Is my science champion really a champion?

Suppose I tell you my neighbor’s son is one of the best soccer player in the world. How would you check? You would immediately Google him to see in which team, in which league, the prodigy plays. If you couldn’t find anything, you would be wondering. Who is this world-class player Google doesn’t know (just try with Messi or Cristiano Ronaldo)? In the same vein, if you found him playing for the Miguelturra team in Spain, you would equally wonder. Who is this alleged best player in the world who plays in Spain, granted, but not in Madrid or Barça, but in the CD Migueltureño, a third division team ?

 The universe Science and Faith is full of names supposed to represent “great” scientists. Obviously, the more the scientist says what I think, the “greater” he is. How can you check? How can you know if such and such, presented as great scientists, really are?      

Just see if they play in first league, in the NBA. For physics, astrophysics, climate science (see the blue section below for climate science), here’s how.

The “astrophysics data system” database

Scientists write articles to explain their work. In these articles, they cite the articles upon which they rely. When I was a PhD student at Orsay University (France) in the early 90s, I would go to the library every week to read the journals publishing articles related to my research. Nature, Science, Physical Review, Physics of Fluids, etc. It was very common for one article to cite another, which cited another, which cited another, which made me navigate from journals to journals. Quickly, I would realize that a given author was often cited for having written one or more influential articles.

I now make this weekly pilgrimage from my computer. In the 90s, when the internet took off [1], databases were organized to index all this information. One of them is the astrophysics data system (“ADS”). Run by NASA and the Harvard–Smithsonian Center for Astrophysics, it indexes nearly 15 million articles in math, physics and astrophysics, some of which date back to the 16th century [2]. There are other databases, but this one has the advantage of being free and powerful. Let me emphasize that it only indexes journals dealing with physics, math or astro. So if you query it about one of the last Nobel Prize winners in medicine, it will only give you what he published in multidisciplinary journals like Nature or Science. Not his complete works.

For each scientific article, ADS indexes the authors, their academic affiliation, the list of all other articles that cite it, etc. Thanks to ADS, a bibliographic search which took 1 week during my PhD thesis is now done in a few minutes. Starting from the name of a scientist, you can easily check,

  1. If your scientist is currently active, that is to say if his last article dates from 2020 or goes back to 1980.
  2. If his work has an impact, that is, if it is often cited because it sparked further research.

All the “big ones” satisfy the second criterion. By definition, all the “big ones” currently active satisfy the first as well.    

How does it work?

When you get to the main page, you find this,

 

 

A simple interface, with a single field to type your request. With the possibility of launching a query on other fields, such as the year of publication or the name of the journal, and of combining them with the AND or OR operators, you can launch quite elaborate searches.

Let’s just ask for the articles of a so-called “Einstein, A”. By clicking on the white magnifying glass on the blue background on the right, or by typing “Enter” on my keyboard, I get this,

As you can see, you have to filter a little more because there is at this very moment at least one other “Einstein, A” in activity, which is obviously not our Albert. I will therefore filter the results to retain only the articles published between 1901 and 1955, the date of his death. I therefore replace 2019 with 1955 in the red enclosed area at the bottom right and press “Apply”. I get this,

 

The search box now contains the weird formula I could have typed directly to get there. The area I mark in red indicates his co-authors. Insiders will recognize Rosen and Infeld, but we also discover Laub and de Haas. The green area tells that the database contains 155 articles in peer-reviewed journals (“refereed”), and 49 elsewhere. As we can see, with 204 works in 53 years (1901-1954), Einstein was remarkably productive.   

But this is not the most important. One can very well publish 204 articles without any impact. This is not the case with Einstein. To see this, let’s click on the menu circled in orange where we see “Date”, and choose “Citation Count” instead. We get that,

Where there was “Date” before, there is now “Citation Count” (marked in orange). Here ADS tells us that Einstein has been cited almost 20,000 times (in red). In case you are wondering, yes, that’s a lot. Articles are now ordered by number of citations received, not by date. The first one has been cited 7,231 times (in green) so far, which is huge. I cannot resist the pleasure of pointing out that this article is false. It is that of the famous EPR paradox. But so it is with brilliant people: they are interesting even when they are wrong [3].

A few comments

I urge you to play around with the database a bit. I have only commented on a few of its options. But you can filter by journal, co-authors, academic affiliation, etc. It is quite intuitive. A few remarks now. Each time I quote a scientist, it will suffice to click on his name to see his record in the ADS database.

 

  • Anglo-Saxons often have a middle name allowing to further refine the search. For example, searching for the works of Freeman Dyson (this is his Wikipedia page. See below for his works on ADS) yields more precise results by typing “Dyson, Freeman J”. The “J” sets him apart from others Freeman Dyson’s. If that is not enough, which is the case for the Dyson I’m interested in, we can filter on the left by “AFFILIATIONS”. Cornell and Princeton for Dyson.      
  • It can be very difficult to isolate the works of a scientist whose name is too common. Knowing what an Anglo-Saxon named “John Smith” or a Korean named “Jeon Park” did can be a real puzzle. Unless additional filters save you the day, you’ll have to hope they posted their publication list on their own website, or that they have an ORCID number.
  • ADS does not tell you if people have a PhD. In fact, frankly, nobody cares. The database tells you what someone accomplished scientifically, PhD or not, and that’s what matters. Freeman Dyson did not have a PhD, but his work had a huge influence.
  • A corollary is that being a PhD does not say anything about your scientific contributions. A “prominent”, “world-class”, “renowned” scientist is someone whose articles matter, PhD or not.      
  • Public fame is not synonymous with scientific stature. Perhaps Einstein and Stephen Hawking are the only ones whose public fame matches scientific contributions. Roger Blandford is one of the most influential astrophysicists of the past 50 years, and he is virtually unknown to the public. Same for Lev Landau, John Wheeler, Iakov Zeldovitch, Carlo Rovelli or Peter Goldreich (the list is far longer).
  • Watch out for the numbers. Blandford has more articles and citations than Einstein, which doesn’t mean he outshines him. He would be the first to recognize it (I know him personally). Beyond a few tens of thousands of quotes, we are dealing with a “big one”, with a very uncertain hierarchy. Now a physicist cited 20,000 times has clearly brought more than another cited 100 or even 1,000 times [4].

So, is my science champion really a champion?

The Science and Faith debate is teeming with scientists presented as “eminent”, “world class”, and alike. Are they really so? Sometimes, alas, well, not really. Just a few examples (let’s make friends):  

  • A Christian apologist once called David Berlinski a “world leading physicist”. As you can see, the ADS version is nearly “who is Berlinski?”.  
  • Hugh Ross, sometimes referred to as “a respected astronomer” [5], has not published anything since 1977 and his 10 articles have had little impact (53 citations to date). He’s “respected” by many, but not by the scientific community.
  • Young Earth Creation Astrophysicist Jason Lisle published the last of his 6 papers in 2008, and received just 193 citations in all. His colleague Russell Humphreys, who now tortures General Relativity, only received 204 citations for his 9 articles. The case of Danny Faulkner is similar, with 209 citations for 27 articles [6].

Note that being a champion in one discipline does not mean you are a champion in another field. Rafael Nadal sucks at curling and Stephen Hawking was a far better physicist than philosopher.

Let’s finish with some Christians, scientists currently in activity, who are genuine champions : Ian Hutchinson (MIT), Anthony Bell (Oxford), Katherine and Stephen Blundell (Oxford), Lorenzo Sironi (Columbia), John Barrow (Cambridge), Karin Oberg (Harvard), Don Page (Alberta), Juan Maldacena (Princeton), Gerald Gabrielse (Harvard), George Ellis (Cape Town), Eric Priest (St Andrew),… 

So all those declared “champions” are not necessarily so. Fortunately, some are, definitely. You now know how to spot them.

What about climate science?

Climate science is also indexed in ADS. Here’s what you get when you plug some good climate scientists in the database: Stefan Rahmstorf, Katharine Hayhoe, Hervé Le Treut, Michael Mann, Richard Alley, Edouard Bard, James Hansen, Raymond Pierrehumbert.


Footnotes

[1] I received my first email in 1994. I didn’t even know I had an email address.

[2] To launch a query that returns the full content of the database, just ask for the articles written between 1500 and 2020. As of September 16, 2020, the query returns 14,843,813 articles. The oldest, in Latin, is from 1502! Noteworthily, 90% of these 15 million were written in the last 50 years.

[3] This reminds me of Niels Bohr when he said “the opposite of a profound truth may very well be another profound truth”.

[4] Todate I’ve been cited more than 2,000 times, and I know very well that my contributions are not those of Blandford.

[5] The Google query “Hugh Ross” ” respected astronomer” returns about 100 pages.

[6] It seems there are several Danny Faulkners. So I filtered by affiliations (Indiana where he did his thesis, then South Carolina, where he is a professor). The 27 items found fit well the “two dozen” mentioned on his creation.com page.

 

 

 

 

 

 

It was Julius Caesar who killed Napoleon

And if you disagree, it’s because official history has brainwashed you…

Irritating, isn’t?

Let’s see why this is irritating.

For a start, that wouldn’t irritate everyone. This sentence would leave a 5-year-old child unmoved, for example. Save extreme precocity, he has no idea of ​​the history of the world and can easily buy that Julius Caesar killed Napoleon. Ditto for the Yanomami Indian of South America who is probably clueless on the history of Europe. On the other hand, the same Indian would laugh when watching me confusing two birds or two plants species, which are like night and day to him.

Another example. Imagine Google Maps does not exist, and I claim that in Madrid, General Moscardo Street is now called Aviator Zorita Street. You would take my word for it. Yet anyone who knows my neighborhood would know I’m dead wrong. General Moscardo Street did change its name, but it is not called Aviator Zorita Street now. Not at all. But since 99.99% of my readers probably don’t know anything about my neighborhood in Madrid, my mistake would surely go unnoticed. The remaining 0.01%, however, would wonder, “What’s the matter with Antoine? “.

 

Where am I going with this? Some claims are clearly right or wrong, but it takes some initiation to see it. A little knowledge of history is enough to know that Caesar did not kill Napoleon (everyone knows it was President Roosevelt). A little knowledge of Madrid is enough to know, without a doubt, that General Moscardo Street is not now Aviator Zorita Street.

And in the Science & Faith debate, do we have similar patterns? Yes. For example, as explained here, some knowledge of General Relativity is enough to know that the Minkowski metric is not the FLRW, which is not that of Schwarzschild, and that time and light do not stop when the coefficient of dt2 in a metric changes sign, as Russell Humphreys claims in his “cosmology”.

Yet, if most adults know enough history to shrug their shoulders, or call a doctor, on hearing someone claim that Julius Caesar killed Napoleon, few know enough my Madrid neighborhood to detect my mistake in the names of the streets, and few know enough of General Relativity to detect the enormities uttered by Humphreys.

 

What can we learn from this? Let us be careful when using science for apologetics. Stimulated by apologetic zeal, it is very easy to find yourself saying that Julius Caesar killed Napoleon. The result will be stumbling block apologetic. Learn before you preach. 1600 years ago, Augustine warned against this very mistake,

“Usually, even a non-Christian knows something about the earth, the heavens, and the other elements of the world, about the motion and orbit of the stars and even their size and relative positions, about the predictable eclipses of the sun and moon, the cycles of the years and the seasons, about the kinds of animals, shrubs, stones, and so forth, and this knowledge he holds to as being certain from reason and experience.

It is a disgraceful and dangerous thing for an infidel to hear a Christian, presumably giving the meaning of Holy Scripture, talking nonsense on these topics; and we should take all means to prevent such an embarrassing situation, in which people show up vast ignorance in a Christian and laugh it to scorn… If they find a Christian mistaken in a field which they themselves know well and hear him maintaining his foolish opinions about our books, how are they going to believe those books in matters concerning the resurrection of the dead, the hope of eternal life, and the kingdom of heaven, when they think their pages are full of falsehoods on facts which they themselves have learnt from experience and the light of reason?

Reckless and incompetent expounders of Holy Scripture bring untold trouble and sorrow on their wiser brethren when they are caught in one of their mischievous false opinions and are taken to task by those who are not bound by the authority of our sacred books.”

Augustine, The literal meaning of Genesis, Book 1, 19.39 (circa AD 415).

Why Russell Humphreys’ cosmology is (really) wrong

The starlight “problem”

Young Earth Creationist (YEC) claim the universe is 6,000 (or 10,000) years old. If it’s really that young, how can we see stars 30,000 (and more, much more) light years away?

Some, like Russell Humphreys, think General Relativity (GR) can help.

How General Relativity works: The Interstellar movie

In the movie Interstellar, Matthew McConaughey misses the teen years of his daughter Murphy for having spent too much time on a planet too close to the “Gargantua” Black Hole. One single hour on “Miller’s planet” is 7 years on Earth! Gargantua weights about 100 million times more than the sun[1], and yes, according to General Relativity (GR), a planet orbiting it like “Miller’s planet”, would enjoy such a crazy time contraction.

According to his own wristwatch, Matthew McConaughey spends a little more than 3 hours on this planet. When he comes back to his mother ship, he finds he’s been away for 23 years. His daughter Murphy was about 10 when he left. She’s now 30 something.

How does it work?

The gravity of the Black Hole (BH) increases as you get closer to it. As long as gravity is not too strong, one may define a so-called gravitational potential, which goes down and down as you approach Gargantua, like in the figure below (absolutely not to scale).

interstellar 3

What GR tells you is that time goes slower in the potential well [2]. The deeper you’re in the well, the slower time passes with respect to Earth. Until you get to the “Event Horizon”.

What happens past then? If you were to fly to the Event Horizon, an observer from Earth would see you approaching it closer and closer, without never crossing it. As for you in your spaceship, you would definitely cross the Event Horizon. Passed this point, it would be impossible to turn back. You would inevitably crash at the center in a time that can be calculated [3].

Note that talking about a “gravitational potential” only makes sense while General Relativistic effects are small. It makes no sense at all below the Event Horizon.

In Interstellar, all this happens over a few billion kilometers. The Earth is far away from this all, completely out of the potential well of the black hole. And yes, according to Einstein’s General Relativity, you would get such a crazy time contraction of Miller’s planet.

In Interstellar, 1 hour on the planet becomes 7 years out there. And 6,000 years? What would they give out there? 0.36 billion years!

Could GR hold the key to thousands of years on earth being like billions in the rest of the universe?

Russell Humphreys’ cosmology

I refer to the cosmology described here.

Humphreys imagine the Earth is at the center of a huge expanding spherical shell with “waters above”. Using GR, he “derives” (why between quotes? See below) the gravitational potential inside the sphere. As you can see on the figure below, the sphere is huge [4]. The Earth is somewhere inside.

humphrey 2

The gravitational potential goes down as one approaches the sphere. It is constant inside. So a clock in the inside, where the Earth is, will tick slower than a clock outside. Like in Interstellar, clocks tick slower as you go down the gravitational potential.

From there Humphreys argues that if “during the fourth day, God creates star masses” so as to lower even more the flat potential inside the sphere, around the Earth, time there would have stopped. It’s even better than Miller’s planet…

Let’s now see the problems.

It just turns out that 1) observations do not back up the existence of Humphreys’ spherical shell and 2) Humphreys’ claims about what would happen if the inside gravitational potential were lowered beyond a “critical potential” (see his figure 7), is wrong according to GR.

What observations tell about the spherical shell

To start with, Humphreys’ solution of GR equations (his equation 2) is not “new”, as he claims. This is just the solution Karl Schwarzschild found in 1916. And it cannot be otherwise. Why? Because there is only one solution to GR equations with spherical symmetry [5] and it is Schwarzschild’s solution (if  there’s but one solution and you find one, then this must be the one). So Humphreys’ solution cannot be “new”.

Then,

  • The waters above the spherical shell cannot be liquid. Why? Because nothing sits on top. So it is under 0 pressure. And under 0 pressure, water cannot be liquid. It is either solid ice, or vapor.
  • What about the shell itself? The universe is expanding, and it seems Humphreys admits this. So let’s play backward the movie of the universe. The spherical shell and the universe contract. They get hotter and hotter. Regardless of what it is made of (what is it made of?), the hotter and hotter spherical shell vaporizes. Its molecules are broken, as are those of the universe inside. Then the atoms that made this all are also broken into electrons, protons, and neutrons. Then protons and neutrons are broken into quarks [6].
    Let’s now play the movie forward from this quark epoch (we don’t really know what came before because we don’t know the laws that applied then). The universe cools down and these quarks assemble to make protons and neutrons. These protons and neutrons assemble to make atoms [7]. The universe keeps expanding, hence cooling down, and these atoms can combine to make molecules. Question: at one point does the spherical shell forms? At the beginning of our movie, it wasn’t there. So when and how did it form? No natural phenomenon is going to make a spherical shell of “something” with “waters above”. And if it was supernaturally there from the start, why going to such great length to come up with a pseudo-natural scenario “explaining” the starlight problem?
  • According to GR, the interior of the spherical shell is “flat”. It’s good old space time. The problem is that such a space time does not expand [8]. That’s what GR dictates. Even if the spherical shell does, the interior does not, and Humphreys equations 2 & 3 are OK with that. Two inside points 1 million light years from each other will still be so 1 billion years later
    This is a problem because we observe the expansion. Stars recede from us. The farther, the faster. In Humphreys’ “cosmology”, there’s no redshift. In Humphreys’ “cosmology”, the temperature of the Cosmos Microwave Background doesn’t change with time. Yet, such a temperature change has been observed.

Humphreys’ GR below the “critical potential” is wrong

Looking at the math of how time passes slower inside the shell than outside, one notices that if the ratio R/M is large enough (R = radius of the shell, M = its mass), something strange happens to the math [9]. If that happens, Humpreys writes that “physical clocks would stop completely. Time would no longer exist” and “light cannot propagate”!

Obviously, stopped clocks allow to squeeze anything you want in just no time.

The problem is that if R/M turned to be large enough, and contrary to what Humphreys claims, GR states that clocks inside the shell would not stop. And light would keep propagating.

These are very well-known results since the situation produced for R/M large enough is precisely the one produced inside the event horizon of a black hole. Admittedly, what happens there is quite weird and it took physicists decades to grasp it. Yet, however involved it may be, some things are sure: clocks keep ticking inside an event horizon, and light keeps propagating. A classical calculation of General Relativity even consists in computing the time it would take for an astronaut to reach the center of a Black Hole [10]. Part of this time is definitely the one is takes to go from the event horizon to the center. According to GR, clocks do tick “inside”. Besides, light does propagate.

Conclusion

Let’s wrap it up. Humphreys’ cosmology fails at various stages. It assumes a huge spherical shell around us, that cannot have formed unless it got there miraculously. Then General Relativity inside this sphere gives a space time which is not expanding whereas observations do show it does. Finally, Humphreys has GR tell that in some special circumstances, time no longer stops inside the shell, and light cannot propagate, whereas GR doesn’t tell this at all [11].

This is clearly some conclusion-driven, bad, “science”. Humphreys comes up with an arbitrary scenario only designed to explain away the YEC starlight problem. Then it becomes bad science: the spherical shell invoked cannot have formed naturally, and its consequences do not match observations. And then it becomes bad GR: after having invoked GR to the rescue, Humphreys has GR predicts phenomena it doesn’t.

This is a good example of why “mainstream science” rejects “creacion science”. The reason why “mainstream science” rejects “creation science” has nothing to do with religion. Einstein talked about God, Abdus Salam was a devout Muslim, Ramanujan attributed his findings to a Hindu goddess. Many of my friends astrophysicists talk about God in the lab. I talk about God.

No, the real reason why creation science is rejected, is because it tramples logic, observations and experiments. It perfectly fits CS Lewis’ words [12],

Science twisted in the interests of apologetics would be sin and folly


Footnote

[1] See The Science of Interstellar by Nobel Prize Kip Thorne. The reader will also find more technical data on the same topic here.

[2] Such gravitational time shift has been checked experimentally many times and is now in use in your GPS.

[3] The falling time is computed in Gravitation, by Misner, Thorne, and Wheeler, page 820. It is finite for the astronaut, and infinite for the observer.

[4] Its size is a little less than the one of the observable universe, about 46 billion light years, see https://arxiv.org/abs/astro-ph/0310571

[5] That’s the Birkhoff’s theorem.

[6] All these states of matter have been studied in the lab. There’s no conjecture here. Matter does that when you heat it more and more.

[7] Using the known laws of physics, you can derive from this scenario the relative abundances of light elements and compare to observations. It was done from 1948 and works well. Others expected and observed consequences of the movie are the Cosmic Microwave Background or the Baryonic Acoustic Oscillations.

[8] The “Minkowski metric” describes the good old flat space time. If you want expansion you need something like the “Friedmann–Lemaître–Robertson–Walker metric”. See for example equation (28.9) page 1371 of Modern Classical Physics by Thorne and Blandford. Or simply Google “FLRW metric”.
By the way, George Lemaître was a priest.

[9] Technically, the coefficient of dt2 in Eq. (2) becomes negative.

[10] See note [3].

[11] Just check for example Figure 26.4 page 1269 of Modern Classical Physics by Thorne and Blandford. It shows how light does propagate within the Even Horizon.

[12] CS Lewis, God in the Dock: Essays on Theology and Ethics, Eerdmans Publishing Co, 1972, p. 93.

Consensus. What’s that?

We often hear about scientific “consensus”. The thing seems quite misunderstood, sometimes seemingly considered as a gentleman agreement between researchers tired of getting headaches over a topic, or wanting to impose a conclusion. “Let’s say it’s like this, and that’s it!”.

No, it doesn’t work like that.

As an illustration, let’s see how a consensus was reached… on the sources of the Nile river. We will then make the comparison with the consensus reached on the Big Bang.

The sources of the Nile

The Nile delta has been known for millennia. Not the same for its source [1] which location remained a mystery for almost the same time. Let’s make this long story short [2]:

  • When Alexander the Great saw the Indus river around 325 BC, he thought he had found the source of the Nile. Still in the 6th century, the Byzantine historian Procopius of Caesarea wrote “the Nile flows from India to Egypt…”.
  • Egyptians contemporary of Herodotus saw the source at Aswan.
  • Juba II king of Mauretania (50 BC – 23 AD) thought he had discovered the sources of the Nile in the Atlas Mountains, northwest of Africa.
  • Ptolemy (2nd century) was perhaps the first to near reality by placing the source of the Blue Nile at Lake Tana, and that of the White Nile further south, in some legendary “Mountains of the Moon”.
  • The British explorer John Speke discovered Lake Victoria in 1858 and thought it would make an excellent source. Of course, his colleagues were not satisfied with his testimony only.
  • It was Henry Stanley who confirmed the discovery in 1875 during the expedition where he was to meet Livingstone and ask the famous and so British “Dr. Livingstone, I presume?”.

So was solved the enigma of the source of the Nile, after literally thousands of years of research. Long before satellite pictures, and, interestingly, long before someone navigated it from start to finish, which only happened in 2004 [3]!

The Big Bang

Well for the Big Bang, pretty much the same happened. On the Nile side, we had:

  • Competing hypotheses: India? Aswan? Mountains of the Moon? Atlas Mountains?
  • A discovery, that of Speke, is not enough.
  • Verification.

It would be difficult to imagine explorers of the 6th century complaining,

We’re fed up with this Nile business. Enough of it. Let’s choose a location for the source, and settle the case!

It is obvious that they were going to seek until they’d find it, that competing hypotheses were going to arise, and that the end of the story would come by checking them all.

What about the Big Bang? Ditto, almost,

  • Competing hypotheses: Static universe or not? From Aristotle to Einstein in his 1917 article, the first option had strong supporters. The second, that of a dynamic universe, was mainly introduced by Hubble’s observations in 1929, but precisely…
  • Hubble’s observations didn’t settle the matter [4]. Einstein changed his mind in 1931 [5], but the controversy did not end there.
  • People wanted to check, which is perfectly normal. One check came from the solution of Einstein’s equations found by Friedmann, Lemaître, Robertson and Walker. The cosmic microwave background (CMB), predicted in 1948 and discovered in 1964, impressed many. The relative abundance of light elements did the same.
  • It was towards the end of the 1960s that the consensus arose, mainly the fruit of the discovery of the CMB [6].

Today, nearly all cosmologists think that some 14 billion years ago, the universe went through a very dense and hot phase and that it has been expanding since then. Other checks [7] have come to strengthen the picture which, ultimately, mainly owes its raison d’être to the expansion of the universe. Just rewind the movie.

Whether it be quantum mechanics, general relativity, plate tectonics, anthropogenic global warming or shockwaves in interstellar vacuum, consensus were established the same way. They don’t arise because people are fed up with not knowing, or fear any conclusion. They arise because years of study and checking have left no choice.

One only needs to make sure he/she doesn’t see consensus were there’s not (like on how the universe began – if it ever did).

But that is another story.


Footnotes

[1] Or rather its sources, since we have to distinguish the White Nile from the Blue, but let’s simplify.

[2] For the long version, see for example Terje Oestigaard & Gedef Abawa Firew, The Source of the Blue Nile: Water Rituals and Traditions in the Lake Tana Region, Cambridge Scholars Publishing, 2014.

[3] “National Geographic” produced in 2005 a documentary on this expedition entitled The Longest River.

[4] The main alternative to redshift as indicating receding velocities was Fritz Zwicky’s “tired light”. It has been discarded for many reasons (distant objects would be blurred, shift would depend on the frequency, etc. More here or here).

[5] Harry Nussbaumer, Einstein’s conversion from his static to an expanding universe, European Physics Journal – History, 39, 37-62 (2014).

[6] See for example Helge Kragh, Cosmology and Controversy, Princeton University Press, 1999.

[7] Temperature of the CMB at several epochs, structures of the universe and their distribution, baryonic acoustic oscillations, etc.

A few deniers’ (bad) habits

  1. Pretend there’s still a debate between experts. That there’s no consensus. If proved wrong, pretend consensus doesn’t mean anything anyway.
  2. Pretend the PhDs on your side are top notch, all time world class, scientists. If proved wrong, pretend expertise doesn’t mean anything anyway.
  3. Pretend the PhDs on your side are top notch, world class scientists. If proved wrong, complain about “Ad Hominem”.
  4. Pretend your alternative theory is about to overcome the status quo, even though in reality, virtually no one knowledgeable cares about it.
  5. Discard any evidences you’re presented. Then claim, “there are no evidences”.
  6. When cornered, never acknowledge. Don’t even wonder why you’re cornered. Just skip to your next argument. Next time you get, serve again the very argument you were cornered with.
  7. When cornered, never acknowledge. Instead, ask another question. That’ll let you deny you’re cornered, as you can argue you won’t pursue the discussion as long as the other doesn’t answer your question.
  8. When cornered, invoke (pseudo) philosophy. Pretend it’s all a matter of “worldview”, “interpretation”, etc. Postmodernism can be useful at times…
  9. Any peer-reviewed paper that goes your way, or even seems to, is dead right. The thousands which definitely don’t, are all dead wrong. Peer-review is trash, except when it goes your way…
  10. Any peer-reviewed paper that seems to go your way… goes your way, even if it doesn’t.
  11. Any evidence that seems to go your way, is true. The thousands or millions of contrary evidences simply don’t exist.
  12. Any PhD who claims what you want to hear, is right. The thousands who disagree are all wrong.
  13. When opposed Wikipedia, a pop science article or ArXiv (you probably don’t know how it works, but don’t ask), claim these are not serious sources (carefully ignore all the primary sources cited there). If opposed Nature or Science or Princeton, Cambridge, Harvard, Oxford… Presses, claim it’s all corrupted.
  14. Fake you suddenly care about peer-review, and demand peer-reviewed refs for textbook level science.
  15. Pretend Einstein, or equivalent, is on your side even if nothing supports that claim. When others disagree, tell them they have to prove you wrong.
  16. Find other pseudoscience(s) you can denounce. This will help you look scientific (ex: YEC denouncing geocentrism or flat earth).
  17. Frequently use pseudo-erudite vocabulary like “fallacy”, “strawman”, “ad-hominem”, “non-sequitur”…  thinking it will help you look scientific (it doesn’t).
  18. Redefine “science” the way it fits your agenda (cite Popper to look erudite).
  19. Pretend you’re ridiculed because you’re the courageous-rebel-thinking-out-of-the-box, forgetting you can perfectly be ridiculed because… you are ridicule.
  20. Pretend what you claim is obvious, even if you have no idea why it should be obvious.
  21. Pretend the opposite views have been refuted many times, like flat earthers pretending globe earth has been refuted many times, or YEC that old universe has been so.
  22. Make up any “scientific” claim you want without providing any reference. When asked for, tell others it’s their job to find it.
  23. Don’t try to learn correct science. Just bully it.
  24. Horribly distort correct science. It’ll be easier to criticize.
  25. The inner coherence of your arguments doesn’t matter. Feel free to argue today that fine tuning proves God, then pretend tomorrow that the laws of physics may have changed in the past.
  26. When really cornered, play the conspiracy trump card. It’s impossible to refute, so you’re on safe ground.
  27. When really cornered, play the assumption trump card, even of you don’t know which, or if your alleged assumptions are not assumed at all (of course, when proving your thesis, freely assume anything you wish, how absurd it may be).
  28. Anything goes as long as it goes your way.
  29. Everything that doesn’t go your way is wrong. Everything that does is right.
  30. Be to science what DDR was to democracy. Butcher what you claim you own.

How do we know it has to be possible to unify General Relativity and Quantum Mechanics?

We often hear about the unification of the two prodigy kids of the last century, namely, General Relativity (GR) and Quantum Mechanics (QM).

But, just why should they absolutely unite?

Couldn’t they eventually play separately, leaving the other alone? Granted, so far this unification-mania has borne much fruit, but hey, Mother Nature could have decreed,

“It’s enough, unification stops there, RG and MQ are the end of the story! Go home everyone!”

Actually, no. Mother Nature hasn’t decided that. And it’s easy to understand. Here is at least one reason for this (see another one here).

Cooking GR

When you derive the equations of GR, the famous Einstein equations, you manage to connect the deformations of space-time to the matter/energy it contains. In the mathematical salad that is being mixed, you have some stuff that describe the distortions of space-time (we call that the metric). And then you have other stuff that describe matter/energy. Once the salad is mixed, you get a mathematical relation between these two kinds of stuff: the equation of General Relativity.

Where’s the pb?

Now let’s see where the problem is: when you describe matter in the salad, you do it in a classical, non quantum, way. Basically, it means that if, for example, you have a proton wandering around, you pretend it’s a point of zero size. But we know that a proton, in the real world, is not a point. It’s not even a ball. It’s more complicated than that. And how do we know? Because of Quantum Mechanics, precisely.

Simply put, GR works “as if” my proton were a point, although it is not. And what happens if we do otherwise? What happens to Einstein equations if, instead of deciding the proton is a point, we let it be what QM tells it really is? Nobody really knows so far. This is precisely the problem of the unification of GR and MQ.

Conclusion, need for unification

We’re already there. Why do GR and QM must be able to merge? Because we know GR “cheats”. GR simplifies the description of matter. As long as space-time doesn’t see the trick, that is, as long as its curvature is much larger than the size of the proton, no problem. In fact, this approximation is almost always fully, abundantly, amply, thoroughly, justified.

Except in extreme circumstances where QM and GR cease to be valid because space-time does see the trick, like… near the Big Bang or in a black hole.

The limits of a theory

There is a concept in physics that is useful to follow the developments of contemporary cosmology, among others: it is the notion of the limits of a theory. Its validity domain.

Fluid mechanics is not valid over too short distances. Newton’s gravitation is not valid in too strong gravitational fields. Newton’s other law, which relates force to acceleration, is not valid when you go too fast. Just what does it mean? Let’s check it on an example.

Kinetic energy

Everyone knows about kinetic energy. A mass M at velocity V carries the kinetic energy,

kinetic

Imagine an experiment where I measure the kinetic energy of a mass of 1 kg at various velocities. As long as it doesn’t go too fast, the formula above works very well. But as we step on the gas, our formula becomes progressively inaccurate. In fact, the formula above will give the blue curve below, while the experience will give the orange one,

1

The two curves gradually separate from each other, from about 5.0 × 108 km/h, that is, 500 million km/h. The orange curve goes to infinity when approaching 109 km/h (1 billion km/h), which is nothing else than the speed of light. Einstein’s Special Relativity gives the formula for the orange curve.

Let’s now replot these two curves, but between 0 and 1 million km/h rather than 2 billion. You get that,

2

“Wait Antoine, you announced two curves and I see only one! Pay back!” Calm down… It just happens that the blue is almost exactly below the orange, so we can’t see it. They are almost superimposed. That’s why for the velocities at stake in our daily life, there is no need for relativity. Even a jet flying at 1 million km/h (Paris-Los Angeles in 32 seconds!), would hardly notice the difference.

Some remarks to conclude,

  • The transition is progressive, yet with a velocity of reference which is the speed of light. The orange curve progressively departs from the blue as we approach the speed of light.
  • There is therefore no particular speed of which can be said “before, it’s blue, after, it’s orange”. It’s progressive. Like a shade of grey that do not go abruptly from black to white, but gradually.
  • Imagine I don’t know the formula for the orange curve. Imagine I’m looking for it. Whatever it be, the fruit of my research must meet a requirement: it must smoothly connect to the blue curve for “small” velocities, that is, much smaller than that of light. Translated into mathematical terms, this “smooth connection” is therefore an acid test for any new scientific theory, since the blue curve at low velocities is consistent with experience.

Implications for cosmology (Big Bang theory)

I talked about cosmology to start with. What does it have to do with this?

According to General Relativity (GR), we come across a singularity with an infinite density when we rewind the movie of the universe.

But… is GR valid all this time? No. Just as the blue curve is only valid for small velocities, GR is only valid for small densities. What does “small” mean now? For the blue curve, “small” meant “much smaller than the speed of light”. For GR, “small density” means “much smaller than the Planck density”, that is, 1087 tons/cm3, or one thousand trillion of trillions of trillions of trillions of trillions of trillions of trillions of tons per cubic centimeter. Phew!

Even if this figure is gigantic, a density that goes to infinity will necessarily end up exceeding it. GR is therefore committing suicide, so to speak. In the movie played backward, as the density approaches that of Planck, GR tells us

“Stoooop! Rewinding further forbidden! I’m no longer valid. I’m no longer trustworthy in these waters”

That’s why the singularity of the Big Bang is not real. GR, that predicts it, is no longer valid at this stage, just as the blue curve tells nonsense for a speed doubling that of light.

In the case of the Big Bang, what is then the equivalent of the orange curve? What scientific theory would it take to know what happens prior to the “Planck wall”? We do not know yet, because we do not know how to marry GR and Quantum Mechanics (QM). But what we do know, is that at small densities, candidates must harmoniously connect with GR on the one hand, and with QM on the other hand, like the orange curve nicely lands on the blue at low speeds.

PS – Fluid mechanics and Newton’s gravitation

I mentioned at the beginning fluid mechanics, which is no longer valid for short distances. “Short” here means “smaller than the distance between two atoms, or molecules, of my fluid”. When fluid mechanics (without viscosity [1]) predicts something on this length scale, watch out! it’s probably talking nonsense.

What about Newton’s gravitation, also mentioned at the beginning? It is no longer valid in “strong” gravitational fields. “Strong” here means “of the order of the gravitational field felt when one approaches a mass at a distance of its Schwarzschild radius”. The Schwarzschild radius of the earth is 1 centimeter. That of the sun, 3 kilometers. Since these two are much larger than their Schwarzschild radius, we obviously cannot approach them so closely. However, as Newton’s law only gradually departs from reality as we approach the sun, very precise measurements have made it possible to detect small deviations from the Newtonian predictions for Mercury, the closest planet to the sun.


Footnotes

[1] For the expert, viscosity only rescues fluid equations for weak shocks. The problem comes back in the strong shock limit. See Zel’dovich & Raizer, Ch. 7.

I’d say math exist

Memory plays tricks, but I think I remember this moment quite well. It was 2 years after my Baccalauréat. In the midst of a massive ingestion of math and physics in “prépa”, I could not help thinking about it all after classes. My thoughts that night were on the laws governing electric and magnetic fields. The so-called Maxwell’s equations. They involve a mathematical arsenal called “partial derivatives”, discovered by Newton and Leibniz in the seventeenth century.

Lost in my Maxwellian dreams, I started to wonder: “How is it that abstract mathematical tools developed over millennia are suddenly perfectly adapted to describe something real?”

I soon learned that I was far from being the first to wonder about this. Had not Galileo written centuries ago that “the book of nature is written in the language of mathematics”?

Albert Einstein also asked [1]:

“How can it be that mathematics, being after all a product of human thought which is independent of experience, is so admirably appropriate to the objects of reality?”

Finally, Eugène Wigner, physics Nobel in 1963, wrote in 1960 a text which title is as famous as explicit: The Unreasonable Effectiveness of Mathematics in the Natural Sciences.

 

A few thoughts later, an idea dawned on me: math exist. They are not invented. They are discovered. And here also, I realized many had came to the same conclusion. Cédric Villani for example Fields Medalist 2010 [2]:

“I am among those who believe that there is a pre-existing harmony… [it is] an unexplained intuition; a personal and quasi-religious conviction.”

Alain Connes, Fields Medalist 1982, is also worth quoting here [3]:

“Two extreme viewpoints are opposed in relation to mathematical activity. The first, to which I completely subscribe, is of Platonic inspiration: it postulates that there exists a mathematical reality, raw, primitive, which predates its discovery. A world which exploration requires the creation of tools, as it was necessary to invent vessels to cross the oceans. The second viewpoint is the one of the formalists; they deny any preexistence to mathematics, believing that they are a formal game, based on axioms and logical deductions, thus a pure human creation.”

Then he adds,

“This viewpoint seems more natural to the non-mathematician, who refuses to postulate an unknown world of which he has no perception. People understand that mathematics is a language, but not that it is a reality external to the human spirit. The great discoveries of the twentieth century, especially the works of Gödel, have shown that the formalist viewpoint is not tenable. Whatever the exploratory medium, the formal system used, there will always be mathematical truths that will elude it, and mathematical reality cannot be reduced to the logical consequences of a formal system.”

As Roger Penrose writes about math in general and the Mandelbrot set in particular [4],

“It is as though human thought is, instead, being guided towards some external truth – a truth which has a reality of its own…. The Mandelbrot set is not an invention of the human mind: it was a discovery. Like Mount Everest, the Mandelbrot set is just there.”

The Mandelbrot set, the Bernoulli numbers, the googolplex-th decimal of Pi [5], the non-trivial zeros of the Riemann zeta function, the Lorenz attractor… the list is endless, infinite indeed. All these things exist.

Could something else than math, exist? Seems Einstein, again, had some beautiful insights with respect to the music of Mozart [6],

“Mozart’s music is so pure that it seemed to have been ever-present in the universe, waiting to be discovered by the master.”

Einstein, Connes, Villani, Penrose… I was finally in good company. This “personal and quasi-religious conviction,” as Villani says, acquainted me with the possibility that something non-material might exist. It was probably, with the reading of Hermann Hesse, the beginning of my spiritual journey.

 

Further reading: I really recommend this conversation between the Platonicist Alain Connes and the neuroscientist and Formalist Jean-Pierre Changeux

512M2kXuERL._SX322_BO1,204,203,200_


Footnotes

[1] Einstein, Geometry and Experience, 1921.

[2] Pierre Cartier, Jean Dhombres, Gerhard Heinzmann, Cédric Villani, Mathématiques en liberté, La Ville Brûle, 2012, page 60.

[3] Alain Connes interviewed by Sylvestre Huet, Libération, december 1, 2001.

[4] Roger Penrore, The Emperor’s New Mind, Chapter 3 on Mathematics and Reality.

[5] A googolplex is 1 followed by 10100 zeroes. We’ll probabbly never know what is this digit, but it exists.

[6] https://www.nytimes.com/2006/01/31/science/a-genius-finds-inspiration-in-the-music-of-another.html

Climate change in 6 questions

Here are some briefs answers to 6 frequently asked questions on the topic. I also think that in the following order, these answers contribute to explain how we know there’s a climate change going on, and how we know it comes from us.

  1. How can we talk about the climate in 100 years if we don’t know if it will rain in 20 days?
  2. How do we know there is a climate change?
  3. How do we know it’s not the Sun?
  4. How do we know it comes from an increase of greenhouse gases (GHG)?
  5. How do we know these GHGs come from human activity?
  6. Do experts agree?

I will try to answer them as briefly as possible. Let’s go.

For Spanish speakers, my course on energy/climate is here.

How can we talk about the climate in 100 years…?

A very good question indeed. To answer it, let me ask two more questions:

  1. Will it be warmer in Madrid in July 2030 than in January 2030?
  2. Will it rain in Madrid on June 20, 2030?

I think anyone would answer “yes” to (1), and “no idea” to (2). How can we achieve certainty for (1) while it’s impossible for (2)?

When we think of (1) we think about what should happen in July and January. And what should happen through one year is mainly related to the height of the Sun in the sky. The higher the hotter. But when we think of (2) we think about what will actually happen on that day, and here we find it impossible to answer more than a week or two in advance.

The graph below shows the daily temperature in Lausanne Switzerland, in 2017. It is obvious that the rather chaotic yellow line runs around a deeper tendency, shown by the blue line.

Climate Weather 2
Daily temperature in Lausanne Switzerland, in 2017 (Wolfram|Alpha Knowledgebase)

The blue line is about the climate. The yellow line is about the weather. Likewise, question (1) is about the climate, (2) is about the weather. As Mike Hulme puts it [1],

“Climate is what you expect, weather is what you get”

It is perfectly possible to forecast the climate. For this reason, travel guide books can inform about the average temperature in Madrid throughout the year, without the need for a crystal ball.

By contrast, predicting the weather well in advance is impossible. For this reason, unfortunate tourists may get rain when visiting Madrid in June, despite their travel guide book forecasting little of it.

How do we know there is a climate change?

The most well-known indicator is the global temperature (see the featured image above). It is an average of the temperatures over the surface of the planet. Global temperature has been rising for about a century. We have gained about 1°C since the XIX century (this figure of 1°C will play an important role in answering the next questions). However, it should be noted that it is not the only indicator. Let’s look at 6 more, see for example NASA or the UK MetOffice, all pointing to a warm-up.

Let’s start with some downward indicators:

  1. The extent of Arctic sea ice is shrinking.
  2. The volume of Greenland ice is shrinking.
  3. The volume of Antarctica ice is shrinking.
  4. The volume of land glaciers is shrinking.

Let’s now continue with rising indicators,

  1. The oceans’ heat content is rising.
  2. Global temperature is rising.
  3. Sea level is rising.

We then come to a total of 7 indicators, all pointing to the same direction: a warming. One can find a few more on the MetOffice web for example. Notably, the impact of global warming on fauna and flora is extensively studied, showing even more signs of a change.

Even before we know their origin, these observations lead us to the conclusion that global warming is occurring. Let’s see why.

How do we know it’s not the Sun?

Our planet is getting warmer. Why?

What does our climate depend on? It depends on the amount of solar energy that comes from the Sun, and of the composition of the atmosphere. Similarly, the temperature in my bed depends on the temperature in my room (the Sun), and of the numbers of blankets I have (the atmosphere). If I’m getting warmer under my blanket, it can only be for 2 reasons: it’s warmer in my bedroom or I have an extra blanket.

Could the Sun be responsible for the warming? It is obviously the first suspect. Does it have cycles that could change the climate? Of course. The last ice ages were the fruit of the so-called Milankovitch cycles. Yet, while they prompted ice ages, they cannot be held responsible for the current change. Why? Because the shortest of these cycles is 20,000 years long; far too long to explain a warming which has been going on for about a century.

So if the Milankovitch cycles are too long, are there shorter natural cycles? Yes. The Sun has a 11 years cycle. But it cannot be responsible either for at least 3 reasons:

  1. It is too short. We’re looking for a warming agent over a time scale of about one century. Here, it’s up, down, up, down, etc. every 11 years. Not an uuuuup lasting 100 years.
  2. Its upper value doesn’t even show an increase over the last decades, rather the contrary.
  3. Finally, a very simple calculation shows that this cycle can prompt variations of the global temperature of only 0.1°C [2]. We observe 10 times more (see previous paragraph).

It’s not the Sun.

How do we know it comes from an increase in greenhouse gases?

If it’s not the Sun, then it must be the atmosphere. No choice. It acts like a blanket which thickness depends on its composition. The most effective gases in this respect, the famous “greenhouse gases” are, in order of importance, water vapor (H20), carbon dioxide (CO2), and methane (CH4) [3]. Without them, the average temperature of the planet would be around -15°C  [4].

What about water vapor? It has something special. The amount of water vapor in the atmosphere depends only on the temperature of the atmosphere. What happens if there is too much? It just rains. This has a very interesting consequence: water vapor alone cannot be the cause of the warming. If there is more up there (and there is), that can only be the result of warming, not the cause. Something else must be warming the atmosphere.

What can that “something else” be? Only two suspects remain: carbon dioxide and methane. It has to be one of the two, or both. Let’s check it out. We can begin by plotting the concentration of these gases in the atmosphere over the last 1000 years:

GHG_Last_1000_years

As can be seen, these gases start rising at the beginning of the XIX century, with an acceleration in the XX century. Today, the CO2 concentration has reached 400+ parts per million (ppm), representing an increase of 42% over the pre-industrial era. As for methane, it has more than doubled. We have our heating factors, with the expected time scale. We already knew it from the previous elimination of suspects, and now we’re just checking. Our atmospheric blanket has been thickening for a century or two. Let’s keep checking: what is the increase in temperature that could be expected from such increases in these gases? Another simple calculation gives about 1°C, that is, what is observed [5].

Current warming comes from an atmospheric GHG increase.

How do we know these GHGs come from human activity?

Also a good question. Where do these CO2 and CH4 rises come from? From the volcanoes? They are often suspected. But we can exculpate them for at least 3 reasons:

  1. We have data for atmospheric CO2 and CH4 over almost a million years back and they never reached current levels. If volcanoes had been recently doing something they didn’t in a million years, we would notice.
    By the way, this point holds for any natural agent supposedly responsible for the current GHG rise: it should be doing something now that it hasn’t been doing in a million years.
  2. As shown in the figure above, CO2 and CH4 are rising steadily. Volcanoes would have to be very well in synch to cause such a gradual increase.
  3. Volcanoes emit about 0.3 Giga-tons (Gt) of CO2 per year. We emit 30 Gt, that is, 100 times more.

So where do these GHGs come from? The figure above gives us a clue: the rise began with the industrial revolution, which consisted in burning coal.

Could these GHGs come from human activity? To check this hypothesis, we can consider the amount of GHG emitted by humans every year since 1750, and reconstruct the evolution of the atmospheric concentration in CO2 and CH4, accounting only for human activity. The figure below is the result of this simple calculation for CO2.CO2_computedI computed the blue curve starting with the concentration known in 1750, then adding each year what was emitted [6]. The red curve comes from observations. Both fit remarkably. The difference between red and blue comes from deforestation.

There is no doubt. The rise of GHGs in the atmosphere has its origin in the massive use of fossil fuels. This can be checked in other ways [7], and all the tests are conclusive. These GHGs are “ours”.

Do climate scientists agree?

There is a climate change. It is due to human activity. And those who contribute to the progress of knowledge in this area, what do they say? What do experts say on the subject? They agree. Several surveys have been conducted in recent years. They concluded that more than 97% of experts agree.

I personally attended the American Geophysical Union Fall Meeting in 2015 and 2018. With more than 20,000 participants, this conference is the largest in the world for this field of knowledge. There, climate scientists present their latest research.

  • How many presentations questioned the existence of a climate change? Zero.
  • How many presentations questioned the role of human activity as the engine of change? Zero.

This can be checked browsing the scientific program of the last AGU 2018 for example.

It should be noted to conclude that what is happening is not a surprise at all. Almost two centuries ago, in 1824, Joseph Fourier already explained how an atmosphere warms its planet. In 1859, John Tyndall measured how some gases absorb radiation and concluded that without water vapour, the earth would be “held fast in the iron grip of frost”. In 1896, Svante Arrhenius calculated, by hand of course, the temperature increase that would come from a doubling of CO2 in the atmosphere. Applying his formula to the recent increase of 42%, one finds a warming of + 3oC. Not bad for someone who ignored the details of the interaction between the molecules of the atmosphere and the radiation sent from earth to space [8].

The current warming is not a surprise for the scientific community. It was expected. It is happening (it didn’t stop in 1998), and it comes from us.


Footnotes

[1] M. Hulme, Why We Disagree About Climate Change (Cambridge University Press, Cambridge, 2009), p. 1.

[2] See A. Bret, The Energy-Climate Continuum (Springer, 2014), p. 47.

[3] There are more, but these 3 are the most important.

[4] See Kendal McGuffie & Ann Henderson-Sellers, A Climate Modelling Primer (Wiley, 2005), ch. 3.

[5] The calculation can be done using equation (4.9) of my book, and this reference, which allows to evaluate the variation of parameter epsilon under a CO2 increase of 40%.

[6] About half of the emitted COgoes into the oceans (see here, p. 467).

[7] An example: if the excess CO2 comes from combustion, then the amount of oxygen in the atmosphere should go down. The observations confirm this perfectly (I designed an exam based on this in 2011). More conclusive evidences can be drawn from Carbon 13 or 14 atmospheric concentrations.

[8] He didn’t know about quantum mechanics.

Peer-review is selective, but maybe not the way you think

Peer-review journals are the forum where professional scientists publish their research. That a journal is “peer-reviewed” does not mean everything it publishes is right. It simply means everything it publishes has been proofread by 1 or more knowledgeable people on the topic the paper deals with, before publication.

There are literally thousands of peer-reviewed journals, attached to all fields of human knowledge. What I’m about to share applies to the journals I’ve been dealing with personally [1]. It certainly applies to more, but I prefer talking only of what I’ve personally experienced.

 

From time to time, some complain about the peer-review system being discriminatory, for example on religious ground. So just in case, I want to make clear the following points,

  • Peer-review doesn’t care about your religion. Nowhere in the submission process, nor at any later stage, is any question asked about your religion. Nowhere.
  • Peer-review doesn’t care about your diploma or your position. You don’t have to be a Professor or a PhD to publish an article. I wasn’t a PhD when I published my first 5 papers.
  • Peer-review doesn’t care about your affiliation. You don’t have to be on a university payroll. Granted, you will be asked for an affiliation, but you can perfectly fill it with your personal address, as a friend of mine once did when writing an article between 2 contracts.
  • Peer-review doesn’t even care about you being a human! There’s a famous example of a physicist choosing his cat as a co-author for an article (he realized before submission that he was using “us”, “our” and “we” throughout the paper, while being single author. Instead of rewriting everything, he made up a second author). Full story here.

So if peer-review doesn’t care about your religion, your diploma, your position, and even your specie, just what does it care about?

Here’s what I’ve seen after having published more than 100 peer-review articles, be a referee even more times, and served as an Associate Editor [2] for a Cambridge Press peer-review journal since 2012.

On the long run, and even the medium one, peer-review eventually cares about your work teaching something new, and not being grossly inconsistent with logic, experiments and observations. That’s it.

Just try.


Footnotes

[1] Here they are:

  • Annales Geophysicae
  • Astronomy & Astrophysics
  • Astrophysical Journal
  • Astrophysical Journal Letters
  • Europhysics Letters
  • Fusion Engineering and Design
  • Fusion Technology
  • Journal of Plasma Physics
  • Laser and Particles Beams
  • Monthly Notices of the Royal Astronomical Society
  • Nature
  • Nature Scientific Reports
  • New Journal of Physics
  • Nuclear Instruments and Methods In Physics Research A, and B
  • Physica Scripta
  • Physical Review E
  • Physical Review Letters
  • Physics Letters A
  • Physics of Plasmas
  • Plasma Physics and Controlled Fusion
  • Reports on Progress in Physics
  • Science

Just Google the title to find their webpage and check the submission process.

[2] The Editors and the Associate Editors are the ones responsible for choosing the referees and eventually accepting the paper, rejecting it, or asking for revisions. As an Associate Editor, I don’t have to get anybody’s approval before accepting or rejecting a paper.