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Thursday, July 7, 2011

What's up for July ?

Hello and Welcome. I am Amateur Astronomer Fenil at SEVENF'S Aeronautics and Space Administration Amateurs Astronomy Club,Gujarat,India.

Asteroids are scraps of the original building material of our solar system. So they tell us about our own origins.

After the planets formed, residual material remained. Bits of dust and rock bumped into each other, sometimes sticking together and sometimes scattering.

Most asteroids orbit the sun between Mars and Jupiter in a region known as the asteroid belt.

Vesta is an asteroid and Ceres is a dwarf planet, like Pluto.

Vesta and Ceres reside in the boundary area of the asteroid belt, where the composition of bodies changes from being almost dry to showing the effects of hydration.

Scientists believe Vesta is very dry, while Ceres may have a layer of water-ice or even liquid water beneath its crust.

Dawn will study the roles of water -- and size -- in determining the evolution of the planets.

The spacecraft will orbit Vesta for a year. Next July it'll depart for the dwarf planet Ceres, arriving in February of 2015.

You can see Vesta yourself this month and next. It'll be a little brighter in August.

It's the only asteroid bright enough to see with your unaided eye, because of its high albedo. Albedo refers to how well an object reflects light.

Ceres, though larger than Vesta, is farther away and not as bright. You can easily spot Ceres in your telescopes next month. Check out the Dawn mission's Vesta Fiesta event page and find a viewing event near you. Or host a Vesta viewing event yourself.

That's all for this month.

-I'm scientist fenil .

Monday, August 3, 2009

ASTRONOMICAL EVENTS FOR Auguste 2009


ASTRONOMICAL EVENTS FOR Auguste 2009

August 2: Mercury and Regulus are just 50’ apart. Very low in west at 8:15pm.

August 3: See bright Venus some 2.5 degrees E of rich open cluster M35 in Gemini.

August 3-4: 6th magnitude star 45 Capricorni will be impermanent satellite of Jupiter.

August 5: Venus makes triangle with Mu and Eta Geminorum.

August 6: Full Moon.

August 6: Penumbral Lunar Eclipse. Starts at 4:40am for most of the parts of Western India.

August 6: Mars is roughly 1 degree E-SE of bright open cluster NGC 1746 in Taurus.

August 6: Moon and Jupiter are 2.5 degrees apart at 10pm.

August 14: Jupiter at opposition.

August 14: Last Quarter Moon.

August 15: The Moon is about 7 degree E-NE of Pleiades.

August 16: A Waning Crescent Moon is just 4 degrees NW of Mars before dawn.

August 17: Saturn and Mercury are just 3 degrees apart. Very low in west at dusk.

August 18: A Waning Crescent Moon is only 3 degrees from Venus in east at dawn.

August 18: Neptune at opposition. Find it about 3.5 degrees E-NE from Jupiter. Trough
telescopes at high magnification, Neptune will appear paired with 8th magnitude star. They will be just 0.01’ apart!

August 20: New Moon.

August 22: A very thin Waxing Crescent Moon poses 4 degrees SW of Mercury and 10 degrees S-SW of Saturn. Very low in west just after sunset.

August 24: Mercury at Greatest Eastern Elongation.

August 24: A Waxing Crescent Moon (4.6 days old) is at 5 degrees SE of Spica.

August 26: Venus stands in almost straight with Castor and Pollux in Gemini.

August 27: First Quarter Moon.

August 27: The Moon is at 4 degrees West of Antares.

August 29: Mars will pass within 1 degree SE from open cluster M35.

August 31: Venus is about 2.5 degrees W-SW from M44. Venus will be 1 degree 16’ from M44 on September 2 at 5am.


- Scientist Fenil Patadiya

Sunday, July 26, 2009

Refined Hubble constant Narrows possible explanations for " Dark Energy "

Less than 100 years ago scientists didn't know if the universe was coming or going, literally. It even fooled the great mind of Albert Einstein. He assumed the universe must be static. But to keep the universe from collapsing under gravity like a house of cards, Einstein hypothesized there was a repulsive force at work, called the cosmological constant, that counterbalanced gravity's tug. Along came Edwin Hubble in 1923 who found that galaxies were receding from us at a proportional rate, called the Hubble constant, which meant the universe was uniformly expanding, so there was no need to shore it up with any mysterious force from deep space. In measuring how this expansion was expected to slow down over time, 11 years ago, two studies, one led by Adam Riess of the Space Telescope Science Institute and the Johns Hopkins University and Brian Schmidt of Mount Stromlo Observatory, and the other by Saul Perlmutter of Lawrence Berkeley National Laboratory, independently discovered dark energy, which seems to behave like Einstein's cosmological constant.

To better characterize dark energy, Riess used Hubble Space Telescope's crisp view (combined with 2003 data from NASA's Wilkinson Microwave Anisotropy Probe, WMAP) to refine the value of the universe's expansion rate to a precision of three percent. That's a big step from 20 years ago when astronomers' estimates for the Hubble constant disagreed by a factor of two. This new value implies that dark energy really is a steady push on the universe as Einstein imagined, rather than something more effervescent (like the early inflationary universe) that changes markedly over time.

Whatever dark energy is, explanations for it have less wiggle room following a Hubble Space Telescope observation that has refined the measurement of the universe's present expansion rate to a precision where the error is smaller than five percent. The new value for the expansion rate, known as the Hubble constant, or H0 (after Edwin Hubble who first measured the expansion of the universe nearly a century ago), is 74.2 kilometers per second per megaparsec (error margin of ± 3.6). The results agree closely with an earlier measurement gleaned from Hubble of 72 ± 8 km/sec/megaparsec, but are now more than twice as precise.

The Hubble measurement, conducted by the SHOES (Supernova H0 for the Equation of State) Team and led by Adam Riess, of the Space Telescope Science Institute and the Johns Hopkins University, uses a number of refinements to streamline and strengthen the construction of a cosmic "distance ladder," a billion light-years in length, that astronomers use to determine the universe's expansion rate.

Hubble observations of pulsating stars called Cepheid variables in a nearby cosmic mile marker, the galaxy NGC 4258, and in the host galaxies of recent supernovae, directly link these distance indicators. The use of Hubble to bridge these rungs in the ladder eliminated the systematic errors that are almost unavoidably introduced by comparing measurements from different telescopes.

Riess explains the new technique: "It's like measuring a building with a long tape measure instead of moving a yard stick end over end. You avoid compounding the little errors you make every time you move the yardstick. The higher the building, the greater the error."

Lucas Macri, professor of physics and astronomy at Texas A&M, and a significant contributor to the results, said, "Cepheids are the backbone of the distance ladder because their pulsation periods, which are easily observed, correlate directly with their luminosities. Another refinement of our ladder is the fact that we have observed the Cepheids in the near-infrared parts of the electromagnetic spectrum where these variable stars are better distance indicators than at optical wavelengths."

This new, more precise value of the Hubble constant was used to test and constrain the properties of dark energy, the form of energy that produces a repulsive force in space, which is causing the expansion rate of the universe to accelerate.

By bracketing the expansion history of the universe between today and when the universe was only approximately 380,000 years old, the astronomers were able to place limits on the nature of the dark energy that is causing the expansion to speed up. (The measurement for the far, early universe is derived from fluctuations in the cosmic microwave background, as resolved by NASA's Wilkinson Microwave Anisotropy Probe, WMAP, in 2003.)

Their result is consistent with the simplest interpretation of dark energy: that it is mathematically equivalent to Albert Einstein's hypothesized cosmological constant, introduced a century ago to push on the fabric of space and prevent the universe from collapsing under the pull of gravity. (Einstein, however, removed the constant once the expansion of the universe was discovered by Edwin Hubble.)

"If you put in a box all the ways that dark energy might differ from the cosmological constant, that box would now be three times smaller," says Riess. "That's progress, but we still have a long way to go to pin down the nature of dark energy."

Though the cosmological constant was conceived of long ago, observational evidence for dark energy didn't come along until 11 years ago, when two studies, one led by Riess and Brian Schmidt of Mount Stromlo Observatory, and the other by Saul Perlmutter of Lawrence Berkeley National Laboratory, discovered dark energy independently, in part with Hubble observations. Since then astronomers have been pursuing observations to better characterize dark energy.

Riess's approach to narrowing alternative explanations for dark energy—whether it is a static cosmological constant or a dynamical field (like the repulsive force that drove inflation after the big bang)—is to further refine measurements of the universe's expansion history.

Before Hubble was launched in 1990, the estimates of the Hubble constant varied by a factor of two. In the late 1990s the Hubble Space Telescope Key Project on the Extragalactic Distance Scale refined the value of the Hubble constant to an error of only about ten percent. This was accomplished by observing Cepheid variables at optical wavelengths out to greater distances than obtained previously and comparing those to similar measurements from ground-based telescopes.

The SHOES team used Hubble's Near Infrared Camera and Multi-Object Spectrometer (NICMOS) and the Advanced Camera for Surveys (ACS) to observe 240 Cepheid variable stars across seven galaxies. One of these galaxies was NGC 4258, whose distance was very accurately determined through observations with radio telescopes. The other six galaxies recently hosted Type Ia supernovae that are reliable distance indicators for even farther measurements in the universe. Type Ia supernovae all explode with nearly the same amount of energy and therefore have almost the same intrinsic brightness.

By observing Cepheids with very similar properties at near-infrared wavelengths in all seven galaxies, and using the same telescope and instrument, the team was able to more precisely calibrate the luminosity of supernovae. With Hubble's powerful capabilities, the team was able to sidestep some of the shakiest rungs along the previous distance ladder involving uncertainties in the behavior of Cepheids.

Riess would eventually like to see the Hubble constant refined to a value with an error of no more than one percent, to put even tighter constraints on solutions to dark energy.

- Fenil Patadiya

Thursday, July 9, 2009

What is solar eclipse ?

A solar eclipse occurs when the moon passes between the sun the earth so that the Sun is fully or partially covered. This can only happen during a new moon, when the Sun and Moon are in conjunction as seen from the Earth. At least two and up to five solar eclipses can occur each year on Earth, with between zero and two of them being total eclipses. Total solar eclipses are nevertheless rare at any location because during each eclipse totality exists only along a narrow corridor in the relatively tiny area of the Moon's umbra.

Saturday, April 4, 2009

SEVENF'S AERONAUTICS AND SPACE ADMINISTRATION AMATEURS ASTRONOMY CLUB

Astronomy is the science dealing with all the celestial bodies in the universe.If you're just getting started in astronomy, the best thing to do is to first spend some time under the stars with just your eyes and get acquainted with the brighter stars and constellations.

SEVENF'S AERONAUTICS AND SPACE ADMINISTRATION AMATEURS ASTRONOMY CLUB is also called " SASAA ". This worldwide organization was established in 2008 in katargam area in the city of Surat of Gujarat state in India. Our activities are sky gabbling, sky gather meet, work shop,give telescope training, and more....

Fenil.A.Patadiya is the founder of SASAA.I am amateurs astronomers and scientist. Email : fenil_patadiya@yahoo.com

What's up for April ?

Hello and welcome. I am Scientist Fenil at SEVENF'S AERONAUTICS AND SPACE ADMINISTRATION AMATEURS ASTRONOMY CLUB , Gujarat , India.

Look up at the night sky this month and you'll see great views of Saturn and the moon.

Each month I'll be telling you about some cool views you can see in the night sky.

One of the views I love to share is Saturn.

Everyone is always amazed that they can actually see the rings.

Just step outside after sunset and you'll see Saturn.

It's a bright golden glow nearly overhead.

You don't even need a telescope.

There is another planet you can see this month, it's Venus.

Just look low in the west after the sun sets. Venus is the brightest object that you'll see.

But wait, there's more! Between April 21st and April 25th, you'll see the moon grow larger and appear higher in the sky each night. By the 25th you'll find it above Saturn!

Here's a viewing tip for next month. In late May -- you'll be able to see asteroid Vesta.

It won't be as bright as the Big Dipper stars, and you'll definitely have to get away from city lights to see it.

I really enjoy viewing the solar system through my own telescopes and sharing the views with others.

That's all for this month.

-I'm scientist fenil .

Wednesday, April 1, 2009

THE EARTH


EARTH DATA :

Diameter : 12,756 km ( 7,926 miles )

Equator : 12,713 km ( 7,899 miles ) at poles

Age : 4.6 billion years old

Distance from sun : 150 million km ( 93 million miles)

Mass : 5,854 billion billion tonnes

Area : 29.2 % land , 70.8 % water

Orbiting time : 365.26 days

Orbiting speed : 29.8 km /sec ( 18.5 miles/sec )