Architectural Fermentation and the Evolution of Cities

One of the most heartbreaking things about living in Los Angeles is how routinely architectural gems are demolished without warning.  In April of this year, the Architects Newspaper reported that the Brentwood home of William Krisel, the iconic mid-century architect of as many as 40,000 dwelling units across Southern California, was being razed.  This would be a huge story almost anywhere except for the fact that it happens so often here, people have be come inured to it.  Perhaps LA is just too vast, with too many potential travesties for anyone to keep track of, let alone care about; still the end result is that the city is diminished in a small but real way each time this happens.

How do we deal with the anxiety over the changing city?  Thinking about it through the lens of Urban Successionism was a good start for me: viewing the city as formed through a natural process – but instead of evolving as a forest does in response to changes in ecological conditions, the city adapts to a shifting economic environment, growing in bursts of development, characterized by the architectural styles popular at the time, with all the stages of succession in ecosystems: the arrival of propagates, a sequence of dominant species, the fugitive equilibria, as well as the traumas and how the systems react to them.  Just as a forest contains within it a record of its growth and development, a city takes shape as an archive of successive economies. 

Considering the city in this way at first did bring some relief to my anxiety, but it did not cure it completely – urban successionism misses the fine grain of what happens between economic expansions, between those styles that define an era.  In Los Angeles, for instance, it does not account for the work of Schindler or Neutra, or the great textile-block houses of Frank Lloyd Wright or his son Lloyd Wright, or even the more recent work of Eric Owen Moss, Morphosis or Frank Gehry, all of whom are important, even canonical, to architects, yet have scant representation across the built landscape of the Southland.

Urban Successionism is inherently retrospective and thus insufficient in apprehending the evolution of a city as it happens.   A closer, more sustained look reveals that cities evolve not in a series of large movements but in small, incremental ones –in fact, very small: it turns out that a city evolves building by building.  Each project, no matter how seemingly insignificant, changes the city just a little. Furthermore, each building is the product of a specific interaction of particular individuals, a negotiation that bears imprint of each participant, and thus is a unique response to economic, social, or programmatic imbalance perceived by each of those individuals.

I call this process Architectural Fermentation. 

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The term came as a sort of epiphany following the convergence of three events: I was beginning the construction phase on a house in the Silverlake neighborhood in Los Angeles with an engaged client who started the project with an unusual request: if I wanted to be his architect I had to watch the HBO series True Blood.  At the same time I was taking an online winemaking class through UC Davis. I was reading about stuck fermentations – what happens when things don’t go quite as planned – when I came upon a phrase credited to noted oenoligist Hans Lüthi who, in his 1957 article, Symbiotic problems related to bacterial deterioration of wines, described all fermentation – good and bad – as a “succession of microbial onslaughts.” 

So there I was, fast-forwarding through part of a True Blood episode I had already seen, when it hit me:  sped up, the scenes appeared to be similar to what Lüthi described – a succession of interactions between two or more agents that together formed a story arc and resulting in some sort of resolution at the end of each show.   Like making wine, but at a scale virtually invisible to us: our own. 

That’s when I began to look more closely at the process behind my Silverlake project: how the interaction between the client and the architect could be thought of as the primary fermentation, the product of which – after 72 iterations in this case – was the design; which was then filtered through the building department; which was followed by the interaction of the client and contractor through construction, AKA the secondary fermentation; which was followed by the punch list and final sign-off from the building department before the structure could be occupied.  With a little creative license, the process seemed to mirror that of making a bottle of wine. 

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Emboldened by this epiphany I turned to science to back me up.  As one might imagine, there is nothing on architectural fermentation; but there is plenty of literature on the evolution of systems. 

Jumping off from Hans Lüthi’s observation on microbial activity, I turned to the late evolutionary biologist Lynn Margulis who, in her book Acquiring Genomes echoes the translation of Lord Kelvin’s second law of thermodynamics from physics to biology to be reread as “Nature abhors a gradient.”  She applies this law to systems both living and non-living, at all scales, even to the point of talking about the myth of the individual, that all organisms are systems of systems in a flexible hierarchy occurring at all scales at all times time, each of which is concerned primarily with overcoming any gradient it perceives.  “we must begin thinking of organisms as communities,” she writes, ”and communities are ecological entities.”  She goes on to say, “As natural selection filters out the many to preserve the remaining few, those few ever more efficiently use environmental energy to ‘purposefully’ (her quotes) reduce their gradients.”

The importance of gradients is also emphasized by Nick Lane in his book, Life Ascending. In that volume he explain the work of Mike Russell, the iconoclastic scientist currently at Cal Tech’s Jet Propulsion Laboratory in Pasadena, California, in particular his study of the sea vents in Tynagh, Ireland.  The argument is long and complicated, but seems to boil down to this: “bubbling alkaline fluids into acidic oceans produced a natural proton gradient” between carbon dioxide and hydrogen that, through chemiosmosis, created organic molecules as well as ATP, and eventually proteins and DNA, the building blocks of life itself.

Lane is convinced that if Russell and his colleagues are correct—and he thinks they are – that all life proceeds from such a gradient or imbalance; more, he contends that contrary to the conventional understanding of entropy, equilibrium is never achieved.  Instead, persistent imbalance is what fuels interactions in all systems, both living and non-living.

DNA, while remarkably good at replicating itself, does produce enough variation, generation by generation, to give evolution options when faced with imbalance.  Thus a species evolves one mutation at a time, an iterative process that, like imbalance itself, is never ending.  But does this apply non-living systems as well?

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In a recent article in the Science Times section of The New York Times, George Johnson wrote an article, Creation, in the Eye of the Beholder, in which he states, “the brains and hands that design civilizations artifacts are products of the same evolutionary algorithm – random generation and testing” that drives evolution itself.

This is algorithm is especially evident in the field of entrepreneurial innovation.  In The Innovator’s Dilemma, Clayton Christiansen talks at great length about how successful companies inevitably outgrow their capacity to adapt to the market and thus become vulnerable to “disruptive technologies” that almost always deliver a less expensive product that targets a market need more simply and precisely.  So, just as in natural systems, evolution of the man-made operates through survival of the fittest.

But how do these disruptive technologies come about?  What is the process through which they are developed?  MIT professor Eugene Fitzgerald, with colleagues Andreas Wankerl and Carl Schramm outline a very specific process that they feel delivers innovation most efficiently.  In their book, Inside Real Innovation, they distinguish between “incremental innovation” and “fundamental innovation,” the former being more adaptive and the latter being more revolutionary.  Focusing on fundamental innovation, they identify a team made up of individuals – not groups – that must be in constant interaction for a true breakthrough to occur, each individual representing three different points of view and thus bring their expertise to bear: technology, market, and implementation.

The person representing technology is most often an inventor of a new product or process that addresses a perceived imbalance and may or may not have an application; the person who represents the market is someone who understands what will work in the marketplace and how the technology might be embraced by the public at some point in the future; the person representing implementation is the one who knows how to connect the technology to the market, how to make the invention functional, and how to deliver it to the market.

What is compelling is how much importance is stressed on these three people interacting.  It is a long, often 15-year process to bring a technology to market, and that time is spent creating iteration after iteration then subjecting them to the critique of each member of the team.  Only if a product or process can survive this relentless gauntlet of judgment will it ever see the light of day.

The key they stress is that for the interaction to really work, each of the three team members must have some experience of the other two points of view.  It can never be a productive interaction if one member is unable to compromise due to an inability to comprehend what the others are saying.  That said, the other key is that all of the team members have strongly-held opinions and that they must fight for them.

Would the same sort of interaction work for architecture?  What if every building project underwent a prolonged and heated interaction between the architect – who understands the technological side; the developer – who initiates the project due to a perceived imbalance in the market; and the contractor – who understands how to implement the architect’s ideas and deliver the building to the developer?  Wouldn’t that create better buildings?  Let the opinions fly if it improves cities just a little bit!  Instead, most buildings are the byproduct of stuck fermentations caused by a lack understanding, communication – and respect – between these three team members. 

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Simply knowing that a city evolves one project at a time through this complex interaction does not really relieve the anxiety of the changing city or guarantee that a corner of town will be improved by a particular project.  However, one would hope that having this knowledge would motivate all participants make any project the best it can possibly be.  But the imbalance we perceive as architects and urban designers may not be the imbalance perceived by contractors or developers; they still are compelled to address their own concerns.  Thus, it is incumbent upon us to own the imbalances we see, to have a clear opinion of how to fix them, and to fight to the bitter end to ensure we prevail.