Contents
AEA Astronomy Club News & Calendar p.1
Video(s) & Picture(s) of the Month p. 2
Astronomy News p. 10
General Calendar p. 15
Colloquia, lectures, mtgs. p. 15
Observing p. 19
Observing p. 19
Useful
Links p. 20
About the Club p. 21
Club News & Calendar.
Club Calendar
About the Club p. 21
Club News & Calendar.
Club Calendar
Club Meeting Schedule:
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2 May
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AEA Astronomy Club Meeting
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NASA video shorts
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(A1/1735)
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AEA
Astronomy Club meetings are now on 1st Thursdays at 11:45 am. For 2018:
Jan. 4 in A1/1029 A/B, Feb. 1 & March 1 in A1/2906 and for the rest
of 2018 (April-Dec), the meeting room is A1/1735.
Club
News:
April 19-21 Joint outing to
Anza-Borrego Desert to camp out, hike & view the dark skies. Here’s a report on the outing,
& use of our giant binocs that we ended up lending, from Cassie Meyer:
The camping
trip went very well! We used the binoculars both Friday and Saturday night to
view the moon. No one really knew how to use the parallelogram mount to it’s
full potential, but we made it work for our needs. My favorite part was
watching the moon rise over the mountain ridges in the distance. On Friday, the
moon had a pink glow before it peeked over the ridge. Once the moon rose higher
in the sky, it did get pretty bright to look at just like you predicted. I’ve
attached a few photos I took with my iphone through one side of the binoculars.
One photo turned out blurry before I realized that the binoculars weren’t in
focus. I also used the binoculars during the day to scan the mountainsides for
big horned sheep – it wasn’t as fruitful as moon viewing.
I can hold
the binoculars, tripod, and mount in my office. The outdoors club is also
having to store club gear in offices and we talked to AEA about getting some
AEA club storage space. It seemed like they supported the idea of some sort of
on-campus storage, but progress is slow. It wouldn’t hurt to have another
squeeky wheel to ask for oil…😊
Thanks
again for lending out the equipment!
-Cassie
Meyer
We need volunteers to help with:
·
Populating
our club Sharepoint site with material & links to the club’s Aerowiki
& Aerolink materials
·
Arranging
future club programs
·
Managing
club equipment
Astronomy Video(s)
& Picture(s) of the Month
(generally from
Astronomy Picture of the Day, APOD: http://apod.nasa.gov/apod/archivepix.html)
VIDEO: Mars Methane Mystery Deepens https://apod.nasa.gov/apod/ap190422.html
Video Credit: NASA's GSFC, Scientific Visualization Studio
Explanation: The methane mystery on Mars just got
stranger. New results from ESA and Roscosmos' ExoMars Trace
Gas Orbiter, has
unexpectedly not detected methane in the
atmosphere of Mars.
This result follows the 2013 detection of methane byNASA's Curiosity rover, a result seemingly confirmed by ESA's orbiting Mars Express the next day. The issue is so
interesting because
life is a major producer of methane on Earth, leading to intriguing speculation
that some sort of life -- possiblymicrobial
life -- is
creating methane beneath the surface of Mars. Non-biological sources of methane are also possible. Pictured is a visualization of the first
claimed methane plume over Mars as detected from Earth in 2003. The new
non-detection of methane by the ExoMars Orbiter could mean that Mars has some
unexpected way of destroying methane, or that only some parts of Mars release methane -- and possibly only at certain
times. As the mystery has now deepened, humanity's
scrutiny of our neighboring planet's atmosphere will deepen as well.Video Credit: NASA's GSFC, Scientific Visualization Studio
VIDEO: Transit of Phobos -- Martian Moon Phobos Crosses the Sun
https://apod.nasa.gov/apod/ap190410.html
Video Credit: NASA, JPL-Caltech, MSSS, Curiosity Rover
Explanation: What's that passing in front of the Sun?
It looks like a moon, but it can't be Earth's Moon, because it isn't round. It's the Martian
moon Phobos. The featured video was taken from the surface of Mars late last month by the Curiosity
rover.Phobos, at 11.5 kilometers across, is 150 times
smaller than Luna (our moon) in diameter, but also 50
times closer to its parent planet. In fact, Phobos is so close to Mars that it is expected to break up and crash
into Mars within the next 50 million years. In
the near term, the low orbit of Phobos results in more rapid solar eclipses
than seen from Earth. The featured
video has
been sped up -- the actual transit took about 35 seconds. A similar
video was
taken of Mars' smaller and most distant moon Diemostransiting the Sun. The videographer --
the robotic rover Curiosity -- continues to explore Gale crater, most recently an area with stunning vistas
and unusual rocks dubbed Glen Torridon.Video Credit: NASA, JPL-Caltech, MSSS, Curiosity Rover
VIDEO: All of Mercury https://apod.nasa.gov/apod/ap190428.html
Image Credit: NASA/JHU Applied Physics Lab/Carnegie Inst. Washington
Explanation: Only six years ago, the entire surface of planet Mercury was finally
mapped. Detailed observations of the innermost
planet's
surprising crust began when the robotic have been ongoing since the
robotic MESSENGER spacecraft first passed Mercury in 2008 and continued
until its controlled crash landing in 2015. Previously, much of
the Mercury's surface was unknown as it is too far for
Earth-bound telescopes to see clearly, while the Mariner 10 flybys in the 1970s observed only
about half. The featured video is a compilation of thousands of
images of Mercury rendered in exaggerated colors to better contrast different surface
features. Visible on the rotating
world are rays emanating from a northern impact that stretch
across much of the planet, while about half-way through the video the light
colored Caloris Basin rotates into view, a northern
ancient impact feature that filled with lava. Recent
analysis of
MESSENGER data indicates that Mercury has a solid
inner core.Image Credit: NASA/JHU Applied Physics Lab/Carnegie Inst. Washington
The Galaxy, the Jet, and the Black
Hole
Image Credit: NASA, JPL-Caltech, Event Horizon Telescope Collaboration
Explanation: Bright elliptical galaxy Messier 87 (M87) is home to the
supermassive black hole captured by planet Earth's Event Horizon Telescope in the first ever image of a black
hole. Giant of the Virgo galaxy cluster about 55 million light-years away, M87
is the large galaxy rendered in blue hues in this infrared image from
the Spitzer Space telescope. Though M87 appears mostly featureless and cloud-like, the
Spitzer image does record details of relativistic jets blasting from the
galaxy's central region. Shown in the inset at top right, the jets themselves
span thousands of light-years. The brighter
jet seen on
the right is approaching and close to our line of sight. Opposite, the shock created
by the otherwise unseen receding jet lights up a fainter arc of material. Inset
at bottom right, the historic
black hole image is
shown in context, at the center of giant galaxy and relativistic jets.
Completely unresolved in the Spitzer image, the supermassive black hole
surrounded by infalling material is the source of the enormous energy driving
the relativistic jets from the center
of active galaxy M87.Image Credit: NASA, JPL-Caltech, Event Horizon Telescope Collaboration
First Horizon-Scale Image of a Black
Hole
Image Credit: Event Horizon Telescope Collaboration
Explanation: What does a black hole look like? To find
out, radio telescopes from around
the Earth coordinated
observations of black
holes with
the largest known event
horizons on the
sky. Alone, black holes are just black, but these monster attractors are known
to be surrounded by glowing gas. The first image was released yesterday
and resolved the area around the black hole at the center of galaxy M87 on a scale below that expected for
its event
horizon. Pictured, the dark central region is not the event
horizon, but rather the black hole's
shadow -- the
central region of emitting gas darkened by the central black hole's gravity.
The size and shape of the shadow is determined by bright gas near the event horizon, by strong gravitational lensing deflections, and by the black hole's spin. In
resolving this black
hole's shadow,
the Event Horizon Telescope (EHT) bolstered evidence that Einstein's gravity works even in extreme
regions, and gave
clear evidence that M87 has a central spinning black hole of
about 6 billion solar masses. The EHT is not done -- future observations
will be geared toward even
higher resolution,
better tracking of variability, and exploring the immediate vicinity of
the black hole in the center of our Milky
Way Galaxy.Image Credit: Event Horizon Telescope Collaboration
Falcon Heavy Launch Close Up
Image Credit: SpaceX
Explanation: Twenty seven Merlin rocket engines are
firing in this close-up of the
launch of a
Falcon Heavy rocket. Derived from three Falcon
9 first stage
rockets with nine Merlin rocket engines each, the Falcon Heavy left NASA's
Kennedy Space Center launch pad 39A on April 11. This second launch of a Falcon Heavy rocket carried the Arabsat 6A communications
satellite to space. In February of 2018, the first Falcon Heavy launch
carried Starman and a Tesla Roadster. Designed to be reusable, both booster
stages and the central core returned safely to planet Earth, the boosters to
Cape Canaveral Air Force Station landing zones. The core stage landed off shore
on autonomous spaceport drone ship Of
Course I Still Love You.Image Credit: SpaceX
ISS from Wallasey
Image Credit & Copyright: Richard Addis
Explanation: After
sunset on March 28,
the International Space Station climbed above the western horizon, as seen from
Wallasey, England at the mouth of the River Mersey. Still glinting in the
sunlight some 400
kilometers above planet Earth, the fast moving ISS was followed by hand with a
small backyard telescope and high frame rate digital camera. A total of 2500
frames were recorded during the 7 minute long visible ISS passage and 100 of
them captured images of the space station. These are the four best frames
showing remarkable details of the ISS in low Earth orbit. Near
the peak of its track, about 60 degrees above the horizon, the ISS was brighter than
the brightest star in the sky and as close as 468 kilometers to the Wallasey
backyard.Image Credit & Copyright: Richard Addis
AZURE Vapor Tracers over Norway
Image Credit & Copyright: Yang Sutie
Explanation: What's happening in the sky? The
atmosphere over northern Norway appeared quite strange for about 30
minutes last Friday when colorful clouds, dots, and plumes suddenly appeared.
The colors were actually created by the NASA-fundedAuroral
Zone Upwelling Rocket Experiment (AZURE) which dispersed gas tracers to probe winds in
Earth's upper
atmosphere. AZURE's
tracers originated
from two short-lived sounding
rockets launched
from the Andøya Space Center in Norway. The harmless gases, trimethylaluminum and a barium/strontium mixture, were released into
the ionosphere at altitudes of 115 and 250 km. The
vapor trails were observed dispersing from several ground stations.
Mapping how AZURE's
vapors dispersed
should increase humanity's understanding of how the solar wind transfers energy to the Earth and
powers aurora.Image Credit & Copyright: Yang Sutie
Moon Occults Saturn
Image Credit & Copyright: Cory Schmitz
Explanation: Sometimes Saturn disappears. It doesn't
really go away, though, it just disappears from view when our Moon moves in front. Such a Saturnian eclipse was visible
along a small swath of
Earth -- from Brazil to Sri Lanka -- near the end of last month.
The featured
color image is
a digital fusion of the clearest
images captured
by successive videos of the
event taken
in red, green, and blue, and taken separately for Saturn and the comparative bright Moon. The exposures were taken fromSouth Africa just before occultation -- and also
just before sunrise. When Saturn
re-appeared on
the other side of the Moon almost two hours later, the Sun
had risen. This
year, eclipses of Saturn by the Moon occur almost monthly, but, unfortunately, are visible only to
those with the right location and with clear and dark skies.Image Credit & Copyright: Cory Schmitz
Astronomy
News:
NASA
ScienceCasts: Hubble’s Contentious Constant
Something Is Not Quite Right In the
Universe, Ultraprecise New Measurement Reveals
By Mara
Johnson-Groh February 09, 2019 Science
& Astronomy
This Hubble
Telescope image shows a doubly-imaged quasar, which can be used to measure the
Hubble constant. A new technique of measuring the Hubble Constant from such
doubly-imaged quasar systems could help astronomers better understand how the
universe's expansion rate has changed over time.
(Image: © NASA Hubble Space Telescope, Tommaso Treu/UCLA, and
Birrer et al)
Something
isn't quite right in the universe. At least based on everything physicists know
so far. Stars, galaxies, black holes and all the other celestial objects are
hurtling away from each other ever faster over time. Past measurements in our
local neighborhood of the universe find that the universe is exploding outward
faster than it was in the beginning. That shouldn't be the case, based on
scientists' best descriptor of the universe.
If their measurements of a value known
as the Hubble Constant are correct, it means that the current model is missing
crucial new physics, such as unaccounted-for fundamental particles, or
something strange going on with the mysterious substance known as dark energy.[5 Elusive Particles Beyond the Higgs | Quantum Physics]
Now, in a new study, published Jan. 22 in
the journal Monthly
Notices of the Royal Astronomical Society, scientists have measured the Hubble
Constant in an entirely new way, confirming that, indeed, the universe is
expanding faster now than it was in its early days.
"Something interesting going on"
To explain how the universe went from a
tiny, hot, dense speck of soupy plasma to the vast expanse we see today, scientists
have proposed what's known as the Lambda Cold Dark Matter (LCDM) model. The
model puts constraints on the properties of dark matter, a kind of matter that exerts
gravitational pull but emits no light, and dark energy, which seems to oppose
gravity. LCDM can successfully reproduce the structure of galaxies and the
cosmic microwave background — the universe's first light — as well as the
amount of hydrogen and helium in the universe. But it can't explain why the
universe is expanding faster now than it did early on. [Big Bang to Civilization: 10 Amazing Origin Events]
That
means that either the LCDM model is wrong or the measurements of expansion rate
are.
The new
method aims to finally settle the expansion-rate debate,Simon Birrer, a
researcher at the University of California, Los Angeles, and lead author on the
new study, told Live Science.So far, the new, independent measurements confirm
the discrepancy, suggesting new physics may be needed.
To nail down Hubble's Constant, scientists
had previously used several different methods. Some used supernovas in the
local universe (the nearby part of the universe), and others have relied
on Cepheids, or types of stars that pulsate and regularly flicker in
brightness. Still others have studied the cosmic background radiation.
The new
research used a technique that involves light from quasars — extremely bright
galaxies powered by massive black holes — in an effort to break the tie.
"No
matter how careful an experiment is, there can always be some effect that is
built into the kinds of tools that they're using to make that measurement. So
when a group comes along like this and uses a completely different set of
tools… and gets the same answer, then you can pretty quickly conclude that that
answer is not a result of some serious effect in the techniques," said
Adam Riess, a Nobel laureate and researcher at the Space Telescope Science
Institute and at Johns Hopkins University. "I think that our confidence is
growing that there's something really interesting going on," Riess, who
was not involved in the study, told Live Science.
Seeing double
Here's how the technique worked: When light
from a quasar passes an intervening galaxy, gravity from the galaxy causes that light to
"gravitationally bend" before hitting Earth. The galaxy
acted like a lens to distort the quasar's light into multiple copies — most
commonly two or four depending on the alignment of the quasars in relation to
the galaxy. Each of those copies traveled a slightly different path around the
galaxy.
Quasars don't usually shine steadily like many stars. On account
of material falling into their central black holes, they change in brightness
on scales of hours to millions of years. Thus, when a quasar's image is lensed
into multiple copies with unequal light paths, any change in the brightness of
the quasar will result in a subtle flickering between the copies, as light from
certain copies takes a touch longer to reach Earth.
From this discrepancy, scientists could
precisely determine how far we are from both the quasar and the intermediary
galaxy. To calculate the Hubble Constant, astronomers then compared that distance
to the object's redshift, or the shift in wavelengths of light toward the red
end of the spectrum (which shows how much the object's light has stretched as the universe
expands).
Studying
light from systems that create four images, or copies, of a quasar has been
done in the past. But, in the new paper, Birrer and his collaborators
successfully demonstrated that it is possible to measure the Hubble Constant
from systems that create just a double image of the quasar. This dramatically
increases the number of systems that can be studied, which ultimately will
allow the Hubble Constant to be measured more precisely.
"Images
of quasars that appear four times are very rare — there are maybe only 50 to
100 across the whole sky, and not all are bright enough to be measured,"
Birrer told Live Science. "Doubly- lensed systems, however, are more
frequent by about a factor of five."
The new
results from a doubly-lensed system, combined with three other previously
measured quadruple-lensed systems, put the value for the Hubble Constant at
72.5 kilometers per second per megaparsec; that's in agreement with other local
universe measurements, but still around 8 percent higher than measurements from
the distant universe (the older, or early, universe). As the new technique is
applied to more systems, researchers will be able to home in on the exact
difference between distant (or early) universe and local (more recent) universe
measurements.
"The
key is to go from a point where we're saying, yeah, these things don't agree,
to having a very precise measure of the level to which they don't agree,
because ultimately that will be the clue that allows theory to say what is
going on," Riess told Live Science.
Accurately measuring the Hubble Constant
helps scientists understand more than just how fast the universe is flying
apart. The value is imperative in determining the age of the universe and the physical size of distant
galaxies. It also gives astronomers clues as to the amount of dark matter, and
dark energy, out there.
As for
explaining what possibly exotic physics might explain their mismatch in
expansion-rate measurements, that's way down the line.
Originally published on Live Science.
The
universe seems to be expanding faster than all expectations
New evidence deepens a mystery around the Hubble constant, one of the
most important numbers in cosmology.
4 MINUTE READ
https://www.nationalgeographic.com/science/2019/04/hubble-constant-universe-expanding-faster-than-all-expectations/
PUBLISHED APRIL
25, 2019
FRESH EVIDENCE SUGGESTS that the universe is expanding
faster today than it did in its infancy, a difference that has set off a search
to understand what cosmic forces could be at play. If confirmed, the changing
rate—which is nine percent faster than had been projected—would force us to
reconsider a fundamental aspect of the cosmos.
The
result, announced in a new report publishing in the Astrophysical
Journal, marks the latest in a long-running controversy over the Hubble
constant, a key measure of the universe's age and expansion rate.
In
recent years, numerous studies have shown that measurements of
the Hubble constant from the cosmic microwave background—the faint afterglow of
the infant universe—are at odds with estimates from far younger stars, such
as those in our Milky Way, even after taking into account other mysterious cosmic
forces such as dark energy, which is accelerating the universe's expansion.
“[The
universe] is outpacing all our expectations in its expansion, and that is very
puzzling,” says lead study author Adam Riess, an astronomer at Johns Hopkins
University who co-won the 2011 Nobel Prize in physics for helping discover dark
energy.
Some
have argued that the discrepancy is a product of incomplete data, or some
unseen errors systematically pressing their thumbs on the scales. But based on fresh measurements of
our cosmic neighborhood from the Hubble Space Telescope, Riess and his
colleagues say that the mismatch is not only real, it's wider than ever.
In the
new study, Riess's team measures the Hubble constant to a value of 74.03
kilometers per second per megaparsec, give or take 1.42. That's at odds
with the best estimates from Planck, a European Space Agency telescope
that made the best measurements to date of the cosmic microwave background.
Planck's data pegs the Hubble constant at about 67.4 kilometers per second per
megaparsec, give or take 0.5. In statistical parlance, the difference between
these two results stands at about 4.4 sigma, or 1-in-100,000 odds that the
discrepancy is merely a fluke.
“To use
an analogy, let’s look at a two-year-old and see how tall they are, and then
try to figure out how tall they are going to be when they grow up. Then we
could actually wait until they grow up and measure them,” Riess says. “If they
far exceed that [extrapolation], we’d have a real mystery on our hands.
Something isn’t right in our understanding of how this person grew.”
Clocking the universe
Calculating
the Hubble constant, and thus the expansion rate of the universe, based on the
movements of stars requires two kinds of data: how far away a given star is,
and how quickly it's receding from us.
To measure a star's relative velocity, astronomers look for shifts in the
star's emitted light. To measure distance, astronomers use a variety of tools,
from straightforward geometry to careful observations of stars called Cepheid
variables. These stars brighten and dim regularly, and the rate of these pulses
is closely related to the star's overall brightness: the brighter the star, the
more slowly it pulsates.
In February
1997, astronauts aboard the space shuttle Discovery took this picture of the
Hubble Space Telescope (HST) after separating from the orbiting telescope.
Astronomers can use this relationship as a ruler. By measuring a
Cepheid's pulse rate, astronomers can work out how luminous the star is, and by
comparing that absolute brightness with the one we see, we can infer how far
away the star is from us. Cepheids also can be combined with observations
of certain kinds of
stellar explosions to measure distances deeper and deeper into the cosmos.
Astronomers have worked for years to assemble this “cosmic distance
ladder,” and they're constantly trying to calibrate it ever more finely. For
this study, Riess's team used the Hubble Space Telescope to peer at 70 Cepheids
in the Large Magellanic Cloud, one of our Milky Way's irregularly shaped satellite
galaxies. These new data let them more precisely estimate the distances between
us and objects in the Large Magellanic Cloud, which in turn let them infer the
Hubble constant with greater precision.
Balancing the books
If the universe really is expanding faster than thought, then some kind
of new physics would have to provide the extra oomph. Is dark energy more
exotic and turbo-charged than we thought? Is dark matter more complex than we
imagined? Is there some
other kind of unseen particle in the cosmos, such as a “sterile neutrino” that
interacts with other types of matter only via gravity?
And if our cosmic checkbooks are truly off, we might want to call in an
outside accountant—and one could be coming soon. In 2017, scientists detected
gravitational waves, ripples in space-time itself, and light flung off by a
colliding pair of neutron stars. The historic
measurement allowed
astronomers to derive an independent estimate of the Hubble constant. So
far, that value slots right in between the Planck values and those
derived from the cosmic distance ladder.
The effectiveness of using such events as “standard sirens” to measure
the expansion of the universe, however, hinges on the number of neutron-star
events that gravitational wave detectors such as LIGO pick up. So far,
astronomers have confirmed only one—but on the morning of April 25, LIGO may have detected another. That said, pinpointing the waves'
origins in the sky proved challenging, which is complicating follow-up
measurements with telescopes.
Meanwhile Riess and astronomers around the world are working to make
their measurements of the Hubble constant even more precise, in the hopes that
even a small discrepancy could unlock a massive new clue to how the universe
works.
“Even nine percent is a big deal,
when you have an uncertainty of one or two percent,” says Riess. “We have some
feeling that the universe is still teaching us.”
General Calendar:
Colloquia, Lectures, Seminars, Meetings, Open Houses & Tours:
Colloquia, Lectures, Seminars, Meetings, Open Houses & Tours:
Colloquia: Carnegie (Tues.
4pm), UCLA, Caltech (Wed. 4pm), IPAC (Wed. 12:15pm) & other Pasadena (daily
12-4pm): http://obs.carnegiescience.edu/seminars/
Carnegie 2019 Astronomy Lecture Series
Each
year the Observatories organizes a series of public lectures on current
astronomical topics. These lectures are given by astronomers from the
Carnegie Observatories as well as other research institutions. The
lectures are geared to the general public and are free.
–
only 4 per year in the Spring www.obs.carnegiescience.edu. For more
information about the Carnegie Observatories or this lecture series, please
contact Reed Haynie. . Click here for
more information.
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2 May
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AEA Astronomy Club Meeting
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NASA video shorts
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(A1/1735)
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3
May
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Friday Night 7:30PM SBAS Monthly General Meeting
in the Planetarium at El Camino College (16007 Crenshaw
Bl. In Torrance)
Topic: TBA
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May 9 & 10 The von
Kármán Lecture Series: 2019
CubeSats
& SmallSats
Some are the size of a toaster.
Others a suitcase. They can ride into space as secondary payloads in a rocket's
"trunk," or even be tossed out of an airlock, to start their
missions. Small satellites, often collectively called "cubesats," are
changing the way we explore space and monitor our home planet.
Host:
Preston Dyches
Preston Dyches
Speaker:
Anne Marinan (JPL) — Systems Engineer, Near Earth Asteroid Scout & Mars Cube One; Team Xc Lead Engineer
Travis Imken (JPL) — Project Systems Engineer, RainCube
Anne Marinan (JPL) — Systems Engineer, Near Earth Asteroid Scout & Mars Cube One; Team Xc Lead Engineer
Travis Imken (JPL) — Project Systems Engineer, RainCube
Location:
Thursday, May 9, 7pm
The von Kármán Auditorium at JPL
4800 Oak Grove Drive
Pasadena, CA › Directions
Friday, May 10, 2019, 7pm
Caltech’s Ramo Auditorium
1200 E California Blvd.
Pasadena, CA › Directions
Thursday, May 9, 7pm
The von Kármán Auditorium at JPL
4800 Oak Grove Drive
Pasadena, CA › Directions
Friday, May 10, 2019, 7pm
Caltech’s Ramo Auditorium
1200 E California Blvd.
Pasadena, CA › Directions
*
Only the Thursday lectures are streamed live.
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May 12, 2019
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UCLA Meteorite Gallery Events
DR. ASHWIN VASAVADA
CURIOSITY ROVER, GALE CRATER AND
EVIDENCE OF FLOWING WATER ON MARS
Location: Geology 3656
Time: 2:30PM
Our next Gallery Lecture will be presented on 12 May 2019 by
Dr. Ashwin Vasavada of JPL, Project Scientist for the Curiosity Mars Rover.
His title is “Curiosity Rover, Gale Crater and evidence of flowing water on
Mars.” Nearly seven years after its dramatic arrival at Mars, the Curiosity
Rover continues to reveal Mars as a once-habitable planet. Streams and lakes
persisted there for millions of years and created landforms that Curiosity explores
within Gale crater. While the water has long since disappeared, shifting
sands and seasonal cycles of methane gas reveal a dynamic planet today. This
talk will cover the latest findings from the mission, some striking images,
the challenges of exploration, and what lies ahead.
Photo Credit: NASA
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13 May
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LAAS General Mtg. 7:30pm Griffith Observatory
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18-19 May Jet
Propulsion Laboratory Open House See
https://www.jpl.nasa.gov/news/news.php?feature=7351 for more information.
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6 June
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AEA Astronomy Club Meeting
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TBD
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(A1/1735)
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Observing:
The
following data are from the 2019 Observer’s Handbook, and Sky & Telescope’s
2019 Skygazer’s Almanac & monthly Sky at a Glance.
Current
sun & moon rise/set/phase data for L.A.:
http://www.timeanddate.com/astronomy/usa/los-angeles
Sun, Moon
& Planets for May:
Moon: May 4 new, May 12 1st
quarter, May 18 Full, May 26 last quarter
Planets:
Venus
visible at dawn all month. Mars visible at dusk, sets
mid-evening. Mercury
visible at dusk after the 29th. Saturn rises near midnight, visible
until dawn. Jupiter rises before
midnight, visible until dawn.
Other
Events:
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4 May
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SBAS
out-of-town Dark Sky observing – contact Greg Benecke to coordinate a
location. http://www.sbastro.net/.
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4 May
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LAAS Private dark
sky Star Party
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5 May Space Day
See https://nationaldaycalendar.com/national-space-day-first-friday-in-may/ for
more information.
5 May Eta Aquarids
Meteor Shower Peak The Eta Aquarids are associated with Halley’s Comet.
Although not as spectacular as the Leonids or Perseids, it’s still an unusual
event. Zenith Hour-Rates are typically around 55 meteors/hour.
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1,8,15,22,29 May
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LAAS
The Garvey Ranch Observatory is open to the public every
Wednesday evening from 7:30 PM to 10 PM. Go into the dome to use the 8 Inch
Refractor or observe through one of our telescopes on the lawn. Visit our
workshop to learn how you can build your own telescope, grind your own
mirror, or sign up for our free seasonal astronomy classes.
Call 213-673-7355 for further information.
Time: 7:30
PM - 10:00 PM
Location: Garvey
Ranch Obs. , 781 Orange Ave., Monterey Park, CA 91755
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18 May Full/Blue Moon
A blue moon is an additional full moon that appears in a subdivision of a year:
either the third of four full moons in a season, or a second full moon in a
month of the common calendar.
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18 May
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LAAS Public
Star Party: Griffith Observatory Grounds 2-10pm See http://www.griffithobservatory.org/programs/publictelescopes.html#starparties for more information.
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1 June
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LAAS Private dark
sky Star Party
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Internet
Links:
Telescope, Binocular & Accessory Buying
Guides
General
About the
Club
Club Websites: Internal (Aerospace): https://aeropedia.aero.org/aeropedia/index.php/Astronomy_Club It is updated to reflect this newsletter, in addition to a listing of past club mtg. presentations, astronomy news, photos & events from prior newsletters, club equipment, membership & constitution. We have linked some presentation materials from past mtgs. Our club newsletters are also being posted to an external blog, “An Astronomical View” http://astronomicalview.blogspot.com/.
Club Websites: Internal (Aerospace): https://aeropedia.aero.org/aeropedia/index.php/Astronomy_Club It is updated to reflect this newsletter, in addition to a listing of past club mtg. presentations, astronomy news, photos & events from prior newsletters, club equipment, membership & constitution. We have linked some presentation materials from past mtgs. Our club newsletters are also being posted to an external blog, “An Astronomical View” http://astronomicalview.blogspot.com/.
Membership. For information, current dues & application, contact Alan Olson, or see the club website (or Aerolink folder) where a form is also available (go to the membership link/folder & look at the bottom). Benefits will include use of club telescope(s) & library/software, membership in The Astronomical League, discounts on Sky & Telescope magazine and Observer’s Handbook, field trips, great programs, having a say in club activities, acquisitions & elections, etc.
Committee Suggestions & Volunteers. Feel free to contact: Mark Clayson, President & Program Committee Chairman, Walt Sturrock, VP, TBD Activities Committee Chairman (& club Secretary), or Alan Olson, Resource Committee Chairman (over equipment & library, and club Treasurer).
Mark Clayson,
AEA Astronomy Club President
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