The View From Les Houches: What is the origin of Collapse?

At the physics school of Les Houches, in March 2018, Gregoire Chambaz of the University of Lausanne gave a talk on the phenomenon of "collapse caused by diminishing returns of complexity." (The image above is not from Les Houches but from a meeting in Lausanne last year).

In itself, it is already interesting that a meeting of physicists gives space to the idea of societal collapse, but the school of Les Houches was one of the rare cases of a truly interdisciplinary meeting. The result was a wide variety of approaches, including the talk by Gregoire Chambaz who approached the problem examining the concept of "diminishing returns of complexity" proposed by Joseph Tainter already in 1988. You can find a summary (in French) of Chambaz's work at this link.

If you are a reader of this blog, you probably know Tainter's graphic to explain his concept. Here it is.

The idea is that, as societies become larger, they must develop more and more complex control systems in order to manage the whole system. These control systems may be in the form of bureaucracy, an imperial court, the army, the church, the legal system, and more. And, as these systems become larger, they become unwieldy, rigid, and unmanageable. The effort needed to increase their size is not matched by the benefit they provide. According to Tainter, this is the ultimate reason for the collapse of large societies.

As a model, Tainter's one has proved to be hugely popular and surely it is a "mind sized model," easy to understand and providing an immediate grasp of the evolution of the system. The problem is that Tainter's model has no evident basis in physics. There is no precise explanation of what would cause the behavior that Tainter proposes, not it is possible to measure concepts such as "the benefits of complexity." It is only a qualitative model.

Can we model this kind of collapse using physics? Perhaps. In principle, there could be two reasons why the system stops improving its performance as it grows in size. One could be an effect of entropy. If you work in a large organization, you understand how, over time, it becomes a tangle of contradictory rules and of people and offices which seem to exist only to prevent any work being done (OK, I have in mind the University of Florence, but I am sure it is not the only case in the world). But how to quantify this effect?

Then, the reason for this behavior could be another one. Maybe it is not an intrinsic property of a large system to lose efficiency as it grows, but an effect of the slow decline of the net energy that it uses. That would explain many things and I put together a tentative dynamic model a few years ago which seemed to work. We are working on improving it taking into account the dynamics of the Seneca Effect. It is a work we are doing together with my coworkers Sara and Ilaria, but it will take a little time before we publish it.

Overall, the impression I have is that we are starting to develop an extremely rich field of studies, that of critical phenomena in complex networks. Tainter gave us a first indication of the way to go, but there is much, much more to do before we can say we have a solid theory explaining the periodical collapse of civilizations we observe in history.  But we keep going.

The View from Les Houches: the Revenge of Lotka and Volterra

Les Houches, March 2018. Fatma Rostom of the University of Paris, shows the basis of her model of the energy transition. It is the good, old Lotka-Volterra model, also known as the "Predator-Prey" or the "Rabbits and Wolves" model. (the LV model, among friends)

Perhaps surprising, this model, presented first in the 1920s, is enjoying a new life today and it was mentioned in several talks. Long considered a toy for freshmen in biology, it turns out to be extremely rich in its capability of describing the stepped dissipation of thermodynamic potentials in a nonequilibrium system.

Dr. Rostom modified the model in order to take into account economic and monetary factors, but even the "raw" LV model can describe real-world phenomena. It was found to be at the basis of the Hubbert Curve (Bardi and Lavacchi, 2009) and it was recently shown to be able to describe the cycle of exploitation of fisheries (Perissi et al. 2017). And, of course, the model is at the basis of the dynamical interpretation of the "Seneca Effect"

The talk by Dr. Rostom was very good for several reasons, one for her emphasis on "mind-sized" models, a concept that I had introduced some years ago under the influence of Seymour Papert. In the current situation of confusion and even of despair, we badly need models that policymakers can understand if they have to act in a meaningful way

But, in the end, what results did Dr. Rostom reported. Well, not very optimistic ones, as you can see in this paper of hers and others

The View From Les Houches: Saving the World Using Physics

 Above, Carey King from the University of Austin, Texas, shows his Trump socks during his talk at the meeting of the School of Physics in Les Houches, France. I strongly suggest to read King's hugely interesting paper titled Information Theory to Assess Relations Between Energy and Structure of the U.S. Economy Over Time. You may find in it aswers to questions you have been asking yourself for a long time.

The School of Physics in Les Houches, France held a session on Energy Transitions during the week from March 4th to March 9, 2018. About 70 scientists, mostly physicists, gathered in a remote village in the French Alps to discuss the energy transition, the supply of mineral resources, and climate change.

It was one more attempt by scientists to save the world. Having been there, I can say that the task is difficult but this group managed to come up with several good ideas, some of which might even work.


In future posts, I'll try to summarize some of the talks at the school. For the time being, let me just thank the organizers for the good experience:


Hervé Bercegol
Marie Degremont
Zeynep Kahraman
Jacques Treiner