Scientific realists take the contrary view that the success of a theory does give us reason to believe in the theoretical entities it posits. Among other arguments, they sometimes appeal to the idea that entities that at one time were unobservable later became observable with the rise of new technologies, such as telescopes, electron microscopes, and ordinary microscopes. This shows, they argue, that the boundary between observable and unobservable entities is not sharp enough to justify skepticism about the latter.
In chapter 4
of his book Scientific Representation, van Fraassen
presents a very clever and interesting challenge to this sort of argument. Taking on scientific realists on what might
seem to be their strongest ground, he denies that even ordinary microscopes must
be seen as confirming the reality of previously unobserved entities.
First a
terminological point. Consider the world
of everyday experience – of tables and chairs, rocks and trees, reflections in
water and shadows on the ground and on walls, rainbows and clouds and stars in
the sky, and so on. These are all
examples of “phenomena” as van Fraassen uses the term. In holding that the aim of science is
empirical adequacy, views like his are often characterized as holding that
science is concerned only to “save the phenomena.” Scientific realism, by contrast, holds that
science gives us reason to believe in an invisible world behind the phenomena.
The claim on
the table, then, is that a microscope amounts to “a window on the invisible world,”
as van Fraassen puts it (p. 93). It
allows us to peer behind the phenomena to what previously had been
unobservable. Van Fraassen allows that
this is one possible interpretation. But
he argues that it is not the only one, so that instruments like microscopes
cannot be appealed to as somehow settling the dispute between constructive empiricism
and scientific realism. Considered by
themselves they are neutral, insofar as what they yield can be interpreted in
ways consistent with either position.
Scientific
instruments, notes van Fraassen, play several roles. Sometimes that role is representative, as in the case of clocks, balances, and measuring
rods. Sometimes it is imitative in the sense of mimicking
effects that occur in nature, as when an electrical generator is used to bring
about an imitation of lightning. Sometimes
the role is instead productive, in
the sense of bringing about phenomena which had not previously been observed,
as when Faraday discovered electromagnetic induction.
Now, a
microscope is a scientific instrument. What
role does it play? The scientific
realist, in conceiving of it as a kind of “window” on otherwise unobservable
reality, thinks of it as playing an essentially representative role. But whether or not it plays that role, van
Fraassen says, it certainly plays the productive
role of creating new phenomena, phenomena that had not been seen before. And he wants to argue that there is nothing
in what they show us that compels us to see them as doing anything more than
that.
Here he
appeals to the idea of a “public hallucination” (p. 101). Hallucinations like the one Macbeth
experienced when he thought he saw a dagger are private, directly knowable only
to the individual experiencing them.
Contrast that with a rainbow, which, like Macbeth’s dagger, is not
something really out there in the world, but is nevertheless experienced by
many individuals at once.
But not all
public hallucinations are quite as distant from really existing things as
that. Van Fraassen draws a distinction
between four types of “images” we distinguish from reality, but which are not
all equally distant from it. At one
extreme we have private images such
as after-images, dreams, and hallucinations, which are not only not actual
things in the objective world, but are accessible only to the individual person
having the experience. At the other
extreme we have graven images such as
paintings, photographs, and sculptures.
These are not really things of the
same sort as what they resemble, but they nevertheless are things in their
own right really existing in the world outside the mind.
In between
are public hallucinations, but these can be divided into two sub-classes. There are public hallucinations that are, as
van Fraassen puts it, “not ‘copy’-qualified” (p. 104). What he means is that they are not images of some thing that is really out there
in the world. Rainbows and mirages would
be examples. They are a step up from private
images because they are shared rather than subjective. But there are also public hallucinations that
are “copy-qualified,” in the sense
that they are images “of” something
really there in the world. Examples
would be shadows and reflections, such as the reflection of a tree in the
water. These are a step down from graven
images, because a reflection is, like a rainbow, not an actual thing out there
in the world. But it is of a thing (for example, the tree) in a
way a rainbow is not. Hence it is a step
up from a public hallucination of the kind that is not copy-qualified.
It is in
this last category that van Fraassen wants to put the images seen in a
microscope. What a microscope gives is,
he argues, is a public hallucination of the copy-qualified kind, like a tree’s
shadow or reflection in the water. By no
means does he want to deny that we do, of course, get much useful information
from microscopes and other scientific instruments. But this, he argues, is due to “our latching
onto significant regularities in the
phenomena” rather having to do with unobserved realities (p. 109).
As always
with van Fraassen, there are further intriguing nuances, examples, and insights,
and I can’t convey them all here in this summary. But I think I have captured the gist of his
argument. It seems to me that the scientific
realist can make the following points in response.
First, while
there are similarities between the case of a tree’s reflection in water and the
case of an image seen in a microscope, there are also important
differences. As I was reading van
Fraassen’s book, I sipped a martini.
Through the glass I could see the books on the shelf behind it – only very
obscurely through the part of the glass that still had liquid in it, a little
bit more clearly through the part that did not.
But though the books were obscured, it seems correct to say that I was
looking at the books themselves –
even though I was doing so through
the medium of the glass – rather than that I was looking at an image in the
glass. I was also wearing eyeglasses,
and when I peered past the martini glass to the books it seems even more
obviously correct to say that what I was looking at were the books, even if I looked at them through the eyeglasses (rather than saying that I was looking at an
image in the eyeglasses).
These cases
are obviously different from the case of looking at a reflection of a tree in
the water. In that case, what I am
looking at is not the tree itself, but something caused by the tree. As van Fraassen emphasizes, the reflection of
the tree is not a thing there in the
water in the sense in which a floating log is a thing there in the water. The reflection will, for example, seem to move
as you keep looking at it while you move along the shore, whereas a floating
log might not do so. That’s why it is
plausible to classify the reflection as a kind of “public hallucination.” By contrast, the books I see through the
martini glass and through the eyeglasses are
things there in the world. And even
given that the martini glass distorts the appearance of the books, the result
is not a hallucination of any kind, precisely because I really am nevertheless
looking at the books.
Now, the
case of the microscope seems obviously closer to the cases of the martini glass
and the eyeglasses than it does to the case of the reflection of the tree. What you see when using a microscope to
examine a cell, for example, is the cell
itself – even if you’re looking at it through
the microscope – rather than merely an image.
If that is the case, though, then it also seems plausible after all to conceive
of a microscopes as a “window on the invisible world,” rather than merely as
something that creates new phenomena.
A second
point in reply to van Fraassen would be this.
Suppose the argument I just gave is wrong, and that van Fraassen is
right to characterize what a microscope produces as a “copy-qualified public
hallucination.” It is not clear that that
would actually support constructive empiricism over scientific realism. After all, what makes an image “copy-qualified”
is that there is a real thing that the image is an image of. For example, a tree’s
reflection in the water is copy-qualified because there really is a tree that
is causing it. The fact that the
reflection is a “public hallucination” therefore would hardly support
anti-realism about trees!
But then, if
an image in a microscope is also a “copy-qualified” image, then that would mean
that there must a real thing that the image is an image of. And that would arguably be sufficient grist
for the scientific realist mill, even if we don’t think of microscopes as
windows on the invisible world.
Related
posts:
Cartwright
on theory and experiment in science
Cartwright
on reductionism in science
Dupré
on the ideologizing of science
I would also take issue with Fraassen's use of the term "public hallucination". I think that (a) he is intentionally vague about what that really is supposed to mean, and (b) employing that vagueness to carry weight for "not real, like dreams and other subjective phenomona."
ReplyDeleteContrast that with a rainbow, which, like Macbeth’s dagger, is not something really out there in the world, but is nevertheless experienced by many individuals at once.
Take the rainbow: the phenomenon IS something real out there: you can take a photo, and it shows up in the photo. you can get a light meter out and measure the wavelengths of light coming in. Those light rays are REAL, objective phenomena: they don't exist only "in" the subject. Moreover, in some cases, at the "bottom" you can see the ground or objects behind the rainbow, so it is translucent: you can TELL it's not representative of a specific physical object with definite form. That is, upon closer, more intent analysis, it doesn't "look like" a physical object colored with those colors, it looks other than that - more like disembodied color. Which IS more like what it is. A prism provides more experiences in the same category, but slightly different ones. In both cases, the experiences ARE subject to testing and analysis, to experiment, to recording, persistence, verification. Go look up definitions of "hallucination" and see if that fits these attributes.
What Fraassen might mean is that the rainbow's color image isn't the light reflected off an object that has those colors, so that the image we get is not native of some object. If so, he was remarkably unnuanced about calling it "not real". The images are certainly real in the sense that real physical light wave phenomena outside of the observer causes it, and does so reliably, predictably, etc.
It is possible that Fraassen doesn't mean to apply the heavy negative weight of the term "hallucination" for this category, but I doubt it, or he would have cast about for a better term.
Yeah, I too raised an eyebrow at the notion that an illusion can be compared to a "hallucination". That doesn't seem right. Mirages are real things that exist independently of the mind, they're just not what they appear to be to said mind. Similarly, rainbows are a real phenomenon based on light refraction in the sky. They would be there even if we didn't see them. They can't really be considered "hallucinations" unless you take a Kantian route and consider all of sense perception itself to be a kind of hallucination.
DeleteThere should be an award for the most fitting thumbnails because Prof keeps knocking them out of the park.
ReplyDeleteThe best example may be electrons. People old enough to have used CRT TV sets and computer monitors know that electrons are not just theoretical constructs, much less "public hallucinations", but very real "little balls" that impacted the phosphorus on TV and monitor screens making it emit light. That electrons behave like waves in electronic miscroscopes does not detract that they behave like balls in CRT's.
ReplyDeleteNow this seems philosophical decadence, the convoluted play of luxuriantly circulating concepts at its finest: There are no dreams, no rainbows or shadows or reflections of trees (no science?) actually really out there in the real actual objective world... There's not only no pot o' gold, there's no rainbow, because correctly describing the empirical adequacy of a realm beyond what is observable ... (Sorry, I appear to be completely lost here.)
ReplyDeleteThis is an interesting topic.
ReplyDeleteOne thing I would mention is that most of the objects observed in microscopes are telescopes are not of such a different kind from the objects we interact with in daily life, other than being much bigger or smaller.
We can see the moon and other planets with the naked eye and a telescope that shows them as bodies similar to the Earth, but with different features does not violate common sense.
Likewise, there are organisms of many sizes visible with the naked eye, so a microscope showing organisms still smaller does not go against the common sense understanding of the world either.
I would guess that one reason people reject (some versions of) scientific realism is because of the idea that people should believe in even parts of scientific theories that violate common sense.
I have no problem believing in galaxies, but I am not so sure about quarks.
Another related topic is that there is a difference between what a quark is, in terms of a model and how physicists think of quarks. How they imagine what a quark really is.
Believing that there is something there, that a scientific theory describes an aspect of the world, does not mean that we have to also agree with some interpretation about what is the reality described by the theory.
I expect that at least on the edges, Fraassen's theory runs into some pretty strong headwinds from actual empirical phenomena. Bob with ordinary eyesight can't see out to the horizon able to make out shapes, may not even see (at all) an object that's there. Then Sam comes along who is farsighted and sees them clearly, and describes them. They walk toward the objects, and - lo and behold - Bob can see them, just as described. Is his description that "Sam had a private hallucination I was not privy to, and now I'm having it too"? No.
ReplyDeleteSame with something up close: a farsighted person Frank looking at extremely fine print only 5 inches from his face, and he can't see more than a blur, or even that. But Bob reads it. Then someone hands Frank a piece of glass, and he can verify the words. Now Bob looks at even finer print, and can't make it out, so he takes a weak magnifying glass to it, and reads it. Then Jane whose vision is much better can read it directly, without the magnifying glass. The Bob doesn't describe what he sees WITH the magnifying glass as "a private hallucination" because neither he nor Frank could see it" without aid, and they joined Jane in what is now a public hallucination. That's not plausible: The fact that someone could see it without aid, and others could see the same thing with aid, proves that what they ALL saw was real, not hallucinatory.
But now we get out a stronger magnifying glass, i.e. just the same as the weak one, but with more curvature. And now even Jane can make out details in the letters, say, a small defect, that she could not see before - as can Bob and Frank. But she can remain seeing the letters themselves just fine, as can Bob and Frank. Are we to assert that because none of them could make out the small defect unaided, that the magnifying glass is presenting a "public hallucination", even though the same instrument is showing them the same letters they saw before, (just larger)? Are we to suggest even that "seeing the letters look larger" is also a hallucination, even though all 3 of them could achieve exactly the same result just by holding the paper closer? These are not plausible accounts of what is happening. Rather, the plausible account is that the glass modifies the visible aspect that is really and readily visible, in a knowable way, and it has the same kind of effect on other visible objects that are only bare visible but really there, and also on visible objects that are too small to be visible directly, but are really there. And we can measure the amount of change in apparent size to match the curvature of the lens. Fraassen's account is just silly.
And a microscope, (ordinary, using glass lenses), we can know with confidence does the same kinds of thing to other objects really there, because these too obey the same relation to lens curvature. The fact that there is a continuum of variation in result that matches the variation of lenses, part of the range being with directly observable objects, (both before and after magnifying), establishes that the action of the lens is not to produce "hallucination".
That was so lyrically well-written, Dr McPike.
ReplyDeleteI'm not perfectly sure how this debate differs from the age-old philosophical debate over epistemology & perception. Does it formally matter whether the medium of perception is the human senses or the microscope? To quote Morty Smith, mutatis mutandis, "That just sounds like slavery with extra steps!"
ReplyDeleteI will read this with interest. I enjoy Fraassen for the his not easily dismissed critiques of Scientific realism.
ReplyDeleteI think his challenge still holds force because there is nothing in a "copy-qualified" image that requires the object-image relation to be representative and not merely causal. Unlike with observing bookshelves through the glasses, there is no alternative way to observe the objects in the image produced by a microscope. Our descriptions of what is seen can only be about the content of the image while we can move the glasses aside and see the bookshelf in an unmediated way.
ReplyDeleteIf you take things that you can see with the naked eye and put them under a microscope and they look the same under the microscope as to the naked eye, then when you use the microscope to observed things not visible to the naked eye, what would dissuade you from thinking that you are observing real things and not just images produced by the microscope ?
ReplyDeleteI'd say that this would confirm representation for macroscopic objects. I doubt it would be enough to remove all skepticism about the microscopic image. Suppose microscopic objects can produce public hallucinations not identical to the objects themselves but with content that suggests different objects exists. Then what we know that confirms the macroscopic representation view wouldn't help us settle the case for microscopic images.
DeleteIn semiconductor design and manufacture, a circuit is designed and is then shrunk down to microscopic size using photolithography. If it became something different when it was miniaturized why would it work as designed in its macro version?
DeleteIs there any justification for believing the microscopic images would act differently from macroscopic images. Why would objects behave differently just because they are beyond our human limit of sensation ? Also, if an electron microscope reveals the same structure as the optical microscope, then you have agreement between two methods.
Delete@bmiller, antirealism about quantum mechanics is still widely thought to be a plausible account of it and is all you need to design and build chips. I am not a fan of priviledging the "shut up and calculate" approach but engineers can and arguably do. Empirical adequacy is at the core of this view.
Delete@Matthew, the same cause can produce similar effects on two different instruments. Neither of which need to be representative effects instead of just merely causal ones. I just think that Van Fraassen's challenge is sustainable. We don't have the resources we need to overcome skepticism about these theoretical entities.
Gofaone Paul,
DeleteMiniaturizing a circuit design does not necessarily involve semiconductor physics. The entire design including transistors and their circuit connections are modeled on a computer (formerly on layered vellum paper) and photographically reduced to a size that cannot be discerned with the naked eye.
The circuit is then manufactured and if there is a problem, microscopes are used to see what went wrong. The microscope images appear the same as the computer design when the device is working and flaws or damage can be detected by comparing the original design to what is observed in the microscope.
So apparently both the original design observed with human eyes correspond to the microscopic image also observed with human eyes. Why would that be the case if the "microscopic world" somehow was different in kind from the macroscopic world?
Thanks for expanding on the process. I found it really helpful. In this case, a macroscopic image from the design was inscribed into the material and was later reproduced by an electron microscope. The inference being that the reproduced image is representative of the microstructure and not merely just caused/produced by it. Fair enough. The process doesn't compel the conclusion but it is good enough evidence for me at least. My only concern is that the image in this case is an artifact of the macroscale that is only ever experienced at that same scale both before and after. Why can't our description end there because that is what we see?
DeleteGofaone Paul,
DeleteThe integrated circuit is designed to behave a certain way and it indeed behaves the way it is designed when it is manufactured. So it is more than just appearances.
One could think of this as a test case to either prove or disprove that "the microscopic world" is a different sort of world than "the macroscopic world". If we were peering into a microscope for the first time, we might wonder if what we are seeing is "really" what is there. In this case, we know what is "really" there because we designed the thing we are looking at and it corresponds to our expectations. Since we know from this example that we are seeing what we think we should see, it gives us confidence in other cases in which we did not design the object under investigation.
I feel like commentators here miss a very interesting aspect of van Fraassens philosophy. Yes, it sounds weird to say that the empirical sciences don't give us the resources to postulate entities beyond it. But at the same time, doesn't that line of reasoning ring a bell in regards to cosmological arguments?
ReplyDeleteVan Fraassen is a full on Kantian and the antirealism he applies hits in exactly that same spot. There's a tension between the idea that causality as we understand it can't be applied beyond the universe or what we perceive, but at the same time give science the exact power we want to take from causality. It's question-begging.
I know it's not van Fraasens intention, since he agrees with Kant. But it looks to me like his argument shows that the kind of skepticism spoken of in regards to the cosmological argument is not consistent with scientific realism. In other words, a scientific reaoist can't adhere to the Kantian arguments against it.
Dominik, I don't follow you at all.
DeleteYes, it sounds weird to say that the empirical sciences don't give us the resources to postulate entities beyond it.
Do you mean "conclude" rather than postulate? Of course the empirical sciences aren't supposed to postulate entities, i.e. as pre-suppositons. Otherwise we could postulate little green men, invisible and immune to all our experiments, and immensely powerful, that cause (whatever needs an account: circulation of blood, the tides, electricity). Science can reason to entities as the conclusion of experiences (and experiments, which are just pointed experiences) and crafting an account of the experiences.
If you mean to dispute the validity of causality itself, I suspect you're working from Hume instead of Kant, but whatever the source, we have direct experience of causality internally when we choose an end, then select a course of action intended to achieve that end, then execute that course of action and satisfyingly arrive at the end intended. And if you claim "that doesn't count" as experiencing cause, I guess you're disputing semantics and epistemology as well as science. The account Prof. Feser gave us didn't intimate that Fraassen had all this baggage, so we didn't take them up. The arguments against Hume are different from those against Kant.
There's a tension between the idea that causality as we understand it can't be applied beyond the universe or what we perceive, but at the same time give science the exact power we want to take from causality. It's question-begging.
So, if we simply don't hold "that causality as we understand it can't be applied beyond the universe or what we perceive" and urge that it can, we don't get the tension, right?
It is not clear what you mean by "be applied beyond...what we perceive". When ball A strikes ball B and ball B moves, we SEE A move, the strike, and B move. Do you mean (as Hume does) that "we don't SEE causality", all we see is B move after A strikes, the second movement is seen but not "causality", nothing about that event constitutes perception of causality, then you mean that "causality as we understand it can't be applied EVEN WITHIN the universe and what we perceive", right? But we observe in the universe that "everywhere we turn to look, for an action that we see, we find something of a cause: either a causal entity that we can see directly or through instruments (like a microscope), or a force that we cannot observe directly but can be described with immense precision through direct and indirect methods of observation." You may take up the dispute whether these forces "exist" and whether their existence is "postulated" rather than, but eventually you'll run up against the Principle of Sufficient Reason: accepting the undisputed regularity of behavior without allowing a cause (not: without allowing for a known, specific cause, but without allowing there being any cause) violates reason. And once we can violate reason, everything else Hume argues is pointless, for he's relying on reason for the arguments. (Yes, this is an incomplete argument against Hume. We didn't think the issues with Fraassen needed to go here.)
Anon, we agree with each other. You need to keep in mind that those who press Kant's objection generally don't accept the PSR
DeleteIn my fervid dreams, I am playing billiards with Hume. He keeps saying there is so causation while I am running the table. My bank shots are incredible.
ReplyDeleteHumerous
DeleteIt's spelled "humorous." But in playing billiards, I do use my humerus bone.
DeleteThat's funny: correcting HUME-erous as humorous. Probably by someone who has the humours, or is out of humour.
DeleteI have dreams like that, too, but in mine, Schopenhauer's "sehr kluger Pudel" keeps knocking the billiard balls back toward the queue in the hope of tracing causality.
DeleteThe philosopher of pessimism had a thing for poodles.
DeleteSince I work as an Orthopedic Nurse Practitioner, ( I couldn't get a job with a B.A in philosophy) I have a thing for bones. I couldn't see HUME; I just thought of the bone. But yes, it was funny. In more ways than one.
ReplyDeleteWhat sensate experience, mediated through a tool like a microscope, or viewed directly, as it were, with our eyes, is not experienced as a "copy-qualified" image in our consciousness? Isn't it the case that when you look at the books, through the lens of your eye, through your eyeglasses, or through your martini glass, what you're seeing is not the books as they are in themselves, but a representation of the books in your consciousness? As an observer, you contribute to the formation of the phenomena. If you only ever saw through a martini glass, what a book would mean would be determined in part by that obscure lens. A bookshelf to a blind man is not the same phenomena as a bookshelf to Ed Feser. It seems to me that Fraassen is right that a microscope forms a new phenomena, or at least adds a new dimension to an existing phenomena. But, what he's missing to make sense of his distinctions is form. What is common between a tree, a hallucination of a tree, the reflection of a tree in water, a sculpture of a tree, and our conscious vision of a tree? Form. And our ability to participate in form explains why a qualified scientific realism is possible.
ReplyDeleteFraassen sounds interesting, but I suspect Owen Barfield contributed more clarity to these questions (and on the nature of a rainbow) with his treatment of participation and consciousness in his book, Saving the Appearances.
Hey Prof
ReplyDeleteI was reading Aristotle's Revenge the other day. I also read Christopher Decaen, an AT philosopher.
Would it be fair to posit that on your view of nature, quantitative microphysical properties like surface reflectance and the qualitative feature of red can be said to exist together or relate to each other only as different aspects of the color red as it exists in the external world namely as the material and formal cause of redness in the external world, on this view their existing together only makes sense in reference to the whole.(Actually existing redness in material objects)
(Technically the color red is itself a feature of a greater whole but even features can be said to have natures in an extended sense like organs for example).
Otherwise to posit such features as just existing together without any reference to a whole would make their relationship completely contingent since one is a quantitative property and one is qualitative. They have to exist together as part of a unity.
What would be your thoughts?
Does this make sense ?
Cheers
Hey Norm, I don't know exactly what Ed would say about this, but I think you can catch a glimpse of the answer on this post: https://edwardfeser.blogspot.com/2019/09/aristotles-revenge-and-naive-color.html
DeleteGod Bless!
Prof had something similar here
Delete"In human experience, conceptual and sensory content are fused, two aspects of one thing rather than an aggregate of a purely intellectual state (as in an angel) and a purely sentient state (as in a non-human animal)."