I see no reason to link the miskeyed, misread, or made-up transmission with the crash. The only thing connecting them is that they happened within a few minutes of each other, but the crash is simply not missing any explanations requiring an interpretation of STENDEC. Consider it an unsolved little tidbit from history, but one whose significance is almost certainly limited to the interest it holds as a puzzle.
REFERENCES & FURTHER READING
Dinkins, R. & J. “CW Operating Aids.” AC6V’s Amateur Radio & DX Reference Guide. Rod Dinkins & Jeff Dinkins, AC6V, 17 Jan. 2008. Web. 29 Oct. 2010.
Editors. “Lost plane found in Andes.” BBC News. British Broadcasting Corporation, 26 Jan. 2000. Web. 29 Oct. 2010.
NOVA Online. “1947 Official Accident Report.” Vanished! Teacher’s Guide and Resources. WGBH Science Unit, 30 Jan. 2001. Web. 28 Oct. 2010.
Rayner, J. Star Dust Falling: The Story of the Plane that Vanished. New York: Doubleday, 2002.
Ruffin, S. Aviation’s Most Wanted: The Top 10 Book of Winged Wonders, Lucky Landings. Herndon: Brassey’s, 2005. 26.
Taylor, M. Jane’s Encyclopedia of Aviation, Volume 2. New York: Crescent Books, 1980. 257.
43. THE SOUTH ATLANTIC ANOMALY
Was this mysterious region in the south Atlantic responsible for the crash of Air France flight 447?
You’ve heard of the Bermuda Triangle, you may have even heard of its Pacific counterpart the Devil’s Sear near Japan. But did you know about the South Atlantic Anomaly? It’s a region over South America and the south Atlantic Ocean centered at about 30 degrees West and 30 degrees South, and it’s big, a little larger than the entire United States. Some say it’s a danger to anything entering it, and they point most specifically to the crash of Air France flight 447 in June of 2009, in which 228 people died. Whereas the Bermuda Triangle and the Devil’s Sea are merely lines drawn on a map, the South Atlantic Anomaly is a measurable physical presence. Today, Skeptoid takes a look at what it is, what kind of danger it presents, and whether it really brought down Flight 447.
To understand the South Atlantic Anomaly, let’s start by taking a quick look at the Earth’s magnetic fields and the Van Allen radiation belts.
We all know that the Earth’s magnetic axis is not the same as its rotational axis. As the Earth’s molten, ferromagnetic liquid core churns, it generates a magnetic field, and the north-south axis of this field is tilted about 16° from the rotational axis. The north magnetic pole is in the north Canadian islands, but it moves around a lot, and it’s currently headed northwest at about 64 km per year.
Here’s the part that many people don’t know. While the north magnetic pole is about 7° from the north rotational pole, the south magnetic pole is about 25° from the south rotational pole. A line drawn from the north magnetic pole to the south does not pass through the center of the Earth. Our magnetic field is torus shaped, like a giant donut around the earth. But it’s not only tilted, it’s also pulled to one side, such that one inner surface of the donut is more squished up against the side of the earth than the other. It’s this offset that causes the South Atlantic Anomaly to be at just one spot on the Earth.
The anomaly itself consists of radiation. It is, in fact, the inner Van Allen radiation belt. If you picture the Earth as a circle enclosed within double parentheses, then bent those parentheses sharply toward it, you can visualize the shape of the Van Allen belt. The inner belt is shaped about like the letter C, while the outer belt is longer and almost completely encloses the inner belt and bends in sharply toward the magnetic poles. Since this whole field is tilted and offset to one side from the Earth, there’s one point where the inner Van Allen belt almost touches the surface. This is exactly what the South Atlantic Anomaly is.
The belts are shaped by the solar wind, and as the Earth spins within them, the offset causes the whole system to wobble and everything is always in motion. This constant stirring is one reason the Northern Lights aren’t static; they dance around. Correspondingly, the South Atlantic Anomaly observes a daily cycle, growing and shrinking and changing intensity, strongest at solar noon each day and weakest around solar midnight. One result of the solar wind hitting the magnetic field is the creation of a cavity within the field called a Chap-man-Ferraro Cavity, and charged particles are trapped and collect within this cavity. These trapped particles are what the inner and outer Van Allen belts physically consist of.
The inner Van Allen belt, where it comes closest to Earth at the South Atlantic Anomaly, is a cloud of energetic protons. Their energies range from about 100 keV (100,000 electron volts), which is enough to penetrate half a millimeter of lead, all the way up to about 400 MeV (400,000,000 electron volts), enough to penetrate 143 mm of lead. You would not want to stay there very long. In fact this is one of the arguments made by the conspiracy theorists who say we never went to the Moon. But the irregular shape of the Van Allen belts relative to the Earth provided part of the solution for the Apollo astronauts, in the form of a gap large enough to squeak through with only minimal exposure. The rest of the solution lay in Apollo’s speed, and the astronauts cleared the belts in only one hour.
Many satellites are not so lucky though, and have to pass through the South Atlantic Anomaly frequently. Some 200 satellites currently have to deal with this. Many, like the Hubble Space Telescope, turn off certain sensitive sensors whenever they pass through. Electronics on such craft that are vulnerable must be shielded. The International Space Station also has this problem, but since it completes an entire orbit every 90 minutes, its exposure time is very brief. Also only a few of its orbits pass through the Anomaly. The total radiation exposure received by space station residents is within safe levels, though they’ve reported odd things like computers crashing when they pass through the Anomaly. Scary stuff.
We know that the South Atlantic Anomaly is hazardous to electronic equipment and to humans who spend time inside it. We know that it dips down close to the Earth. So if we add these together, it suddenly sounds plausible that Flight 447 might have been taken down by it. Right?
Well, all by itself, wrong. Although the Anomaly is a dangerous place, its edges are pretty well defined. The closest it ever gets to the Earth’s surface is about 200 km, and at that height it’s very small. The highest commercial aircraft might ever get is about 15 km, and usually lower. Flight 447 was absolutely not, no way, impossible, not in the South Atlantic Anomaly, either when it crashed, or at any other time. The Anomaly is in space, it is not in the atmosphere; and you’re completely safe if you’re below it and not in it. Your computers will not crash, your electronics will not fry, and you will not be baked by radiation. You’ll never even know it’s up there.
Consider also that half of South America, including nearly all of Brazil, is directly underneath the South Atlantic Anomaly. Aircraft fly safely throughout South America all day every day. Computers, hospitals, and data centers operate here trouble free year round. There is simply no evidence, nor any plausible hypothetical argument, to suspect that the relative nearness of the Van Allen belts posed any danger at all to Flight 447.
Parts of Air France 447 being recovered
Moreover, Flight 447 had already cleared the area below the Anomaly when it disappeared. Its last reported position was some 1,000 kilometers beyond the Anomaly’s northern reaches. It made it past the Anomaly, and then continued flying safely northeast for nearly two hours before whatever happened happened.
So how do we explain that little detail, the crashed airplane?
The crash was investigated by the BEA, France’s version of the American NTSB, the Bureau of Investigations and Analysis for the Safety of Civil Aviation. The aircraft’s flight data recorders were recovered in 2011. At about the same time that it disappeared from radar, the plane’s systems send a burst of automated error messages to Airbus for maintenance purposes. These messages were al
most all about inconsistencies between the three pitot probes that measure airspeed, almost certainly indicating that they were icing up. The plane was flying through storm clouds, though not a strong storm and not one to normally be concerned about, but evidently it was enough to ice up the airspeed sensors. In fact, a number of such automated error messages from other planes had prompted Air France to update the pitot probes on its Airbus 330s and 340s, and the replacement probes for this particular aircraft had been received by Air France six days before the crash, and were due to be installed.
The aircraft then stalled at 38,000 feet, and plunged to the ocean in only three and a half minutes.
Analysis of the debris and the bodies showed that the plane was in cruise mode and that no preparations for a crash had been made. It bellyflopped flat on the water, hard enough to kill the victims and destroy the aircraft. The BEA has determined that insufficient information exists to determine the exact cause of the crash, and they are in fact making plans to again try to recover the flight data recorders.
A number of independent researchers have not given up on trying to pin the blame for the crash on solar radiation. On May 31, earlier in the day, Sunspot 1019 appeared. The principal danger of sunspots is a wave of ejected high-energy protons, which start arriving at Earth about 15 minutes after a solar flare event and continue for many hours. Could a burst of solar radiation from Sunspot 1019 have knocked down Flight 447?
It is, absolutely, a possibility. But it’s not as strong a candidate as it may initially seem. According to NOAA’s space weather report for the period, Sunspot 1019 produced no flares on May 31, and no proton events at all were observed. Flux was reported to be at normal levels, and geomagnetic activity was described as quiet.
This reduces the possibility that solar or cosmic radiation caused the crash to pure speculation. It’s improbable that a rogue particle or two would have caused a system error as specific as multiple inconsistencies reported by the airspeed sensors, especially given that icing from the storm cloud was a far more probable culprit. How this translated into the subsequent systemwide failures and crash is still unknown, but there’s no evidence at this point that any external causes were at fault.
Perhaps a future recovery of the flight data recorders will shed additional light, but for now, there don’t seem to be any questions about Flight 447 that can only be answered by the South Atlantic Anomaly. It’s there, and it’s real, and it does pose problems for spacecraft and astronauts passing through it, but all the information we have now indicates there’s no reason for people on the ground or in the air beneath it to be concerned.
REFERENCES & FURTHER READING
Bailey, J. Biomedical Results of Apollo. Washington, DC: Scientific and Technical Information Office, National Aeronautics and Space Administration, 1975. Chapter 3.
BEA. Update on the Investigation into the Accident to flight AF 447 on 1st June 2009. Paris: Bureau d’Enquêtes et d’Analyses, 2009.
Goldhammer, L. Proton spectrum characteristics of the 7 July 1966 solar-flare. Pocatello: Idaho State University, 1967.
Hope, F. “Did a solar flare knock Air France 447 out of the sky?” Future News Today. Frank Hope, 21 Jun. 2009. Web. 15 Nov. 2010.
IPS Radio & Space Services. “The Most Powerful Solar Flares Ever Recorded.” SpaceWeather.com. Dr. Tony Phillips, 20 Apr. 2001. Web. 14 Nov. 2010.
NOAA. “Preliminary Report and Forecast of Solar Geophysical Data.” Space Weather Prediction Center. 2 Jun. 2009, Number 1761: 1.
Walt, M. Introduction to Geomagnetically Trapped Radiation. New York: Cambridge University Press, 1994.
44. IQ TESTING
How valid are IQ tests, what do they really measure, and where do you fit in?
Don’t you just love the idea that your level of intelligence can be boiled down to a single number, and ranked along with those of all the other dummies in the world? You may have taken an IQ test in the past, and may even know your score. It’s an unfortunate fact of statistics that half the people walking around are below average intelligence — the way the tests are scored assures that 100 is both the median and the average — and sometimes we question the value of force-ranking ourselves, and assigning so much cultural significance and stigma to it, based on one narrow metric. IQ tests look like the ideal place to point Skeptoid’s skeptical eye.
There are a number of obvious apparent criticisms of the idea of ranking everyone with a single number that purports to encompass how intelligent they are. Some people are “book smart” but with no “common sense”, and some are the opposite. Some people have high or low creativity or humor, but may ace all their tests in school or fail them. Each of us is complex, with many strengths and weaknesses, aptitudes and preferences, and it seems that any one number purporting to quantify our intelligence must be grossly misleading in every case.
There are even obvious criticisms of the tests themselves. There are a number of different IQ tests in use, and it’s well established that the same people will score differently on the various tests: I might get a higher score than you on one test, while you outscore me on another. Critics often point out that any IQ test is necessarily skewed toward a particular cultural frame of reference, making it unfair to measure someone from Africa using a test developed in Denmark (for example).
These basic criticisms are answered by a closer study of what IQ tests actually purport to measure. They’ve got nothing to do with “book smarts” and are intended to have no cultural relevance. The tests measure only your intelligence. There are as many different definitions of intelligence as there are psychologists, but we can extract some common themes from the definitions offered by those who have played the biggest roles in developing these tests. Generally speaking, your intelligence is your problem solving and reasoning ability. It encompasses learning, planning, and understanding.
IQ testing has an ominous history. It originally grew out of the eugenics movement in the United States around the turn of the twentieth century. The basic idea of eugenics was to identify desirable traits, such as intelligence, health, and even financial success, and to increase birth rates among such people. At the same time, birth rates among people with negative traits such as lower intelligence, criminal behavior, poverty, and illness, would be discouraged. When it was discovered that heredity played a large role in some mental illnesses, forced sterilization was imposed upon mental patients in some states in an effort to breed such traits out of the population. According to most counts, some 64,000 mentally ill Americans were sterilized until the practice was finally terminated in the 1960s. In the Nuremberg Trials, it was revealed that the Nazis considered the American program so effective that it was the inspiration for the Nazis’ forced sterilization of some 450,000 people.
The father of eugenics was the Englishman Sir Francis Galton, a cousin of Charles Darwin. Over the course of Galton’s varied and productive career, he not only codified the science of eugenics but also pioneered psychometry as a tool for measuring people’s intelligence and determining whether it would be best for them to breed or not. Galton coined the phrase nature versus nurture and identified the trend of regression towards the mean, though his original term for this was reversion towards mediocrity. So long as unintelligent people were allowed to reproduce freely, mankind could never rise above its native mediocrity.
A tool for quantitatively identifying mental retardation was needed by American eugenicists, and so they turned to two French researchers, Alfred Binet and Théodore Simon, who had developed the Binet-Simon test as a way of identifying French schoolchildren who needed special assistance. Binet-Simon did not ask questions about general knowledge, instead it imposed a diverse system of tasks, from simple physical tests to memory puzzles. The resulting score was expressed as the mental age.
Lewis Ternan, a psychologist from Stanford University, translated a
nd improved the test in 1910, and it became known as the Stanford-Binet. The result was your Intelligence Quotient, a quotient of your mental age divided by your chronological age. If you were 10 years old but had the reasoning ability of a 15-year-old, your IQ was 150. For the first time, eugenicists had a tool that could spell out, in black and white, a person’s value to society.
World War I saw widespread adoption of intelligence testing by the United States Army. The intent was that the most intelligent recruits would be sent to officer training, the least intelligent would be rejected from service, and those in the middle assigned to technical, combat, or other duties according to their scores. But the process didn’t go as smoothly as its proponents hoped. Different testing methodologies were tried, there were inadequate resources for testing such large numbers of men, and many of the results were controversial.
What arose from this was a thorough revision of the scoring, developed by David Wechsler, the chief psychologist at Bellevue Psychiatric Hospital. As a young man he’d worked with the Army during its troubled attempt at implementing intelligence testing. His innovation was to grade the tests on a curve, with your score representing your placement within the distribution of all the aggregated scores. This is now the universal standard. The scoring is designed in such a way that graphing all the scores of a given population will result in a perfect bell curve. The intent is for the peak of the curve to hit exactly at a score of 100 (which should represent about 2.7% of the population), with the long tails of the curve petering out at about 50 and 150. For those of a statistical mindset, the distribution is intended to have a standard deviation of 15. Whenever the tests are revised (we’re now using Stanford-Binet 5), the scoring system is reset so that the average is again 100 and the standard deviation is again 15. We still call it the IQ, even though it’s no longer a quotient.
Skeptoid 4: Astronauts, Aliens, and Ape-Men Page 28