attract the  local marine ecology , who will find their own ecological niches within this architecture.

So, this is really interesting. Now we have an architecture that connects a city to the natural world in a very direct and immediate way. But perhaps the most exciting thing about it is that the driver of this technology is available everywhere. This is  terrestrial chemistry . We’ve all got it, which means that this technology is just as appropriate for developing countries as it is for First World countries. So, in summary, I’m generating metabolic materials as a counterpoise to Victorian technologies, and building architectures from a bottom-up approach.

Secondly, these metabolic materials have some of the properties of living systems, which means they can perform in similar ways. They can expect to have a lot of forms and functions within the practice of architecture. And finally, an observer in the future marveling at a beautiful structure in the environment may find it almost  impossible to tell whether this structure has been created by a natural process or an artificial one .

Thank you.


FEATURED IMAGE CREDIT: Fougerouse Arnaud

 

4 thoughts on “Saving Venice

  • 12/10/2013 at 22:23
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    Venice flood barriers pass first test
    Barriers designed to protect the Italian city of Venice from flooding during high tides have been successfully tested for the first time.

    Four large floodgates rose out of the water creating a temporary sea barrier.

    Once completed, 78 mobile flood barriers will be raised from the seabed to shut off the lagoon in the event of rising sea levels and winter storms.

    The city suffers flooding on a yearly basis. In 1966, 80% of the city was flooded by high tides.

    Reply
  • 02/08/2016 at 06:13
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    Rachel Armstrong, Professor of Experimental Architecture at Newcastle University, UK, SO ROCKS!!!

    As we speak, she is coordinating a $3.6-million interdisciplinary project to develop “living bricks”  that fit together to create ‘bioreactor walls’.

    BIOREACTOR WALLS

    Inside each brick is a Microbial Fuel Cell which is filled with Synthetic Microorganisms that can be programmed to

    1. purify water

    2. reclaim phosphate from the air

    3. generate electricity, and

    4. create detergents.

    They are robotically activated and digitally coordinated.

    Reply

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