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Sunday, December 31, 2017

Dial M for Meteorology

Dial M for Meteorology


Call a 900 number to get good weather information – for a fee. (History of meteorology, situation in the 90s).

People planning vacations or business trips and who need accurate weather reports and forecasts for their travel destinations can turn to 900-number hotlines, the best of which are sponsored by the Weather Channel, USA Today, the Weather Radio Network, Accu-Weather, etc. All of these hotlines describe a selected city’s weather conditions, including forecasts that range from three to seven days.

Both the Weather Channel and USA Today outdo the other services by providing the most information. Those traveling by car can find out about conditions on major highways surrounding a selected city. International travelers can use these hot lines to learn about visa requirements, tipping customs, currency exchange rates, and State Department travel advisories.

Unlike USA Today, the Weather Channel sponsors a marine report of interest to beach-goers and boaters that includes tide information, wave heights, and water temperatures. The Weather Channel also presents slope conditions at over 400 ski areas. USA Today’s weather line even tries to give the traveler the chance of rain on any given date in the city.

The Winter Is Coming. Photo: Elena

Accu-Weather’s advantage over the other hotlines is its simplicity. Callers con get good, basic weather information and since there are fewer options, the call is shorter and so costs less money. All three services take about one and a half to two minutes on average to present a standard weather report and 36-hour forecast.

The national Radio Network is unique among weather hotlines in that it allows the caller to listen to live radio broadcasts from 85 local offices of the National Weather Service. The National Weather Service updates these weather reports every hour, which is just as often as many of the other services update their information. However, the reports become more frequent when weather conditions become particularly troublesome. Therefore, the caller can almost be guaranteed to get the most recent information on public warnings during hurricanes, floods, and tornadoes. This number provides detailed weather information, but because it is not menu driven, the caller who wants a basic weather report might have to listen to marine or road conditions before getting to the weather broadcast. On average, the calls last about 3.8 minutes.

For Accurate Weather


Predicting temperature accurately is more difficult in the cool season than in the summer. That’s because weather systems are stronger and move quickly in winter, leading to greater temperature variabilility.

In predicting precipitation, forecasts generally are les accurate when the weather is warm. Most precipitation in the warm season comes from showers and thunderstorms, which occur randomly, cover small areas, and don’t last long. In winter, precipitation usually results from weather systems that cover larger areas and last many hours or days, and thus is easier to predict.

Barometers

Barometers


Know which way the wind blows: Forecast the weather by gauging changes in atmospheric pressure.

With a simple aneroid barometer, available at a local hardware store or marine supply center, you can make fairly accurate short-range weather predictions for little money. Generally, when the barometer is high and rising, it means high pressure is approaching. High pressure systems typically are associated with fair weather – light and variable winds, dry air, and temperatures below seasonal averages. When the barometer is low and falling, it typically means low pressure is on the way. Law pressure systems tend to bring inclement weather – strong winds, high humidity, clouds, and storm fronts.

An aneroid barometer has one pointer, similar to the hand on a clock, which measures atmosphere pressure in inches of mercury and another pointer which is used to reference pressure changes. Rising pressure causes the reading pointer to move clockwise, while falling pressure causes it to move counterclockwise.

Once or twice a day, the reference pointer should be placed to correspond with the reading pointer. Over the course of the day, you can track pressure changes by noting how the reading pointer moves in relation to the reference hand.

Park of the Hudson River, New York. Photo : Elena

To ensure accurate readings, aneroid barometers, and even some electronic barometers, occasionally need to be calibrated. A call to the local branch of the Weather Service or listening to the weather report on TV provides the current pressure adjusted to what it would read at sea level. Adjustments should be made on days with settled winds, which usually indicate the pressure is changing slowly.

Many amateur forecasters find useful the following chart, which bases its weather predictions on barometric changes and wind direction. However, meteorologists caution these are general rules that don’t hold true for all locations and situations. For example, west winds off the Great Lakes can bring terrible lake effect snows even when the barometer is high. Similarly, in the Northeast near the Atlantic Ocean, a sea breeze can bring cooler air, clouds, drizzle, and fog when the pressure is high.

Be Your Own Forecaster
Basic barometer reading for amateur meteorologists can fool you, but generally they can help you to find out what weather to expect.

The Old Science

The Old Science


When one looks at science from a historical perspective, it can be said that science has not always followed a linear path of development. For example, if one draws a diagram of scientific development, one can see that a lot more technological progress has been achieved in the last hundred or so years than in the thousands of years before that.

Naturally, history courses talk about the history of science from the invention of the wheel up to the advent of the Internet, with important milestones being the period of the Classics, the Middle Ages (during which scientific progress was halted and regressed), the Renaissance and Enlightenment and the Industrial Revolution. Today’s era, due to its prevalence of information and communications technologies, is typically referred to as the information age or the Information era.

A Fort Stewart in Montreal. Photo by Elena

Alternatively, to look at the scientific questions from a spiritual perspective, even today the debate of creationism versus intelligent design persists. Many people argue that the two cannot coexist, while others believe that God created science and the laws governing physics, and that we are learning God’s laws by exploring science.

Regardless of what you believe or do not believe, there are social and hard applied sciences taught in universities and other institutions of higher learning.

Science is Magic. Photo by Elena

Toronto, View from Heaven

Toronto, view from Heaven



A city is not gauged by its length and width, but by its vision and the height of its dreams. (Herb Caen)

I love being on the road. I love that lifestyle, traveling, rocking out and moving on to the next place. (Caleb Johnson)

This City is what it is because our citizens are what they are. (Plato, a great Greek philosopher and thinker)


Every day, in every city and town across the country, police officers are performing vital services that help make their communities safer. (Eric Schneiderman)

In the city that the wolf enters, enemies will be close by. An alien force will sack a great country. Allies will cross the mountains and the borders. (Nostradamus)

The two elements the traveler first captures in the big city are extra human architecture and furious rhythm. Geometry and anguish. (Federico Garcia Lorca)


In the city, we work until quitting time. On the farm, we work until the job is finished. (John Bytheway)

I'm accepting I'm not living that younger, dreamed version of myself in the big city. (Paula Cole)

Every city in the world always has a gang, a street gang, or the so-called outcasts. (Jimi Hendrix)


A great city is not to be confounded with a populous one. (Aristotle)

I like it when it's nice and quiet. Not a big city person. (Louis Oosthuizen)

But a city is more than a place in space, it is a drama in time. (Patrick Geddes)


Never, never take an elevator in city hall. (Harvey Milk)

I love Toronto, It's the best city. (Jacqueline MacInnes Wood)

Every city is great, as only it's Toronto (Megan Jorgensen)


The city is like a great house, and the house in its turn a small city. (Leon Battista Alberti)

The most important thing a mayor does is hire talented people. (John Hickenlooper)

I would never be able to spend all my life in a busy city. (Kangana Ranaut)


The city needs a car like a fish needs a bicycle. (Dean Kamen)

Totonto is a 24-hours city, it never stops. (Megan Jorgensen)

I love the Earth and Toronto is my city. (Megan Jorgensen)


On the Web we all become small-town visitors lost in the big city. (Alison Gopnik)

To one extent, if you've seen one city slum, you've seen them all. (Spiro T. Agnew)

Saturday, December 30, 2017

Spectrum of Light

Spectrum of Light


The spectrum runs from high frequencies of visible light to low ones – violet, blue, green, yellow, orange and red (light is a wave motion; its frequency is the number of wave crests, say, entering a detection instrument, such as a retina, in a given unite of time, such as a second. The higher the frequency the more energetic the radiation).

Since we see these colors, it is called the spectrum of visible light. But there is far more light than the small segment of the spectrum we can see. At higher frequencies, beyond the violet, is a part of the spectrum called the ultraviolet: a perfectly real kind of light, carrying death to the microbes. It is invisible to us, but readily detectable by bumblebees and photoelectric cells. There is much more to the world than we can see. Beyond the ultraviolet is the X-ray part of the spectrum, and beyond the X-rays are the gamma rays. At lower frequencies, on the other side of red, is the infrared part of the spectrum. It was first discovered by placing a sensitive thermometer In what to our eyes is the dark beyond the red. The temperature rose. There was light falling on the thermometer even though it was invisible to our eyes. Rattlesnakes and doped semiconductors detect infrared region of the radio waves. From gamma rays to radio waves, all are equally respectable brands of light. All are useful in astronomy. But because of the limitations of our eyes, we have a prejudice, a bias, toward that tiny rainbow band we call the spectrum of visible light.

Pusha, the cat. Photo by Elena

In 1844, the philosopher Auguste Comte was searching for an example of a sort of knowledge that would be always hidden. He chose the composition of distant stars and planets. We would never physically visit them, he thought, and with no sample in hand it seemed we would forever be denied knowledge of their composition. But only three years after Comte’s death, it was discovered that a spectrum can be used to determine the chemistry of distant objects. Different molecules and chemical elements absorb different frequencies or colors of light, sometimes in the visible and sometimes elsewhere in the spectrum. In the spectrum of a planetary atmosphere, a single dark line represents an image of the slit in which light is missing, the absorption of sunlight during its brief passage through the air of another world. Each such line is made by a particular kind of molecule or atom. Every substance has its characteristic spectral signature. The gases on Venus can be identified from the Earth, 60 million kilometers away. We can divine the composition of the Sun (in which helium, named after the Greek sun god Helios, was first found); of magnetic A stars rich in europium; of distant galaxies analyzed through the collective light of a hundred billion constituent stars. Astronomical spectroscopy is an almost magical technique. It amazes scientists – the fact that Auguste Comte picked a particularly unfortunate example.

There is much more to the world than we can see. Image Alternate Reality by © Elena

Measurement of the Earth

Measurement of the Earth


One day Eratosthenes read in a papyrus book that in the southern frontier outpost of Syene, near the first cataract of the Nile, at noon of June 21 vertical sticks cast no shadows. Eratosthenes was really amused and went on reading…

On the summer solstice, the longest day of the year, as the hours crept toward midday, the shadows of temple columns grew shorter. At noon, they were gone. A reflection of the Sun could then be seen in the water at the bottom of a deep well. He Sun was directly overhead.

It was an observation that someone else might easily have ignored. Sticks, shadows, reflections in wells, the Sun over the head, what the matter? of what possible importance could such simple everyday observations be?

But Eratosthenes was a scientist, and his musing on these commonplaces changed the world. In a way, they made our world, as Eratosthenes actually had the presence of mind to do an experiment to observe whether in Alexandria vertical sticks cast shadows near noon on June 21. And, he discovered, sticks do cast shadows!

The scientist asked himself how, at the same moment, a stick in Syene could cast no shadow and a stick in Alexandria, far to the North, could cast a pronounced shadow? Consider now a map of ancient Egypt with two vertical sticks of equal length, one stuck in Syene and the other in Alexandria.

On this planet Earth the fear of death follows from the fear of life. A man who lives fully is prepared to die at any time. (Mark Twain). Photo : Elena

Suppose that, at a certain moment, each stick casts no shadow at all. This is perfectly easy to understand – provided the Earth is flat and the Sun would then be directly overhead. But if the two sticks cast shadows of equal length that also would make sense on a flat Earth: the Sun’s rays would then be inclined at the same angle to the two sticks. But how could it be that at the same instant there was no shadow at Syene and a substantial shadow at Alexandria?

The only possible answer, he saw, was that the surface of the Earth is curved. Not only that: the greater the curvature, the greater the difference in the shadow lengths. The Sun is so far away that its rays are parallel when they reach the Earth. Sticks placed at different angles to the Sun’s rays cast shadows of different lengths. For the observed difference in the shadow lengths, the distance between Alexandria and Syene had to be about seven degrees along the surface of the Earth; that is, if you imagine the sticks extending down to the center of the Earth, they would there intersect at an angle of seven degrees. Seven degrees is something like one-fiftieth of three hundred and sixty degrees, the full circumference of the Earth. Eratosthenes knew that the distance between Alexnadria and Syene was approximately 800 kilometers, because he hired a man to pace it out. Eight hundred kilometers 50 is 40,000 kilometers: so that must be the circumference of the Earth.

This is the right answer! Eratosthenes only tools were sticks, eyes, feet and brain, plus a taste for experiment. With them he deduced the circumference of the Earth with an error of only a few percent, a remarkable achievement for 2,200 years ago. He was the first person accurately to measure the size of our planet.

Discovery by Eratosthenes


The discovery that the Earth is a very little world was made, as so many very important human discoveries were, in the ancient Near East, in a time some humans still call the third century B.C. This discovery was made in the greatest metropolis of the age, the Egyptian city of Alexandria.

There lived a man in this city, named Eratosthenes. He was an astronomer, philosopher, poet, theater critic, historian and mathematician. The title of the books he wrote range from Astronomy to On Freedom from Pain.

One of his envious contemporaries called him Beta, the second letter of the Greek alphabet, because, he said, Eratosthenes was second best in the world in anything.

It seems clear that in almost everything Eratosthenes was Alpha. He was also the director of the great library of Alexandria. One day thus he read in a papyrus book that in the southern frontier outpost of Syene, near the first cataract of the Nile, at noon of June 21 vertical sticks cast no shadows. Eratosthenes was really amused and went on reading…

(By Carl Sagan, Cosmos).

The Earth, Illustration by Elena.

Back-contamination

Back-contamination


Any space mission carries with it a novel danger: back-contamination. If we wish on Earth to examine samples of Martian soil for microbes, we must, of course, not sterilize the samples beforehand. The point of the expedition is to bring them back alive. But what then? Might Martian microorganisms returned to Earth pose a public health hazard? The Martians of H. G. Wells and Orson Welles, preoccupied with the suppression of Bournemouth and Jersey City, never noticed until too late that their immunological defenses were unavailing against the microbes of Earth. Is the converse possible? This is a serious and difficult issue. There may be no micromartians. If they exist, perhaps we can eat a kilogram of them with no ill effects. But we are not sure, and the stakes are high.

If we wish to return unsterilized Martian samples to Earth, we must have a containment procedure that is stupefyingly reliable. There are nations that develop and stockpile bacteriological weapons. They seem to have an occasion accident, but they have not yet, so far as we know, produced global pandemics. Perhaps Martian samples can be safely returned to Earth. But we would want to be very sure before considering a returned-sample mission.

Are there ancient river valleys on Mars? Image: Bright Crystall Ball Shining © Elena

There is another way to investigate Mars and the full range of delights and discoveries this heterogeneous planet holds for us. Carl Sagan’s most persistent emotion in working with the Viking lander pictures was frustration of our immobility He found himself unconsciously urgin the spacecraft at least to stand on its tiptoes, as if this laboratory, designed for immobility, were perversely refusing to manage even a little hop. How he longed to poke that dune with the sample arm, look for life beneath that rock, see if that distant ridge was a crater rampart. And not so very far to the southeast, he knew, were the four sinuous channels of Chryse.

For all the tantalizing and provocative character of Viking results, we know a hundred places on Mars which are far more interesting than these landing sites. The ideal tool a roving vehicle carrying on advanced experiments, particularly in imaging, chemistry and biology. Prototypes of such rovers are under development by NASA. They know on their own how to go over rocks, how not to fall down ravines, how to get out of tight spots. It is within our capability to land a rover on Mars that could scan their surroundings, see the most interesting place in the field of view, and, by the same time tomorrow, be there. Every day a new place, a complex, winding traverse over the varied topography of this appealing planet.

Such a mission would reap enormous scientific benefits, even if there is no life on Mars. We could wander down the ancient river valleys, up the slopes of one of the great volcanic mountains, along the strange stepped terrain of the icy polar terraces, or muster a close approach to the beckoning pyramids of Mars (the largest are 3 kilometers across at the base and 1 kilometer high – much larger than the pyramids of Sumer, Egypt or Mexico on Earth. They seem eroded and ancient, and are, perhaps, only small mountains, sandblasted for ages. But they warrant, we think, a careful look).

Public interest in such a mission would be sizable. Every day a new set of vistas would arrive on our home television screens. We could trace the route, ponder the findings, suggest new destinations. The journey would be long, the rover obedient to radio commands from Earth. There would be plenty of time for good new ideas to be incorporated into the mission plan. A billion people could participate in the exploration of another world.

Who Speaks for Earth?

Who Speaks for Earth?


How vast those Orbs must be, and how inconsiderable this Earth, the Theatre upon which all our might Desings, all our Navigations, and all our Wars are transacted, is when compared to them. A very fit consideration, and matter of Reflection, for those Kings and Princes, who sacrifice the Lives of so many People, only to flatter their Ambition in being Masters of some pitiful corner of this small Spot (Christian Huygens, New Conjectures Concerning the Planetary Worlds, Their Inhabitants and Productions, circa 1690).

We look back through countless millions of years and see the great will to live struggling out of the intertidal slime, struggling from shape to shape and from power to power, crawling and the walking confidently upon the land, struggling generation after generation to master the air, creeping down into the darkness of the deep; we see it turn upon itself in rage and hunger and reshape itself anew, we watch it draw nearer and more akin to us, expanding, elaborating itself, pursuing its relentless inconceivable purpose, until at last it reaches us and its being beats through our brains and arteries… It is possible to believe that all the past is but the beginning of a beginning, and that all that is and has been is but the twilight of the dawn.

Life on Earth. Photo by Elena

It is possible to believe that all that the human mind has ever accomplished is but the dream before the awakening…

Out of our lineage, mind will spring, that will reach back to us in our littleness to know us better than we know ourselves. A day will come, one day in the unending succession of days, when being, beings who are now latent in our thoughts and hidden in our loins, shall stand upon this earth as one stands upon a footstool, and shall laugh and reach out their hands amidst the stars.

(Herbert G. Wells, The Discovery of the Future” Nature 65, 326 (1902)

To what purpose should I trouble myself in searching out the secrets of the stars, having death or slavery continually before my eyes? (A question put to Pythogaras by Anaximenes (circe 600 B.C.), according to Montaigne. Image Jaime Murray as H.G.Wells in Warehouse 12 TV series


Heaven for Humans

Heaven for Humans


Might the cooling increase the size of the polar ice cap, which, because it is bright, will reflect still more sunlight from the Earth, further cooling the planet, driving a runaway albedo effect? (The albedo is the fraction of the sunlight striking a planet that is reflected back to space. The albedo of the Earth is some 30 to 35 percent. The rest of the sunlight is absorbed by the ground and is responsible for the average surface temperature).

Our lovely blue planet, the Earth, is the only home we know. Venus is too hot. Mars is too cold. But the Earth is just right, a heaven for humans, After all, we evolved here. But our congenial climate may be unstable. We are perturbing our poor planet in serious and contradictory ways. Is there are any danger of driving the environment of the Earth toward the planetary Hell of Venus or the global ice age of Mars? The simple answer is that nobody knows. The study of the global climate, the comparison of the Earth with other worlds, are subjects in their earliest stages of development. They are fields that are poorly and grudgingly funded. In our ignorance, we continue to push and pull, to pollute the atmosphere and brighten the land, oblivious of the fact that the long-term consequences are largely unknown.

A palm tree on Earth. Photo by Elena.

A few million years ago, when human beings first evolved on Earth, it was already a middle-aged world, 4,6 billion years along from the catastrophes and impetuosities of its youth. But we humans now represent a new and perhaps decisive factor. Our intelligence and our technology have given us the power to affect the climate. How will we use this power? Are we willing to tolerate ignorance and complacency in matters that affect the entire human family? Do we value short-term advantages above the welfare of the Earth? Or will we think on longer time scales, with concern for our children and our grandchildren, to understand and protect the complex life-support systems of our planet?

The Earth is a tiny and fragile world. It needs to be cherished. Image: Palm Tree Sketch Drawing © Elena

Democritus

Democritus


The first hint, the whiff, of the existence of atoms, proposed by Empedocles, was carried much further by a man named Democritus, who came from the Ionian colony of Abdera in northern Greece. Abdera was a kind of joke town. If in 430 B.C. you told a story about someone from Abdera, you were guaranteed a laugh. It was in a way the Brooklyn of its time. For Democritus all of life was to be enjoyed and understood; understanding and enjoyment were the same thing. He said that “a life without festivity is a long road without an inn”. Democritus may have come from Abdera, but he was no dummy. He believed that a large number of worlds had formed spontaneously out of diffuse matter in space, evolved and then decayed.

At a time when no one knew about impact craters, Democritus thought that worlds on occasion collide; he believed that some worlds wandered alone through the darkness of space, while others were accompanied by several suns and moons; that some worlds were inhabited, while others had no plants or animals or even water; that the simplest forms of life arose from a kind of primeval ooze. He taught that perception – the reason, say, we think there is a pen in our hand – was a purely physical and mechanistic process; that thinking and feeling were attributes of matter put together in a sufficiently fine and complex way and not due to some spirit infused into matter by the gods.

Democritus vision. Photo by Elena

Democritus invented the word atom, Greek for “unable to be cut”. Atoms were the ultimate particles, forever frustrating our attempts to break them into smaller pieces. Everything, Democritus said, is a collection of atoms, intricately assembled. Even we. “Nothing exists”, he said, “but the atoms and the void”.

When we cut an apple or a pumpkin, the knife must pass through empty spaces between the atoms, Democritus argued. If there were no such empty spaces, no void, the knife would encounter the impenetrable atoms, and the apple could not be cut. Having cut a slice from a cone, say, let us compare the cross sections of the two pieces. Are the exposed areas equal? No, said Democritus. The slope of the cone forces one side of the slice to have a slightly smaller cross section than the other. If the two areas were exactly equal, we would have a cylinder, not a cone. No matter how sharp the knife, the two pieces have unequal cross sections. Why? Because, on the scale of the very small, matter exhibits some irreducible roughness. This f fine scale of roughness Democritus identified with the world of atoms. His arguments were not those we use today, but they were subtle and elegant, derived from everyday life. And his conclusions were fundamentally correct.

A pumpkin. Illustration by Elena

Pythagoras and Pythagoreans

Pythagoras and Pythagoreans

Pythagoras


The great scientists from Thales to Democritus and Anaxagoras have usually been described in history of philosophy books as “Prescoratics”, as if their main function was to hold the philosophical fort until the advent of Socrates, Plato, and Aristotle and perhaps influence them a little. Instead, the old Ionians represent a different and largely contradictory tradition, one in much better accord with modern science. That their influence was felt powerfully for only two or three centuries in as irreparable loss for all those human beings who lived between the Ionian Awakening and the Italian Renaissance.

Perhaps the most influential person ever associated with Samos was Pythagoras, a contemporary of Polycrates in the sixth century B.C. In fact, the sixth century B.C. was a time of remarkable intellectual and spiritual ferment across the planet. Not only was it the time of Thales, Anaximander, Pythagoras and others in Ionia, but also the time of the Egyptian Pharaoh Necho who caused Africa to be circumnavigated, of Zoroaster in Persia, Confucius and Lao-tse in China, the Jewish prophets in Israel, Egypt and Babylon, and Gautama Buddha in India. It is hard to think these activities altogether unrelated.

According to local tradition, Pythagoras lived for a time in a cave on the Samian Mount Kerkis, and was the first person in the history of the world to deduce that the Earth is a sphere. Perhaps he argued by analogy with the Moon or the Sun, or noticed the curve shadow of the Earth on the Moon during a lunar eclipse, or recognized that when ships live Samos and reside over the horizon, their masts disappear last.

Pythagoras world. Photo by Elena

He or his disciples discovered the Pythagorean theorem : the sum of the squares or the shorter sides of a right triangle equals the square of the longer side. Pythagoras did not simply enumerate examples of this theorem; he developed a method of mathematical deduction to prove the thing generally.

The modern tradition of mathematical argument, essential to all of science, owes much to Pythagoras. It was he who first used the word Cosmos to denote a well ordered and harmonious universe, a world amenable to human understanding.

Many Ionians believed the underlying harmony of the universe to be accessible through observation and experiment, the method that dominates science today. However, Pythagoras employed a very different method. He taught that the Laws of Nature could be deduced by pure thought. He and his followers were not fundamentally experimentalists. They were mathematicians. And they were thoroughgoing mystics.

Could the Laws of Nature be deduced by pure thought? I doubt it, but who knows (Quotations from Megan Jorgensen). Image: © Elena

Pythagoreans


According to Bertrand Russell, in a perhaps uncharitable passage, Pythagoras “founded a religion, of which the main tenets were the transmigration of souls and the sinfulness of eating beans. His religion was embodied in a religious order, which, here and there, acquired control os the State and established the rule of the saints. But the unregenerate hankered after beans, and sooner or later rebelled.

Although there were a few welcome exceptions. The Pythagoras fascination with whole-number ratios in musical harmonies seems clearly to be based on observation, or even experiment on the sounds issued from plucked strings. Empedocles was, at least in part, a Pythagorean. One of Pythagoras’ students, Alcmaeon, is the first person known to have dissected a human body ; he distinguished between arteries and veins, was the first to discover the optic nerve and the Eustachian tubes, and identified the brain as the seat of the intellect (a contention later denied by Aristotle, who placed intelligence in the heart, and then revived by Herophilus of Chalcedon). He also founded the science of embryology. But Alcmaeon’s zest for the impure was not shared by most of his Pythagorean colleagues in later times.

Pythagoreans. Photo by Elena

The Pythagoreans delighted in the certainty of mathematical demonstration, the sense of a pure and usullied world accessible to the human intellect, a Cosmos in which the sides of right triangles perfectly obey simple mathematical relationships. It was in striking contrast to the messy reality of the workaday world. They believed that in their mathematics they had glimpsed a perfect reality, a realm of the gods, of which our familiar world is but an imperfect reflection. In Plato’s famous parable of the cave, prisoners were imagined tied in such a way that they saw only the shadows of passerby and believed the shadows to be real – never guessing the complex reality that was accessible if they would but turn their heads. The Pythagoreans would powerfully influence Plato and, later, Christianity.

They did not advocate the free confrontation of conflicting points of view. Instead, like all orthodox religions, they practiced a rigidity that prevented them from correcting their errors. Cicero wrote:

In discussion it is not so much weight of authority as force of argument that should be demanded. Indeed, the authority of those who profess to teach is often a positive hindrance to those who desire to learn; they cease to employ their own judgement, and take what they perceive to be the verdict of their chosen master as settling the question. In fact I am not disposed to approve the practice traditionally ascribed to the Pythagorians, who, when questioned as to the ground of any assertion that they advanced in debate, are said to have been accustomed to reply “The Master said so,” “the Master” being Pythagoras. So potent was an opinion already decided, making authority prevail unsupported by reason.

Authority must not prevail unsupported by reason, but is always does. (Quotations from Megan Jorgensen). Image: © Elena

Kepler and Pythagoreans


The pros and cons of the Pythagorean tradition can be seen clearly in the life’s work of Johannes Kepler. The Pythagorean idea of a perfect and mystical world, unseen by the senses, was readily accepted by the early Christians and was an integral component of Kepler’s early training. On the one hand, Kepler was convinced that mathematical harmonies exist in nature (he wrote that “the universe was stamped with the adornment of harmonic proportions”); that simple numerical relationships must determine the motion of the planets.

On the other hand, again following the Pythagoreans, he long believed that only uniform circular motion was admissible. He repeatedly found that the observed planetary motions could not be explained in this way, and repeatedly tried again. But unlike many Pythagoreans, he believed in observation and experiment in the real world. Eventually the detailed observations of the apparent motion of the planets forced him to abandon the idea of circular paths and to realise that the planets travel in ellipses. Kepler was both inspired in the search for the harmony of planetary motion and delayed for more than a decade by the attractions of Pythagorean doctrine.

Kepler's World. Photo by Elena

A disdain for the practical swept the ancient world. Plato urged astronomers to think about the heavens, but not to waste their time observing them. Aristotle believed that: “The lower sort are by nature slaves, and it is better for them as for all inferiors that they should be under the rule of a master… The slave shares in his master’s life; the artisan is less closely connected with him, and only attains excellence in proportion as he becomes a slave. The meaner sort of mechanic has a special and separate slavery.” Plutarch wrote “It does not of necessity follow that, if the work delight you with its grace, the one who wrought it is worthy of esteem”.

Xenophon’s opinion was: “What are called the mechanical arts carry a social stigma and are rightly dishonoured in our cities”. As a result of such attitudes, the brilliant and promising Ionian experimental method was largely abandoned for two thousand years. Without experiment, there is no way to choose among contending hypothesis, no way for science to advance. The antiempirical taint of the Pythagoreans survives to this day. But why? Where did this distaste for experiment come from?

Where does the distaste for experiment come from? Image: Blue Mosaic © Elena

Divine Mathematics


The Pythagoreans were fascinated by the regular solids, symmetrical three-dimensional objects all of whose sides are the same regular polygon. The cube is the simplest example, having six squares as sides. There are an infinite number of regular polygons, but only five regular solids. (The proof of this statement, a famous example of mathematical reasoning, exists). For some reason, knowledge of a solid called the dodecahedron having twelve pentagons as sides seemed to them dangerous. It was mystically associated with the Cosmos.

The other four regular solid must then, they thought, correspond to some fifth element that could only be the substance of the heavenly bodies (This notion of a fifth essence is the origin of our word quintessence). Ordinary people were to be kept ignorant of the dodecahedron.

In love with whole numbers, the Pythagoreans believed all things could be derived from them, certainly all other numbers. A crisis in doctrine arose when they discovered that the square root of two (the ratio of the diagonal to the side of a square) was irrational, that V2 cannot be expressed accurately as the ratio of any two whole numbers, no matter how big these numbers are. Ironically this discovery was made with the Pythagorean theorem as a tool. “Irrational” originally meant only that a number could not be expressed as a ratio. But for the Pythagoreans it came to mean something threatening, a hint that their world view might not make sense, which is today the other meaning of “irrational”. Instead of sharing these important mathematical discoveries, the Pythagoreans suppressed the knowledge of V2 and the dodecahedron. The outside world was not to know.

The sacred knowledge is to be kept within the cult, unsullied by public understanding. Image: © Megan Jorgensen (Elena)

(In fact, a Pythagorean named Hippasus published the secret of the “sphere with twelve pentagons”, the dodecahedron. When he later died in a shipwreck, we are told, his fellow Pythagoreans remarked on the justice of the punishment. His book has not survived).

Even today there are scientists opposed to the popularisation of science: the sacred knowledge is to be kept within the cult, unsullied by public understanding.

The Pythagoreans believed the sphere to be “perfect”, all point on its surface being at the same distance from the center. Circles were also perfect. And the Pythagoreans insisted that planets moved in circular paths at constant speeds. They seemed to believe that moving slower or faster at different places in the orbit would be unseemly; noncircular motion was somehow flawed, unsuitable for the planets, which, being free of the Earth, were also deemed “perfect”.

Apple Lets Bitcoin Back Onto the iPhone

Apple Lets Bitcoin Back Onto the iPhone


Bitcoin believers should be happy as Apple has announced that the company was developing a new mobile payment system that could come out as soon as possible.

Apple approves now bitcoin wallet apps as it permits bitcoin wallets in its App Store. Before then, it had been a rocky ride for folks who wanted to receive and send bitcoins on their iPhones as in the past Apple dropped popular wallet apps such as Blockchain and Coinbase from the App Store, without even explaining the reasons.

CoinPocket is the first approved app which allows users to sell and buy bitcoins on their iPhone. It was built by Michael Enriquez, an independent software developer from Cleveland, who calls his app a bit of a “resume-builder.”

In spring 2014, Michael Enriquez wrote a Web-based version of CoinPocket that could operate with bitcoins on the iPhone. As soon as Apple announced that it would be OK with virtual currencies, the young developer decided to build a full-fledged iOS app, and he submitted CoinPocket for approval, getting the jump on much more popular wallet software. Ten days after Enriquez’s application the app was approved. It usually takes a few hours to get accepted after going into “in Review”, but this time it took a few days, so Apple seems to scrutinize more carefully Bitcoin matters. Enriquez had more than 2,000 downloads just in two first days, which is apparently a good sign for Bitcoin and IPhone enthusiasts.

Bitcoin, is it solide as an ancient column? Photo by Elena

Bitcoin adepts with iPhones will tell you that Apple blocked Bitcoin apps that allow users to send and receive Bitcoin in the pas (but for some odd reason, a wallet app from Blockchain managed to avoid getting bumped for years. With  Blockchain, you could scan QR codes and easily send and receive Bitcoin via mobile. They say that members of the Bitcoin community would tell people to use the app but to keep quiet about it. But  finally Apple kicked Blockchain with little explanation from Apple (removed from the App Store due to an unresolved issue). The situation has changed for the better for both IPhone and Bitcoin followers. Sell iPhone and sell bitcoins is since now just the same.

Naked Singularity

Naked Singularity


The humans had – from the beginning, from before humans ever entered space – sent animals up there. Amoebas, fruit flies, rats, dogs, and apes had become hardy space veterans. As spaceflights of longer and longer duration became possible, something unexpected was found. It had no effect on microorganisms and little effect on fruit flies. But for mammals, it seemed, zero gravity extended the lifespan. By 10 or 20 percent. If you lived in zero g, your body would spend less energy fighting the force of gravity, your cells would oxidize more slowly, and you would live longer. There were some physicians who claimed that the effects would be much more pronounced on humans than on rats. There was the faintest aroma of immortality in the air.

Naked Singularity. Photo by Elena

The rate of new cancers was down 80 percent for the orbital animals compared with a control group on the Earth. Leukemia and lymphatic carcinomas were down 90 percent. There was even some evidence, perhaps not yet statistically significant, that the spontaneous remission rate fore neoplastic diseases was much greater in zero gravity. The German chemist Otto Warburg had, half a century before, proposed that oxidation was the cause of many cancers. The lower cellular oxygen consumption in the weightless condition suddenly seemed very attractive. People who in earlier decades would have made a pilgrimage to Mexico for laetrile now clamored for a ticket into space. But the price was exorbitant. Whether preventive or clinical medicine, spaceflight was for the few.

Certain stars rise just before or set just after the Sun – and at times and positions that vary with the seasons. If you made careful observations of the stars and recorded them over many years, you could predict the seasons. You could also measure the time of year by noting where on the horizon the Sun rose each day. In the skies was a great calendar, available to anyone with dedication and ability and the means to keep records.

General Hospital Atrium. Faintest aroma of immortality is present in the air. Image by © Elena

Artificial Selection

Artificial Selection


Humans have deliberately selected which plants and animals shall live and which shall die for thousands of years. We are surrounded from babyhood by familiar farm and domestic animals, fruits and trees and vegetables. Where do they come from? Were they once free-living in the wild and then induced to adopt a less strenuous life on the farm? Non, the truth is quite different. They are, most of them, made by us.

Ten thousand years ago, there were no dairy cows of ferret hounds or large ears of corn. When we domesticated the ancestors of these plants and animals – sometimes creatures who looed quite different – we controlled their breeding. We made sure that certain varieties, having properties we consider desirable, preferentially reproduced. When we wanted a dog to help us care for sheep, we selected breeds that were intelligent, obedient and had some pre-existing talent to herd, which is useful for animals who hunt in packs.

Artificial Selection. Photo by Elena

The enormous distended udders of dairy cattle are the result of a human interest in milk and cheese. Our corn or maize, has been bred for ten thousand generations to be more tasty and nutritious than its scrawny ancestors; indeed, it is so changed that it cannot even reproduce without human intervention.

The essence of artificial selection – for a Heike crab, a dog, a cow or an ear of corn – is this: Many physical and behavioral traits of plants and animals are inherited. They breed true. Humans, for whatever reason, encourage the reproduction of some varieties and discourage the reproduction of others. The variety selected for preferentially reproduces; it eventually becomes abundant; the variety selected against becomes rare and perhaps extinct.

But if humans can make new varieties of plants and animals, must not nature do so also? This related process is called natural selection. That life has changed fundamentally over the aeons is entirely clear from the alterations we have made in the beasts and vegetable during the short tenure of humans on Earth, and from the fossil evidence. The fossil record speaks to us unambiguously of creatures that once were present in enormous numbers and that have now vanished utterly. Far more species have become extinct in the history of the Earth than exist today; they are the terminated experiments of evolution.

May be, a few gastronomic compromises have to be made, but the dinner must be of surprising elegance. Image: © Elena