Hello Dear Readers,
Today I'm making the move over to Medium.
https://medium.com/@PrimeViridian
This will be the last post I make on blogger, but all the old links will stay active.
Cheers
-Robert
Things are interesting
Saturday, July 16, 2016
Sunday, July 10, 2016
Mom's Icosahedrons
Mom is a nurse with the Red Cross. Recently she took up the hobby of stringing together syringe-cover tubes to make icosahedrons (30 tubes and 1 piece of string):
I couldn't figure out how she managed each of the tubes being run through exactly twice, so I had her show me when I was out for a visit. I made mental notes so later I could put this assembly guide together: https://drive.google.com/open?id=0B2eEHrHZqClKdlZiOG1wRGVPOVk
When the lesson concluded, she insisted I take enough tubes home so I could make a "Mom mobile." While the icosahedrons have been assembled pretty much since I got home, today I finally hung them up with cotton string and disposable bamboo chopsticks:
This was a fun project. I'm ecstatic to find Mom has the same affinity for 3D geometry that I first started exploring when I was 7. Apparently all she needed to get going was a combination of Pinterest and a preponderance of disposable tubes.
Friday, June 24, 2016
Rabbits in my Garden
Earlier today I was watering my garden and in the back corner I noticed something running around.
It’s not uncommon to see rabbits chilling out in my back yard, but the fence I
put up has always kept them out of the actual garden. I expected the things
running around to run away, but not today… No, today there was a baby bunny INSIDE
the garden. It was trying to get out the corner, which made it easy to pick up
by the scruff of its neck. I started talking to it:
“You
are in so much trouble.”
“You’re so small you can get in the fence holes I didn’t bother to patch, didn’t you?”
“Are you why my peppers didn’t sprout?”
“You know I eat creatures like you? You’re called ‘meat.’ You know that, right?”
“You’re a pest! I should exterminate you!”
“You’re so small you can get in the fence holes I didn’t bother to patch, didn’t you?”
“Are you why my peppers didn’t sprout?”
“You know I eat creatures like you? You’re called ‘meat.’ You know that, right?”
“You’re a pest! I should exterminate you!”
This went on for a few more minutes and (swearing) I let the
thing go.
I went back to watering my garden and saw a second baby bunny in there. I had to sneak up on this one because it was hiding under the Chinese cabbage. This time I got a picture:
I went back to watering my garden and saw a second baby bunny in there. I had to sneak up on this one because it was hiding under the Chinese cabbage. This time I got a picture:
Unlike the first baby bunny, this one made a lot of noise; so much noise that this full-grown bunny ran out in response:
I realized this was probably the mother. I yelled at it for
making things more complicated.
Out of the corner of my eye I saw a third baby bunny running
around; it was probably just excited mama was there:
I did not pick this one up.
The mom remained still, just sitting there:
I realized this animal must be too big to get through the holes her babies used, and now it wants me to get her third baby
out.
A prey animal had made itself vulnerable to me. I eat
meat. I had a desire to kill this animal and eat it, but the neighbors (who definitely heard all the
swearing when I let the first bunny go), and in particular the lady next door, would NOT be okay with me slaughtering wild/feral rabbits. Particularly heavy on my mind is my cat (indoor/screenporch/leash only). Callisto will always eat meat. This would
be the best free-range grass-fed cat food ever! I would adore the opportunity
to slaughter such a fine meal for my pet.
I was standing there so long (just staring at this rabbit) that I
called my dad. I expected him to tell me I was crazy and that I should just let the third bunny go and find something else to worry about. My dad said he couldn't tell me what I want to hear, though we did talk about it for a while. I have a habit of pacing while I'm on the phone. At one point I was within 3 ft of the mother. While she looked scared, she didn't move at all.
Still on the phone, I got worn out to the point where I just left. A half-hour later, the mother was still sitting on the lawn. I took this photo from my rear window.
A cat eventually scared the mother away. The cat just wandered back the way it came.
It's dark now, and as far as I know, the third baby bunny is still in the
garden. It certainly has enough food in there, and the mother will probably stay nearby. Tomorrow when I water the garden I'll probably just do what I did today: I'll pick the third bunny up, it'll holler, it's mama will come running, I'll let it go, and then I'll just leave this wild/feral warren alone.
I'll also fix the fence.
As an aside, if the city and my apartment-management company are okay with with it, I'm now considering raising a few rabbits for meat, only I won't catch wild/feral bunnies from my garden. I figure domesticated rabbits would be a better suited to cages and my neighbor wouldn't be on my case about cruelty to the native wildlife. We have plenty of basement space we could use in the winter too. I'll file rabbits on the "someday" list, and for now accept some level in hypocrisy in eating meat and letting the garden pests go. I never expected gardening to challenge me morally. Send help.
Have a nice weekend everyone.
Friday, May 20, 2016
Sustainable Fuels Question 1
I occasionally get questions about sustainable fuels. I'm happy to answer them, but I hate losing track of answers on Facebook, so from now on my answers go on my blog!
Today's question comes from an old high school jazz band friend:
Hey Logan. There’s layers to this question. Here goes.
I know for sure you’re not electrolyzing water since methane
(CH4) has a carbon atom in it, and water (H2O) doesn’t.
That methane's carbon has to come from somewhere, so it either (A) started off as in a fossil
fuel (and ended up in the atmosphere when you burned it in the rocket), or else
(B) started off in the atmosphere as CO2 and got converted into methane (and thus the burning it to make CO2 was part of a cycle that didn’t contribute to the total
amount of atmospheric carbon).
As a brief aside, electrolysis is the process of zapping things
like water or methane to get hydrogen gas (H2) and leave all the carbon
behind. This is useful for folks (with which I disagree) who envision a “hydrogen economy.” To use carbon (as opposed to just hydrogen) sustainably takes more steps,
but it’s worth it since carbon-based fuels like gasoline are so much more
energy dense and easier to transport than hydrogen. To get the hydrogen to have
the same energy in the same space requires dangerously high
pressures.
The rest of this blog entry discusses how to accomplish the sustainable option of making fuel from atmospheric CO2. In order accomplish this it's absolutely necessary that we start with concentrating carbon from the atmosphere. This can
either be done with plants like grass and trees (which concentrate atmospheric carbon in the form of
a solid chemicals such as cellulose) or big solar-powered gizmos that filter
out atmospheric CO2 for storage in tanks (such gizmos probably won’t
ever be as land-space efficient as a plants, but they could work in the desert
where plants can’t grow).
After concentrating the carbon, we then need some method
of converting it into fuel. Thermochemical
conversion methods such as gasification/pyrolysis and several varieties of catalysis
can all use some form of solar energy to convert both biomass and bottled
CO2 into pretty much any carbon-based fuel (be it methane,
gasoline, or diesel). Biochemical conversion methods are another set of techniques that all have the disadvantage of not converting
CO2 in tanks, meaning they only work on biomass. Many biochemical
methods (such as fermentation to make ethanol) are really inefficient at
producing fuel and only work on things we nominally consider food (like cane sugar).
Since you asked about methane, one biochemical method I like quite a bit is anaerobic digestion. Anaerobic digestion works on
practically any kind of biomass (not just food) and is much more efficient at making fuel than other biochemical methods. The
process makes gaseous methane which is both more convenient than hydrogen since it’s
more energy dense, but less convenient than liquids like gasoline or ethanol. Here’s an article I wrote about how Washington D.C. is
using anaerobic digestion to get a portion of their power from poop: http://www.thedailybeast.com/articles/2015/10/14/america-s-capital-powered-by-poop.html
Since all these methods take carbon from the atmosphere
and turn it into fuel, the burning of that fuel in a rocket is just a part of a cycle that goes plant (or tank) -> fuel ->
atmosphere -> and back to plant (or tank). Fuel gathered in this way is
sustainable carbon fuel, and it doesn’t contribute to the total amount of carbon
in the atmosphere.
Monday, May 2, 2016
Infinitely positive is neither infinite nor positive?
There's a recently publicized British biographical drama called "The Man Who Knew Infinity" about Srinivasa Ramanujan (1887-1920), a mathematician who, after growing up poor in Madras, India, earns admittance to Cambridge University and becomes a pioneer in mathematics. One of the things Ramanujan is particularly remembered for is adding an infinite number of (positive) things together, but getting something that is neither infinite, nor positive. For example: 1 + 2 + 3 + 4 + ... = -1/12
Every time this comes up, somebody asks me how adding an infinite number of progressively larger things can come out negative. Shouldn't the right answer be infinity?
It turns out (depending on what the dots mean) that both answers are correct. To understand how this is possible, suppose Achilles is out for a run and after spotting a wandering tortoise 100 meters ahead, he decides to catch up with it, only he plays a game of catching up to where the tortoise is now rather than where it will be. By the time Achilles catches up to where the tortoise was, the tortoise is 50 meters away. If Achilles again catches up to where the tortoise was, that sneaky tortoise is now 25 meters away. Achilles can keep playing this game indefinitely; to actually catch the tortoise would require catching up to where the tortoise was an infinite number of times.
Despite the infinite number of times Achilles catches up to the previous location of the tortoise, Achilles will, in fact, catch it. The trick is that these distances (as well as the times it takes for Achilles to cover them), get smaller and smaller. If Achilles runs at 1m/s and the tortoise at ½m/s, the infinite sum works out so the duo will meet after 100 seconds and Achilles has run 200 meters. (100m + 50m + 25m + ... = 200m)
This scenario, sometimes referred to as Zeno's Paradox, embodies what mathematicians call a "convergent series." The word "series" means all the terms are being added together and convergent means the sum approaches some number as terms are added. Usually, when terms get smaller and smaller, the series converges (though there are a few exceptions such as the harmonic series.) Convergent series are why, for example, a ball could theoretically bounce an infinite number of times before coming to rest a few seconds later.
Ramanujan's infinite sum is what mathematicians call a "divergent series" because the terms get bigger and bigger so the sum just blows up to infinity. Divergent series can apply to Achilles and the tortoise as well. Suppose Achilles is 100 meters ahead of the tortoise. How long until he catches the tortoise?
- A very good answer is "never." If the race were infinitely long, there's just no way for Achilles to catch the tortoise because Achilles already is ahead of it.
- Another very good answer is "in the past" since Achilles passed the tortoise 100 meters before the starting line 100 seconds before the race started. An equivalent way of saying this is that Achilles will catch the tortoise after negative one-hundred seconds (-100s) having traveled a distance of negative one-hundred meters (-100m).
So what does this have to do with Ramanujan and his infinite sum? Well, the tortoise can catch up to where Achilles was, and he can do this again and again... forever. It's just like before where Achilles closed in on the tortoise, only now the distances (as well as the time it takes to cover them) get bigger and bigger. Adding all these distances together makes a divergent series. Evaluating this sum, it makes sense to get an answer that's infinite... but it also makes sense to get an answer that's both non-infinite and negative. Similar logic can be applied to Ramanujan's sum.
Showing how Ramanujan's sum comes out to -1/12 takes a few more tricks. See below for a ad-hoc derivation:
Tuesday, March 1, 2016
Reflections on the Anthropocene
Humans are responsible for the spread of countless food/resource plants and animals, human parasites, and other invasive species across
constants (particularly from the 16th century onward). We’re also the cause a
sixth mass extinction, a measurable increase deforestation and desertification,
the shifting of sedimentation patterns from roads and damns, a significant dent
in the availability of fossil fuels, a 100-ppm (and counting) increase in
atmospheric carbon, the detonating hundreds of atmospheric nuclear devices
(thus ruining carbon-dating methods for anything past 1950), and the production
of many new minerals such as ceramic, plastic, concrete, aluminum, titanium,
and extremely radioactive substances such as corium (the product of nuclear
meltdowns).
Anatomically modern humans have only existed for roughly 200
thousand years, and we’ve only been practicing agriculture for roughly the last 10
thousand. The longest-lived civilization ever to grace the earth only
lasted 1.5 thousand years, and that’s being incredibly generous. How long into
the next million years will we even last? What force will end the last human
civilization, and how long after that will it take for the last human to die off?
The next time the evolutionary engine of Earth produces a
species capable of discovering geology – be it the descendants of dolphins,
bees, or slime molds – that species will be able to tell some interesting tales of an ancient ape who came down from the trees, developed stone harvesting and hunting tools, spread
as far as the megafauna could lead them, plopped down to build civilizations
around the domestication of specific plants and animals, and quickly developed
technologies that altered the geology of the time.
Upon discovering our fossilized remains and our geologic
impact, what will they think of us? Will they idolize us or hold us in contempt? Will there be lessons to be gleamed from our failures? With fossil fuels less available, will they be forced to develop renewable technologies? Will they be able to reverse engineer our ancient methods? Will they eventually be able to
reach farther than us? Will they come to physically realize realities we never even dreamed of?
The story of humanity thus far is simultaneously amazing,
tragic, and understandable. I hope that by the time the end of our story is written in
the rocks, it will show that we learned, for a time, how to live sustainably,
peacefully, equitably, and happily.
Friday, January 29, 2016
New article on Nautilus today!
This went up today. I've been wanting to write about this
particular topic ever since I entered the world of science writing.
The original topic I pitched was to actually show examples of
Ancient-Greek and Medieval-Islamic mathematics, but after some back-and-forth
with my editor we finally cut them. I don't know who reads this blog, but if
you're here you'll probably find these examples interesting.
The Nautilus article mentions the Golden Ratio because it's an
irrational value/length that Ancient Greek scholars were able to determine geometrically. Because of the phobia surrounding irrational numbers an algebraic determination
didn't come until more than a thousand years later. For the algebraic solution, we can thank Medieval Islamic
scholars.
Ancient Greek Geometry:
A rectangle with the golden ratio has the following
property:
When you cut a square off a Golden Rectangle, the
rectangle remaining has the same aspect ratio as the original, rotated at a
right angle, like so:
So how do we construct a
Golden Rectangle? And how can we be
sure the construction actually works?
The following construction procedure is found in Eudlid's Elements (3rd-century
BCE). The cult of the Pythagoreans (6th-century BCE) probably proved
this particular construction produced a Golden Rectangle; Euclid just included
it in his famous geometry textbook:
1.
Start with a square (shown in red).
2.
Draw a line from the midpoint of the base of the
red square to its upper right corner.
3.
Swing this length down to the red square's base.
To prove this construction produces a Golden Rectangle, certain areas within the rectangle had to be proven equal. To determine which areas, the Pythagoreans started with the one thing they knew about a Golden Rectangle: matching aspect ratios. While what follows is today called "cross multiplying", Euclid refers to it as Book 6 Prop. 17.
Book 2 Prop. 11 shows that for the construction described above, the red and blue areas are indeed equal:
The first part on the left uses a rule about tacking on
lengths to a bisected line (Book 2 Prop. 6). The second part on the right
uses the Pythagorean Theorem (Book 1 Prop. 47).
This shows that Ancient Greek scholars figured out how
to solve this problem geometrically. The algebraic solution came more than a
millennium later in Medieval Baghdad.
Medieval Islamic Algebra:
Algebra began in Ancient Babylonia. The conquests of Alexander the Great in the 4th-century BCE, which stretched from Greece and Egypt to India, likely brought this knowledge to Hellenistic Greece. While Greek scholars did measurably advance the topic, Medieval Islamic scholars took it much further.
In 19th-century BCE Babylonia, a problem like “x² = x + 870” looked like this:
In 19th-century BCE Babylonia, a problem like “x² = x + 870” looked like this:
British Museum Tablet 13901 |
Here's a translation from Babylonian into English (and sexagesimal into decimal).
Problem: I added 870 to
the side of my square to get its area. What is the side length of my square?
Solution: You divide 1
(multiplied by the side length) by two, it gives ½. You multiply it by itself,
it gives ¼. You add it to 870, it gives 870+¼. It is the square of 29+½. You
add ½ (which you multiplied) to 29+½, it gives 30 (the side length). (Adapted
from this book)
And here it is again translated into modern notation:
Problem: x² = x + 870
More generally, all problems of this form can be solved
using the following formula:
Problem: x² = px + q
This "rhetorical form" of algebra was pretty much constant across its advancement under the Ancient Babylonians, Hellenistic Greeks, Classical Indians, and Medieval Muslims. What 9th-century CE Islamic scholars did that nobody else had ever thought to do before was apply these procedures to the quadratic irrational lengths found in Greek
Geometry.
Since the aspect ratios are equal, the problem can be
represented algebraically. Keep in mind, Medieval Islamic scholars would have written their equations out as sentences, but the steps taken would have been pretty much the same.
x/1 = 1/(x-1)
Cross multiply:
x·(x-1) = 1²
Distribute x across (x-1):
x² - x = 1
Add x to both sides:
x² = x + 1
Since the problem is now in the form of x² = px + q, we can apply the ancient Babylonian solution procedure.
Problem: x² = x + 1
A commentary on Euclid’s Elements by the 9th-century Islamic mathematician Al-Mahani is the first known work that algebraically explores quadratic (and cubic) irrational numbers. Thus Medieval Islamic Scholars were able to algebraically solve problems that Ancient Greek Scholars had geometrically solved more than a millennium earlier.
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