There are philosophers of biology and physics, but surely philosophy and chemistry are worlds apart? Think again, says Lila Guterman
IT'S EARLY August and a small group of men and women from many countries gather in a classroom, tucked away in a quiet courtyard at Cambridge University. With the students on holiday, conferences like this are an everyday event at the university. But as the day progresses, things begin to look distinctly odd.
Most of the speakers are chemists, and while they are all talking science, they present no data. Instead of complex equations, their talks are dotted with terms like "fuzzy reasoning", "ontology", and "postmodernism". At one point, delegates even discuss the importance of tissues for wiping runny noses.
But this small gathering—the second meeting of the International Society for the Philosophy of Chemistry—represents the tentative beginnings of a new field. The 15 chemists and philosophers present are looking hard at the much-neglected philosophical underbelly of chemistry for anything from grand theories of matter to useful metaphors derived from the everyday work of chemists toiling in the lab over complex instruments and reactions. And so far, it's all looking very interesting.
The subject certainly offers uncharted waters to philosophers. While quantum mechanics and natural selection have given philosophers of physics and biology much food for thought, few philosophers have explored what chemistry has to offer. "It's interesting and puzzling why we have a philosophy of physics and a philosophy of biology but there's no philosophy of chemistry," says Davis Baird, a philosopher at the University of South Carolina in Columbia.
So does chemistry have any similarly grand theories on which to build a philosophy of chemistry? Until recently, many philosophers have simply overlooked the field, maybe by accepting the well-worn view that chemistry is nothing more than applied physics. This "physics imperialism" claims that anything—a chemical reaction, an orchid, an erupting volcano, a telephone conversation—can be completely explained by the fundamental laws of physics. But this reductionist approach is not always successful, says Eric Scerri, a chemist at Purdue University in West Lafayette, Indiana, and a strong campaigner for the philosophy of chemistry. In particular, he argues, important facets of chemistry have not been explained by quantum mechanics—a fact that many philosophers overlook (see "Wrong filling").
Scerri has published numerous papers on the problems of reduction in both chemical and philosophical journals and is the editor of a new journal called Foundations of Chemistry due to be launched early next year. And his campaign to put the philosophy of chemistry firmly on the map is gaining momentum.
A growing number of people have begun to consider chemistry from a philosophical viewpoint. More than 250 people have now joined an Internet mailing list dedicated to discussions on the philosophy of chemistry. And Baird suspects the group of dedicated researchers—as well as the mailing list—will grow. "There's a whole pile of interesting science and history of science that has been unexplored from the philosophical point of view," he says.
Like Scerri, Baird draws philosophical inspiration from chemistry. Baird is studying what chemistry can reveal about our understanding of the nature of matter by looking at how chemists build and use scientific instruments like lasers, detectors and spectrometers.
Philosophers are interested in the nature and status of the human belief systems and truth claims that are put forward to describe the material world. Some philosophers regard the world as being governed by laws: everything in the world, be it a tennis match, an autumn leaf or this magazine, is simply an expression of laws. For them a scientific instrument is nothing more than a magnifying glass which helps researchers to read the "law book" and weigh those laws against each other.
While Baird respects this view of reality, he thinks this way of working is an oversimplification. Viewing instruments as nothing more than information producers ignores the material nature of the world: he believes that theories and information are no substitute for real objects—things that have size, mass and shape. Ignore these, and you miss the wider picture—what Baird describes as "the thinginess of things".
As an example, during his talk at the Cambridge meeting he displays an image of a tissue and raises the problem of a runny nose. "When you need a Kleenex, information about it simply won't do," says Baird. Having a thorough understanding of the tissue's shape, structure and size won't solve the problem in hand. "You need a physical thing," he says.
And instruments themselves express our knowledge of the way the world works in a way that no single theory ever could. Before a chemist can use a scientific instrument, someone must design and build it using their knowledge of the Universe and its laws of physics, chemistry, optics and electronics. So scientists express their knowledge of the world in a variety of different ways: not just through theories such as quantum mechanics, but also through objects such as scientific instruments.
Baird believes chemists understand their instruments intuitively and don't use them merely as "conduits" for information. Unlike theoretical physicists, they work in the "real " world, which is made up of messy bunches of buzzing molecules in different states—hot and cold, big and small, solid and liquid. Chemists must coax their results from within this white noise of statistical errors. The very nature of the material world is built into their instruments. Philosophers of science who consider only the laws of physics to be worth studying could learn a good lesson from them, he says.
But how can one define, or even describe, what constitutes a material thing? Where is the boundary between a Kleenex and a theory? And even though the Kleenex is made of fibres, which themselves have internal structure, we consider it a single thing. Why?
Here again it should be possible to draw new philosophical ideas from chemistry. Joe Earley certainly thinks so. He is a chemist from Georgetown University in Washington DC, whom Scerri introduces to the conference as "the very embodiment of a philosopher of chemistry". Earley, who has been thinking philosophically about chemistry for more than twenty years, tells the meeting that by looking at chemical reactions, philosophers can devise a new definition of what constitutes a "thingy thing".
Earley claims philosophers have been too content with a narrow view of what counts as a "thing". To most philosophers, a material object must be something like a rock—something held together by forces, producing a tangible object that functions as one unit and resists change. But there are many dynamic objects, Earley says, that philosophers have difficulty describing. Take a storm cloud. "It's a swarm of rapidly moving air molecules, but it's also a unit," Earley says. In such systems, simple components or processes can work together to generate a more complex whole.
Chemists' expertise lies in dealing with parts that combine into larger wholes, says Earley—atoms combining into molecules, for example. And he has found an example from chemistry that can help to define for philosophers how the components of dynamic objects must balance to produce a unified whole—oscillating chemical reactions.
These are reactions that cycle through distinct states only to come back to the starting point and begin all over again. A well-known example is the Belousov-Zhabotinsky reaction, in which concentrations of ions oscillate regularly (see "Let T equal tiger", New Scientist, 6 November 1993, p 40). "You have something that is an autocatalytic process, where one makes two, makes four, makes eight—something exploding. Then there's some control mechanism that shuts that down and starts you again. Explode, shut off, explode, shut off," says Earley.
To him, balancing these processes so that the cycle repeats indefinitely produces a whole that is more than the sum of its parts. The components constitute one "thing" because they work together and the chemical reactions influence each other to achieve a balance. "That's the thinginess of that thing," he says.
Earley suggests that all oscillating reactions have four characteristics (see "Round in circles"). When all four are present, the components of the reaction interact to produce a larger structure that functions as a single unit. This unit can even act in coordination with other units to produce yet larger composite wholes, Earley believes.
Earley thinks this model of a "composite whole" works from the micro to the macro scale. Just as an oscillating chemical reaction is a composite whole, so are a kitten, the Sun and a storm cloud. So, too, is a community of people and their environment, interacting through a multitude of cyclic processes. "They must be considered together—as one," says Earley.
"I'm not saying this isn't a strange way of looking at things," Earley admits. But it is a powerful tool: "Once you start looking at things this way, then you can see its influence all over the place."
Earley, like Scerri and Baird, has begun to produce a distinctly chemical answer to a philosophical question, and many more questions remain. Chemistry may not yet offer the world a single theory that raises the challenging questions posed by, say, quantum mechanics. But it's certainly giving philosophers a new angle on familiar questions. And Earley, Scerri and Baird hope others will join their pursuit of knowledge through analysing chemistry.
Perhaps Earley's concept of autocatalysis will even apply to the International Society for the Philosophy of Chemistry. The enthusiasm of the few in the field now may bring in more enthusiasts. If this group establishes a cycle with new members joining as others leave, they just might create a unit that persists indefinitely. Then perhaps the philosophy of chemistry will have become larger than the sum of its parts—and a true thing.
Wrong filling
"THE reduction of chemistry to physics is supposed to happen automatically, and people seldom question it," Eric Scerri notes. So how is it, he asks, that the heart of modern chemistry—the periodic table—has never been explained successfully by the laws of physics.
Mendelyev designed his table on the basis of experiment: arranging the elements roughly by weight and lining up elements with similar properties into columns. When quantum mechanics arrived, its laws gave chemists a way to describe the motion of electrons around the nuclei of atoms. But despite its achievements, quantum mechanics failed to justify the ordering of the elements in the table.
Electrons are thought to orbit atomic nuclei in a series of "concentric" shells. According to quantum mechanics, these shells should fill sequentially as you move from one element to the next along a row. And this does occur, but only as far as potassium. "That's where the trouble starts," Scerri says.
Potassium's outer-most electron sits in the fourth shell, even though 10 of the 18 spaces in the third shell remain empty. Its neighbour, calcium, behaves the same way. But then the next element, scandium, "remembers" that the third shell is not yet full and puts its extra electrons into it. "If the shells were to fill in a sequential order, we would have a perfect quantum mechanical explanation of the periodic table," says Scerri. But they don't.
Although the periodic table may one day be reduced successfully to physics, Scerri doesn't believe chemistry as a whole ever will be. "You will never reduce all of chemistry," he says. And without this, the philosophy of chemistry can never be reduced to the philosophy of physics.
Even chemists have overlooked this failure of reduction, Scerri says. Many chemistry teachers explain the periodic table backwards, Scerri thinks—they begin with shell filling and end up with the elements arranged in the table. Some textbooks even state that quantum theory predicts the structure of the periodic table.
Round in circles
THERE are four requirements for a chemical system to oscillate indefinitely, says Joe Earley, a chemist from Georgetown University in Washington DC.
* The system must be far from equilibrium. Most chemical reactions move smoothly towards an equilibrium state, going from reactants to products. But these systems are not "wholes"—they contain products with little or no influence over one another.
* There must be autocatalysis, or positive feedback. Once started, the reaction must feed on itself and speed up. The product of the reaction causes yet more product to form. Without some check, this reaction would simply accelerate out of control, so the oscillating system must have an "exit" reaction. As the product builds up, it is simultaneously removed by another chemical reaction running in parallel.
* The components above must work together to create a cycle. When the amount of the product is low, autocatalysis speeds up the primary reaction so it is faster than the exit reaction. This forms more of the product. As the product builds up, the exit reaction starts to occur faster than the autocatalytic reaction, reducing the amount of product. And the cycle continues.
Lila Guterman