Space Science Awesomeness at Florida Space Institute and a Reusable Rocket in the Port

Hello pretty reusable rocket stage! - May 10, 2016

I have an internal debate every time. Should I bring my baby to this professional event? Why shouldn't I? But I've never seen anyone else bring a baby. What are my options, aside from skipping the event? Will anyone actually care?

Lately, the debate has been decided by this definitive statement: “I'm about to bring a baby to a conference for three whole days. I need to get over it.”

And so, for the National Space Club's monthly luncheon, I brought my baby along with me. The guest speaker was Ray Lugo, the head of the Florida Space Institute (FSI) which I was sort of under as a graduate student at the University of Central Florida (UCF). I wasn't going to miss his talk about my grad university and colleagues!

Attendees immediately made me feel welcome as I walked through the door with Josephine in my arms. The first person I spoke with, Barry, told me that he was glad I brought her. To my surprise, three people took photos with me and her. Eddie put my unsettled mind at ease, telling me that he brought his kid to events like this when they were little. The man I sat next to even plated my salad and poured my water for me. Thank you, everyone!

She slept while I ate. Then awoke and babbled during the talk! - May 10, 2016

Ray gave an overview of FSI for those unfamiliar. This began with an overview of the professors, all of which I knew and had worked with during my time as a graduate student. Then he went over some of their current research project. First, Josh Colwell and Addie Dove's projects. Strata-1 is a regolith size distribution project launched to the International Space Station. The cubesat experiment Q-PACE is another regolith experiment to study dust dynamics in microgravity, very similar to my grad research. NanoRocks, which had just begun when I was a student, flew on ISS in 2014 with NanoRacks.

Next, Phil Metzger's projects. World is Not Enough (WINE) is a collaboration with Honeybee Robotics to develop an ISS cubesat to test in-situ resource utilization technology such as sample acquisition, volatiles capture, and 3D-printed cold gas thrusters that use water vapor. Phil is also working on developing asteroid simulants and ISRU using clay but the slides moved too quickly for me to read it all.

Ray then discussed some of Dan Britt's projects such as the development of Martian sensors and a mission called Gulliver to conduct Martian moon sample return. He also mentioned an Earth observation cubesat mission and ground-penetrating radar to study asteroids. He concluded his talk by mentioning that UCF may bid to take over the operationsof the Arecibo observatory in Puerto Rico.

Ray Lugo at the National Space Club Florida Committee luncheon - May 10, 2016

Already at Port Canaveral for the talk, I stopped by Milliken's to check out the recovered SpaceX Falcon 9 rocket stage that launch and landed on a ship in the ocean on Friday. I stepped off the sidewalk onto a little dirt path so I could get a shot with the rocks and palm frond. So cool! I love living in Florida.

A space geek, a reusable rocket, and a baby. - May 10, 2016

Thank you, National Space Club Florida Committee, for making this working mom feel welcome.

Baby at the Science Fair

For the third year, I was honored to return to my undergraduate alma mater, Florida Institute of Technology in Melbourne, to judge the space sciences senior projects. Some of these students have been working on their research for just a semester, while others have been learning and refining their project over the course of their undergraduate career. I love meeting the students and learning about their research, which does change from year to year!

I was really rushed in recording my vlog at the event, so I want to summarize the projects here. The nine that I learned about from the students' mouths today were (in the numerical order they were assigned):

The Small Extreme-Contrast Ratio Imaging Telescope which uses the charge injection device (CID) technology that I learned about when evaluating International Space Station science proposals. (A CID was approved to fly on ISS, currently scheduled for June.)

A look at the closest and brightest quasar's quirky jet as seen from the Hubble Space Telescope in optical and X-ray.

A look at why cosmic rays hitting Earth aren't isotropic but instead concentrated in one area of the sky, as seen by two neutrino detectors.

A model to understand the planetary orbital resonances of exoplanets observed by Kepler.

A model to understand the spectroscopy (energy emitted) of regolith (dirt) on planetary bodies without atmospheres, including asteroids, with a particular look at porosity (how densely packed or how many holes there are in the grains). This is one of the many steps in a project I've been assisting with.

An examination of protein fiber growth that returned from flying on the ISS, another project I learned about when I did ISS research evaluation. It was nice to learn about the results of that experiment!

A look at the magnetic field of a massive O-type star as seen from a telescope in Hawaii.

Scale testing of the mirror deployment of the James Webb Space Telescope which should launch in 2018. Got to make sure those mirrors deploy perfectly in space!

A model to understand three-body resonances in exoplanetary systems as observed by Kepler.

My co-judge, baby Josephine, was with me this year. This would be her third time on Florida Tech's campus. We attended the Showcase reception together last night. She was also on the campus of the University of Central Florida in Orlando with me yesterday. We visited the Center for Microgravity Research, my former lab, the group responsible for the payload that flew on Blue Origin recently. Baby Josephine will continue her university tour later this month when we visit Embry-Riddle Aeronautical University in Daytona Beach.

Josephine and I at UCF visiting my former lab - April 7, 2016

Josephine and I posing with the panther at FIT - April 7, 2016

My co-judge squirming out of her wrap at the Science & Engineering Showcase at FIT - April 8, 2016

COLLIDE-ing Suborbital Science with Blue Origin

I usually don’t blog on the weekend. I’m usually at the ice skating rink at this time on a Saturday. But amazing feats of science and engineering don’t limit themselves to weekday work hours. Right now, I’m geeking out to the latest successful launch and landing by private rocket company Blue Origin!

After I earned my master’s degree in high-energy astrophysics in Huntsville, I switched over to “experimental planetary science” (my phrasing) at the University of Central Florida with Dr. Josh Colwell as my advisor.

Josh was working on a number of projects, but one that caught my attention was the study of how space and planetary dust (regolith) interact at very low velocities. When the grains or clumps collide, do they stick together, bounce, break apart, or what? Most of what could do in the lab in 1 g (Earth’s gravity) was even faster than we wanted to observe. We built a drop tower in the lab to examine our experiment in microgravity, but our short tower only allowed less than a second of free fall. We wanted more. I flew on two parabolic aircraft campaigns with Josh to gain a few more seconds of microgravity per parabola. But still, we wanted more.

Josh had flown an experiment on orbit on the International Space Station, COLLIDE, Collisions Into Dust Experiment. He was preparing another version of COLLIDE to fly suborbitally on a Blue Origin experimental rocket. I was intrigued by the partnership with an emerging commercial space company. For my first year and a half in the lab, I participated in teleconferences with Blue and worked on preparing the experiment for launch. The engineering students on our team did most of the work, but I was pleased and excited to participate in any way I could.

A COLLIDE box in foreground, the original COLLIDE in background, and me recording something. - February 2011

But in 2011, Blue Origin’s test rocket malfunctioned and was destroyed. Our chance to fly COLLIDE with Blue was postponed indefinitely. We were all disappointed, but that’s the way it works in the space industry. This stuff is hard and set-backs happen.

I’ve been out-of-the-loop with the experiment since leaving UCF. But yesterday, I heard the exciting news that COLLIDE would launch soon. And this morning, it did just that. Blue Origin’s rocket New Shepard launch and landed successfully in Texas.

We’re all currently awaiting the release of the official video of the successful test. I’m awaiting news of how my grad school team’s experiment fared. Knowing first-hand just how tricky those experiment boxes can be, I’m crossing fingers and hoping for the best.

The official Blue Origin COLLIDE video can be seen here:

I will update this entry with the official Blue Origin rocket video once it’s published. But first, ice skating.

Relativity, Engaging Scientists in Policy, and the US Commercial Space Industry

I've fallen behind in writing about the awesome space and science talks that I've attended in the past week! Now seems like a good time to catch up and let you all know about some cool happenings.

Relativity

Drs. Jeffrey Bennett and Dan Batcheldor - September 25, 2015 

On Friday evening, unrelated to but coinciding perfectly with a student career preparation conference that I helped with, I attended Florida Institute of Technology's monthly public science lecture series with Dr. Jeffrey Bennett who last year published the book What Is Relativity? I enjoyed conversing with my former professors prior to the talk and ended up unexpectedly taking a front row seat. I'm glad that I did!

Overall, I found the couch-sitting interview-style talk to be informative, entertaining, and even humorous, not what one would expect for a physics talk! I have the advantage of a doctoral-level education in physics and an interest in relativity since high school, so the concepts discussed were well known to me. I could focus instead on the presentation style and perspectives. I was surprised and even amused by the analogous scenarios presented to explain some of the mind-bending curiosities of relativity.

I did not previously know that 2015 is the International Year of Light. It has been approximately 100 years since Einstein's publications on relativity. One of Jeff Bennett's goals is to address the misconceptions about space and relativity. One misconception, a personal pet peeve of mine that my own employer is guilty of, is being too casual with wording by stating or implying that there is no gravity in space. There is always gravity in space, anywhere in space, though gravitational pulls may cancel to a net gravity of zero.

Other misconceptions stem from the fact that when it comes to relativity, we don't have any common sense. We have never traveled at relativistic speeds. Similar to quantum mechanics, it's hard to wrap our minds around something that we don't have any direct experience with. Yet relativity does affect us every day. For example, navigational satellites such as GPS use relativity in their calculations. We've been testing relativity since the Michelson–Morley experiment in 1887. I and countless other physics students have replicated this experiment in physics labs.

One interesting point was that humans don't like being told what we can and cannot do. Relativity tells us that we can't go faster than the speed of light c. We immediately try to figure a way around this. Science fiction writers usually don't even try to break c; instead they speculate about loopholes such as inter-dimensional travel.

The conversation covered gravitational lensing, black holes, determinism, multiverses, and the “theory of everything.” One funny moment came when the speaker stated, “I don't like determinism and I don't know why,” and the moderator responded, “You have no choice.” Ah, geek humor.

I was the first in line to ask a question clarifying Stephen Hawking's latest black hole theory. I was also the only female to ask a question in a long line of curious males. I did see a few female students approach the speaker after the talk, as if they were interested but didn't want to stand up to be heard. Come on ladies, let's show the world that we have brains and mouths!

Engaging Scientists and Engineers in Policy

On Tuesday I attended an American Association for the Advancement of Science webinar on Engaging Scientists and Engineers in Policy by Dr. Rush Holt, a physicist, the CEO of AAAS, and former New Jersey Congressman. The title of this talk was mislabeled, or otherwise their wasn't much meat in the talk about the topic at hand.

The majority of the presentation was lamenting the lack of science understanding in the general public, which I can totally get behind. The speaker was preaching to the choir, in my opinion. He would often slip economics understanding into the discussion, which seemed out of place, but was obviously on his mind. One of my PhD economist husband's biggest pet peeves is when non-economists act like authorities on economics while ignoring or dismissing actual experts. It is the same in science.

Two of the speaker's biggest concerns were students and news media. Both are not taught well how to ask for evidence but instead take what is presented to them at face value, blindly believing it. I see this all the time in the general public, even among my friends. A celebrity, a trend-setter, or a seeming authority makes a statement or writes an article (or blog post!) about a scientific topic and, without doing any research of their own, people blindly believe it. It's no wonder that scientific understanding in our culture is so poor when even our own journalists don't investigate to make their own conclusions. This is the information age and the world is at our fingertips – use it!

Approximately five minutes of the 45 minute talk was actually dedicated to what scientists/engineers can do in policy. The advice: take on a fellowship to work a temporary position in Capitol Hill. I've been hearing this advice since graduate school and it's so disconnected from reality. Science-trained politicians and staffers are a fantastic asset to our government and policy-makers, but the vast majority of scientists are not able to pause their lives, disrupt their families, and move to Washington, D.C. for a year (the term period for most of these fellowships). This just isn't feasible for 99.99% of scientists, so what is the advice for the rest of us?

The biggest take-away from the talk was that we as scientists can help others learn to question. Science is within everyone's grasp and isn't just for experts. Anyone can ask Why? How? What is the evidence? If someone has a misconception about science, ask them probing questions about what evidence was used to come to that conclusion. Make them think. This advice wasn't really relevant to the talk's topic, but still very good advice.

US Commercial Space Industry

Dr. Roger Handberg - September 30, 2015

Yesterday, coinciding well with a university mentorship program that I participated in on campus later that day, I hung out with some of my former professors and colleagues at the University of Central Florida for the Florida Space Institute's lecture series. The talk was by Dr. Roger Handberg, a political science professor. The topic: US commercial space industry.

Overall, the speaker gave a good historical overview of the public-private partnerships in the US space industry. More recent happenings and analysis is where the speaker got a little stuck with lack of knowledge and mixed up a few things. His assessments were very pessimistic, which is actually a refreshing counter to the rah-rah advocacy so prevalent in the space industry. I don't agree with all of his negative outlooks, especially in the areas where his information is lacking, but my skeptical scientist side did appreciate the alternative perspective.

He began by speaking about the decline in government funding in the space program and how that decline is stressing private industry, generally speaking and not mentioning any particular government cuts. He didn't give figures, but I'm curious to know what they are. If a reader could point me in the right direction, I'd appreciate it.

He went over some recent difficulties in the industry, such as the Virgin Galactic, Orbital Sciences, and SpaceX accidents. He also discussed the current challenges with politics forcing ULA to replace its Russian RD-180 engine. With ULA phasing out Atlas V and most of Delta IV, and with the Blue Origin BE-4 engine replacement still in development, he worried that SpaceX may become a national monopoly for government launches. I think that this is highly unlikely, but time will tell.

He spoke about some of the more successful space applications, such as communication, navigation, and remote sensing satellites. Historically, I did not realize that denial of satellite imagry to adversaries during wartime was an actually strategy that the US military used. He said that it's harder to do now with so much Earth observation competition. He also touched upon some of the challenges in the satellite industry that I'm less familiar with such as the limited number of receivers and spectrum interference.

The bottom line is that the cost to orbit is still the number one problem in the space industry. Spacecraft reusibility may lower cost significantly but is very difficult to achieve. High cost holds back tourism, as well as safety concerns and the lack of reliable transportation. State spaceports have popped up all over due to increased popularity and enthusiasm after the 2004 SpaceShipOne X-Prize win, but lack of progress and high cost hinders the industry. Space manufacturing and space mining isn't economically feasible due to high launch costs. The economics doesn't work unless the industry is government subsidized, he said. It wasn't a positive outlook on the industry, but probably more realistic than many would admit.

Buried Ancient Worlds Uncovered from Space - Space Archaeology!

Getting to downtown Orlando from the coast is not an easy drive for me, but I wasn't going to pass up the chance to miss this talk, sponsored by my doctoral university. I don't mention it much, but since childhood, I've been an Egyptology geek. I named my childhood cat Cleopatra and my grad school cat (still living) Nefertiti. I even considered ancient Egyptian names for my child. Around my house, you'll a spot Bastet statuette, an ankh mirror, and I just splurged on an Isis wall plaque (the goddess, not the terrorist group). Since childhood, it has been my desire to learn some basic hieroglyphics and visit the ancient sites of Egypt, though the turmoil in that part of the world makes that goal so difficult.

I saw a lecture by Dr. Sarah Parcak at the National Space Science & Technology Center when I lived in Huntsville 7 or 8 years ago. Most lectures go in one ear and out the other, but I remember this one. Her team uses satellite imagery and remote sensing techniques to discover previously unknown archaeological sites. From that talk years ago (unless I'm getting it confused with another), she even described how she can mark how the Nile River has changed position over time.

A Digital Revolution: Archaeology from Space by Sarah Parcak - September 23, 2015

Sarah Parcak began her talk last night by giving us good news: increased number of remote sensing satellites and improvements in the technology to lower costs have removed barriers to entry for her work. Imagery resolution has increased and image processing techniques have been improved, but there are more improvements to be made. Her advice to students: fail continuously to finally learn what works. I can relate to that advice.

Using a combination of image analysis, spectroscopy (I assume that's what's meant by chemical signatures), and lidar via satellites and aircraft, she is able to locate and identify previously unknown buried structures. She displayed a picture of rectangles and called them tombs, easily identifiable by their shape. She described the differences in moisture signatures and topography in Egyptian sites compared to the surrounding environment. Lidar can model the ground terrain through trees. Stunted roots in vegetation are another indicator of a buried structure. Satellite and aircraft work complement ground work.

She pointed to another image and explained that she can identify palaces and other residential areas. From understanding that higher class individuals would live closer to the palace, she can infer ancient class systems and how those people lived and worked.

Pointing out the details from the satellite imagery - September 23, 2015

It's impossible to know how many unknown sites in Egypt are left to discover, but if I heard her right, she estimates that only 0.001% are known! Her map of possible newly discovered sites in Egypt is extensive, far more than she can possible explore. Although her focus is primarily Egypt, she also works in other areas of the world such as Romania, Italy, Jordan, Viking territory, and even Alabama where she's based.

Looting and urban growth are a big problem. Looters use the same technology as she does to identify sites and profit from black market sales. As cities expand, unprotected ancient sites can become damaged in the growth. She advised that anyone who wants to see these sites should go now. I wish that I could!

Her work is inspirational to me. I spent my astronomy research years remotely sensing outward and my latter time at CASIS focusing on Earth observation remote sensing from the International Space Station for terrestrial benefit primarily for business/commerce. Space archeology is an application of space technology to inform of us our own human past. I can totally get behind that.

Terrestrial and Extraterrestrial Sloooooow Impacts: My Time at UCF

Today's travels brought me to the University of Central Florida in Orlando where I conducted my doctoral work. I met with my former advisor, Dr. Josh Colwell and several other professors of the Planetary Sciences group in the Physics Department. I took a tour of my own former lab and got to see what new projects the lab group is working on. I was tickled to see that two of my old conference posters still hung on the walls. Such memories!

I started grad school at UCF in January 2010 after gaining my master's degree from the University of Alabama in Huntsville. Up to that point, all of my research had been astrophysics analysis. I had obtained astronomy data from space telescopes and processed that data to make sense of what we were observing. I didn't do observational astronomy myself, so I didn't have the experience of doing any hands-on research.

I could have gotten involved in telescope operation, but instead I decided to try something a bit more alien. I went into experimental planetary science using analog dirt (regolith), reduced gravity, and low pressure in vacuum chambers to transform a terrestrial experiment into simulated extraterrestrial.

My heart has always been on the Moon, so Josh's research appealed to me. He examined low velocity impacts on planetary body surfaces. At the time I began at UCF, NASA's Constellation Program was in motion and so much research was being focused on lunar science. When the direction of NASA's human exploration program became less clear, the research was broadened to any kind of planetary body with a dust or soil surface. The research was also useful for studying the interactions of dust particles in space, such as the early formation of planets or planetary rings. Earth is also a planet, so the research was also translatable to Earth surface impact models.

Much of my research at UCF was focused on the continuation of an impact experiment which involved dropping marbles into granular materials such as small beads, fake lunar regolith, and fake Mars regolith. These experiments were often conducted in a vacuum chamber that was depressurized to minimize air molecule interactions and mimic a space environment. The small heights that the marbles were dropped didn't allow for much speed to build up. We wanted the impacts to be as slow and low energy we could make them.

To get even slower impact speeds, we build a drop tower in the lab. Using the same principle as a roller coaster or amusement park drop ride, drop towers allow for moments of microgravity while the canister is free falling. Our small drop tower gave us less than a second of microgravity, but that was enough. We used light springs to push the marble into the regolith at velocities lower than what we could achieve with a tabletop experiment. To obtain even longer periods of microgravity for our experiments, we used parabolic "ZeroG" aircraft. Last September, they even put an experiment on the International Space Station.

The splash from the impact and the resulting ejecta (ejected particles) informed us about the way that regolith acts. We want to understand how much ejecta is kicked up, how far it spreads, how fast it travels, the tendency for the regolith to be cohesive and stick together, how differently the regolith acts if it's packed more densely, and other characteristics. In more advanced versions of the experiment, a clump of regolith impacted with a regolith surface or two clumps of regolith impacted each other, all at very slow speeds.

Much research has been done to study high velocity impacts, but low velocities impacts have been largely ignored because they're harder to do. By looking at the boundary between whether splash happens or doesn't happen from an impact, we can understand how impact energy is distributed in a material. By throwing clumps together at slow speeds, we can understand when two clumps in space may hit and stick together, forming a larger clump, or hit and break apart, forming pieces, or maybe even just hit and bounce off each other unharmed. Understanding how bodies are formed in space helps us to understand how Earth came to be.

 

I researched at UCF until I obtained a job at CASIS two years ago this March. I also took classes and completed all the requirements for a doctorate in physics except for the dissertation and the defense. This is a topic for a separate entry, but it was the right decision for me to move forward in my career. I accomplished what I had set out to accomplish, learned a ton, and lived some great experiences. I also got my hands dirty for a little while!