Monthly Archives: January 2023

Birth dearth in China => collapse? war?

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China passed us in life-expectancy in 2022, and also in fertility, going the other way. In China lifespan at birth increased to 77.3 years. In the US it dropped an additional 0.9 years, to 76.8. US lifespans suffered from continuing COVID and an increase in accidents, heart disease, suicide, drugs, and alcohol abuse. Black men were hit particularly hard, so that today, a black man in the US has the same life expectancy as he would in Rwanda. China seems to have avoided this, but should expect problems due to declining fertility and birth rates.

China passed us in life expectancy in 2022.

Fertility rates will eventually burden the US too, as US fertility is only slightly greater than in China, 1.78 children per woman, lifetime, compared to 1.702 in China. But China has far fewer people of childbearing ages, relatively, and only 47% are women. Three decades of one child policy resulted in few young adults and a tendency to abort girls. Currently, the birthrate in China is barely more than half ours: 6.77 per 1000, compared to 12.01 per 1000. And the proportion of the aged keeps rising. China will soon face a severe shortage of care-givers, and an excess of housing.

Years of low birthrate preceded the “Lost decades” of financial crisis in Japan and the USSR. Between 1990 and 2011, business stagnated and house prices dropped. China faces the same; few workers and more need for care: it’s not a good recipe.

Beginning about 1991, Japan saw a major financial collapse with banks failing, and home values falling. China seems over-due.

Few children also signals a psychic lack of confidence in the country, and suggests that, going forward, there will be a lack of something to work for. Already Chinese citizens don’t trust the state to allow them to raise healthy children. They have stopped getting married, especially in the cities, and look more to have fun.

Affluent women claim they can’t find a good man to marry: one who’s manly, who will love them, and who will reliably raise their standard of life. Women seem less picky in China’s rural areas, or perhaps they find better men there. However it goes, urban women get married late and have few children, both in China and here. China produces great, sappy, soap operas though: a country girl or secretary in a high-power job meets a manly, urban manager who lovers her intensely. A fine example is “The Eternal Love” (watch it here). It involves time travel, and a noble romance from the past. Japan produced similar fiction before the crisis. And a crisis seems to be coming.

While Japan and Korea responded quietly to crisis and “the lost decades,” allowing banks to fail and home values to fall, Russia’s response was more violent. It went to war with Chechnya, then with Belarus and Ukraine, and now with NATO. I fear that China will go to war too — with Taiwan, Japan, and the US. It’s a scary thought; China is a much tougher enemy than Russia. There is already trouble brewing over new islands that they are building.

Robert Buxbaum January 25, 2023. If you want to see a Korean soap opera on the Secretary – manager theme, watch: “What’s wrong with Secretary Kim”. (I credit my wife with the research here.) I suspect that Americans too would like sappy shows like this.

Hydrogen transport in metallic membranes

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The main products of my company, REB Research, involve metallic membranes, often palladium-based, that provide 100% selective hydrogen filtering or long term hydrogen storage. One way to understand why these metallic membrane provide 100% selectivity has to do with the fact that metallic atoms are much bigger than hydrogen ions, with absolutely regular, small spaces between them that fit hydrogen and nothing else.

Palladium atoms are essentially spheres. In the metallic form, the atoms pack in an FCC structure (face-centered cubic) with a radius of, 1.375 Å. There is a cloud of free electrons that provide conductivity and heat transfer, but as far as the structure of the metal, there is only a tiny space of 0.426 Å between the atoms, see below. This hole is too small of any molecule, or any inert gas. In the gas phase hydrogen molecules are about 1.06 Å in diameter, and other molecules are bigger. Hydrogen atoms shrink when inside a metal, though, to 0.3 to 0.4 Å, just small enough to fit through the holes.

The reason that hydrogen shrinks has to do with its electron leaving to join palladium’s condition cloud. Hydrogen is usually put on the upper left of the periodic table because, in most cases, it behaves as a metal. Like a metal, it reacts with oxygen, and chlorine, forming stoichiometric compounds like H2O and HCl. It also behaves like a metal in that it alloys, non-stoichiometrically, with other metals. Not with all metals, but with many, Pd and the transition metals in particular. Metal atoms are a lot bigger than hydrogen so there is little metallic expansion on alloying. The hydrogen fits in the tiny spaces between atoms. I’ve previously written about hydrogen transport through transition metals (we provide membranes for this too).

No other atom or molecule fits in the tiny space between palladium atoms. Other atoms and molecules are bigger, 1.5Å or more in size. This is far too big to fit in a hole 0.426Å in diameter. The result is that palladium is basically 100% selective to hydrogen. Other metals are too, but palladium is particularly good in that it does not readily oxidize. We sometime sell transition metal membranes and sorbers, but typically coat the underlying metal with palladium.

We don’t typically sell products of pure palladium, by the way. Instead most of our products use, Pd-25%Ag or Pd-Cu. These alloys are slightly cheaper than pure Pd and more stable. Pd-25% silver is also slightly more permeable to hydrogen than pure Pd is — a win-win-win for the alloy.

Robert Buxbaum, January 22, 2023

Fusion advance: LLNL’s small H-bomb, 1.5 lb TNT didn’t destroy the lab.

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There was a major advance in nuclear fusion this month at the The National Ignition Facility of Lawrence Livermore National Laboratory (LLNL), but the press could not figure out what it was, quite. They claimed ignition, and it was not. They claimed that it opened the door to limitless power. It did not. Some heat-energy was produced, but not much, 2.5 MJ was reported. Translated to the English system, that’s 600 kCal, about as much heat in a “Big Mac”. That’s far less energy went into lasers that set the reaction off. The importance wasn’t the amount in the energy produced, in my opinion, it’s that the folks at LLNL fired off a small hydrogen bomb, in house, and survived the explosion. 600 kCal is about the explosive power of 1.5 lb of TNT.

Many laser beams converge on a droplet of deuterium-tritium setting off the explosion of a small fraction of the fuel. The explosion had about the power of 1.2 kg of TNT. Drawing from IEEE Spectrum

The process, as reported in the Financial Times, involved “a BB-sized” droplet of holmium -enclosed deuterium and tritium. The folks at LLNL fast-cooked this droplet using 100 lasers, see figure of 2.1MJ total output, converging on one spot simultaneously. As I understand it 4.6 MJ came out, 2.5 MJ more than went in. The impressive part is that the delicate lasers survived the event. By comparison, the blast that bought down Pan Am flight 103 over Lockerbie took only 2-3 ounces of explosive, about 70g. The folks at LLNL say they can do this once per day, something I find impressive.

The New York Times seemed to think this was ignition. It was not. Given the size of a BB, and the density of liquid deuterium-tritium, it would seem the weight of the drop was about 0.022g. This is not much but if it were all fused, it would release 12 GJ, the equivalent of about 3 tons of TNT. That the energy released was only 2.5MJ, suggests that only 0.02% of the droplet was fused. It is possible, though unlikely, that the folks at LLNL could have ignited the entire droplet. If they did, the damage from 5 tons of TNT equivalent would have certainly wrecked the facility. And that’s part of the problem; to make practical energy, you need to ignite the whole droplet and do it every second or so. That’s to say, you have to burn the equivalent of 5000 Big Macs per second.

You also need the droplets to be a lot cheaper than they are. Today, these holmium capsules cost about $100,000 each. We will need to make them, one per second for a cost around $! for this to make any sort of sense. Not to say that the experiments are useless. This is a great way to test H-bomb designs without destroying the environment. But it’s not a practical energy production method. Even ignoring the energy input to the laser, it is impossible to deal with energy when it comes in the form of huge explosions. In a sense we got unlimited power. Unfortunately it’s in the form of H-Bombs.

Robert Buxbaum, January 5, 2023

Almost no one over 50 has normal blood pressure now.

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Four years ago, when the average lifespan of American men was 3.1 years longer than today, the American Heart Association and the American College of Cardiology dropped the standard for normal- acceptable blood pressure for 50+ years olds from 140/90 to 120/80. The new standard of normal was for everyone regardless or age or gender despite the fact that virtually no one over 50 now reached it. Normal is now quite un-common.

By the new definition, virtually everyone over 50 now is diagnosed with high blood pressure or hypertension. Almost all require one or two medications — no more baby aspirin. Though the evidence for aspirin’s benefit is strong, it doesn’t lower blood pressure. AHA guidance is to lower a patients blood pressure to <140/90 mmHg or at least treat him/her with 2–3 antihypertensive medications.4 

Average systolic blood pressures for long-lived populations of men and women without drugs.

The graphs shows the average blood pressures, without drugs in a 2008 study of the longest-lived, Scandinavian populations. These were the source of the previous targets: the natural pressures for the healthiest populations at the time, based on the study of 1304 men (50-79 years old) and 1246 women (38-79 years old) observed for up to 12 years. In this healthy population, the average untreated systolic pressure is seen till age 70, reaching 154 for men, and over 160 for women. By the new standards, these individuals would be considered highly unhealthy, though they live a lot longer than we do. The most common blood-pressure drug prescribed in the US today is atenolol, a beta blocker. See my essay on Atenolol. It’s good at lowering blood pressure, but does not decrease mortality.

The plot at left shows the relationship between systolic blood pressure and death. There is a relationship, but it is not clear that the one is the cause of the other, especially for individuals with systolic pressure below 160. Those with pressures of 170 and above have significantly higher mortality, and perhaps should take atenolol, but even here it might be that high cholesterol, or something else, is causing both the high blood pressure and the elevated death risk.

The death-risk difference between 160 and 100 mmHg is small and likely insignificant. The minimum at 110 is rather suspect too. I suspect it’s an artifact of a plot that ignores age. Only young people have this low number, and young people have fewer heart attacks. Artificially lowering a person’s blood pressure, even to this level does not make him young, [2][3] and brings some problems. Among the older-old, 85 and above, a systolic blood pressure of 180 mmHg is associated with resilience to physical and cognitive decline, though it is also associated with higher death rate.

The AHA used a smoothed version of the life risk graph above to justify their new standards, see below. In this version, any blood pressure looks like it’s bad. The ideal systolic pressure seems to be 100 or below. This is vastly too low a target, especially for a 60 year old. Based on the original graph, I would think that anything below 155 is OK.

smoothed chart of deaths per 1000 vs blood pressure. According to this chart, any blood pressure is bad. There is no optimum.

Light exercise seems to do some good especially for the overweight. Walking helps, as does biking, and aerobics. Weight loss without exercise seems to hurt health. Aspirin is known to do some good, with minimal cost and side effects. Ablation seems to help for those with atrial fibrillation. Elequis (a common blood thinner) seems to have value too, for those with atrial fibrillation — not necessarily for those without. Low sodium helps some, and coffee, reducing gout, dementia and Parkinson’s, and alcohol. Some 2-3 drinks per day (red wine?) is found to improve heart health.

I suspect that the Scandinavians live longer because they drink mildly, exercise mildly, have good healthcare (but not too good), and have a low crime rate. They seem to have dodged the COVID problem too, even Sweden that did next to nothing. it’s postulated that the problem is over medication, including heart medication.

Robert Buxbaum, January 4, 2023. The low US lifespan is startling. Despite spending more than any other developed countries on heath treatments, we have horribly lower lifespans, and it’s falling fast. A black man in the US has the same expected lifespan as in Rwanda. Causes include heart attacks and strokes, accidents, suicide, drugs, and disease. Opioids too, especially since the COVID lockdowns.