Optical Communications: Explore Lasers In Space

Two Steps Forward in the Search for Life on Mars

We haven’t found aliens but we are a little further along in our search for life on Mars thanks to two recent discoveries from our Curiosity Rover.

We detected organic molecules at the harsh surface of Mars! And what’s important about this is we now have a lot more certainty that there’s organic molecules preserved at the surface of Mars. We didn’t know that before.

One of the discoveries is we found organic molecules just beneath the surface of Mars in 3 billion-year-old sedimentary rocks.

Second, we’ve found seasonal variations in methane levels in the atmosphere over 3 Mars years (nearly 6 Earth years). These two discoveries increase the chances that the record of habitability and potential life has been preserved on the Red Planet despite extremely harsh conditions on the surface.

Both discoveries were made by our chem lab that rides aboard the Curiosity rover on Mars.

Here’s an image from when we installed the SAM lab on the rover. SAM stands for “Sample Analysis at Mars” and SAM did two things on Mars for this discovery.

One - it tested Martian rocks. After the arm selects a sample of pulverized rock, it heats up that sample and sends that gas into the chamber, where the electron stream breaks up the chemicals so they can be analyzed.

What SAM found are fragments of large organic molecules preserved in ancient rocks which we think come from the bottom of an ancient Martian lake. These organic molecules are made up of carbon and hydrogen, and can include other elements like nitrogen and oxygen. That’s a possible indicator of ancient life…although non-biological processes can make organic molecules, too.

The other action SAM did was ‘sniff’ the air.

When it did that, it detected methane in the air. And for the first time, we saw a repeatable pattern of methane in the Martian atmosphere. The methane peaked in the warm, summer months, and then dropped in the cooler, winter months.

On Earth, 90 percent of methane is produced by biology, so we have to consider the possibility that Martian methane could be produced by life under the surface. But it also could be produced by non-biological sources. Right now, we don’t know, so we need to keep studying the Mars!

One of our upcoming Martian missions is the InSight lander. InSight, short for Interior Exploration using Seismic Investigations, Geodesy and Heat Transport, is a Mars lander designed to give the Red Planet its first thorough checkup since it formed 4.5 billion years ago. It is the first outer space robotic explorer to study in-depth the "inner space" of Mars: its crust, mantle, and core.

Finding methane in the atmosphere and ancient carbon preserved on the surface gives scientists confidence that our Mars 2020 rover and ESA’s (European Space Agency's) ExoMars rover will find even more organics, both on the surface and in the shallow subsurface.

Read the full release on today’s announcement HERE. 

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A View into the Past

Our Hubble Space Telescope just found the farthest individual star ever seen to date!

Nicknamed “Earendel” (“morning star” in Old English), this star existed within the first billion years after the universe’s birth in the big bang. Earendel is so far away from Earth that its light has taken 12.9 billion years to reach us, far eclipsing the previous single-star record holder whose light took 9 billion years to reach us.

Though Earendel is at least 50 times the mass of our Sun and millions of times as bright, we’d normally be unable to see it from Earth. However, the mass of a huge galaxy cluster between us and Earendel has created a powerful natural magnifying glass. Astronomers expect that the star will be highly magnified for years.

Earendel will be observed by NASA’s James Webb Space Telescope. Webb's high sensitivity to infrared light is needed to learn more about this star, because its light is stretched to longer infrared wavelengths due to the universe's expansion.

What’s Up for November 2016

What’s Up for November: Venus at sunset, Jupiter at dawn, your last evening glimpse of Saturn until spring, and more meteors!

Through November 3, catch glimpses of a gibbous Venus, a crescent moon and ringed Saturn in the southwest sky just after sunset.

Wake up before sunrise every day this month to see Jupiter just above Spica, the brightest star in the constellation Virgo, shining in the east-southeast sky.

Just before dawn on November 23-24, see the waning crescent moon just above Jupiter.

November is a great time to see the constellation Ceres as it glides past Cetus, the Whale and you will be able to see the dwarf planet move relative to the background stars, but you’ll need a telescope for this one.

This month, just like last month, there will be three meteor showers--the Northern Tuarids, the Leonids and the November Orionids.

Watch the full November “What’s Up" video for more: 

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10 Questions for Our New Head of Science

Guess what?! We have a new lead for our science missions, and we’re excited to introduce him to you. Recently, NASA Administrator Charles Bolden has named Thomas Zurbuchen as the new head of our organization for science missions. Let’s get to know him...

Zurbuchen was most recently a professor of space science and aerospace engineering at the University of Michigan in Ann Arbor. He was also the university’s founding director of the Center for Entrepreneurship in the College of Engineering.

Zurbuchen’s experience includes research in solar and heliospheric physics, experimental space research, space systems and innovation and entrepreneurship.

We asked him a few questions to see what he has in store for science at NASA…let’s take a look:

1. What is your vision for science at NASA?

Right now, I am focusing on my team and I am learning how I can help them achieve the goals we have; to design and build the missions we are currently working on. Once the presidential transition is complete, we will engage in strategic activity with that team. It has been my experience that the best ideas always come from great and diverse teams working together. I intend to do that here as well.

2. What solar system destination are you most eager for NASA to explore?

Tough question to answer. Basically, I want to go where there are answers to the most important questions. One question on my mind is the origin of extraterrestrial life. Some parts of the answer to this question can be answered at Mars, some at Europa or other moons in the outer solar system like Enceladus. Other parts of the answer is around other stars, where we have found thousands of planets…some of which are amazingly similar to Earth!

3. With raw images posted to several websites from our missions, what’s one thing you hope members of the public can help NASA do with that powerful data?

I hope that people all over the world play with the data and find new ways to explore. It’s almost like hanging out in the most amazing libraries talking about nature. Many of the books in this library have never been opened and curious minds can find true treasures in there. I know that there are over a billion data-products NASA is making available about the Earth – it’s a treasure chest!

4. In your opinion, what big science breakthrough from the past informs missions of today?

In science, everything we do builds on successes and also failures of the past. Sometimes we forget our failures or near-failures, which tend to teach us a lot about what to do and what not to do. One of my favorite stories is about the Explorer 1 mission: first they observed almost nothing, until they realized that there was so much radiation that the detectors were chocking. The Van Allen Probes is a mission that are conducting the best exploration today of these radiation belts, discovered by Explorer 1. Our exploration history is full of stories like that.

5. Behind every pretty space image is a team of scientists who analyze all the data to make the discovery happen. What do you wish the public knew about the people and work that goes into each of those pretty pictures?

I wish people knew that every picture they see, every data-set they use, is a product of a team. One of the most exhilarating facts of working in space is to be able to work in teams composed of some of the nicest and most interesting people I have ever met. There are some super-famous people I run with every time we are in the same town, others who like to play music and listen to it, and some who have been in space or climbed mountains.

6. If you were a member of the public, what mission events in the next year would you be most excited about?

The public’s lives will be directly affected by our missions in our Earth Science portfolio. Some of them are done together with NOAA, our sister agency responsible for forecasts. For example, GOES will feature a lightning detector that will enable better predictions of storms. We are also launching CYGNSS in December. This NASA mission, composed of 8 spacecraft will provide unique and high-resolution data designed to provide a deeper understanding and better prediction for hurricanes globally.

7. NASA science rewrites textbooks all the time. What do you hope the kids of tomorrow will know as facts that are merely hypothesis today?

I hope they will know about life elsewhere. They will learn how life evolves, and where there is life today.

8. NASA has explored planets within our solar system. With the launch of the James Webb Space Telescope in 2020, what do you hope we learn about distant worlds?

James Webb is going to allow us to go back in time and look at the first stars and first galaxies. This is something we have never seen – we can only guess what will happen. James Webb is going to allow us to look at many, many more planets around other stars and will allow us to start doing the kind of research that links to the question about how habitable life is there.

9. What sort of elements make for an exciting new science discovery? What do you hope is the next big discovery?

Almost always, an exciting discovery is a surprise. Sometimes, discoveries happen because we are looking for something totally different. The biggest discoveries are the ones that change everything we thought before. All of a sudden, nature wags the finger at us and says “you are wrong!” That is how you know you are up to something new.

I hope the next big discovery tells us about the origin of the 95% of the universe we don’t know enough about. We call these 95% “Dark Energy” and “Dark Matter”, but – to be honest – we really don’t know. So, we are today living in a time where we know with 100% certainty that we don’t know what makes up 95% of our universe.

10. In your opinion, why should people care about the science at NASA?

They should care because we improve and protect lives on Earth. They should also care because we make the world we live in bigger. This is because we find things out we never knew, which creates new opportunities for humankind. Some of these opportunities are near-term – they are patents, innovations, companies or great educations. But, some of them are long-term – they change how we think about life itself.

Stay updated on science at NASA and Dr. Thomas Zurbuchen by following him on Twitter: @Dr_ThomasZ

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Benefits To Humanity

How does research in space help life on Earth? That’s a great question! It seems crazy that a laboratory orbiting about 200 miles over us can have a benefits on science on the ground. Here are a few ways that research aboard the International Space Station benefits humanity:

Improve Human Health

The space station has supported research that supports areas such as aging, trauma, disease and the environment. Advances in human health have been gained from the unique microgravity environment.

For example, crew aboard the station experience issues such as bone loss while in space. Learning about the causes and understanding the treatments can help the elderly or people prone to Osteoporosis here on Earth.

Are you Asthmatic? Crew aboard the space station use a tool that could be used for Asthma patients. The lightweight, easy-to-use device is used to monitor levels of asthma control and the efficiency of medication. This leads to more accurate dosing, reduced attacks and improved quality of life.

Drinkable water on the space station isn’t something just sitting in water bottles waiting to be consumed. Since storage and weight are limited in transporting things to space, crew members must recycle old, dirty water and reuse it day after day. The technology they use for this on the space station, can also be used in at-risk areas on Earth that don’t have access to clean water.

Earth Observations

The International Space Station has a unique vantage point for observing Earth’s ecosystems. A wide variety of payloads can be attached to the station’s exterior to collect data on things like: global climate, environmental change and natural hazards.

Farming from Space

Farmers can leverage images from the International Space Station to grow crops. The camera captures frequent images of Earth in visible and infrared light, that helps farmers monitor crop growth for disease or fertility differences.

From NASA to Napa. Some of the research on the space station has even provided benefits to the wine industry on Earth! Solutions for growing crops in space translates really well to solutions for mold prevention in wine cellars and other confined spaces on Earth.

For many other ways that research on the International Space Station benefits life on Earth, go HERE.

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5 Ways NASA Technology is Shaping the Transportation of Tomorrow

We have always been in the transportation business, whether launching astronauts to the Moon or improving airplanes to make them fly faster and safer on less fuel. And whether directly – like more aerodynamic wings for passenger jets – or indirectly – like more comfortable driver seats in sedans – this is yet another way our innovations benefit the public.

Today, the world of transportation is on the brink of some big changes. Drones are poised to make more efficient deliveries, crop surveillance and even disaster relief efforts. Taxis may soon take to the skies as well. And self-driving cars are ever closer to reality.

As we release our latest edition of NASA Spinoff, our yearly publication that celebrates the many ways our technology helps people on Earth, let’s take a closer look at some ways we’re helping augment transportation — and keeping everyone on the roads and in the skies safe.

1. Better data for driverless navigation

If cars are going to drive themselves, they need to be able to “see” and assess the world around them, from other cars to pedestrians and bicyclists to a construction cone in the road. This is accomplished with the help of 3D cameras, or light detection and ranging (lidar), which sends out laser pulses and calculates where obstacles are by how long it takes that laser to bounce back.

But that, says engineer Farzin Amzajerdian at our Langley Research Center, is like building a 3D picture one pixel at a time. Instead, a new kind of lidar grabs a full array of pixels all at once. This “flash lidar” is faster and, because it has fewer moving parts, more reliable. It sailed through initial tests for possible use on a future Moon lander, and our partner has also sold the technology to a major car parts manufacturer, for autonomous cars. 

2. Opening the airspace for drones

Air traffic control has largely been a human operation so far, with people in control towers actively directing all 50,000 or so flights daily across the United States. But add in drones, and humans won’t be able to keep up: experts estimate there will soon be millions of aircraft in flight every day.

We’re helping automate and streamline flight control, working with the Federal Aviation Administration (FAA) and private companies to build the new technology needed to manage the anticipated challenges. Among other advances as a result, one company has built a platform used at airports, by air traffic controllers, and by drone operators around the world to more easily file flight plans, view the airspace, get clearance in restricted areas and more.

3. Software modeling for air taxis

It may sound like something from the Jetsons, but real people are imagining the technology needed to make flying taxis a thing. And they’re probably not going to look anything like the passenger planes that we’re used to.

But when you start with a totally new design, there are all sorts of variables, including how much it will weigh. When it comes to flying, weight is a critical factor. For one thing, a heavier craft needs more fuel, but more fuel makes it even heavier. And all that weight stresses the structure, which means reinforcing it (more weight again!). Do it wrong, and all these factors cycle endlessly until you have something too heavy to get off the ground.

New software, designed with our help, generates fast and accurate weight estimates of novel aircraft designs, helping engineers figure out what works and how to make it better. Among other customers? UberElevate, which is trying to take rideshares to the skies.

4. More nimble hand controls

We’ve even played a part in improving different kinds of joysticks, for everything from planes and video games, over the years. We had to because—especially in the early days of space travel—spacesuits were pretty unwieldy under the high g forces of launch and re-entry, so we needed to develop easy-to-use hand controls.

One former astronaut, Scott Parazynski, had acquired a wealth of experience training on and using NASA joysticks for jobs like maneuvering the International Space Station’s robotic arm. He realized similar technology could have even more of an impact on Earth. Parazynski, who is also a medical doctor, envisions improving robotic surgery with the new joystick he created; in the meantime, it’s already on the market for drones, making it easier than ever to use them to record aerial video, inspect a gas pipeline or even assess damage after a hurricane.

5. Helping farmers get the full picture

The “bird’s-eye view” is an expression for a reason: flying overhead provides a perspective you just can’t get with two feet planted on the ground. For the first time ever, we are going to get that bird’s eye view on Mars, and the same expertise that got us there is also giving farmers a new way to keep track of their crops.

The Mars Helicopter is poised to hitch a ride to the Red Planet with our latest rover, Perseverance, later this year. Designing it was a challenge: because there is so little air to provide lift on Mars, we needed something incredibly light (less than four pounds!) with large rotors that spin incredibly fast (nearly 3,000 times per minute).

We teamed up with a company we’ve worked with in the past on high-altitude, solar-powered, unmanned flyers. That company had something else in the works, using the same expertise: a drone equipped with two high-res cameras to capture images of crops as it flies overhead. The data from these images tells farmers where plants are thriving and where they’re not, informing them where they might need more (or less) water or fertilizer.

You can learn more about all these innovations, and dozens more, in the 2020 edition of NASA Spinoff. Read it online or request a limited quantity print copy and we’ll mail it to you!

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Subtle Lunar Eclipse

Today’s (Feb. 10) lunar activity comes in the form of a penumbral eclipse. What does that mean and how does this type differ from a total eclipse? Let’s take a look:

First off, what is a penumbra? During a lunar eclipse, two shadows are cast by the Earth. The first is called the umbra (UM bruh). This shadow gets smaller as it goes away from the Earth. It is the dark center of the eclipse shadow where the moon is completely in the shadow of the Earth.

The second shadow is called the penumbra (pe NUM bruh). The penumbra gets larger as it goes away from the Earth. The penumbra is the weak or pale part of the shadow. This occurs because the Earth is covering a portion of the sun.

Penumbral eclipses occur when only the outer shadow (the penumbra) of Earth falls on the moon’s surface. This type of eclipse is much more difficult to observe than total eclipses or when a portion of the moon passes into the umbra. That said, if you’re very observant, you may notice a dark shadow on the moon during mid-eclipse on Friday evening. You may not notice anything at all. It’s likely the moon will just look at little bit darker than normal…like this: 

Earth’s penumbral shadow forms a diverging cone that expands into space in the opposite direction of the sun. From within this zone, Earth blocks part but not the entire disk of the sun. Thus, some fraction of the sun’s direct rays continues to reach the most deeply eclipsed parts of the moon during a penumbral eclipse.

For most of North America, the penumbral eclipse will begin at moonrise (sunset) on Friday, Feb. 10 and will be obscured by evening light. Here’s a guide of when to look up:

Fun fact: Aristotle (384 – 322 BCE) first proved that Earth was round using the curved umbral shadow seen at partial eclipses. In comparing observations of several eclipses, he noted that Earth’s shadow was round no matter where the eclipse took place. Aristotle correctly reasoned that only a sphere casts a round shadow from every angle.

To learn more about lunar eclipses, visit: https://svs.gsfc.nasa.gov/11828

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What’s Up for September 2016

We won’t have a solar eclipse until Aug. 21, 2017, but observers in central Africa will see an annular eclipse, where the moon covers most but not all of the sun, on Sept. 1. Observers always need to use safe solar eclipse glasses or filters on telescopes, binoculars and cameras.

Also this month, there are two minor meteor showers, both with about 5 swift and bright meteors per hour at their peak, which will be near dawn. The first is the Aurigid shower on Sept. 1. The new moon on the first means the sky will be nice and dark for the Aurigids. 

The second shower is the Epsilon Perseids on Sept. 9. The first quarter moon sets on the 9th at midnight, just in time for the best viewing of the Perseids.

There are many nice pair-ups between the moon and planets this month. You can see the moon between Venus and Jupiter on Sept. 2, and above Venus on the 3rd, right after sunset low on the West-Southwest horizon. On the 15th the nearly full moon pairs up with Neptune, two weeks after its opposition, when the 8th planet is closest to Earth in its orbit around the sun.

Watch the full September “What’s Up” video for more: 

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Update your phones with our #CountdownToMars wallpapers, like this one, today: https://www.nasa.gov/feature/perseverance-mars-rover-wallpaper-images/

It's LANDING DAY for our Perseverance Mars Rover and her mission to search for ancient signs of life on the Red Planet!

Watch LIVE coverage today starting at 2:15pm ET (18:15 UTC):

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The Science Goals of the James Webb Space Telescope

Our James Webb Space Telescope is an epic mission that will give us a window into the early universe, allowing us to see the time period during which the first stars and galaxies formed. Webb will not only change what we know, but also how we think about the night sky and our place in the cosmos. Want to learn more? Join two of our scientists as they talk about what the James Webb Telescope is, why it is being built and what it will help us learn about the universe…

First, meet Dr. Amber Straughn. She grew up in a small farming town in Arkansas, where her fascination with astronomy began under beautifully dark, rural skies. After finishing a PhD in Physics, she came to NASA Goddard to study galaxies using data from our Hubble Space Telescope. In addition to research, Amber's role with the Webb project’s science team involves working with Communications and Outreach activities. She is looking forward to using data from Webb in her research on galaxy formation and evolution.

We also talked with Dr. John Mather, the Senior Project Scientist for Webb, who leads our science team. He won a Nobel Prize in 2006 for confirming the Big Bang theory with extreme precision via a mission called the Cosmic Background Explorer (COBE) mission. John was the Principal Investigator (PI) of the Far IR Absolute Spectrophotometer (FIRAS) instrument on COBE.  He’s an expert on cosmology, and infrared astronomy and instrumentation. 

Now, let’s get to the science of Webb!

Dr. Amber Straughn: The James Webb Space Telescope at its core is designed to answer some of the biggest questions we have in astronomy today. And these are questions that go beyond just being science questions; they are questions that really get to the heart of who we are as human beings; questions like where do we come from? How did we get here? And, of course, the big one – are we alone?

To answer the biggest questions in astronomy today we really need a very big telescope. And the James Webb Space Telescope is the biggest telescope we’ve ever attempted to send into space. It sets us up with some really big engineering challenges.

Dr. John Mather: One of the wonderful challenges about astronomy is that we have to imagine something so we can go look for it. But nature has a way of being even more creative than we are, so we have always been surprised by what we see in the sky. That’s why building a telescope has always been interesting. Every time we build a better one, we see something we never imagined was out there. That’s been going on for centuries. This is the next step in that great series, of bigger and better and more powerful telescopes that surely will surprise us in some way that I can’t tell you.

It has never been done before, building a big telescope that will unfold in space. We knew we needed something that was bigger than the rocket to achieve the scientific discoveries that we wanted to make. We had to invent a new way to make the mirrors, a way to focus it out in outer space, several new kinds of infrared detectors, and we had to invent the big unfolding umbrella we call the sunshield.

Amber: One of Webb’s goals is to detect the very first stars and galaxies that were born in the very early universe. This is a part of the universe that we haven’t seen at all yet. We don’t know what’s there, so the telescope in a sense is going to open up this brand-new part of the universe, the part of the universe that got everything started.

John: The first stars and galaxies are really the big mystery for us. We don’t know how that happened. We don’t know when it happened. We don’t know what those stars were like. We have a pretty good idea that they were very much larger than the sun and that they would burn out in a tremendous burst of glory in just a few million years.

Amber: We also want to watch how galaxies grow and change over time. We have questions like how galaxies merge, how black holes form and how gas inflows and outflows affect galaxy evolution. But we’re really missing a key piece of the puzzle, which is how galaxies got their start.

John: Astronomy is one of the most observationally based sciences we’ve ever had. Everything we know about the sky has been a surprise. The ancients knew about the stars, but they didn’t know they were far away. They didn’t know they were like the Sun. Eventually we found that our own galaxy is one of hundreds of billions of galaxies and that the Universe is actually very old, but not infinitely old. So that was a big surprise too. Einstein thought, of course the Universe must have an infinite age, without a starting point. Well, he was wrong! Our intuition has just been wrong almost all the time. We’re pretty confident that we don’t know what we’re going to find.

Amber: As an astronomer one of the most exciting things about working on a telescope like this is the prospect of what it will tell us that we haven’t even thought of yet. We have all these really detailed science questions that we’ll ask, that we know to ask, and that we’ll answer. And in a sense that is what science is all about… in answering the questions we come up with more questions. There’s this almost infinite supply of questions, of things that we have to learn. So that’s why we build telescopes to get to this fundamental part of who we are as human beings. We’re explorers, and we want to learn about what our Universe is like. 

Webb will be the world's premier space science observatory. It will solve mysteries in our solar system, look beyond to distant worlds around other stars and probe the mysterious structures and origins of our universe – including our place in it. Webb is an international project we’re leading with our partners, ESA (European Space Agency) and the Canadian Space Agency.

To learn more about our James Webb Space Telescope, visit the website, or follow the mission on Facebook, Twitter and Instagram.

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