While I have many issues with how the Nobel Prizes are put together as an institution, the scientific achievements they have revealed have been some of the funnest concepts I’ve discovered in science, including the clever ways in which scientists revealed them. If I had to rank them on this metric, the first place would be a tie between the chemistry and the physics prizes of 2016. The chemistry prize went to Jean-Pierre Sauvage, Fraser Stoddart, and Ben Feringa for “for the design and synthesis of molecular machines”. Likewise, the physics prize was shared between David Thouless, Duncan Haldane, and John Kosterlitz “for theoretical discoveries of topological phase transitions and topological phases of matter”. If you like, you can read my piece about the 2016 chemistry prize here. A short excerpt about the laureates’ work:

… it is fruitless to carry on speculating about what these achievements could be good for. J. Fraser Stoddart, who shared the Nobel Prize last year with Feringa for having assembled curious molecular arrangements like Borromean rings, wrote in an essay in 2005, “It is amazing how something that was difficult to do in the beginning will surely become easy to do in the event of its having been done. The Borromean rings have captured our imagination simply because of their sheer beauty. What will they be good for? Something for sure, and we still have the excitement of finding out what that something might be.” Feringa said in a 2014 interview that he likes to build his “own world of molecules”. In fact, Stoddart, Feringa and Jean-Pierre Sauvage shared the chemistry prize for having developed new techniques to synthesise and assemble organic molecules in their pursuits.

In the annals of the science Nobel Prizes, there are many, many laureates who allowed their curiosity about something rather than its applications to guide their research. In the course of these pursuits, they developed techniques, insights, technologies or something else that benefited their field as a whole but which wasn’t the end goal. Over time the objects of many of these pursuits have also paved the way for some futuristic technology themselves. All of this is a testament to the peculiar roads the guiding light of curiosity opens. Of course, scientists need specific conditions of their work to be met before they can commitment themselves to such lines of inquiry. For just two examples, they shouldn’t be under pressure to publish papers and they shouldn’t have to worry about losing their jobs if they don’t file patents. I can also see where the critics of such blue-sky research stand and why: while there are benefits, it’s hard to say ahead of time what they might be and when they might appear.

This said, the work that won the 2016 physics prize is of a similar nature and also particularly relevant in light of a ‘development’ in the realm of quantum computing earlier this month. Two of the three laureates, Thouless and Kosterlitz, performed an experiment in the 1970s in which they found something unusual. To quote from my piece in The Hindu on February 23:

If you cool some water vapour, it will become water and then ice. If you keep lowering the temperature until nearly absolute zero, the system will have minimal thermal energy, allowing quantum states of matter to show. In the 1970s, Michael Kosterlitz and David Thouless found that the surface of superfluid helium sometimes developed microscopic vortices that moved in pairs. When they raised the temperature, the vortices decoupled and moved freely. It was a new kind of … phase transition: the object’s topological attributes changed in response to changes in energy [rather than it turning from liquid to gas].

The findings here, followed by many others that followed, together with efforts by physicists to describe this new property of matter using mathematics, in harmony with other existing theories of nature all laid the foundation for Microsoft’s February 19 announcement: that it had developed a quantum-computing chip named Majorana 1 with topological qubits inside. (For more on this, please read my February 23 piece.) Microsoft has been trying to build this chip since at least 2000, when a physicist then on the company’s payroll named Alexei Kitaev published a paper exploring its possibility. Building the thing was a tall order, requiring advances in a variety of fields that eventually had to be brought together in just the right way, but Microsoft knew that if it succeeded the payoff would be tremendous.

This said, even if this wasn’t curiosity-driven research on Microsoft’s part, such research has already played a big role in both the company’s and the world’s fortunes. In the world’s fortune because, as with the work of Stoddart, Feringa, and Sauvage, the team explored, invented and/or refined new methods en route to building Majorana 1, methods which the rest of the world can potentially use to solve other problems. And in the company’s fortune because while Kitaev’s paper was motivated by the possibility of a device of considerable technological and commercial value, it drew from a large body of knowledge that — at the time it was unearthed and harmonised with the rest of science — wasn’t at all concerned with a quantum-computing chip in its then-distant future. For all its criticism, blue-sky research leads to some outcomes that no other forms of research can. This isn’t an argument in support of it so much as in defence of not sidelining it altogether.

While I have many issues with how the Nobel Prizes are put together as an institution, I’ve covered each edition with not inconsiderable excitement[1]. Given the fondness of the prize-giving committee for work on or with artificial intelligence last year, it’s possible there’s a physics prize vouchsafed for work on the foundations of contemporary quantum computers in the not-too-distant future. When it comes to pass, I will be all too happy to fall back on the many pieces I’ve written on this topic over the years, to be able to confidently piece together the achievements in context and, personally, to understand the work beyond my needs as a journalist, as a global citizen. But until that day, I can’t justify the time I do spend reading up about and writing on this and similar topics as a journalist in a non-niche news publication — one publishing reports, analyses, and commentary for a general audience rather than those with specialised interests.

The justification is necessary at all because the time I spend doing something is time spent not doing something else and the opportunity cost needs to be rational in the eyes of my employers. At the same time, journalism as a “history of now” would fail if it didn’t bring the ideas, priorities, and goals at play in the development of curiosity-driven research and — with the benefit of hindsight — its almost inevitable value for commerce and strategy to the people at large. This post so far, until this point, is the preamble I had in mind for my edition of The Hindu’s Notebook column today. Excerpt:

It isn’t until a revolutionary new technology appears that the value of investing in basic research becomes clear. Many scientists are rooting for more of it. India’s National Science Day, today, is itself rooted in celebrating the discovery of the Raman effect by curiosity-driven study. The Indian government also wants such research in this age of quantum computing, renewable energy, and artificial intelligence. But it isn’t until such technology appears that the value of investing in a science journalism of the underlying research — slow-moving, unglamorous, not application-oriented — also becomes clear. It might even be too late by then.

The scientific ideas that most journalists have overlooked are still very important: they’re the pillars on which the technologies reshaping the world stand. So it’s not fair that they’re overlooked when they’re happening and obscured by other concerns by the time they’ve matured. Without public understanding, input, and scrutiny in the developmental phase, the resulting technologies have fewer chances to be democratic, and the absence of the corresponding variety of journalism is partly to blame.

I would have liked to include the preamble with the piece itself but the word limit is an exacting 620. This is also why I left something else unsaid in the piece, something important for me, the author, to have acknowledged. After the penultimate line — “You might think just the fact that journalists are writing about an idea should fetch it from the fringes to the mainstream, but it does not” — I wanted to say there’s a confounding factor: the skills, choices, and circumstances of the journalists themselves. If a journalist isn’t a good writer[2] or doesn’t have the assistance of good editors, what they write about curiosity-driven research, which already runs on weak legs among the people at large, may simply pass through their feeds and newsletters without inviting even a “huh?”. But as I put down the aforementioned line, a more discomfiting thought erupted at the back of my mind.

In 2017, on the Last Word on Nothing blog, science journalist Cassandra Willyard made a passionate case for the science journalism of obscure things to put people at its centre in order to be effective. The argument’s allure was obvious but it has never sat well with me. The narrative power of human emotion, drawn from the highs or lows in the lives of the people working on obscure scientific ideas, is in being able to render those ideas more relatable. But my view is that there’s a lot out there we may never write about if we couldn’t also write about what highs/lows it rendered among its discoverers or beholders, and more so if such highs/lows don’t exist at all, as is often the case with a big chunk of curiosity-driven research. Willyard herself had used the then-recent example of the detection of gravitational waves from two neutron stars smashing into each other billions of lightyears away. This is conveniently (but perhaps not by her design) an example of Big Science where many people spent a long time looking for something and finally found it. There’s certainly a lot of drama here.

But the reason I call having to countenance Willyard’s arguments discomfiting is that I understand what she’s getting at and I know I’m rebutting it on the back of only a small modicum of logic. It’s a sentimental holdout, even: I don’t want to have to care about the lives of other people when I know I care very well for how we extracted a world’s worth of new information by ‘reading’ gravitational waves emitted by a highly unusual cosmic event. The awe, to me, is right there. Yet I’m also keenly aware how impactful the journalism advocated by Willyard can be, having seen it in ‘action’ in the feature-esque pieces published by science magazines, where the people are front and centre, and the number of people that read and talk about them.

I hold out because I believe there are, like me, many people out there (I’ve met a few) that can be awed by narratives of neutron-star collisions that dispense with invoking the human condition. I also believe that while a large number of people may read those feature-esque pieces, I’m not convinced they have a value that goes beyond storytelling, which is of course typically excellent. But I suppose those narratives of purely scientific research devoid of human protagonists (or antagonists) would have to be at least as excellent in order to captivate audiences just as well. If a journalist — together with the context in which they produce their work — isn’t up to the mark yet, they should strive to be. And this striving is essential if “you might think just the fact that journalists are writing about an idea should fetch it from the fringes to the mainstream, but it does not” is to be meaningful.

[1] Not least because each Nobel Prize announcement is accompanied by three press releases: one making the announcement, one explaining the prize-winning work to a non-expert audience, and one explaining it in its full technical context. Journalism with these resources is actually quite enjoyable. This helps, too.

[2] I’m predominantly a textual journalist and default to “write” when writing about journalistic communication. But of course in this sentence I mean journalists who aren’t good writers and/or good video-makers or editors and/or good podcasters, etc.

The Nobel Prizes are a deeply flawed institution both out of touch with science as it is done today and with an outsized influence on scientific practice at the most demanding levels. Yet these relationships all persist with the prizes continuing to crown some of the greatest achievements in the history of modern science.

What the Nobel Prizes are not

The winners of this year’s Nobel Prizes are being announced this week. The prizes are an opportunity to discover new areas of research, and developments there that scientists consider particularly notable. In this endeavour, it is equally necessary to remember what the Nobel Prizes are not. For starters, the

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The prizes are exclusive by design and their prestige is enforced through a system of secrecy: the reasons for picking each laureate are locked away for 50 years even as the selection process happens behind closed doors. In keeping with a historical tradition of all prizes being distinguished by their laureates, the Nobel Prizes are sought after so scientists can enter the same ranks that hold Niels Bohr, Albert Einstein, Marie Curie, etc.

Of course the institution like others of its kind reinforces the need for itself, creating self-fulfilling conditions by mooching off the reputation of scientists who have laboured for decades in specific social, economic, cultural, and political contexts to produce knowledge of incredible value and in return conferring a reputation of a different kind. This is why Jean-Paul Sartre tried to decline the Nobel Prize for literature in 1964.

Then again, the way the award-giving foundation conducts the prizes’ announcements has also helped to ameliorate the neglectful treatment many sections of the mainstream media, especially in India, have meted out to the sort of scientific work the prizes fete, even if the foundation’s conduct also panders to the causes of such treatment.

The prizes

I think the Nobel Prizes for physiology/medicine and for physics caught many science communicators off guard because they were both concerned with very involved pieces of work with no direct applications. The medicine prize was for the discovery of microRNA and post-transcriptional gene regulation, which when it happened overturned what biologists had assumed was a complete picture of how the body’s cells regulate genes to make different proteins.

The physics prize was for the first work on artificial neural networks (ANNs), which produced a machine-friendly version of cognition by drawing on ideas in biology, neuropsychology, and statistical mechanics. If this work hadn’t happened, ChatGPT may not exist today, but several other developments built on the first ANNs to produce more new knowledge whose accumulation eventually led to ChatGPT et al. Ergo, calling ChatGPT et al. an application of the first ANNs would be thoroughly misguided.

The chemistry prize — for the development of computational tools to design proteins and to predict their structures — presented a slightly different problem: the tools' advent meant humans suddenly found themselves spending much less time on deciphering the structures, yet the tools didn't, and still don't, say why proteins prefer these structures over others. Scientists still need to figure out the why by themselves.

All this said, I’m grateful this year as I’ve been before for the prizes’ ability to throw up an opportunity for all sections of the media to discuss scientific work many of them would most likely have neglected otherwise. Reading the research papers that first reported the existence of microRNA and the papers that explained how models to understand exotic states of matter lent themselves to the first ANN concepts allowed me personally to refresh my basics as well as be reminded of the ability of blue-sky scicomm — as a direct counterpart of blue-sky research, one that isn’t fixated on applications — to wow us.

This post benefited from feedback from Thomas Manuel and Mahima Jain.

The Rosalind Lee issue

To reiterate from the introduction, the Nobel Prizes are one institution with deep and well-defined flaws. And I have learnt from (journalistic) experience that there’s no changing its mind. It's too big to change and doesn’t admit the need to do so, and its members have had no compunctions about articulating that in public. The vast majority of scientists also subscribe to the prizes’ value and their general desirability. So it is my view today that we work around the prizes and/or renounce the prizes altogether when dealing with the award-giving group’s choices.

Caste, and science’s notability threshold

A webinar by The Life of Science on the construct of the ‘scientific genius’ just concluded, with Gita Chadha and Shalini Mahadev, a PhD scholar at HCU, as panellists. It was an hour long and I learnt a lot in this short time, which shouldn’t be surprising because, more

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A third option is to change the foundation’s mind but this requires a considerable amount of collective work to which I doubt more than a few would like to dedicate themselves. Mind-changing work is demanding work. Then again the problem is if you fall anywhere in between these two more-viable options, you risk admitting other possibilities vis-à-vis the Nobel Prizes that (I imagine) you’d rather not.

For a background on the Rosalind Lee issue, I suggest you browse X.com. My notes on it follow:

(i) The Nobel Foundation has historically reserved the Nobel Prizes for persons who conceived of important ideas and made testable predictions about them. The latter is important. IIRC this is why SN Bose didn't win a Nobel Prize for coming up with Bose-Einstein particle statistics. Albert Einstein could have won instead because he built on Bose's ideas to predict the existence of a particular state of matter: the Bose-Einstein condensate. Who came up with the testable predictions in the paper that won Victor Ambros a share of the medicine Nobel Prize?

I’m not directly defending the exclusion of Rosalind Lee, who was the first author of that and in fact many of the more important papers Ambros published in his career. Instead, I’m pointing to an answer that could explain her exclusion with a reminder that the answer is flawed and that it has always been flawed. I suppose I’m saying that we couldn’t have expected better. 🙃

(ii) Physics World recently published an interview with Lars Brink, a physicist who has been part of the decision-making for many physics prizes the last decade. Brinks bluntly states at one point that the Nobel Academy doesn't give the prizes to collaborations or in fact even more than three people at a time because they don't want 5,000 people (for example at CERN) claiming they're Nobel laureates all of a sudden. There is an explicit and deliberate design here to keep the prizes exclusive, like Hermes handbags.

(iii) The first author is often the one who designs the experiment, performs it, collects the data, analyses it, etc. — basically everything beyond, but not necessarily excluding, the act of having an idea itself and including most of the legwork. The Nobel Prizes however are not awards for legwork. This sucks because it’s a profound misunderstanding of the people required to produce good-quality scientific knowledge.

Thanks to the influence the prizes exert on the scientific community, the people who are left out also fade further — in the public view and also in terms of not being able to benefit from the systematic rewards vouchsafed for the Nobel laureates who are now institutions unto themselves. The fading is likely compounded for people already struggling to be noticed in the scientific literature: the “technicians” who equip, maintain, and operate laboratory instruments, among others (a.k.a. the Matthew effect). Of course the axis of discrimination is gendered as well: as one friend put it, “the ‘leg work’ of science is historically feminised”, and when awards and other forms of recognition exclude such work they perpetuate the Matilda effect.

How cut-throat competition forces scientists to act against the collective

Brian Keating, an astrophysicist who led the infamous cosmic inflation announcement in 2014, thinks this is how science works: “… you put out a result, and other scientists work to test the result”. However, his own story shows that this is a cute ideal that’s often unreasonable to expect on

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Overall, whether the prize-giving body is aware of these narratives and issues is moot. What matters is that it acknowledges and responds to them — which it has signalled it won’t do. QED.

(iv) In fact, all these rules of the Nobel Prizes are arbitrary. It's effectively a sport and a poorly managed one at that. You make up a playing field, publicise some of the rules, keep the governing body beyond reach or reproach, hide the scorecard, and then you say you have to jump five feet in the air to qualify. The outragers are raising their voices for Rosalind Lee (what does she want, by the way?) but not for the first authors of all the other papers by other laureates over the years. If they don’t belong to marginalised social groups, is it okay to leave them out? Then again these are moot questions, pursuits leading nowhere at all thanks to the Nobel Prizes’ presumption that they’re not of this world.

The Nobel Prizes have also wronged many women, but I can't claim to know whether there's a case-by-case explanation (with arbitrary foundations) or if it was a systematic program to do so. Both seem equally likely given how slow attitudes have been to change on this front. This said, just because women have been wronged doesn’t mean all forms of reparation will be equally useful. More specifically, what will breaking the (arbitrary) rules do to change for women in science?

Obviously this is part of a broader question about the influence of the Nobel Prizes on doing science. Mukund Thattai ran a survey on Twitter years ago asking scientists about why they got into or stayed in science. "Because of a Nobel laureate” received the fewest votes in a large pool of respondents. It wasn’t a representative survey but it does hint at an important piece of reality. Once we start to argue that including Rosalind Lee would have been better, we also tacitly admit the Nobel Prizes matter for who chooses to stay in science and who is condemned to fade — but do they?

On the other side of this coin lie all the other prizes that did fete Rosalind Lee along with Victor Ambros. If we’d like to have any prizes at all (I don’t but YMMV), shall we celebrate the Newcomb Cleveland Prize more than the Nobel Prizes? Likewise, by railing against Rosalind Lee’s exclusion on arbitrary grounds, what do we hope to achieve? It may be more gainful to spread awareness of the Nobel Prizes’ flaws and finitude and focus on the deeper question of how the opportunities to win X award can influence the way science is done, who does it, and why.

Couple things in my news feed this morning that really woke me up — one a startling statistic and the other a reminder of what statistics miss. The first from Nature, 'How to win a Nobel prize: what kind of scientist scoops medals?':

John W. Strutt, who won a physics prize in 1904 for his work on the properties of gases, has 228 academic descendants with Nobels — his students, their students and so on. … An incredible 702 out of 736 researchers who have won science and economics prizes up to 2023 are part of the same academic family — connected by an academic link in common somewhere in their history. Only 32 laureates … have no connection to the bigger academic family.

Meaning it's nearly impossible for 'true' outsiders to break in. Either you become part of the The Network or you have a very low chance of winning a Nobel Prize. Of course the prize-giving apparatus isn't a machine. There are humans making these decisions and clearly in a famously human way: not really paying attention to the consequences of their preferences or assuming that that doesn't, or even shouldn't, matter.

But what does The Network say about science itself, especially about good* science and where that gets done? That is, what institutional mechanisms and/or forces are (even passively) encouraging the scientists who do such work to clump together?

One factor that immediately comes to mind is funding: in the typical Indian experience, because most places of research have traditionally not been well-funded, the government or some philanthropic entity endeavours to set up a few facilities focused on research and funds them well, while the rest struggle on.

On a related note, should the diffusion of researchers who produce good-quality research (and know how to do it) into previously neglected locales be desirable?

Next, the reminder of what statistics miss:

The French researcher and physician Didier Raoult has been banned from practising medicine for two years. It is the latest and probably most significant sanction against Raoult after he became infamous during the pandemic for his enthusiastic support for hydroxychloroquine even though the drug lacked evidence of its efficacy against COVID-19.

His claims brought the spotlight on him as he probably intended but then expanded to reveal he had published too many papers — much more than should be humanly possible. But Raoult took pride in his research metrics, so even as research integrity investigators including Elisabeth Bik revealed dire problems in his published** papers — including image manipulation and ethical lapses in clinical trials that rendered them illegal — Raoult and his supporters came out swinging on social media.

He also filed a lawsuit against Bik alleging she and others were besmirching his name without reason. Raoult eventually lost these disputes and in the process the trust and respect of the research community. Now his medical license has been revoked. He was retired but the action was clearly symbolic: Raoult is done.

It took Bik's and her peers' scepticism to reveal the extent of Raoult's misdemeanours. His metrics betrayed nothing of it except through their largeness.

As if on cue, The Hindu published an excellent opinion piece by S. Swaminathan today about why and how we educate people, including those who become professional scientists:

The metrics-focused system has created a situation which implies that education is a market rather than a citizen’s right and the state’s duty.

* "Good" here means worthy of winning a Nobel Prize, not good per se.

** Remember that they were published, meaning the journals that did are answerable, too.