Scientists's; mistake uncovers 'impossible material': - USA TODAY

Sometimes screwing up a science experiment isn't such a bad thing. Case in point: Researchers in Sweden accidentally left their equipment running on an experiment over a weekend, and ended up creating something awesome — Upsalite, the world's most efficient water absorber, reports The Independent.

This substance, prohibitively expensive and difficult to produce until now, can potentially do everything from controlling moisture on a hockey rink to cleaning up toxic waste and oil spills, reports Science Blog.

This "is expected to pave the way for new sustainable products in a number of industrial applications," says nanotechnology professor Maria Stromme.

NEWSER: Female frog favors mates who multitask

Scientists have been trying — and failing — to cheaply create a dry, powdered form of magnesium carbonate since the early 1900s, earning it the nickname the "impossible material."

Turns out, all they needed to do was use the same process they've been attempting for more than 100 years, but at three times the atmospheric pressure.

When the scientists at the University of Uppsala inadvertently did this, they returned to the lab Monday morning to find a gel had formed.

When heated to more than 158 degrees, that gel "solidifies and collapses into a white and coarse powder," they report, per Phys.org. "It became clear that we had indeed synthesized the material that previously had been claimed impossible to make," Stromme says.

Find more amazing discoveries at Newser, a USA TODAY content partner providing general news, commentary and coverage from around the Web. Its content is produced independently of USA TODAY.

View the original article here

Happy Birthday, Buzz Aldrin! Apollo 11 Moonwalker Is 83 Today

Famed space man Buzz Aldrin, the second person ever to walk on the moon, is celebrating his 83rd birthday today (Jan. 20) in cosmic style.

Aldrin, who along with Apollo 11 astronaut Neil Armstrong boldly walked where no one had before in 1969, is marking his birthday on the road with a trip to England.

"I'm heading home today if the UK weather allows," Aldrin wrote in a post on Twitter today, where he writes as @TheRealBuzz.

This month, Aldrin helped launch the AXE Space Academy, a private spaceflight competition that aims to launch 22 people on suborbital spaceflights as part a deal with the space tourism company Space Expedition Curacao and XCOR Aerospace, which is building the Lynx space plane  to be used on the flights.

"Space travel for everyone is the next frontier in the human experience," Aldrin said during the project's launch this month.

But Buzz Aldrin is likely most well-known for his role on NASA's Apollo 11 mission, which made the first manned moon landing on July 20, 1969, when and Armstrong landed on the moon and performed the first moonwalk. Aldrin served as lunar module pilot for the Apollo 11 mission, with Armstrong commanded the mission. Astronaut Michael Collins, meanwhile, served as command module pilot and remained in orbit around the moon during the landing. Armstrong died at age 82 last year.

Aldrin is a retired colonel in the U.S. Air Force and flew combat missions in Korea before joining NASA's astronaut corps in 1963 as one of the space agency's third group of astronauts. He was born Edwin Aldrin ("Buzz" was originally a nickname) in Montclair, N.J., and earned a Ph.D. in astronautics from the Massachusetts Institute of Technology. [Photos of Buzz Aldrin at NASA]

Aldrin's fist space mission, Gemini 12, launched on Nov. 11, 1966, sending him and astronaut James Lovell on a four-day mission to test spacewalk methods, among other goals. It was the final mission of NASA's Gemini program, allowing the space agency to proceed with the Apollo missions that ultimately sent Aldrin to the moon.

Aldrin, Armstrong and Collins launched their Apollo 11 mission on July 16, 1969. Aldrin and Armstrong spent two hours and 15 minutes walking on the lunar surface during their time on the moon. The Apollo 11 crew returned to Earth on July 24, 1969. Five more successful moon landing missions would follow.

Aldrin left NASA in 1971 and retired from the Air Force a year later. Altogether, he logged 289 hours and 53 minutes in space.

Since then, Aldrin has used his moonwalker fame to lobby for continued space exploration, specifically a return to the moon and missions to Mars. He has written several books, including two autobiographies, and made several notable television appearances, with stints on "Dancing with the Stars," "Top Chef," "The Colbert Report" and "Big Bang Theory."

Earlier this year, Aldrin settled his divorce from his wife Lois Driggs Cannon after 23 years of marriage, citing "irreconcilable differences."

You can follow SPACE.com Managing Editor Tariq Malik on Twitter @tariqjmalik. Follow SPACE.com for the latest in space science and exploration news on Twitter @Spacedotcom and on Facebook.

Copyright 2013 SPACE.com, a TechMediaNetwork company. All rights reserved. This material may not be published, broadcast, rewritten or redistributed.

View the original article here

Leap Second Science: NASA Explains Earth's Longer Day Today

Today will be one second longer than usual, and we have the moon to thank for the extra time.

A "leap second" will be added to the world's official clocks this evening (June 30), to account for the fact that Earth's rotation is slowing ever so slightly — meaning our days are getting longer, at the rate of about 1.4 milliseconds every 100 years.

"At the time of the dinosaurs, Earth completed one rotation in about 23 hours," Daniel MacMillan, of NASA’s Goddard Space Flight Center in Greenbelt, Md., said in a statement. "In the year 1820, a rotation took exactly 24 hours, or 86,400 standard seconds. Since 1820, the mean solar day has increased by about 2.5 milliseconds."

It's happening because of tidal forces between the Earth and moon. This mutual gravitational jostling results in the transfer of our planet's rotational momentum to the moon, pushing it away from us at about 1.6 inches (4 centimeters) per year.

Earth's rotational slowdown won't stop until it becomes tidally locked to the moon, researchers say — meaning we will always show the same face to our celestial neighbor. The moon is tidally locked to Earth now, keeping its far side forever out of sight. [Hit Snooze: 10 Best Alarm Clocks]

Scientists figured out the planet's lagging rotation rate using a technique called Very Long Baseline Interferometry. VLBI measures how long it takes radio waves emitted by faraway active black holes called quasars — the brightest objects in the universe — to reach a network of telescopes set up around the world.

From the tiny differences in arrival times to these various instruments, researchers can calculate Earth's rotational speed and a number of other interesting characteristics about our planet and its path through space.

Decades ago, scientists realized that some measurements and technologies required more precise timekeeping than Earth's rotation could provide. So in 1967, they officially changed the definition of a second, basing it on measurements of electromagnetic transitions in cesium atoms rather than the length of a day.

Such "atomic clocks" are accurate to approximately one second in 200 million years, researchers say. The widely used time standard based on the cesium atom is called Coordinated Universal Time, or UTC.

Timekeepers add leap seconds to UTC every once in a while to square it up with another time standard that's based on Earth's day length. So June 30 will get an extra second just before 8 p.m. EDT (midnight GMT on July 1).

The master clock at the U.S. Naval Observatory will move to 7:59:60 p.m. EDT, or 23:59:60 UTC, before ticking over. In practice, this means that clocks in many systems will be turned off for one second, NASA researchers said.

Saturday's adjustment will mark the 25th time a leap second has been added since the practice was initiated in 1972. The most recent leap second was inserted on New Year's Eve of 2008.

Follow SPACE.com on Twitter @Spacedotcom. We're also on Facebook and Google+.

Copyright 2012 SPACE.com, a TechMediaNetwork company. All rights reserved. This material may not be published, broadcast, rewritten or redistributed.

View the original article here

NASA Hopes to Launch Delayed Moon Gravity-Mapping Probes Today (SPACE.com)

After two days of delay caused by bad weather and a technical glitch, NASA is once again ready to launch two probes toward the moon to unlock the secrets of lunar gravity.

The twin Grail spacecraft are expected to launch from Florida's Cape Canaveral Air Force Station today (Sept. 10) at 8:29 a.m. EDT (1229 GMT), with a second opportunity available at 9:08 a.m. EDT (1308 GMT), if needed, NASA officials said.

The $496 million moon probes were initially slated to launch atop their unmanned Delta 2 rocket on Thursday (Sept. 8), but unacceptable high-altitude winds forced NASA to delay the liftoff.

Another chance on Friday was called off to give engineers time to assess the rocket's propulsion system after a potential glitch was detected.After a series of reviews, the team concluded that there are no issues with the rocket or its propulsion system, NASA officials said. [Photos of NASA's Grail Moon Gravity Mission]

Today's weather forecast is more optimistic, and current predictions show a 60 percent chance of acceptable conditions at the time of launch, agency officials said.

NASA has specific limits for acceptable launch weather conditions, with high winds, rain, thunder and lightning all present potential safety risks. For example, high upper level winds can affect the way rockets fly through Earth's upper atmosphere as they blast into orbit. 

The agency will closely monitor weather conditions overnight in preparation for tomorrow's attempt. The Grail mission (whose name is short for Gravity Recovery and Interior Laboratory) has a 42-day launch window that extends through Oct. 19, officials have said. [Video: Grail's Mission to Map Moon Gravity]

The twin Grail spacecraft, called Grail-A and Grail-B, will closely examine the composition of the lunar interior, and will make detailed and precise maps of the moon's gravitational field. The three-month mission is expected to help scientists solve mysteries of the moon's origin and its evolution since the natural satellite was formed 4.6 billion years ago.

Researchers are also hoping to use Grail's observations to better understand how other large, rocky bodies in the inner solar system were formed.

You can follow SPACE.com staff writer Denise Chow on Twitter @denisechow. Follow SPACE.com for the latest in space science and exploration news on Twitter @Spacedotcomand on Facebook.

View the original article here

Solstice Sun Storm May Spark Dazzling Northern Lights Today (SPACE.com)

A wave of sun particles unleashed during a strong solar flare this week is arriving at Earth today (June 24) and could touch off a dazzling northern lights display, NASA officials say.

The solar storm occurred Tuesday, June 21, during Earth's solstice, which marked the first day of summer in the Northern Hemisphere and the start of winter in the Southern Hemisphere.

The storm triggered a powerful explosion on the sun, called a coronal mass ejection, which sent a vast wave of solar particles directly at Earth at a speed of about 1.4 million mph (2.3 million kph). Those particles are now buffeting Earth's magnetic field in interactions that could amplify the planet's polar auroras, also known as the northern and southern lights.

"High-latitude sky watchers should be alert for auroras," officials with NASA's Goddard Space Center said in an update today. [Auroras Dazzle Northern Observers]

Supercharged auroras

Auroras occur when solar wind particles collide with atoms of oxygen and nitrogen in Earth's upper atmosphere. The interaction excites the atoms, which then emit light (the aurora) as they return to their normal energy level. [Video: Fantastic Aurora at Earth's Poles]

Tuesday's solar flare registered as a class C7.7 flare (C-class flares are the weakest types of flares), but lasted for several hours. There are three classes of solar flares. M-class solar flares are medium-strength flares, while the most intense solar storms register as X-class flares.

There is a 30 percent to 35 percent chance of a minor geomagnetic storm in Earth's atmosphere today from this week's storm, NASA officials said.

The active sun

This week's solar flare was detected by the space-based Solar and Heliospheric Observatory (SOHO) operated by NASA and the European Space Agency. It came just weeks after another strong solar flare on June 7, which unleashed a massive coronal mass ejection that stunned astronomers with its intensity.

The June 7 event  kicked up a wave of plasma that rained back down on the sun over an area 75 times the width of Earth. The leading edge of the particles that erupted from the sun were traveling at about 3.5 million mph (5.7 million kph), SOHO officials have said.

Another coronal mass ejection on June 14 unleashed an eerie wave of material that formed a partial halo as it expanded into space.

The most severe solar storms, when aimed at Earth, can pose a danger to astronauts in space, satellites and even ground-based communications and power systems. This week's solar flare, however, is not powerful enough to pose a serious risk, NASA officials said.

The sun is currently in an active period of its 11-year solar cycle. NASA and other space and weather agencies are keeping a close watch on the sun using space-based observatories, satellites and ground-based monitoring systems.

You can follow SPACE.com Managing Editor Tariq Malik on Twitter @tariqjmalik. Follow SPACE.com for the latest in space science and exploration news on Twitter @Spacedotcom and on Facebook.

View the original article here

New Space Station Crew to Launch Into Orbit Today (SPACE.com)

Three new crewmembers are set to launch to the International Space Station today (June 7) to begin their months-long mission at the orbiting outpost.

NASA astronaut Mike Fossum, Russian cosmonaut Sergei Volkov, and Satoshi Furukawa of the Japan Aerospace Exploration Agency (JAXA), will ride into orbit today aboard a Russian-built Soyuz spacecraft. The trio is slated to launch at 4:12 p.m. EDT (2012 GMT) from the Baikonour Cosmodrome in Kazakhstan.

"The State Commission approved our ship and crew for launch tomorrow night. Looks like we're going to do this!!" Fossum wrote via Twitter on Monday (June 6).

The three crewmates are launching less than a week after the successful completion of NASA's second-to-last space shuttle mission. The shuttle Endeavour landed at Kennedy Space Center in Florida on June 1 to end the orbiter's final flight before being retired. [Photos: Shuttle Endeavour's Last Landing]

Fossum, Volkov and Furukawa are set to begin their long-term stints aboard the space station, where they will make up the remainder of the station's Expedition 28 crew. The spaceflyers will join NASA astronaut Ron Garan and Russian cosmonauts Alexander Samokutyaev and Andrey Borisenko, who have been living and working at the space station since early April. [Amazing Photos by Astronaut Ron Garan]

The new crewmembers are scheduled to arrive at the space station on Thursday at 5:22 p.m. EDT (2122 GMT). They will be flying on a Russian-built Soyuz TMA-02M spacecraft, the second version of Russia's upgraded digital Soyuz capsule which has also been modified to fix computer console display glitches that popped up during the design's first flight.

Space station science

In September, Garan, Samokutyaev and Borisenko will return to Earth, and Fossum will take command of the station to begin the next Expedition 29 mission.

As part of their stay at the orbiting laboratory, the crewmembers will conduct a variety of experiments in a number of fields, including physical sciences, human life sciences and Earth observation, according to NASA officials.

During Endeavour's STS-134 mission, the visiting shuttle astronauts performed four spacewalks and completed the last major stage of construction for the station's U.S. segment. This will allow NASA and its international partners to focus on the science and research capabilities that the station has to offer, NASA officials have said. [Amazing Spacewalk Photos: Shuttle Endeavour at Space Station]

"Now we’re moving out of that phase as this construction assembly’s complete, and more into the science phase that it was really built to do, so it’s exciting as we’re bringing online all of these, the payloads, the different equipment to begin moving it forward with that research capability," Fossum said in a preflight interview.

Meet the Soyuz crew

Fossum, 53, will be making his third spaceflight, having already logged more than 26 days in space. Fossum was previously a member of NASA's STS-121 and STS-124 missions to the International Space Station, both on the space shuttle Discovery.

Volkov, 38, spent 199 days in space during his first stint at the space station in 2008. He performed two spacewalks and served as commander of the space station's Expedition 17 mission. Volkov is a second-generation cosmonaut and was also the youngest station commander appointed to date.

Furukawa, 47, will be making his first spaceflight today after completing astronaut training in 2006 at NASA's Johnson Space Center in Houston. As a trained surgeon, Furukawa is looking forward to the scientific potential that the space station has to offer. [Video: Venomous Spiders on Space Station]

"Conducting many scientific experiments on board the space station, dedicating the progress of science and making everybody’s life on Earth better than now, that's my first interest," Furukawa said in a preflight interview. "Other than that, I would like to look at the beautiful Earth from some of the windows on board the station, and plus, I would like to take many photographs and share them with all."

In addition to their scientific duties, the Expedition 28 crew will also host the final mission of NASA's space shuttle program, the STS-135 flight of Atlantis, which is scheduled to launch in early July. Atlantis' flight will wrap up the agency's 30-year shuttle program, making way for NASA to focus on developing spacecraft to explore beyond low-Earth orbit.

You can follow SPACE.com Staff Writer Denise Chow on Twitter @denisechow. Follow SPACE.com for the latest in space science and exploration news on Twitter @Spacedotcom and on Facebook.

View the original article here

Ask USA TODAY Weather

Doyle Rice, the USA TODAY weather editor, is available to answer your weather and climate questions. Send your questions to askweather@usatoday.com. If your question is selected, you can look for the answer below. Due to the volume of questions received, not all can be answered, either individually or on this page. ***********************************************

Q: Why is Texas so humid?— D.A. Marquez

A: Eastern Texas and the entire southeastern part of the USA receive plenty of moisture blown in from the nearby Gulf of Mexico, along with evaporated moisture from lakes, rivers, the ground and vegetation. With extensive heating from the spring, summer and fall sun high in the sky at these low latitudes, the evaporation potential is high, and the combination of warm temperatures and high-moisture content makes it really feel muggy.

However, while eastern Texas can be very humid and muggy, much of western Texas is quite dry, thanks to mountain air that dries out as it descends into Texas from Mexico and New Mexico. The dividing line is most pronounced in summer and is known as a dryline, which separates the different air masses.

Our state weather snapshot of Texas has more about the climate of the Lone Star State. — Doyle Rice

******************************************************************************************

Q: My 8-year old son asked me the other day, "At what temperature can you see your breath?" Can you help us? — John Robinette

A: That was a tough one, so I asked for help from an expert at the National Weather Service, meteorologist James Peronto. Here is his answer:

You can see your breath at a variety of temperatures (even as high as 70 degrees). It really depends on how much moisture is in the air (relative humidity). When you exhale, the air has water vapor in it. That exhaled water vapor is at a certain temperature (typically warmer than the surrounding air you are exhaling into). Warmer air can hold more water vapor.

Therefore, as your exhaled air hits the cooler surrounding air, the water vapor condenses into tiny water droplets (the same way clouds form). The higher the relative humidity of the surrounding air you exhale into, the better chance of creating water droplets from your breath.

So, getting back to your original question, the temperature at which you see your breath can really vary, depending upon the relative humidity of the surrounding air. I've seen my own breath at temperatures around 60 degrees in very moist air! Hope this helps. — James Peronto

******************************************************************************************

Q: Can it be too cold too snow?— James Hoffman

A: No, it can snow even at very cold temperatures if there's a source of moisture and some way to lift or cool the air. But when temperatures drop into the single digits or below zero, the air's capacity for water vapor becomes very small, making heavy snow unlikely. Most heavy snowfalls happen with relatively warm air temperatures near the ground — usually 15 degrees or above.

One example of a cold place that doesn't get much snow is Barrow, Alaska, where an average of only two inches of snow falls in January, when the average high temperature is only 2 degrees and the average low is -20 degrees.

A little snow even falls at the South Pole, where the temperature hardly ever rises above zero – the highest ever there is 7 degrees. But, the colder the air, the less moisture it has to make snow, which is why a year's worth of South Pole snow melts down to less than two or three inches of water.

The National Snow and Ice Data Center has an FAQ with much more info about snow. — Doyle Rice

******************************************************************************************

Q: I would like to know the direction of the sunset, when facing the horizon, over several weeks, in the months of September and October. Would the sunset move to the right or to the left on the horizon over 5-day intervals?— Sophia Deno

A: In the Northern Hemisphere, between the summer solstice (roughly June 21) and the winter solstice (roughly Dec. 21), the location at which the sun sets, relative to the observer, moves a fraction toward the left each day. The process reverses between the winter and summer solstices, as the sunset location would move a bit to the right each day.

This USA TODAY resource page and this FAQ page have much more about the seasons, solstices, equinoxes, and the length of days. — Doyle Rice

******************************************************************************************

Q: I often wonder why the sky, which starts-out brilliant clear on October mornings, usually clouds-up around 10 a.m.? I am a photographer and the clouds dull the colors of the foliage. What's even stranger is that folks just 40 miles to the south, at about 1,000 feet lower altitude, say the sky was sunny all day. Any explanation? This has happened quite a few times. Around 3 p.m., suddenly the clouds dissipate but it's too late for me by then. — Myron Shulman

A: First, when the air is unstable, despite a clear start, clouds tend to increase in the late-morning and into the afternoon.

According to the excellent weather textbook A World of Weather: Fundamentals of Meteorology, these clouds are known as fair-weather cumulus clouds, those shorter heaps of puffy clouds that often develop on a tranquil, sunny day as parcels of surface air are heated by the ground and buoyed upward. Sometimes enough clouds form to entirely cover the sky and rain will fall. The clouds will diminish later in the day as the sun's heating fades away.

This blog entry from Nick Borelli at FoxWeather details more about this.

The air's stability is important for our weather, as it helps determine what types of clouds form and what kinds of precipitation fall from them. This USA TODAY resource page explains much more about atmospheric stability and instability.

Second, as for why more clouds tend to form at higher elevations, it has to do with orographic lift, when air is forced up and over mountains. This air rises, cools, and forms clouds.

For more info, this Google page has lots of photos and diagrams about orographic lift. — Doyle Rice

******************************************************************************************

Q: Does anyone track the number of daily record high temperatures or daily low temperatures that are set across the USA? It would be interesting to see if there are more record high temperatures than record low temperatures, in view of global warming.— Jack Lucero Fleck

A: Yes. Meteorologist Guy Walton of the Weather Channel has kept track of this since 2000. Through last week, since Jan. 1, 2000, he says there have been 310,437 daily record highs and 152,064 daily record lows. The numbers for all-time record highs and lows are even more striking: Since Jan. 1, 2000, there have been 1,470 all-time record highs and only 40 all-time record lows.

Walton uses this U.S. records database from the National Climatic Data Center to track this.

Walton co-authored a 2009 study in the journal Geophysical Research Letters about this. According to the article abstract, the current ratio of daily record high maximum temperatures to record low minimum temperatures, when averaged across the USA, is about two to one.... Based on one of the global warming scenarios from the Intergovernmental Panel on Climate Change, this ratio is projected to continue to increase, with ratios of about 20 to 1 by mid-century, and roughly 50 to 1 by the end of the century. — Doyle Rice

******************************************************************************************

Q: With more carbon dioxide and other gases being released into the atmosphere as a result of climate change, is the standard atmospheric pressure at sea level increasing? And, are lighter gases being displaced into outer space because of the increase in CO2, etc.?—David Glass

A: I turned to an expert, Andrew Gettelman, a scientist at the National Center for Atmospheric Research, for help with these questions. He determined that the answer to both questions is no:

"The gases that are being released add only a little bit of mass to the atmosphere. Carbon dioxide comprises oxygen that's already in the air, as well as carbon stored in the ground. However, the amounts are small and many orders of magnitude less than the changes in mass and pressure caused by regular surface pressure variations due to storms.

The atmosphere, below 60 miles, has a mixture of major long-lived gases (such as oxygen, nitrogen, argon and carbon dioxide), which are not displaced by the gases that are being released by human activities. The gases mix with the other gases, the mixture we call 'air.'" — Andrew Gettelman

******************************************************************************************

Q: Which presses down on Earth's surface more, a high- or low-pressure area?— Allen Langley

A: High pressure presses down on the Earth more than low pressure, since air sinks in high pressure and rises in low pressure.

As the name says, an area of "high" pressure is an area where the air's pressure is higher than the pressure of the surrounding air. A "low' is where it's lower. Meteorologists don't have any particular number that divides high from low pressure; it's the relative differences that count.

The pressure is high at the surface where air is slowly descending — much too slowly to feel. And, this is going on over a large area, maybe a few hundred square miles. As air descends, it warms, which inhibits the formation of clouds. This is why high pressure is usually associated with nice weather.

The air that descends in high-pressure areas has to get to high altitudes in some way, and its done by rising in areas where the pressure at the surface is low. As air rises it cools. As the air cools, the humidity in it begins to condense into tiny drops of water, or if it's cold enough, into tiny ice crystals. If there's enough water or ice, rain or snow begin to fall. This is why low pressure is associated with bad weather.

Incidentally, I wrote an article last year about new research into how high and low pressure might be a trigger for earthquakes. — Doyle Rice

******************************************************************************************

Q: What kind of winter are we expecting in the Middle Atlantic states?— Sue Lasater

A: The Climate Prediction Center, the best source for long-term climate forecasts, shows that for the months of December 2010, January 2011 and February 2011, most of the southern tier of states should be warmer than average. The areas that are expected to be colder-than-average are the northern Plains, the Northwest, and much of Alaska. The rest of the nation — including the Mid-Atlantic — should see temperatures close to average. This map shows this.

As for rain and snow, most of the southern tier should be drier-than-average, while the western Great Lakes, Ohio Valley, and Northwest should be wetter than average. Most of the Mid-Atlantic should see a typical amount of rain and snow, with southern Virginia and the Carolinas seeing less precipitation than normal. Winter precipitation map.

These forecasts will continue to be refined and updated over the next several months, with their "official" winter forecast coming out in November.

This forecast is based partially on the fact that the USA has entered a La Nina climate pattern. During typical La Nina winters, significant cold-air outbreaks can be more frequent across the northern tier of the USA, while the southern states experience less storminess and precipitation. In the eastern USA, during a La Nina winter, there are generally fewer coastal storms and more Alberta Clippers than normal.

This USA TODAY graphic shows more about La Nina and El Nino.

AccuWeather also came out with its winter forecast earlier this month. — Doyle Rice

******************************************************************************************

Q: In a 365-day cycle, does every point on Earth have an equal number of daylight/night minutes?— G. Kiner

A: That's an excellent question, one that stumped me. For help, I contacted Travis Metcalfe, an astrophysicist at the National Center for Atmospheric Research in Boulder, Colo. Here is his answer:

"For questions like this, I find it helpful to think of the extreme cases (with fictional flat horizons). Someone on the equator gets 12 hours of daylight and 12 hours of darkness every day, 365 days a year (no seasons). Someone at one of the poles gets 24 hours of daylight for half the year, and 24 hours of darkness for the other half. This means that at the poles, there is only one sunrise and one sunset per year, as the sun just spirals upwards in the sky for a few months, and then spirals back down.

A slight subtlety is that because Earth is not on a perfectly circular orbit around the sun, the number of days between the spring and fall equinox (186.32 days in 2010) differs from the number of days between fall and spring equinox (178.84 days in 2009-10).

The Earth moves slightly faster when it is closer to the sun (with the peak speed around the New Year), so someone at the North Pole gets 2% less than six months of darkness, while someone at the South Pole gets 2% more than six months. At the mid-latitudes here in the USA, the asymmetry is slightly smaller.

So the final answer would be no, every point on Earth does not get an equal amount of darkness and light in a given year." — Travis Metcalfe

******************************************************************************************

View the original article here