Poly-Awareness and the Year 1900

On the way to the year 1900, we encounter the comment, “In 1890 the stock exchanges of London, Paris, Berlin and New York controlled the economic progress of the whole world.” This marriage of geography and the financial world is very striking, culminating with:

The year 1900 was a wonderful one, when men were proud to be middle-class, and to be Europeans. The fate of the whole world was decided around green baize-covered tables in London, Paris or Berlin. Rubber trees from the Amazons were shipped to Malaya, the vast coal seams of the Upper Hwang-Ho were being exploited at the expense of the wretched labourers, and in the north of the Upper Vaal a mining city sprang up in a few short weeks. Mobilized by steam, the planet’s riches were being shifted ‘from one side of the world to the other’, to quote Le Bateau Ivre, on orders flashed by telegraph in two or three minutes. Decisions reached by boards of directors in London, Paris or Berlin affected the lives of millions of human beings who did not suspect that their right to happiness depended on quotations scribbled on blackboards in three noisy exchanges built like temples, in which raged the battles of unbridled financial ambition. Not a single detail escaped the notice of Europe’s financial capitals: they fixed the price of a tram ticket in Rio de Janeiro, and the working hours of a coolie in Hong Kong. So much power had never before been concentrated in so few hands within so small an area of the globe. It was the age of triumph of the European middle classes.

Charles Morazé, The Triumph of the Middle Classes: A Political and Social History of Europe in the Nineteenth CenturyAnchor Books, 1968, page ix.

Morazé adds the following sentence, “The Europe of 1900 knew nothing of the world catastrophes which were to come.” At the core of this is the rise of modern science and technology. Max Planck published the first paper that gave us quantum mechanics. David Hilbert, at the 1900 Paris conference of the International Congress of Mathematicians, presented a collection of 23 problems (later known as Hilbert’s problems). Mathematicians, including Grigori Perelman (famous for his contributions to Riemannian geometry), are still attempting to solve these problems.

Henry Adams, attending the Exposition Universelle (1900), observed the dynamo and wrote the chapter “The Dynamo and the Virgin” in his book The Education of Henry Adams. He thinks of the dynamos as a moral force, much as the early Christians felt the Cross.

Remember that in the world of 1900, in the background to all of this, we have the Boxer Rebellion in China, part of the Chinese century of humiliation (which angers them to this day).

The quest for meta-intelligent understanding (i.e., poly-awareness) involves comparing then and now and how they are connected.

Education and the “Knowability” Problem

There was a wonderful PBS Nature episode in 2006 called “The Queen of Trees” [full video, YouTube] which went into details about the survival strategy and rhythms and interactions with the environment of one tree in Africa and all the complexities this involves:

This Nature episode explores the evolution of a fig tree in Africa and its only pollinator, the fig wasp. This film takes us through a journey of intertwining relationships. It shows how the fig (queen) tree is life sustaining for an entire range of species, from plants, to insects, to other animals and even mammals. These other species are in turn life-sustaining to the fig tree itself. It could not survive without the interaction of all these different creatures and the various functions they perform. This is one of the single greatest documented (on video) examples of the wonders of our natural world; the intricacies involved for survival and ensuring the perpetual existence of species.

It shows us how fragile the balance is between survival and extinction.

One can begin to see that the tree/animal/bacteria/season/roots/climate interaction is highly complex and not quite fully understood to this day.

The fact that one tree yields new information every time we probe into it gives you a “meta” (i.e., meta-intelligent) clue that final theories of the cosmos and fully unified theories of physics will be elusive at best and unreachable at worst. If one can hardly pin down the workings of a single tree, does it sound plausible that “everything that is” from the electron to galaxy clusters to multiverses will be captured by an equation? The objective answer has to be: not particularly.

Think of the quest of the great unifiers like the great philosopherphysicist Hermann Weyl (died in 1955, like Einstein):

Since the 19th century, some physicists, notably Albert Einstein, have attempted to develop a single theoretical framework that can account for all the fundamental forces of nature–a unified field theory. Classical unified field theories are attempts to create a unified field theory based on classical physics. In particular, unification of gravitation and electromagnetism was actively pursued by several physicists and mathematicians in the years between the two World Wars. This work spurred the purely mathematical development of differential geometry.

Hermann Klaus Hugo Weyl (9 November, 1885 – 8 December, 1955) was a German mathematician, theoretical physicist and philosopher. Although much of his working life was spent in Zürich, Switzerland and then Princeton, New Jersey, he is associated with the University of Göttingen tradition of mathematics, represented by David Hilbert and Hermann Minkowski.

His research has had major significance for theoretical physics as well as purely mathematical disciplines including number theory. He was one of the most influential mathematicians of the twentieth century, and an important member of the Institute for Advanced Study during its early years.

Weyl published technical and some general works on space, time, matter, philosophy, logic, symmetry and the history of mathematics. He was one of the first to conceive of combining general relativity with the laws of electromagnetism. While no mathematician of his generation aspired to the “universalism” of Henri Poincaré or Hilbert, Weyl came as close as anyone.

Weyl is quoted as saying:

“I am bold enough to believe that the whole of physical phenomena may be derived from one single universal world-law of the greatest mathematical simplicity.”

(The Trouble with Physics, Lee Smolin, Houghton Mifflin Co., 2006, page 46)

This reminds one of Stephen Hawking’s credo that he repeated often and without wavering, that the rational human mind would soon understand “the mind of God.”

This WeylHawkingEinstein program of “knowing the mind of God” via a world-equation seems both extremely charming and beautiful, as a human quest, but potentially mono-maniacal à la Captain Ahab in Moby-Dick. The reason that only Ishmael survives the sinking of the ship, the Pequod, is that he has become non-monomaniacal and accepts the variegatedness of the world and thus achieves a more moderate view of human existence and its limits. “The Whiteness of the Whale” chapter in the novel gives you Melville’s sense (from 1851) of the unknowability of some final world-reality or world-theory or world-equation.