joigus

Maybe he's somebody else's brother and she's somebody else's sister. But I think they're cousins. https://en.wikipedia.org/wiki/John_C._Baez#Family Anyway, he explains there why length and mass can't scale independently from each other.

The quote is due to Baez.

Google: Search string: "half life of uranium 238" Google: Search string: "how abundant is uranium on earth" Google: Search string: "most abundant radioactive materials on earth" Wikipedia: https://en.wikipedia.org/wiki/Uranium Iso­tope Abun­dance Half-life (t1/2) Decay mode Pro­duct 232U syn 68.9 y SF – α 228Th 233U trace 1.592×105 y SF – α 229Th 234U 0.005% 2.455×105 y SF – α 230Th 235U 0.720% 7.04×108 y SF – α 231Th 236U trace 2.342×107 y SF – α 232Th 238U 99.274% 4.468×109 y α 234Th SF – β−β− 238Pu Radiation is dangerous, but how dangerous it is depends on how exposed you are to it, as well as the radiactive material. Radioactive materials are present in many rocks, as eg. granite, but not so concentrated that they will give you cancer in any noticeable time.

Purpose is indistinguishable from the illusion of purpose.

Right. The emphasis was meant on the 'big.' There was a time when we were new too, remember? It's been knocking at our door for so many decades that it still sounds new. You could say it's the future of physics, it's always been, and it always will be.

I'll take a closer look at it later, but let me tell you physics is not just about making sense. Lord Kelvin's theory of electromagnetic knots made perfect sense, yet it's not what Nature is like. I have some comments to make about this idea of observer-dependent scaling. It's akin to a slippery-slope kind of argument, but for good reasons. Maybe tomorrow.

Ah, I missed this, @MigL. I'm sorry. Let me get back to you later. It's based on some musings by Leonard Susskind. During his lectures on supersymmetry, he laments that SUSY probably is telling us something very deep, but we still don't know what it is. I'm quoting him almost literally. Essentially it rests on the (mathematical) fact that the SUSY generators, that exchange boson for fermion, can be arranged in a way that produces space-time translations. Now that could be just a mathematical mirage, but it seems very profound. Another one is that, when you put superspace variables (anticommuting complex coordinates) together with space-time, the Lagrangians of relativistic quantum field theory appear as if by (mathematical) magic. That's what I mean by "really compelling." Now, I think you know me enough to know that I don't easily fall for 'big' new ideas that have to do with forcing the mathematics. I'm convinced that the way to go is to look at the mathematical form that we know to be right, while trying to interpret it in a way that opens the way to an extrapolation. I'm not sure I'm explaining myself very well. Maybe tomorrow. (Famous last words.)

https://math.ucr.edu/home/baez/lengths.html You don't contemplate quantum mechanics, that's why you don't understand. The world is quantum. \( \frac{\hbar}{mc} \) is a length. It's the length scale from which you must start making quantum relativistic corrections. You can't leave quantum mechanics out of the story. Otherwise your story is not about the real world. It's about a fantasy world. Solids are subject to quantum mechanics too.

Mass scales as inverse length. By together, I didn't mean the same way.

(My emphasis.) Who gave it? And are you a co-author? x-posted with Swansont. In any case, mass and length scale together due to relativity and quantum mechanics, so no, you can't pull this off. Unless you explain very good reasons why \( \hbar \) and c (speed of light) are irrelevant in physics.

I think they're insurmountable. If the universe were made of just photons and neutrinos on a scale-invariant background, it would display scale invariance, but it isn't, so it doesn't. MigL has given a nice cosmological account that complements Markus'. I think the argument, when you consider the quantum theory, becomes even more involved, as you would have to prove that the beta function --the function that tells you how the interaction scales with energy, and thereby with length-- vanishes. I don't know how massless physicists would feel in a universe like that, but it's been known for a while that it doesn't work. I don't understand how the equivalence principle allows you to pull this off. If anything, the EP tells you that free-falling local observers cannot tell they're falling, so the standard model would be still there, in all its locally-valid glory, telling you the universe is not scale-invariant... I also hope you don't mean special-relativity length contraction & time dilation. That's nothing like scale invariance...

Emmy Noether's case is particularly poignant for me, because of the ratio (treatment she got)/(genius)x(human qualities). Plus the theorem that bears her name is my favourite of all mathematical physics. She seems to have been an extremely nice person too. But yes, there are many. Many who had it worse than Noether too. Absolutely. Standard bearers. Jane Goodal in particular is one of my heroes. I was in two minds about posting this. Most women prefer day-to-day action, rather than this kind of gestures. But then I thought, what the hell. I couldn't not do it.

Thanks for your interest. Your numbers 1, 2, and 6 are in my heart too. Another one is American biologist Barbara McClintock, discoverer of transposable genes.

LOL.

She must have been a great teacher! Edit: I'll never forget Mercedes Serra, she taught me maths and physics. I wonder what became of her.

Cometh the comedian, cometh the comedown. And cometh the comet, cometh the final homecoming. You still haven't told me your favourite woman in science, DR.

"Fighting" encompasses so many things... You forgot to tell me your favourite woman in science, @dimreepr.

You're right, but until that day comes...

To all women @SFN, and to all women in science: Happy Women's Day!! We value you, trust you, we love your work, and we wish you to keep going strong. Most importantly: We are inspired by you. You're better off without a Y chromosome, believe me. What's your favourite woman in science? Mine is Emmy Noether.

Yes, I'm sorry too, because now I realise I wasn't clear. I meant there may be even more redundancies further down the line replication --> transcription --> translation. And by XYZ... I meant the protein, that is, the sequence of aminoacids. Suppose the nucleotide sequence codes for a particular protein, instead of a transcription factor, or a protein that needs to fold in a very precise way at the level of beta structure, etc., like, eg. hemoglobin. Just a simple alpha-structure completely boring structural chain. So in that case there would be even more redundancy at the "production line" level, so to speak. For some proteins it could be the case that cutting (splicing) here or there doesn't really make that much of a difference. By XYZ I should have specified valine-glycine-whatever. In some proteins the Y aminoacid (say it's hydrophobic) could be just fine if you simply replace it by another hydrophobic aminoacid and everything would be OK structurally. Even if it's a transcription factor, it could be the case that it binds just a little bit less efficiently by changing one aminoacid, so your equilibrium constant would be displaced just the slightest bit to the left... So you're right. I don't disagree with you. There would be the redundancies that you point out, and maybe even more. In fact I understand redundancies of this kind are essential for there being a possibility of evolution to be so "malleable." It's an interesting discussion, but we're getting off the track...

I was absolutely unaware of this. Thank you. Is this compatible, incompatible, or completely independent (maybe a previous eon) of the RNA-world hypothesis?

I didn't really mean errors in replication. I meant different versions of splicing. And I did say that. Didn't I? Look, I did: Splicing is different. It happens after replication. And mind you, making mistakes in replication could be fatal, but making mistakes in trancription, and even more in translation, is quite innocuous in comparison.* Deletion, insertion and frameshift mutation happen before. But you may be right that it wouldn't be completely inconsequential. Do you happen to know how the hypothetical protein I wrote is going to fold? I'm not sure. That's why I said, That's the whole point I was trying to make. I don't know. Do you know? Gosh! I really do have to have my wits around me when you're there... But thank you. * mRNA degrades very quickly.

You're absolutely right. There's quite a lot of redundancy, including several start/stop codons. There may even be redundancy after splicing, as chains like XYZXYZXYZ are essentially the same as YZXYZXYZX, aren't they? Cyclic symmetries,.... But that's another matter.

Right. As CharonY has said, chemolithotrophs* came before. I overlooked those because I was thinking in terms of a plant/animal dichotomy. Other things came before and probably exploited a wide variety of red-ox reactions. Some organisms "respirated" H2S from volcanoes, but they didn't get a sweet deal in energetic terms, I think. Nothing like the 36-39 ATP mol per glucose mol that eukaryotes get. When it came down, it must have been the goose that laid the golden eggs. * I wonder if chemolithotrophs aren't the real rulers of the universe in terms of sheer abundance in the universe. I bet they are.

Very interesting question. Welcome to SFN. I'm looking forward to expert answers. Viruses/viri are peripheral to life. They need hosts, so they came later. But not much later, as they need much less combinatorics than prokaryotes to go by. There's a certain redundancy in proteins (some proteins can be synthesised from slightly different sequences of nucleic acids). Maybe some sequences of nucleic acids can use deception? Some kind of reverse-redundancy?: They "look" similar to ribosomes polymerases in the binding site, but they execute completely different functions...