Yeah, we tend to get a triple-whammy down south. I recall reading that the tilt of the earth, as well as atmospheric pollution make even more of a difference. If I recall the figures correctly, the UV hole can increase UV by ~3% in the southern hemisphere compared to the northern hemisphere, but the fact we tilt slightly closer to the sun in summer than the northern hemisphere makes 6-7% difference, and the fact that there is far less atmospheric pollution (aerosols, etc. that absorb some UV) in the south makes another ~6%. So even in summer when the UV hole is at its minimum, at the same distance from the equator you can have something like 12-14% more UV exposure than the northern hemisphere in summer.
It's ironic that better pollution controls, while causing many health benefits, will potentially make things worse for skin cancer in the northern hemisphere by gradually increase the UV doses, so you all are going to have to get better at sun safety or melanoma will become a much bigger issue there.
> but the fact we tilt slightly closer to the sun in summer than the northern hemisphere makes 6-7% difference
How could that be a fact? Axial precession (a) has a period that is much longer than a year, meaning there is no systematic difference between the northern and southern hemispheres; and (b) has a period that is MUCH longer than a year, meaning the difference between the northern and southern hemispheres in the same year is negligible.
I'm not following you. What is the difference between your point a and b? Did you just wrote "much" with capitals and reworded that there is no effect?
> Axial precession has a period that is much longer than a year
Yes, much longer. The cycle of axial precession is about 26,000 years.[1]
> meaning there is no systematic difference between the northern and southern hemispheres
This does not follow. The fact that the axial precession's period is much longer than a year means that the angle of the axis can be considered approximately constant during a year. Why would that mean there is no systemic difference between the northern and southern hemispheres?
"Axial precession makes seasonal contrasts more extreme in one hemisphere and less extreme in the other. Currently perihelion occurs during winter in the Northern Hemisphere and in summer in the Southern Hemisphere. This makes Southern Hemisphere summers hotter and moderates Northern Hemisphere seasonal variations."
> The fact that the axial precession's period is much longer than a year means that the angle of the axis can be considered approximately constant during a year. Why would that mean there is no systemic difference between the northern and southern hemispheres?
Well, you're citing the conclusion of point B and then responding to the conclusion of point A. (Yes, they have identical premises, but B is more technically accurate.)
If the obliquity[1] of the earth is constant during a year (which it effectively is), then there is no difference in the obliquity of the earth between summer of year X and winter of year X, and therefore the obliquity of the earth cannot be responsible for any difference between the northern hemisphere and the southern hemisphere. This should be painfully obvious.
Back on point A, in order for there to be a systematic difference between the seasons in the northern and southern hemispheres, precession would need to have a period that was a multiple of the solar year. This would keep the difference in place over time. Without meeting that requirement, the hypothetical precession-based phenomenon would wander through the calendar year, which would prevent it from systematically having different effects in different hemispheres.
Being a multiple of the solar year is not ruled out by the fact that the precessional period is on the order of tens of thousands years, but it becomes vanishingly unlikely.
> Did you just wrote "much" with capitals and reworded that there is no effect?
No.
> What is the difference between your point a and b?
They are addressing different points.
One is talking about year-to-year differences; if summer in December 2437 is hotter than summer in June 2437, does it follow that summer in December 12437 will be hotter than summer in June 12437? (No, because the precessional period is not related to the orbital period.)
The other is talking about within-year differences. If summer in June 2437 is whatever temperature it is, does it follow that summer in December 2437 will be hotter than that? (No, because the precessional period is much longer than the orbital period.)
> Axial precession makes seasonal contrasts more extreme in one hemisphere and less extreme in the other. Currently perihelion occurs during winter in the Northern Hemisphere and in summer in the Southern Hemisphere. This makes Southern Hemisphere summers hotter and moderates Northern Hemisphere seasonal variations.
This is logically incoherent. There are two problems:
1. Axial precession isn't doing any work here. The difference, as described, comes from an interaction between the earth's orientation and the eccentricity of its orbit. Axial precession has no role to play in the phenomenon; the conclusion ("southern summers are hotter and southern summers are colder") would be equally true if there was no precession. (In fact, more true, since in that case it would remain true into the future.) The effect of precession is described in the following sentence:
> But in about 13,000 years, axial precession will cause these conditions to flip, with the Northern Hemisphere seeing more extremes in solar radiation and the Southern Hemisphere experiencing more moderate seasonal variations.
2. Perihelion is not a concept related to the obliquity of the earth or the axial precession. As such, once you've invoked perihelion, you can't attribute responsibility to obliquity or precession. Going by the description here, there is a period (perihelion) which causes the seasons in one part of the earth to be more extreme, and axial precession is the phenomenon that causes which part of the earth experiences that greater extremity of climate to shift over time. How do you get from "axial precession distributes the effect of perihelion evenly over the earth" to "axial precession is why the seasons are more extreme in the southern hemisphere"?
So, going back to the original claim:
>> but the fact we tilt slightly closer to the sun in summer than the northern hemisphere makes 6-7% difference
This is not a fact. It's false. There is no significant difference in tilt. The difference is in physical distance to the sun, not angular distance to the sun.
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[1] You're making a mistake here; the angle of the earth to the orbital plane ("which latitude points directly at the sun?") is not affected by axial precession ("where in the sky is the north pole?"). I was making the same mistake.
Atmospheric pollution scatters and absorbs some UV light in the upper atmosphere and stops it reaching the ground. While reducing pollution is a net good, one unfortunate consequence of controlling and reducing the pollution that gets up to the upper atmosphere is that it will lead to a few percent increase in the UV dose people receive in the northern hemisphere. Skin cancer is associated with UV exposure so incidence of skin cancers will go up if sun safety is not observed.
Oh it's far more than that. Giant volcanic eruptions have been responsible for non negligible reductions in global temperatures due to reducing the sunlight which hits earth via scattering and other effects due to the pollution.
They probably didn't mean to a large degree, but air pollution does scatter light and UV radiation. As well as cause breathing problems, asthma, probably lung cancer, etc.
The sun has been really strong since the early 2000s. It's a shame that the Southern hemisphere got that affected given it probably produced less than 20% of the damage.
There is some evidence that soleus push ups can induce significant insulin responses, without the need for drugs.
Soleus is the muscle below the calf and normally used when walking running and jumping
> All of the 600 muscles combined normally contribute only about 15% of the whole-body oxidative metabolism in the three hours after ingesting carbohydrate. Despite the fact that the soleus is only 1% the body weight, it is capable of raising its metabolic rate during SPU contractions to easily double, even sometimes triple, the whole-body carbohydrate oxidation.
All right, this is a single Data point, and of course is anecdotal evidence… if you’re into taking health advice off the Internet rather than from your doctor… well you probably will end up disappointed.
OK disclaimers aside now: when I switched to clipless petals on my mountain bike, I dropped 12 lbs over the course of the summer. SPD clipless work the hell out of your calves when they are placed under the ball of your foot, especially in mountain biking applications because you spend so much time out of the saddle.
There is so many lurking variables here and nothing was normalized. I just thought that was an interesting connection.
My speculation, as with others, is that Alzheimer's disease (as well as many other slow progressing diseases) is just a metabolic disease, inline with the "type 3 diabetes" comments.
Look into supporting mitochondria health [0] and the glymphatic system [1]: good diet (with fasting), light to moderate exercise, sleep and wake at the same time each day for circadian rhythm training, reduce unnecessary stress.
Once the basics have been implemented, some supplements could help to further support cell function if needed: Longevity supplements that Dr David Sinclair takes [2], boosting cellular glutathione stores, with NACET, glycine, selenium [3]
Not to mention the social load on integrating a new person to a team. Depending on the depth, breadth and number of interactions with other individuals, this causes others to have to also get up to speed on the new person's strengths, weakness, quirks, etc.
