SCIENCE IN ACTION
How to follow
scientists and engineers
through society
Bruno Latour
Harvard UnlvetSHy Press
Cambridge, Massachusetts 1987
INTRODUCTION
Opening Pandora's
Black Box
Scene 1: On a cold and sunny morning in October 1985, John Whittaker entered his
office in the molecular biology building of the Institut Pasteur in Paris and switched
on his Eclipse MV/8000 computer. A few seconds after loading the special programs
he had written, a three-dimensional picture of the DNA double helix flashed onto
the screen. John, a visiting computer scientist, had been invited by the Institute to
write programs that could produce three-dimensional images of the coils of DNA
and relate them to the thousands of new nucleic acid sequences pouring out every
year into the journals and data banks. 'Nice picture, eh?' said his boss, Pierre, who
was just entering the office. 'Yes, good machine too,' answered John.
Scene 2: In 1951 in the Cavendish laboratory at Cambridge, England, the X-ray
pictures of crystallised deoxyribonucleic acid were not 'nice pictures' on a computer
screen. The two young researchers, Jim Watson and Francis Crick 1, had a hard time
obtaining them from Maurice Wilkins and Rosalind Franklin in London. It was
impossible yet to decide if the form of the acid was a triple or a double helix, if the
phosphate bonds were at the inside or at the outside of the molecule, or indeed if it
was an helix at all. It did not matter much to their boss, Sir Francis Bragg, since the
two were not supposed to be working on DNA anyway, but it mattered a lot to
them, especially since Linus Pauling, the famous chemist, was said to be about to
uncover the structure of DNA in a few months.
Scene 3: In 1980 in a Data General building on Route 495 in Westborough,
Massachusetts, Tom Westl and his team were still trying to debug a makeshift
prototype of a new machine nicknamed Eagle that the company had not planned to
build at first, but that was beginning to rouse the marketing department's interest.
However, the debugging program was a year behind schedule. Besides, the choice
West had made of using the new PAL chips kept delaying the machine- renamed
Eclipse MV/8000, since no one was sure at the time if the company manufacturing
the chips could deliver them on demand. In the meantime, their main competitor,
DEC, was selling many copies of its VAX 111780, increasing the gap between the
two companies.
1
2 Science in Action
(1) Looking for a way in
Where can we start a study of science and technology? The choice of a way in
crucially depends on good timing. In 1985, in Paris, John Whittaker obtains 'nice
pictures' of DNA on a 'good machine'. In 1951 in Cambridge Watson and Crick
are struggling to define a shape for DNA that is compatible with the pictures they
glimpsed in Wilkins's office. In 1980, in the basement of a building, another team
of researchers is fighting to make a new computer work and to catch up with
DEC. What is the meaning of these 'flashbacks', to use the cinema term? They
carry us back through space and time.
When we use this travel machine, DNA ceases to have a shape so well
established that computer programs can be written to display it on a screen. As to
the computers, they don't exist at all. Hundreds of nucleic acid sequences are not
pouring in every year. Not a single one is known and even the notion of a
sequence is doubtful since it is still unsure, for many people at the time, whether
DNA plays any significant role in passing genetic material from one generation
to the next. Twice already, Watson and Crick had proudly announced that they
had solved the riddle and both times their model had been reduced to ashes. As to
the 'good machine' Eagle, the flashback takes us back to a moment when it
cannot run any program at all. Instead of a routine piece of equipment John
Whittaker can switch on, it is a disorderly array of cables and chips surveyed by
two other computers and surrounded by dozens of engineers trying to make it
work reliably for more than a few seconds. No one in the team knows yet if this
project is not going to turn out to be another complete failure like the EGO
computer on which they worked for years and which was killed, they say, by the
management.
In Whittaker's research project many things are unsettled. He does not know
how long he is going to stay, if his fellowship will be renewed, if any program of
his own can handle millions of base pairs and compare them in a way that is
biologically significant. But there are at least two elements that raise no problems
for him: the double helix shape of DNA and his Data General computer. What
was for Watson and Crick the problematic focus of a fierce challenge, that won
them a Nobel Prize, is now the basic dogma of his program, embedded in
thousand of lines of his listing. As for the machine that made West's team work
day and night for years, it is now no more problematic than a piece of furniture as
it hums quietly away in his office. To be sure, the maintenance man of Data
General stops by every week to fix up some minor problems; but neither the man
nor John have to overhaul the computer all over again and force the company to
develop a new line of products. Whittaker is equally well aware of the many
problems plaguing the Basic Dogma of biology- Crick, now an old gentleman,
gave a lecture at the Institute on this a few weeks ago- but neither John nor his
boss have to rethink entirely the shape of the double helix or to establish a new
dogma.
The word black box is used by cyberneticians whenever a piece of machinery or
Opening Pandora's Black Box 3
a set of commands is too complex. In its place they draw a little box about
which they need to know nothing but its input and output. As far as John
Whittaker is concerned the double helix and the machine are two black boxes.
That is, no matter how controversial their history, how complex their inner
workings, how large the commercial or academic networks that hold them in
place, only their input and output count. When you switch on the Eclipse it runs
the programs you load; when you ,compare nucleic acid sequences you start from
the double helix shape.
The flashback from October 1985 in Paris to Autumn 1951 in Cambridge or
December 1980 in Westborough, Massachusetts, presents two completely
different pictures of each of these two objects, a scientific fact- the double-
helix- and a technical artefact- the Eagle minicomputer. In the first picture John
Whittaker uses two black boxes because they are unproblematic and certain;
during the flashback the boxes get reopened and a bright coloured light
illuminates them. In the first picture, there is no longer any need to decide where to
put the phosphate backbone of the double helix, it is just there at the outside;
there is no longer any squabble to decide if the Eclipse should be a 32-bit fully
compatible machine, as you just hook it up to the other NOVA computers.
During the flashbacks, a lot of people are introduced back into the picture, many
of them staking their career on the decisions they take: Rosalind Franklin decides
to reject the model-building approach Jim and Francis have chosen and to
concentrate instead on basic X-ray crystallography in order to obtain better
photographs; West decides to make a 32-bit compatible machine even though
this means building a tinkered 'kludge', as they contemptuously say, and losing
some of his best engineers, who want to design a neat new one.
In the Pasteur Institute John Whittaker is taking no big risk in believing the
three-dimensional shape of the double helix or in running his program on the
Eclipse. These are now routine choices. The risks he and his boss take lie
elsewhere, in this gigantic program of comparing all the base pairs generated by
molecular biologists all over the world. But if we go back to Cambridge, thirty
years ago, who should we believe? Rosalind Franklin who says it might be a
three-strand helix? Bragg who orders Watson and Crick to give up this hopeless
work entirely and get back to serious business? Pauling, the best chemist in the
world, who unveils a structure that breaks all the known laws of chemistry? The
same uncertainty arises in .theWestborough of a few years ago. Should West obey
his boss, de Castro, when he is explicitly asked not to do a new research project
there, since all the company research has now moved to North Carolina? How
long should West pretend he is not working on a new computer? Should he
believe the marketing experts when they say that all their customers want a fully
compatible machine (on which they can reuse their old software) instead of doing
as his competitor DEC does a 'culturally compatible' one (on which they cannot
reuse their software but only the most basic commands)? What confidence
should he have in his old team burned out by the failure of the EGO project?
Should he risk using the new PAL chips instead of the older but safer ones?
4 Science in Action
Ready Made Science
Science in the Making
Figure 1.1
Uncertainty, people at work, decisions, competition, controversies are what
one gets when making a flashback from certain, cold, unproblematic black boxes
to their recent past. If you take two pictures, one of the black boxes and the other
of the open controversies, they are utterly different. They are as different as the
two sides, one lively, the other severe, of a two-faced Janus. 'Science in the
making' on the right side, 'all made science' or 'ready made science' on the other;
such is Janus bifrons, the first character that greets us at the beginning of our
journey.
In John's office, the two black boxes cannot and should not be reopened. As to
the two controverial pieces of work going on in the Cavendish and in
Westborough, they are laid open for us by the scientists at work. The impossible
task of opening the black box is made feasible(ifnot easy) by moving in time and
space until one finds the controversial topic on which scientists and engineers are
busy at work. This is the first decision we have to make: our entry into science and
technology will be through the back door of science in the making, not through
the more grandiose entrance of ready made science.
Now that the way in has, been decided upon, with what sort of prior knowledge
should one be equipped before enreting ·science and technology? In John
Whittaker's office the double helix model and ihe computer are clearly distinct
from the rest of his worries. They do not interfere witlt his psychological mood,
the financial problems of the Institute, the big grants for which his boss has
applied, or with the political struggle they are all engaged in to create in France a
big data bank for molecular biologists. They are just sitting there in the
background, their scientific or technical contents neatly distinct from the mess
tl:)at John is immersed in. If he wishes to know something about the DNA
structure or about the Eclipse, John opens Molecular Biology of the Gene or the
User's Manual, books that he can take off the shelf. However, if we go back to
Westborough or to Cambridge this clean distinction between a context and a
content disappears.
Opening Pandora's Black Box 5
Scene 4: Tom West sneaks into the basement of a building where a friend lets him in
at night to look at a VAX computer. West starts pulling out the printed circuits
boards and analyses his competitor. Even his first analysis merges technical and
quick economic calculations with the strategic decisions already taken. After a few
hours, he is reassured.
'I'd beenlivinginfearofVAXfora year,' West said afterward. ( ... )'I think I
got a high when I looked at it and saw how complex and expensive it was.lt
made me feel good about some of the decisions we've made'.
Then his evaluation becomes still more complex, including social, stylistic and
organisational features:
Looking into the VAX, West had imagined he saw a diagram of DEC's
corporate organization. He felt that VAX was too complicated. He did not
like, for instance, the system by which various parts of the machine
communicated with each other, for his taste, there was too much protocol
involved. He decided that VAX embodied flaws in DEC's corporate
organization. The machine expressed that phenomenally successful com-
pany's cautious, bureaucratic style. Was this true? West said it did not
matter, it was a useful theory. Then he rephrased his opinions. 'With VAX,
DEC was trying to minimize the risk', he said, as he swerved around another
car. Grinning, he went on: 'We're trying to maximize the win, and make
Eagle go as fast as a raped ape.'
(Kidder: 1981, p. 36)
This heterogeneous evaluation of his competitor is not a marginal moment in the
story; it is the crucial episode when West decides that in spite of a two-year delay,
the opposition of theN orth Carolina group, the failure of the EGO project, they
can still make the Eagle work. 'Organis9-tion', 'taste', 'protocol', 'bureaucracy',
'minimisation of risks', are not common technical words to describe a chip. This
is true, however, only once the chip is a black box sold to consumers. When it is
submitted to a competitor's trial, like the one West does, all these bizarre words
become part and parcel of the technical evaluation. Context and contents merge.
Scene 5: Jim Watson and Francis Crick get a copy of the paper unveiling the
structure of DNA written by Linus Pauling and brought to them by his son:
Peter's face betrayed something important as he entered the door, and my
stomach sank in apprehension at ·learning that all was lost. Seeing that
neither Francis nor I could bear any further suspense, he quickly told us that
the model was a three-chain helix with the sugar phosphate backbone in the
center. This sounded so suspiciously like our aborted effort oflast year that
immediately I wondered whether we might already have had the credit and
glory of a great discovery if Bragg had not held us back.
(Watson: 1968, p. 102)
Was it Bragg who made them miss a major discovery, or was it Linus who missed a
good opportunity for keeping his mouth shut? Francis and Jim hurriedly try out the
paper and look to see if the sugar phosphate backbone is solid enough to hold the
structure together. To their amazement, the three chains described by Pauling had
6 Science in Action
no hydrogen atoms to tie the three strands together. Without them, if they knew
their chemistry, the structure will immediately fly apart.
Yet somehow Linus, unquestionably the world's most astute chemist, had
come to the opposite conclusion. When Francis was amazed equally by
Pauling's unorthodox chemistry, I began to breathe slower. By then I knew
we were still in the game. Neither of us, however, had the slightestclueto the
steps that had led Linus to his blunder. If a student had made a similar
mistake, he would be thought unfit to benefit from Cal Tech's chemistry
faculty. Thus, we could not but initially worry whether Linus's model
followed from a revolutionary reevaluation of the acid-based properties of
very large molecules. The tone of the manuscript, however, argued against
any such advance in chemical theory.
(idem: p. 103)
To decide whether they are still in the game Watson and Crick have to
evaluate simultaneously Linus Pauling's reputation, common chemistry, the
tone of the paper, the level of Cal Tech's students; they have to decide if a
revolution is under way, in which case they have been beaten off, or if an
enormous blunder has been committed, in which case they have to rush still faster
because Pauling will not be long in picking it up:
When his mistake became known, Linus would not stop until he had captured the
right structure. Now our immediate hope was that his chemical colleagues would be
more than ever awed by his intellect and not probe the details of his model. But since
the manuscript had already been dispatched to the Proceedings of the National
Academy, by mid-March at thf; lateSt Ljnus's paper would be spread around the
world. Then it would be only a matter of P-ays before the error would be discovered.
We had anywhere up to six weeks before Linus again was in full-time pursuit of
DNA.
(idem: p. 104)
'Suspense', 'game', 'tone', 'delay of publication', 'awe', 'six weeks delay' are
not common words for describing a molecule structure. This is the case at least
once the structure is known and learned by every student. However, as long as the
structure is submitted to a competitor's probing, these queer words are part and
parcel of the very chemical structure under investigation. Here again context and
content fuse together.
The equipment necessary to travel through science and technology is at once
light and multiple. Multiple beca.use. it means mixing hydrogen bonds with
deadlines, the probing of one another's authority with money, debugging and
bureaucratic style; but the equipment is also light because it means simply leaving
aside all the prejudices about what distinguishes the context in which knowledge
is embedded and this knowledge itself. At the entrance of Dante's Inferno is
written:
ABANDON HOPE ALL YE WHO ENTER HERE.
At the onset of this voyage should be written:
Opening Pandora's Black Box 7
ABANDON KNOWLEDGE ABOUT KNOWLEDGE
ALL YE WHO ENTER HERE.
Learning to use the double helix and Eagle in 1985 to write programs reveals
none of the bizarre mixture they are composed of; studying these in 1952 or in
1980 reveals it all. On the two black boxes sitting in Whittaker's office it is
inscribed, as on Pandora's box: DANGER: DO NOT OPEN. From the two tasks
at hand in the Cavendish and in Data General Headquarters, passions,
deadlines, decisions escape in all directions from a box that lies open. Pandora,
the mythical android sent by Zeus to Prometheus, is the second character after
Janus to greet us at the beginning of our trip. (We might need more than one
blessing from more than one of the antique gods if we want to reach our
destination safely.)
(2) When enough is never enough
Science has two faces: one that knows, the other that does not know yet. We will
choose the more ignorant. Insiders, and outsiders as well, have lots of ideas about
the ingredients necessary for science in the making. We will have as few ideas as
possible on what constitutes science. But how are we going to account for the
closing of the boxes, because they do, after all, close up? The shape of the double
helix is settled in John's office in 1985; so is that of the Eclipse MV/8000
computer. How did they move from the Cavendish in 1952 or from
Westborough, Massachusetts, to Paris 1985? It is all very well to choose
controversies as a way in, but we need to follow also the closure of these
controversies. Here we have to get used to a _strange acoustic phenomenon. The
two faces of Janus talk at once and they say entirely different things that we
should not confuse.
Janus' first dictum:
Figure 1.2
8 Science in Action
Scene 6: Jim copies from various textbooks the forms of the base pairs that make up
DNA, and plays with them trying to see if a symmetry can be seen when pairing
them. To his amazement adenine coupled with adenine, cytosine with cytosine,
guanine with guanine and thymine with thymine make very nice superimposable
forms. To be sure this symmetry renders the sugar phosphate backbone strangely
misshapen but this is not enough to stop Jim's pulse racing or to stop him writing a
triumphant letter to his boss.
I no sooner got to the office and began explaining my scheme than the
American crystallographer Jerry Donohue protested that the idea would not
work. The tautomeric forms I had copied out of Davidson's book were, in
Jerry's. opinion, incorrectly assigned. My immediate retort that several other
texts also pictured guanine and thymine in the enol form cut no ice with
Jerry. Happily he let out that for years organic chemists had been arbitrarily
favoring particular tautomeric forms over their alternatives on only the
flimsiest of grounds.( ... ) Though my immediate reaction was to hope that
Jerry was blowing hot air, I did not dismiss his criticism. Next to Linus
himself, Jerry knew more about hydrogen bonds than anyone in the world.
Since for many years he had worked at Cal Tech on the crystal structures of
small organic molecules, I couldn't kid myself that he did not grasp our
problem. During the six months that he occupied a desk in our office, I had
never heard him shooting off his mouth on subjects about which he knew
nothing. Thoroughly worried, I went back to my desk hoping that some
gimmick might emerge to salvage the like-with-like idea.
(Watson: 1968, pp. 121-2)
Jim had got the facts straight out of textbooks which, unanimously, provided
him with a nice black the enol form. In this case, however, this is the very fact
that should be dismissed or put into question. Or at least this is what Donohue
says. But whom should Jim believe? The unanimous opinion of organic chemists
or this chemist's opinion? Jim, who tries to salvage his model, switches from one
rule of method, 'get the facts straight', to other more strategic ones, 'look for a
weak point', 'choose who to believe'. Donohue studied with Pauling, he worked
on small molecules, in six months he never. said absurd things. Discipline,
affiliation, curriculum vitae, psychological appraisal are mixed together by Jim
to reach a decision. Better sacrifice them and the nice like-with-like model, than
Donohue's criticism. The fact, no matter how 'straight', has to be dismissed.
The unforeseen dividend of having Jerry share an office with Francis, Peter, and
me, though obvious to all, was not spoken about. If he had not been with us in
Cambridge, I might still have been pumping out for a like-with-like structure.
Maurice, in a lab devoid of structural chemists, did not have anyone to tell him that
all the textbook pictures were wrong. But for Jerry, only Pauling would have been
likely to make the right choice and stick by its consequences.
(idem: p. 132)
The advice of Janus' left side is easy to follow when things are settled, but not
as long as things remain unsettled. What is on the left side, universal well-known
facts of chemistry, becomes, from the right side point of view, scarce
Opening Pandora's Black Box 9
pronouncements uttered by two people in the whole world. They have a quality
that crucially depends on localisation, on chance, on appraising simultaneously
the worth of the people and of what they say.
Janus's second dictum:
r
Decide on
what
l
.'
1_, r'
Figure 1.3
Scene 7: West and his main collaborator, Alsing, are discussing how to tackle the
debugging program:
'I want to build a simulator, Tom.'
'It'll take too long, Alsing. The machine'll be debugged before you get your
simulator debugged.'
This time, Alsing insisted. They could not build Eagle in anything like a
year if they had to debug all the Il!:crocode on prototypes. If they went that
way, moreover, they'd need to liave at least one and probably two extra
prototypes right from the start, and that would mean a doubling of the
boring, grueling work of updating boards. Alsing wanted a program that
would behave like a perfected Eagle, so that they could debug their
microcode separately from the hardware.
West said: 'Go ahead. But I betchya it'll all be over by the time you get it
done.'
(Kidder: 1981, p. 146)
The right side's advice is strictly followed by the two men since they want to
build the best possible computer. This however does not prevent a new
controversy starting between the two men on how to mimic in advance an
efficient machine. If Alsing cannot convince one of his team members, Peck, to
finish in six weeks the simulator that should have taken a year and a half, then
West will be right: the simulator is not an efficient way to proceed because it will
come too late. But if Alsing and Peck succeed, then it is West's definition of
efficiency which will tum out to be wrong. Efficiency will be the consequence of
who succeeds; it does not help deciding, on the spot, who is right and wrong. The
right side's advice is all very well once Eagle is sent to manufacturing; before
that, it is the left side's confusing strategic advice that should be followed.
10 Science in Action
Janus'third dictum:
machine works
people will be
convinced
Figure !.4
Scene 8: West has insulated his team for two years from the rest of the company.
'Some of the kids,' he S!I.YS, 'don't have a notion that there's a company behind all of
this. It could be the CIA funding this. It could be·a nsychological test' (Kidder:
1982, p. 200). During this time, however, West has constantly lobbied the company
on behalf of Eagle. Acting as a middle-man he has filtered the constraints imposed
on the future machine by de Castro (the Big Boss), the marketing department, the
other research group in North Carolina, the other machines presented in computer
fairs, and so ,0n. He was also the one who kept negotiating the deadlines that were
never met. But there comes a point w.hen all the other departments he has lobbied so
intensely want to see something, and call his bluff. The situation becomes especially
tricky when it is clear at last that the North Carolina group will not deliver a
machine, that DEC is selling VAX like liot cakes and that all the customers want a
supermini 32-bit fully compatible machine from Data General. At this point West
has to break the protective shell he has built around his team. To be sure, he
designed the machine so as to fit it in with the other departments' interests, but he is
still uncertain of their reaction and of tliat of his team suddenly bereft of the
machine.
As the summer came on, increasing numbers of intruders were being led into
the lab- diagnostic programmers and, particularly, those programmers from
Software. Some Hardy Boys had grown fond of the prototypes ofEagle, as
you might of a pet or a plant you've raisedfrom a seedling. Now Rasala was
telling them that they couldn't work on their machines at certain hours,
because Software needed to use them. There was an explanation: the project
was at a precarious stage; if Software didn't get to know and like the
hardware and did not speak enthusiastically about it, the project might be
ruined; the Hardy Boys were lucky that Software wanted to use the
prototypes-and they had to keep Software happy.
(idem: p. 201)
Not only the Software people have to be kept happy, but also the manufacturing
people, those from marketing, those who write the technical documentation, the
designers who have· to place the whole machine in a nice looking box (not a black
one this time!), not mentioning the stockholders and the customers. Although the
Opening Pandora's Black Box 11
machine has been conceived by West, through many compromises, to keep all these
people happy and busy, he cannot be sure itis going to hold them together. Each of
the interest groups has to try their own different sort of tests on the machine and see
how it withstands them. The worst, for Tom West, is that the company
manufacturing the new PAL chips is going bankrupt, that the team is suffering a
postpartum depression, and that the machine is not yet debugged. 'Our credibility, I
think, is running out,' West tells his assistants. Eagle still does not run more than a
few seconds without flashing error messages on the screen. Every time they
painstakingly pinpoint the bug, they fix it and then try a new and more difficult
debugging program.
Eagle was failing its Multiprogramming Reliability Test mysteriously. It was
blowing away, crashing, going out to never-never land, and falling off the end
of the world after every four hours or so of smooth running.
'Machines somewhere in the agony of the last few bugs are very
vulnerable,' says Alsing. 'The shouting starts about it. It'll never work, and so
on. Managers and support groups start saying this. Hangers-on say, "Gee, I
thought you'd get it done a lot sooner." That's when people start talking
about redesigning the whole thing.'
Alsing added, 'Watch out for Tom now.'
West sat in his office. 'I'm thinking of throwing the kids out of the lab and
going in there with Rasala and fix it. It's true. I don't understand all the
details of that sucker, but I will, and I'll get it to work.'
'Gimme a few more days,' said Rasala.
(idem: p. 231)
A few weeks later, after Eagle has successfully run a computer game called
Adventure, the whole team felt they had reached one approximate end: 'It's a
computer,' Rasala said (idem: p. 233). On Monday 8 October, a maintenance
crew comes to wheel down the hall what was quickly becoming a black box. Why
has it become such? Because it is a good machine, says the left side of our Janus
friend. But it was not a good machine before it work{:d. Thus while it is being
made it cannot convince anyone because of its good' working order. It is only after
endless little bugs have been taken out, each bug being revealed by a new trial
imposed by a new interested group, that the machine will eventually and
progressively be made to work. All the reasons for why it will work once it is
finished do not help the engineers while they are making it.
Scene 9: How does the double helix story end? In a series of trials imposed on the
new model by each of the successive people Jim Watso1.1 and Francis Crick have
worked with (or against). Jim is playing with cardboard models of the base pairs,
now in the keto form suggested by Jerry Donohue. To his amazement he realises
that the shape drawn by pairing adenine with thymine and guanine with cytosine
are superimpqsable. The steps of the double helix have the same shape. Contrary to
his earlier model, the structure might be complementary instead ofbeing like-with-
like. He hesitates a while, because he sees no reason at first for this
complementarity. Then he remembers what was called 'Chargafflaws', one of these
many empirical facts they had kept in the background. These 'laws' stated that there
12 Science in Action
Janus's fourth dictum:
was always as much adenine as thymine and as much guanine as cytosine, no matter
which DNA one chose to·analyse. This isolated fact, devoid of any meaning in his
earlier like-with-like model, suddenly brings a new strength to his emerging new
model. Not only are the pairs superimposable, but Chargaff laws can be made a
consequence of his model. Another feature came to strengthen the model: it
suggests a way for a gene to split into two parts and then for each strand to create an
exact complementary copy of itself. One helix could give birth to two identical
helices. Thus biological meaning could support the model.
Still Jim's cardboard model could be destroyed in spite of these three advantages.
Maybe Donohue will bum it to ashes as he did the attempt a few days earlier. So Jim
called him to check if he had any objection. 'When he said no, my morale
skyrocketed' (Watson: 1968, p.l24). Then it is Francis who rushes into the lab and
'pushes the bases together in a number of ways'. The model, this time, resists
Francis's scepticism. There are now many decisive elements tied together with and
by the new structure.
Still, all the convinced people are in the same office and although they think they
are right, they could still be deluding themselves. What will Bragg and all the other
crystallographers say? What objections will Maurice Wilkins and Rosalind
Franklin, the only ones with X-rays pictures of the DNA, have? Will they see the
model as the only form able to give, by projection, the shape visible on Rosalind's
photographs? They'd like to know fast but dread the danger ofthefinalshowdown
with people who, several times already, have ruined their efforts. Besides, another
ally is missing to set up the trial, a humble ally for sure but necessary all the same:
'That night, however, we could not firmly establish the double helix. Until the metal
bases were on hand, any model building would be too sloppy to be convincing'
(idem: p. 127). Even with Chargaff laws, with biological significance, with
Donohue's approval, with their excitement, with the base pairing all on their side,
the is still sloppy. Metal is necessary to reinforce the structure long enough to
withstand the trials that the competitors/colleagues are going to impose on it.
The remainder of the double helix story looks like the final rounds of a
presidential nomination. Every one of the other contenders is introduced into the
office where the model is now set up, fights with it for a while before being quickly
Opening Pandora's Black Box 13
overwhelmed and then pledging complete support to it. Bragg is convinced
although still worried that no one more serious than Jim and Francis had checked
the helix. Now for the big game, the encounter between the model and those who for
years had captured its projected image. 'Maurice needed but a minute's look at the
model to like it.' 'He was back in London only two days before he rang up to say
that both he and Rosy found that their X-ray data strongly supported the double
helix' (p; 131 ). Soon Pauling rallies himself to the structure, then it is the turn of the
referees of Nature.
'Of course,' says the left side of Janus, 'everyone is convinced because Jim and
Francis stumbled on the right structure. The DNA shape itself is enough to rally
everyone.' 'No, says the right side, every time someone else is convinced it
progressively becomes a more right structure.' Enough is never enough: years
later in India and New Zealand other researchers were working on a so
called 'warped zipper' 3 model that did everything the double helix does-plus a bit
more; Pauling strongly supported his own structure that had turned out to be
entirely wrong; Jim found biological significance in a like-with-like structure
that survived only a few hours; Rosalind Franklin had been stubbornly
convinced earlier that it was a three-strand helix; Wilkins ignored the keto forms
revealed by Jerry Donohue; Chargafrs laws were an insignificant fact they kept
in the background for a long time; as to the metal atom toys, they have lent strong
support to countless models that turned out to be wrong. All these allies appear
strong once the structure is blackboxed. As long as it is not, Jim and Francis are
still struggling to recruit them, modifying the DNA structure until everyone is
satisfied. When they are through, they will follow the advice of Janus's right side.
As long as they are still searching for the right DNA shape, they would be better
off following the right side's confusing advices.
We could review all the opinions offered to explain why an open controversy
closes, but we will always stumble on a new controversy dealing with how and
why it closed. We will have to learn to live with two contradictory voices talking
at once, one about science in the making, the other about ready made science.
The latter produces sentences like 'just do this ... just do that ... ';the former says
'enough it never enough'. The left side considers that facts and machines are well
determined enough. The right side considers that facts and machines in the
making are always under-determined.4 Some little thing is always missing to close
the black box once and for all. Until the last minute Eagle can fail if West is not
careful enough to keep the Software people interested, to maintain the pressure
on the debugging crew, to advertise the machine to the marketing department.
(3) The first rule of method
We will enter facts and machines while they are in the making; we will carry with
us no preconceptions of what constitutes knowledge; we will watch the closure of
14 Science in Action
The DNA molecule has the shape "The DNA molecule has the shape
of a double helix of a double helix''
J5l
IQJ
tt t
"Watson and Crick have shown Since the molecule of DNA
that the DNA molecule has the has the shape of a double
shape of a double helix" helix the replication ofgenes
is made understandable
Figure 1.6
Opening Pandora's Black Box 15
the black boxes and be careful to distinguish between two contradictory
explanations of this closure, one uttered when it is finished, the other while it is
being attempted. This will constitute our first rule of method and will make our
voyage possible.
To sketch the general shape of this book, it is best to picture the following
comic strip: we start with a textbook sentence which is devoid of any trace of
fabrication, construction or ownership; we then put it in quotation marks,
surround it with a bubble, place it in the mouth of someone who speaks; then we
add to this speaking character, another character. to whom it is speaking; then we
place all of them in a specific situation, somewhere in time and space, surrounded
by equipment, machines, colleagues; then when the controversy heats up a bit we
look at where the disputing people go and what sort of new elements they fetch,
recruit or seduce in order to convince their colleagues; then, we see how the
people being convinced stop discussing with one another; situations,
localisations, even people start being slowly erased; on the last picture we see a
new sentence, without any quotation marks, written in a text book similar to the
one we started with in the first picture. This is the general movement of what we
will study over and over again in the course of this book, penetrating science from
the outside, following controversies and accompanying scientists up to the end,
being slowly led out of science in the making.
In spite of the rich, confusing, ambiguous and fascinating picture that is thus
revealed, surprisingly few people have penetrated from the outside the inner
workings of science and technology, and then got out of it to explain to the
outsider how it all works. For sure, many young people have entered science, but
they have become scientists and engineers; what they have done is visible iil the
machines we use, the textbooks we learn, the pills we take, the landscape we look
at, the blinking satellites in the night sky above our head. How they did it, we
don't know. Some scientists talk about science, its ways and means, but few of
them accept the discipline of becoming also an outsider; what they say about
their trade is hard to double check in the absence of independent scrutiny. Other
people talk about science, its solidity, its foundation, its development or its
dangers; unfortunately, almost none of them are interested in science in the
making. They shy away from the disorderly mixture revealed by science in action
and prefer the orderly pattern of scientific method and rationality. Defending
science and reason against pseudo-sciences, against fraud, against irrationality,
keeps most of these people too busy to study it. As to the millions, or billions, of
outsiders, they know about science and technology through popularisation only.
The facts and the artefacts they produce fall on their head like an external fate
as foreign, as inhuman, as unpredictable as the olden Fatum of the Romans.
Apart from those who make science, who study it, who defend it or who submit
to it, there exist, fortunately, a few people either trained as scientists or not, who
open the black boxes so that outsiders may have a glimpse at it. They go by many
different names (historians of science and technology, economists, sociologists,
science teachers, science policy analysts, journalists, philosophers, concerned
16 Science in Action
simply wish to summarise their method and to sketch the ground that, sometimes
unwittingly, they all have in common. In doing so I wish to help overcome two
of the limitations of'science, technology and society' studies that appear to me to
thwart their impact, that is their organisation by discipline and by object.
Economists of innovation ignore sociologists of technology; cognitive
scientists never use social studies of science; ethnoscience is far remote from
pedagogy; historians of science pay little attention to literary studies or to
rhetoric; sociologists of science often see no relation between their academic
work and the in vivo experiences performed by concerned scientists or citizens;
journalists rarely quote scholarly work on social studies of science; and so on.
This Babel of disciplines would not matter much if it was not worsened by
anothet: division made according to the objects each of them study. There exist
historians of eighteenth-century chemistry or of German turn-of-the-century
physics; even citizens' associations are specialised, some in fighting atomic
energy, others in struggling against drug companies, still others against new
maths teaching; some cognitive scientists study young children in experimental
settings while others are interested in adult daily reasoning; even among
sociologists of science, some focus on micro-studies of science while others tackle
large-scale engineering projects; historians of technology are often aligned along
the technical specialities of the engineers, some studying aircraft industries while
others prefer telecommunications or the development of steam engines; as to the
anthropologists studying 'savage' reasoning, very few get to deal with modern
knowledge. This scattering of disciplines and objects would not be a problem if it
was the hallmark of a necessary and fecund specialisation, growing from a core of
common problems and methods. This is however far from the case. The sciences
and the technologies to be studied are the main factors in determining this
haphazard growth of interests and methods. I have never met two people who
could on what the domain called 'science, technology and society'
meant- in fact, I have rarely seen anyone agree on the name or indeed that the
domain exists!
I claim that the domain exists, that there is a core of common problems and
methods, that it is important and that all the disciplines and objects of'science,
technology and society' studies can be employed as so much specialised material
with which to study it. To define what is at stake in this domain, the only thing we
need is a few sets of concepts sturdy enough to stand the trip through all these
many disciplines, periods and objects.
I am well aware that there exist many more sophisticated, subtle, fast or
powerful notions than the ones I have chosen. Are they not going to break down?
Are they going to last the distance? Will they be able to tie together enough
scientists and citizens, cognitive anthropologists or cognitive psychologists), and
are most often filed under the general label of'science, technology and society'. It
is on their work that this book is built. A summary of their many results and
achievements would be worth doing, but is beyond the scope of my knowledge. I
empirical facts? Are they handy enough for doing practical exercises*? These are
Opening Pandora's Black Box 17
the questions that guided me in selecting from the literature rules of method and
principles and to dedicate one chapter to each pair**. The status of these rules
and that of the principles is rather distinct and I do not expect them to be
evaluated in the same way. By 'rules of methods' I mean what a priori decisions
should be made in order to consider all of the empirical facts provided by the
specialised disciplines as being part of the domain of 'science, technology and
society'. By 'principles' I mean what is my personal summary of the empirical
facts at hand after a decade of work in this area. Thus, I expect these principles to
be debated, falsified, replaced by other summaries. On the other hand, the rules
of method are a package that do not seem to be easily negotiable without losing
sight of the common ground I want to sketch. With them it is more a question of
all or nothing, and I think they should be judged only on this ground: do they link
more elements than others? Do they allow outsiders to follow science and
technology further, longer and more independently? This will be the only rule of
the game, that is, the only 'meta' rule that we will need to get on with our work.
• The present book was originally planned with exercises at the end of each chapter. For
lack of space, these practical tasks will be the object of a second volume.
•• Except for the first rule of method defined above. A summary of these rules and principles
is given at the end of the book.
Part I
From Weaker
to Stronger
Rhetoric