Thursday, October 31, 2024
L.A. Is the King of the Baseball World Once Again!
Major League Baseball
Happy Halloween, everyone! Last night, the Los Angeles Dodgers defeated the New York Yankees, 7-6, in Game 5 of the World Series...winning their second championship in five years!
The latest Major League Baseball title is the 8th in Dodgers franchise history, and comes after Freddie Freeman, Shohei Ohtani, Mookie Betts, Walker Buehler, Yoshinobu Yamamoto and company emerged victorious from a series that was the 12th matchup with the Yankees since 1941. Before this year's Fall Classic, Los Angeles and New York last clashed in 1981—with the late and great Fernando Valenzuela helping the Dodgers to win the championship that October.
As for the World Series' Most Valuable Player trophy, Freddie Freeman won the award...after he immediately became a legend hitting that walk-off grand slam to seal a Game 1 victory against the Yanks on October 25th.
It's so awesome for the City of Angels to become the City of Champions once more! Hopefully, Shohei will come close to winning the additional nine titles that he wanted after clinching his first with the Dodgers last night; Mookie Betts will tie Yankees legend Derek Jeter with two more World Series rings (Betts now has three—two with the Dodgers and one with the Boston Red Sox), and Yankees left fielder and power hitter Juan Soto (who's now a free agent) will sign with Los Angeles in the offseason.
Okay, I'm not holding my breath on that last one with Soto. Go Dodger Blue!
Major League Baseball
Major League Baseball
Major League Baseball
Wednesday, October 30, 2024
The Latest Update on America's Next Great Observatory...
NASA / JPL - Caltech
NASA Successfully Integrates Coronagraph for Roman Space Telescope (News Release - October 28)
The instrument will demonstrate advanced hardware for studying Earth-size planets with the right conditions for life.
NASA’s Nancy Grace Roman Space Telescope team has successfully completed integration of the Roman Coronagraph Instrument onto Roman’s Instrument Carrier, a piece of infrastructure that will hold the mission’s instruments, which will be integrated onto the larger spacecraft at a later date. The Roman Coronagraph is a technology demonstration that scientists will use to take an important step in the search for habitable worlds and, eventually, life beyond Earth.
This integration took place at NASA’s Goddard Space Flight Center in Greenbelt, Maryland, where the space telescope is located and in development. This milestone follows the coronagraph’s arrival at the center earlier this year from NASA’s Jet Propulsion Laboratory in Southern California, where the instrument was developed, built and tested.
The Roman Coronagraph Instrument is a technology demonstration that will launch aboard the Nancy Grace Roman Space Telescope, NASA’s next flagship astrophysics mission. Roman will have a field of view at least 100 times larger than the agency’s Hubble Space Telescope and explore scientific mysteries surrounding dark energy, exoplanets and infrared astrophysics. Roman is expected to launch no later than May of 2027.
The mission’s coronagraph is designed to make direct observations of exoplanets, or planets outside of our Solar System, by using a complex suite of masks and active mirrors to obscure the glare of the planets’ host stars, making the planets visible. Being a technology demonstration means that the coronagraph’s goal is to test this technology in space and showcase its capabilities. The Roman Coronagraph is poised to act as a technological stepping stone, enabling future technologies on missions like NASA’s proposed Habitable Worlds Observatory, which would be the first telescope designed specifically to search for signs of life on exoplanets.
“In order to get from where we are to where we want to be, we need the Roman Coronagraph to demonstrate this technology,” said Rob Zellem, Roman Space Telescope deputy project scientist for communications at NASA Goddard. “We’ll be applying those lessons learned to the next generation of NASA flagship missions that will be explicitly designed to look for Earth-like planets.”
A Major Mission Milestone
The coronagraph was successfully integrated into Roman’s Instrument Carrier, a large grid-like structure that sits between the space telescope’s primary mirror and spacecraft bus, which will deliver the telescope to orbit and enable the telescope’s functionality upon arrival in space. Assembly of the mission’s spacecraft bus was completed in September.
The Instrument Carrier will hold both the coronagraph and Roman’s Wide Field Instrument, the mission’s primary science instrument, which is set to be integrated later this year along with the Roman telescope itself. “You can think of [the Instrument Carrier] as the skeleton of the observatory, what everything interfaces to,” said Brandon Creager, lead mechanical engineer for the Roman Coronagraph at JPL.
The integration process began months ago with mission teams from across NASA coming together to plan the maneuver. Additionally, after its arrival at NASA Goddard, mission teams ran tests to prepare the coronagraph to be joined to the spacecraft bus.
During the integration itself, the coronagraph, which is roughly the size and shape of a baby grand piano (measuring about 5.5 feet, or 1.7 meters across), was mounted onto the Instrument Carrier using what’s called the Horizontal Integration Tool.
First, a specialized adapter developed at JPL was attached to the instrument, and then the Horizontal Integration Tool was attached to the adapter. The tool acts as a moveable counterweight, so the instrument was suspended from the tool as it was carefully moved into its final position in the Instrument Carrier. Then, the attached Horizontal Integration Tool and adapter were removed from the coronagraph.
The Horizontal Integration Tool has previously been used for integrations on NASA’s Hubble and James Webb Space Telescope.
As part of the integration process, engineers also ensured that blanketing layers were in place to insulate the coronagraph within its place in the Instrument Carrier. The coronagraph is designed to operate at room temperature, so insulation is critical to keep the instrument at the right temperature in the cold vacuum of space. This insulation will also provide an additional boundary to block stray light that could otherwise obscure observations.
Following this successful integration, engineers will perform different checks and tests to ensure that everything is connected properly and correctly aligned before moving forward to integrate the Wide Field Instrument and the telescope itself. Successful alignment of the Roman Coronagraph’s optics is critical to the instrument’s success in orbit.
This latest mission milestone is the culmination of an enduring collaboration between a number of Roman partners, but especially between NASA Goddard and JPL.
“It’s really rewarding to watch these teams come together and build up the Roman observatory. That’s the result of a lot of teams, long hours, hard work, sweat and tears,” said Liz Daly, the integrated payload assembly integration and test lead for Roman at Goddard.
“Support and trust were shared across both teams... We were all just one team,” said Gasia Bedrosian, the integration and test lead for the Roman Coronagraph at JPL. Following the integration, “we celebrated our success together,” she added.
Source: Jet Propulsion Laboratory
****
NASA / Sydney Rohde
Monday, October 28, 2024
A Gorgeous View from Jezero Crater on Mars...
NASA / JPL - Caltech / ASU / MSSS
NASA’s Perseverance Rover Looks Back While Climbing Slippery Slope (News Release)
On its way up the side of Jezero Crater, the agency’s latest Red Planet off-roader peers all the way back to its landing site and scopes the path ahead.
NASA’s Perseverance Mars rover is negotiating a steeply sloping route up Jezero Crater’s western wall with the aim of cresting the rim in early December. During the climb, the rover snapped not only a sweeping view of Jezero Crater’s interior, but also imagery of the tracks that it left after some wheel slippage along the way.
Stitched together from 44 frames acquired on September 27, the 1,282nd Martian day of Perseverance’s mission, the image mosaic features many landmarks and Martian firsts that have made the rover’s 3½-year exploration of Jezero so memorable, including the rover’s landing site, the spot where it first found sedimentary rocks, the location of the first sample depot on another planet, and the final airfield for NASA’s Ingenuity Mars Helicopter. The rover captured the view near a location that the team calls “Faraway Rock,” at about the halfway point in its climb up the crater wall.
“The image not only shows our past and present, but also shows the biggest challenge to getting where we want to be in the future,” said Perseverance’s deputy project manager, Rick Welch of NASA’s Jet Propulsion Laboratory in Southern California. “If you look at the right side of the mosaic, you begin to get an idea what we’re dealing with. Mars didn’t want to make it easy for anyone to get to the top of this ridge.”
Visible on the right side of the mosaic is a slope of about 20 degrees. While Perseverance has climbed 20-degree inclines before (both NASA’s Curiosity and Opportunity rovers had crested hills at least 10 degrees steeper), this is the first time it’s traveled that steep a grade on such a slippery surface.
Soft, Fluffy
During much of the climb, the rover has been driving over loosely-packed dust and sand with a thin, brittle crust. On several days, Perseverance covered only about 50% of the distance that it would have on a less slippery surface, and on one occasion, it covered just 20% of the planned route.
“Mars rovers have driven over steeper terrain, and they’ve driven over more slippery terrain, but this is the first time one had to handle both — and on this scale,” said JPL’s Camden Miller, who was a rover planner, or “driver,” for Curiosity and now serves the same role on the Perseverance mission. “For every two steps forward Perseverance takes, we were taking at least one step back. The rover planners saw this was trending toward a long, hard slog, so we got together to think up some options.”
On October 3, they sent commands for Perseverance to test strategies to reduce slippage. First, they had it drive backward up the slope (testing on Earth has shown that under certain conditions the rover’s “rocker-bogie” suspension system maintains better traction during backward driving). Then they tried cross-slope driving (switchbacking) and driving closer to the northern edge of “Summerland Trail,” the name that the mission has given to the rover’s route up the crater rim.
Data from those efforts showed that while all three approaches enhanced traction, sticking close to the slope’s northern edge proved the most beneficial. The rover planners believe the presence of larger rocks closer to the surface made the difference.
“That’s the plan right now, but we may have to change things up the road,” said Miller. “No Mars rover mission has tried to climb up a mountain this big this fast. The science team wants to get to the top of the crater rim as soon as possible because of the scientific opportunities up there. It’s up to us rover planners to figure out a way to get them there.”
Tube Status
In a few weeks, Perseverance is expected to crest the crater rim at a location that the science team calls “Lookout Hill.” From there, it will drive about another quarter-mile (450 meters) to “Witch Hazel Hill.” Orbital data shows that Witch Hazel Hill contains light-toned, layered bedrock.
The team is looking forward to comparing this new site to “Bright Angel,” the area where Perseverance recently discovered and sampled the “Cheyava Falls” rock.
The rover landed on Mars carrying 43 tubes for collecting samples from the Martian surface. So far, Perseverance has sealed and cached 24 samples of rock and regolith (broken rock and dust), plus one atmospheric sample and three witness tubes. Early in the mission’s development, NASA set the requirement for the rover to be capable of caching at least 31 samples of rock, regolith and witness tubes over the course of Perseverance’s mission at Jezero.
The project added 12 tubes, bringing the total to 43. The extras were included in anticipation of the challenging conditions found at Mars that could result in some tubes not functioning as designed.
NASA decided to retire two of the spare empty tubes because accessing them would pose a risk to the rover’s small internal robotic sample-handling arm needed for the task: A wire harness connected to the arm could catch on a fastener on the rover’s frame when reaching for the two empty sample tubes.
With those spares now retired, Perseverance currently has 11 empty tubes for sampling rock and two empty witness tubes.
Source: Jet Propulsion Laboratory
****
Sunday, October 20, 2024
Photos of the Day: Capturing Comet Tsuchinshan–ATLAS Images for the Third and Final Time...
Richard T. Par
Yesterday, I drove back to Diamond Bar's Summitridge Park in California to take one final group of photos of comet C/2023 A3 (Tsuchinshan–ATLAS).
I originally went to Summitridge Park for a third attempt last Friday, October 18, but showed up a bit later than I should have (around 7:30 PM, PDT) since I ate dinner at home beforehand. The marine layer coming in from the Pacific Ocean (43 miles away) was already obscuring much of the sky across Los Angeles County from my vantage point at Summitridge...making it more difficult for me to spot the increasingly-faint comet.
I arrived at the park a few minutes before 7 PM, PDT last night (sunset was at 6:11 PM, PDT), and as shown with the images that I've included with this post, Tsuchinshan–ATLAS is becoming less and less visible as it moves away from Earth. The comet, once it disappears from view at the end of this month, won't return to our inner Solar System for another 80,000 years.
Here are the settings on my Nikon D3300 DSLR camera for yesterday's cosmic photoshoot:
Lens: 70-300mm Nikon telephoto lens
ISO: 400 to 800
F-stop: f/5.6
Shutter speed: 2.5 seconds
Live View mode on my LCD screen used instead of the viewfinder
Hope you guys were able to spot Tsuchinshan–ATLAS over the past few weeks as well! Happy Sunday.
Richard T. Par
Richard T. Par
Richard T. Par
Tuesday, October 15, 2024
Photos of the Day: Comet Tsuchinshan–ATLAS Pictures That I Took Last Night...
Richard T. Par
As promised in my Blog entry last Saturday, I went back to Diamond Bar's Summitridge Park in California yesterday to take more photos of comet C/2023 A3 (Tsuchinshan–ATLAS)!
Comet Tsuchinshan–ATLAS was a bit higher in the sky on October 14, and was more visible than on October 12 since the celestial body was no longer caught in the glare of the Sun as it set below the horizon.
Here are the settings on my Nikon D3300 DSLR camera for last night's cosmic photoshoot:
Lens: 70-300mm Nikon telephoto lens
ISO: 400 to 800
F-stop: f/4.5
Shutter speed: 4 seconds
Live View mode on my LCD screen used instead of the viewfinder
Will I head back out one last time to see this comet before it disappears from our skies for the next 80,000 years? We'll see.
I already took care of FOMO (Fear Of Missing Out) with my two trips to Summitridge Park. Happy Tuesday!
Richard T. Par
Richard T. Par
Richard T. Par
Richard T. Par
Richard T. Par
Monday, October 14, 2024
America's Next Jupiter-bound Orbiter Has Finally Departed from Earth!
SpaceX
Liftoff! NASA’s Europa Clipper Sails Toward Ocean Moon of Jupiter (Press Release)
NASA’s Europa Clipper has embarked on its long voyage to Jupiter, where it will investigate Europa, a moon with an enormous subsurface ocean that may have conditions to support life. The spacecraft launched at 12:06 p.m. EDT on Monday aboard a SpaceX Falcon Heavy rocket from Launch Complex 39A at NASA’s Kennedy Space Center in Florida.
The largest spacecraft that NASA has ever built for a mission headed to another planet, Europa Clipper is also the first NASA mission dedicated to studying an ocean world beyond Earth. The spacecraft will travel 1.8 billion miles (2.9 billion kilometers) on a trajectory that will leverage the power of gravity assists, first to Mars in four months and then back to Earth for another gravity assist flyby in 2026. After it begins orbiting Jupiter in April 2030, the spacecraft will fly past Europa 49 times.
“Congratulations to our Europa Clipper team for beginning the first journey to an ocean world beyond Earth,” said NASA Administrator Bill Nelson. “NASA leads the world in exploration and discovery, and the Europa Clipper mission is no different. By exploring the unknown, Europa Clipper will help us better understand whether there is the potential for life not just within our Solar System, but among the billions of moons and planets beyond our Sun.”
Approximately five minutes after liftoff, the rocket’s second stage fired up and the payload fairing, or the rocket’s nose cone, opened to reveal Europa Clipper. About an hour after launch, the spacecraft separated from the rocket. Ground controllers received a signal soon after, and two-way communication was established at 1:13 p.m. with NASA’s Deep Space Network facility in Canberra, Australia.
Mission teams celebrated as initial telemetry reports showed that Europa Clipper is in good health and operating as expected.
“We could not be more excited for the incredible and unprecedented science NASA’s Europa Clipper mission will deliver in the generations to come,” said Nicky Fox, associate administrator, Science Mission Directorate at NASA Headquarters in Washington. “Everything in NASA science is interconnected, and Europa Clipper’s scientific discoveries will build upon the legacy that our other missions exploring Jupiter — including Juno, Galileo and Voyager — created in our search for habitable worlds beyond our home planet.”
The main goal of the mission is to determine whether Europa has conditions that could support life. Europa is about the size of our own Moon, but its interior is different. Information from NASA’s Galileo mission in the 1990s showed strong evidence that under Europa’s ice lies an enormous, salty ocean with more water than all of Earth’s oceans combined.
Scientists have also found evidence that Europa may host organic compounds and energy sources under its surface. If the mission determines that Europa is habitable, it may mean there are more habitable worlds in our Solar System and beyond than imagined.
“We’re ecstatic to send Europa Clipper on its way to explore a potentially habitable ocean world, thanks to our colleagues and partners who’ve worked so hard to get us to this day,” said Laurie Leshin, director, NASA’s Jet Propulsion Laboratory in Southern California. “Europa Clipper will undoubtedly deliver mind-blowing science. While always bittersweet to send something we’ve labored over for years off on its long journey, we know this remarkable team and spacecraft will expand our knowledge of our Solar System and inspire future exploration.”
In 2031, the spacecraft will begin conducting its science-dedicated flybys of Europa. Coming as close as 16 miles (25 kilometers) to the surface, Europa Clipper is equipped with nine science instruments and a gravity experiment, including an ice-penetrating radar, cameras and a thermal instrument to look for areas of warmer ice and any recent eruptions of water. As the most sophisticated suite of science instruments that NASA has ever sent to Jupiter, they will work in concert to learn more about the moon’s icy shell, thin atmosphere and deep interior.
To power those instruments in the faint sunlight that reaches Jupiter, Europa Clipper also carries the largest solar arrays NASA has ever used for an interplanetary mission. With arrays extended, the spacecraft spans 100 feet (30.5 meters) from end to end. With propellant loaded, it weighs about 13,000 pounds (5,900 kilograms).
In all, more than 4,000 people have contributed to the Europa Clipper mission since it was formally approved in 2015.
“As Europa Clipper embarks on its journey, I’ll be thinking about the countless hours of dedication, innovation and teamwork that made this moment possible,” said Jordan Evans, project manager at NASA JPL. “This launch isn’t just the next chapter in our exploration of the Solar System; it’s a leap toward uncovering the mysteries of another ocean world, driven by our shared curiosity and continued search to answer the question, ‘are we alone?’”
Source: NASA.Gov
****
NASA / JPL - Caltech
NASA / JPL - Caltech
SpaceX
Saturday, October 12, 2024
Photos of the Day: My Snapshots of Comet Tsuchinshan–ATLAS!
Richard T. Par
A few hours ago, I drove down to Summitridge Park in the city of Diamond Bar to take photos of comet C/2023 A3 (Tsuchinshan–ATLAS)...which will be visible in the evening sky for the next two weeks or so. Once it heads back out to the Oort Cloud two light-years away, comet Tsuchinshan–ATLAS won't return to our inner Solar System for another 80,000 years!
I used my Google Pixel 5 and Nikon D3300 DSLR camera to capture these snapshots. Here are the settings that I employed on my DSLR:
Lens: 70-300mm Nikon telephoto lens
ISO: 400 to 1600
F-stop: f/5.6
Shutter speed: 2.5 seconds
Live View mode on my LCD screen used instead of the viewfinder
I plan on heading back out to capture more images of C/2023 A3 as it gets higher up in the sky over the coming days. This is my second comet in over four years (after comet NEOWISE in July of 2020) that I was fortunate enough to take photos of from Los Angeles County, CA!
Hope you guys are having a nice weekend.
Richard T. Par
Richard T. Par
Richard T. Par
Richard T. Par
Richard T. Par
Friday, October 11, 2024
The Latest Update on the Orbital Test Vehicle...
Boeing
Boeing-built X-37B Begins Advanced Space Maneuvering (News Release - October 10)
- 10 months into its 7th mission, the Orbital Test Vehicle (OTV-7) continues to set the pace of technology demonstrations in space.
- Upcoming aerobraking will expand the United States Space Force’s knowledge of maneuvering between orbits with minimal fuel usage.
KENNEDY SPACE CENTER, Fla — The Boeing [NYSE: BA]-built X-37B will soon perform a series of advanced aerobraking maneuvers, taking the dynamic spaceplane from a Highly-Elliptical Orbit (HEO), where it’s been operating since December 2023, and lowering its altitude using minimal fuel.
This will be the first time that Boeing, the United States Space Force (USSF) and the X-37B attempt to accomplish this novel demonstration.
“Space is a vast and unforgiving environment where testing technologies is critical to the success of future endeavors,” said Michelle Parker, vice president of Boeing’s Space Mission Systems. “There is no other space platform as capable, flexible and maneuverable as the X-37B, and its next demonstration will be another proof point that this test vehicle sets the pace of innovation.”
During aerobraking, the X-37B will use the drag of Earth’s atmosphere to slow it down, reducing the vehicle’s energy and changing the orbit while expending minimal fuel. The Service Module disposal will be conducted in accordance with established standards for space debris mitigation, and the X-37B’s orbit change will occur in a safe and responsible manner. Once aerobraking is complete, the X-37B will resume its test and experimentation objectives.
“This first-of-a kind maneuver from the X-37B is an incredibly important milestone for the United States Space Force as we seek to expand our aptitude and ability to perform in this challenging domain,” said Gen. Chance Saltzman, Chief of Space Operations.
The program will leverage six successful missions of safely operating the X-37B around Earth during this next demonstration. Boeing brings decades of lessons learned from operating other spacecraft in a variety of orbits, from the Apollo missions, the Space Shuttle Program, and hundreds of government and commercial satellites.
Source: Boeing
Thursday, October 10, 2024
America's Next Jupiter-bound Orbiter Will Get a New Launch Date After Florida Weathers the Latest Tropical Cyclone...
NASA / Ben Smegelsky
NASA Begins Post-Hurricane Milton Assessments at Kennedy (News Release)
NASA’s Kennedy Space Center in Florida remains closed as Hurricane Milton moves off the coast.
The safety of everyone impacted by the storm remains our top priority as the agency begins the assessment and recovery process from the hurricane.
Once the winds subsided to a safe level, the center’s Ride Out Team and engineering teams began initial checkouts to ensure that bridges are safe and useable. Later, a larger assessment team will thoroughly check the entire center.
The agency’s Europa Clipper launch team will schedule an official launch date when teams from NASA and SpaceX are able to perform their assessments, and confirm that it’s safe to launch. Teams are working to protect launch opportunities no earlier than Sunday, October 13. Clipper has launch opportunities through Wednesday, November 6.
NASA will provide more information on Clipper launch opportunities as it becomes available.
Source: NASA.Gov
****
Kennedy's Ride Out Team is conducting an initial assessment of the center. The majority of the impacts observed at this time are minor damage to doors, traffic lights, awnings, and small trailers.
— NASA's Kennedy Space Center (@NASAKennedy) October 10, 2024
The Damage Assessment and Recovery Team, or DART, will conduct a comprehensive… pic.twitter.com/jazgk1JbdH
Tuesday, October 08, 2024
The Latest Update on the Mars Sample Return Campaign...
Rocket Lab
Rocket Lab Awarded NASA Study Contract to Explore Bringing Rock Samples from Mars to Earth for the First Time (Press Release - October 7)
The study proposes using Rocket Lab’s vertically-integrated technologies to retrieve samples from the Red Planet for the first time in history as part of NASA’s Mars Sample Return Program.
Long Beach, California. Rocket Lab USA, Inc. (Nasdaq: RKLB) (“Rocket Lab” or “the Company”), a global leader in launch services and space systems, today announced that the Company has been selected by NASA to complete a study for retrieving rock samples from the Martian surface and bringing them to Earth for the first time. The mission would fulfill some of the highest priority Solar System exploration goals for the science community – to revolutionize humanity’s understanding of Mars, potentially answer whether life ever existed on the Martian surface, and help prepare for the first human explorers to the Red Planet.
NASA’s Rapid Mission Design Studies for Mars Sample Return solicits industry proposals to carry out rapid studies of mission designs and mission elements capable of delivering samples collected by the Mars Perseverance rover from the surface of Mars to Earth. The results of this study will inform a potential update to NASA’s Mars Sample Return Program and may result in future procurements with industry. Rocket Lab’s study will explore a simplified, end-to-end mission concept that would be delivered for a fraction of the current projected program cost and completed several years earlier than the current expected sample return date in 2040.
“Retrieving samples from Mars is one of the most ambitious and scientifically important endeavors humanity has ever embarked upon. We’ve developed an innovative mission concept to make it happen affordably and on an accelerated schedule,” said Rocket Lab founder and CEO, Sir Peter Beck. “Rocket Lab has been methodically implementing a strategy for cost-effective planetary science in recent years, making us uniquely suited to deliver a low-cost, rapid Mars Sample Return. We’ve demonstrated this strategy by delivering a NASA mission to the Moon, enabling rendezvous and proximity operations in orbit, successfully re-entering a capsule from orbit to Earth, delivering two spacecraft to NASA for a Mars mission, and much more. We look forward to bringing our proven capabilities together to deliver a compelling, innovative mission solution that puts Mars rocks in the hands of scientists sooner.”
Rocket Lab’s proposed mission architecture will be revealed once the study is complete in the coming months.
Source: Rocket Lab
Monday, October 07, 2024
DART's Successor Is on Its Way to Didymos...
SpaceX
Planetary Defence Mission Hera Heading for Deflected Asteroid (News Release)
ESA’s first planetary defence spacecraft has departed planet Earth. The Hera mission is headed to a unique target among the more than 1.3 million known asteroids in our Solar System – the only body to have had its orbit shifted by human action – to solve lingering mysteries associated with its deflection.
By sharpening scientific understanding of the ‘kinetic impact’ technique of asteroid deflection, Hera aims to make Earth safer. The mission is part of a broader ambition to turn terrestrial asteroid impacts into a fully-avoidable class of natural disaster.
Developed as part of ESA’s Space Safety programme and sharing technological heritage with the agency’s Rosetta comet hunter, Hera lifted off on a SpaceX Falcon 9 from Cape Canaveral Space Force Station in Florida, USA, on 7 October at 10:52 local time (16:52 CEST, 14:52 UTC) with its solar arrays deploying about one hour later.
The automobile-sized Hera will carry out the first detailed survey of a ‘binary’ – or double-body – asteroid, 65803 Didymos, which is orbited by a smaller body, Dimorphos. Hera’s main focus will be on the smaller of the two, whose orbit around the larger asteroid was changed by NASA's Double Asteroid Redirection Test (DART) mission, demonstrating asteroid deflection by kinetic impact, in 2022.
“Planetary defence is an inherently international endeavour, and I am really happy to see ESA’s Hera spacecraft at the forefront of Europe’s efforts to help protect Earth. Hera is a bold step in scaling up ESA’s engagement in planetary defence,” said ESA Director General Josef Aschbacher.
Hera will also perform challenging deep-space technology experiments including the deployment of twin shoebox-sized CubeSats to fly closer to the target asteroid, manoeuvring in ultra-low gravity to acquire additional scientific data before eventually landing. The main spacecraft will also attempt ‘self-driving’ navigation around the asteroids based on visual tracking.
The mission’s launch and journey into deep space is being overseen from ESA’s European Space Operations Centre in Darmstadt, Germany.
“Hera is finally on its way to Didymos; today we are writing a new page of space history,” said Hera mission manager Ian Carnelli. “This deep space mission took shape from contract signing to launch in only four years, a testimony to the hard work and dedication of the Hera team across ESA, European industry, science and the Japanese space agency JAXA.”
“But the underlying idea of a planetary defence mission based on one spacecraft impacting an asteroid with a second that gathers data goes back two decades, with a significant contribution made by the late Prof. Andrea Milani, a pioneer in asteroid risk monitoring whose name has been lent to one of Hera’s two onboard CubeSats.”
ESA, together with NASA and other partner agencies, maintains a watch on the sky to identify and track dangerous asteroids. But if an incoming body was spotted, what if anything could be done to stop it?
NASA’s DART mission was created to help answer that question. On 26 September 2022, the DART spacecraft performed humankind’s first asteroid deflection by intentionally crashing into Dimorphos, the Great-Pyramid-sized moonlet of the larger, mountain-sized asteroid Didymos, shifting its orbit.
Based on observations from Earth, DART succeeded in shrinking the orbital period of Dimorphos around Didymos by 33 minutes, nearly 5% of its original value, while also casting a plume of debris thousands of kilometres in space.
But many unknowns remain about the event, which scientists need to resolve in order to help turn this ‘kinetic impact’ method of asteroid deflection into a well-understood and reliably-repeatable planetary defence technique. How big was the crater left by DART’s impact, or did the entire asteroid undergo reshaping? What is the mineralogy, structure and precise mass of Dimorphos?
With a cube-shaped main body measuring approximately 1.6 meters across and flanked by twin 5-meter solar wings, the Hera spacecraft is ESA’s own contribution to this international planetary defence collaboration. Once it reaches the Didymos binary asteroid in two years’ time, the mission will perform a close-up ‘crash scene investigation’ to gather all of the missing knowledge needed.
“Hera’s ability to closely study its asteroid target will be just what is needed for operational planetary defence,” explains Richard Moissl, heading ESA’s Planetary Defence Office. “You can imagine a scenario where a reconnaissance mission is dispatched rapidly, to assess if any follow-up deflection action is needed. We should soon be practicing this again with our Ramses spacecraft, a proposed planetary defence mission to rendezvous with the Apophis asteroid during its close approach to Earth in 2029.”
Around 100 European companies and institutes across 18 ESA Member States have been involved in developing the Hera mission. OHB System AG led the industrial consortium, including responsibility for the overall spacecraft design, development, assembly and testing.
Hera will perform the most detailed exploration yet of a binary asteroid system. Although binaries make up 15% of all known asteroids, none has ever been surveyed in detail. In addition, the Dimorphos asteroid is the smallest body yet visited by a space mission while Didymos is a fast spinner for its size, coming close to the limits of structural stability given its dimensions.
The Milani CubeSat, developed for ESA by Italian industry led by Tyvak International, will survey the mineral makeup of Dimorphos and its surrounding dust, while the Juventas CubeSat, produced by a Luxembourg-led consortium under GOMspace, will perform the first subsurface radar probe of an asteroid. Late in its six-month asteroid survey, Hera will also test out an experimental self-driving mode that will allow it to navigate around the asteroids autonomously based on monitoring of surface features.
ESA Hera mission scientist Michael Kueppers comments: “By the end of Hera’s mission, the Didymos pair should become the best studied asteroids in history, helping to secure Earth from the threat of incoming asteroids.”
Hera Principal Investigator Patrick Michel, Director of Research at CNRS / Observatoire de la Côte d'Azur, adds: “DART’s impact was like the first episode in a cosmic adventure – a spectacular flash seen across space that left scientists with the question: what happened next?”
“Now Hera is on its way in the next episode, to turn the brief glimpses of the Didymos asteroids that the DART mission beamed back to us into a detailed survey, promising us fresh insights into the planetary collision process – which has been one of the primary mechanisms for creating the Solar System as we know it.”
Today’s launch put Hera on a direct-departure trajectory away from Earth, beginning its two-year cruise phase. A scheduled manoeuvre next month will be followed by a swingby of Mars in March 2025, which will give the spacecraft added velocity for its eventual rendezvous with Didymos. During the Mars gravity assist, Hera will perform a survey of martian moon Deimos, deploying its instruments for scientific use for the first time.
The arrival at Didymos is foreseen for autumn 2026, when the asteroid mission will enter its main science and technology demonstration phase.
Source: European Space Agency
****
SpaceX
ESA - Science Office
Sunday, October 06, 2024
America's Next Jupiter-bound Orbiter Will Not Launch Next Thursday, October 10, As Planned...
NASA
NASA, SpaceX Secure Europa Clipper Ahead of Hurricane (News Release)
NASA and SpaceX are standing down from the Thursday, October 10, launch attempt of the agency’s Europa Clipper mission due to anticipated hurricane conditions in the area. Hurricane Milton is expected to move from the Gulf of Mexico this week, heading east to the Space Coast. High winds and heavy rain are expected in the Cape Canaveral and Merritt Island regions on Florida’s east coast.
Launch teams have secured NASA’s Europa Clipper spacecraft in SpaceX’s hangar at Launch Complex 39A at the agency’s Kennedy Space Center in Florida ahead of the severe weather, and the center began hurricane preparations on Sunday.
“The safety of launch team personnel is our highest priority, and all precautions will be taken to protect the Europa Clipper spacecraft,” said Tim Dunn, senior launch director at NASA’s Launch Services Program.
On October 4, workers transported NASA’s Europa Clipper spacecraft from the Payload Hazardous Servicing Facility at NASA’s Kennedy Space Center to the SpaceX Falcon Heavy rocket in the hangar as part of final launch preparations ahead of its journey to Jupiter’s icy moon. While Europa Clipper’s launch period opens on October 10, the window provides launch opportunities until Wednesday, November 6.
Once the storm passes, recovery teams will assess the safety of the spaceport before personnel return to work. Then launch teams will assess the launch processing facilities for damage from the storm.
“Once we have the ‘all-clear’ followed by facility assessment and any recovery actions, we will determine the next launch opportunity for this NASA flagship mission,” said Dunn.
Source: NASA.Gov
****
NASA / Ben Smegelsky
Saturday, October 05, 2024
America's Next Jupiter-bound Orbiter Meets Its SpaceX Rocket Fairings...
NASA / Ben Smegelsky
NASA’s Europa Clipper Mated to Payload Adapter, Encapsulated (News Release - October 4)
NASA and SpaceX technicians recently completed several important milestones as they prepare for the upcoming launch of the agency’s Europa Clipper spacecraft to explore Jupiter’s icy moon Europa.
First, teams connected the Europa Clipper spacecraft to the payload adapter on Thursday, September 26, inside the Payload Hazardous Servicing Facility at NASA’s Kennedy Space Center in Florida. With Europa Clipper securely attached to the payload adapter, the team then connected the combined assembly to the payload attach fitting on Monday, September 30. These operations will enable the spacecraft to join with the rocket in the coming days.
Next, teams detached various coverings that shielded sensitive parts of the spacecraft during processing. Finally, on Wednesday, October 2, teams encapsulated the spacecraft inside payload fairings, which will protect the spacecraft from aerodynamic pressure and heat during launch. After liftoff, the fairings will separate once the rocket’s second stage climbs high enough, approximately 5 minutes into the flight, and the fairings will return to Earth where SpaceX plans to recover them.
NASA is targeting Thursday, October 10, for launching Europa Clipper on a SpaceX Falcon Heavy from Launch Complex 39A at Kennedy. This will start a years-long journey to Jupiter, where it will help scientists determine if the enigmatic moon has conditions suitable to support life.
Source: NASA.Gov
****
NASA / Ben Smegelsky
NASA / Ben Smegelsky
NASA / Ben Smegelsky
NASA / Ben Smegelsky
NASA / Ben Smegelsky
Friday, October 04, 2024
Despite an SRB Anomaly, Vulcan Centaur Completes Its Second Mission This Morning (On My Birthday)...
United Launch Alliance
United Launch Alliance Successfully Launches Second Vulcan Certification Flight (Press Release)
Cape Canaveral Space Force Station, Fla. – United Launch Alliance (ULA) ushers in a new era of space capabilities with the successful launch of its second certification flight (Cert-2) of the next-generation Vulcan rocket on October 4 at 7:25 a.m. EDT from Space Launch Complex 41 at Cape Canaveral Space Force Station.
“The success of Vulcan’s second certification flight heralds a new age of forward-looking technology committed to meeting the ever-growing requirements of space launch and supporting our nation’s assured access to space. We had an observation on one of our solid rocket boosters (SRB) that we are reviewing, but we are overall pleased with the rocket’s performance and had a bullseye insertion,” said Tory Bruno, ULA’s president and CEO. “Vulcan provides high performance and greater affordability while continuing to deliver our unmatched reliability and orbital precision for all our customers across the national security, civil and commercial markets.”
The Cert-2 mission carried experiments and demonstrations associated with future capabilities of Centaur V, the world’s highest-performing upper stage designed to further deliver on ULA’s unrivaled legacy of reliability and precision. Centaur V provides 2.5 times the energy and 450 times the endurance of its predecessors, enabling the most complex orbital insertions within the most challenging and clandestine orbits.
“Vulcan is built with the strength of a national workforce whose unmatched dedication and innovation has modernized the very best of our industry-leading heritage,” said Mark Peller, vice president of Vulcan Development. “The foundation of Vulcan’s purpose-built design rests on the best of what we’ve learned from more than 130 combined years of launch experience with Atlas and Delta.”
The Cert-2 mission served as the second of two certification flights required for the U.S. Space Force’s certification process and ULA has now completed all requirements for certification. ULA continues to work closely with the U.S. Space Force as they take the next few weeks to review the data and compare it to ULA’s first certification mission to ensure that the vehicle performed as expected and there are no additional items that need review. Once the evaluation is complete to the Space Force's standards, the Vulcan rocket will be certified to launch national security missions.
“The team will continue to modify our infrastructure as we work towards an accelerated launch cadence to meet our customers’ manifest requirements while building off today’s successful launch and developing future Vulcan upgrades, including SMART reuse plans for downrange, non-propulsive recovery of Vulcan engines,” said Bruno.
ULA has sold more than 70 Vulcan launches to date, including 38 missions for Amazon’s Project Kuiper and multiple national security space launch missions as the part of the country’s Phase 2 launch procurement.
All rockets are not created equal. ULA is the nation’s most experienced, reliable and accurate launch service provider delivering unmatched value, a tireless drive to improve, and commitment to the extraordinary. Vulcan’s inaugural launch marked the beginning of a new era of space capabilities and provides higher performance and greater affordability while offering the world’s only high-energy architecture rocket to deliver any payload, at any time, directly to any orbit.
Source: United Launch Alliance
****
United Launch Alliance
United Launch Alliance
United Launch Alliance
Note the difference in the plumes from the two SRBs several seconds after the burst of material from one of them, which would suggest a damaged nozzle. pic.twitter.com/OC1R97ZOtX
— Jeff Foust (@jeff_foust) October 4, 2024
A closer look at that third pic… almost seems like you can look up the nozzle of the SRB https://t.co/y5Wtd0TEJn pic.twitter.com/JRw4yy92i1
— Jared Locke 🚀 (@baserunner0723) October 4, 2024
BE-4s earn praise for compensating. https://t.co/2uZVPmNnbp
— Chris Bergin - NSF (@NASASpaceflight) October 4, 2024
And here’s the Bullseye plot. #CERT2 #VulcanRocket pic.twitter.com/SNoT5gDytz
— Tory Bruno (@torybruno) October 4, 2024
Thursday, October 03, 2024
The Latest Celestial Discovery by Kepler's Successor...
NASA GSFC
NASA’s TESS Spots Record-Breaking Stellar Triplets (News Release - October 2)
Professional and amateur astronomers teamed up with artificial intelligence to find an unmatched stellar trio called TIC 290061484, thanks to cosmic “strobe lights” captured by NASA’s TESS (Transiting Exoplanet Survey Satellite).
The system contains a set of twin stars orbiting each other every 1.8 days, and a third star that circles the pair in just 25 days. The discovery smashes the record for shortest outer orbital period for this type of system, set in 1956, which had a third star orbiting an inner pair in 33 days.
“Thanks to the compact, edge-on configuration of the system, we can measure the orbits, masses, sizes and temperatures of its stars,” said Veselin Kostov, a research scientist at NASA’s Goddard Space Flight Center in Greenbelt, Maryland, and the SETI Institute in Mountain View, California. “And we can study how the system formed and predict how it may evolve.”
A paper, led by Kostov, describing the results was published in The Astrophysical Journal on October 2.
Flickers in starlight helped reveal the tight trio, which is located in the constellation Cygnus. The system happens to be almost flat from our perspective. This means that the stars cross right in front of, or eclipse, each other as they orbit.
When that happens, the nearer star blocks some of the farther star’s light.
Using machine learning, scientists filtered through enormous sets of starlight data from TESS to identify patterns of dimming that reveal eclipses. Then, a small team of citizen scientists filtered further, relying on years of experience and informal training to find particularly interesting cases.
These amateur astronomers, who are co-authors on the new study, met as participants in an online citizen science project called Planet Hunters, which was active from 2010 to 2013. The volunteers later teamed up with professional astronomers to create a new collaboration called the Visual Survey Group, which has been active for over a decade.
“We’re mainly looking for signatures of compact multi-star systems, unusual pulsating stars in binary systems, and weird objects,” said Saul Rappaport, an emeritus professor of physics at MIT in Cambridge. Rappaport co-authored the paper and has helped lead the Visual Survey Group for more than a decade. “It’s exciting to identify a system like this because they’re rarely found, but they may be more common than current tallies suggest.”
Many more likely speckle our galaxy, waiting to be discovered.
Partly because the stars in the newfound system orbit in nearly the same plane, scientists say that it’s likely very stable despite their tight configuration (the trio’s orbits fit within a smaller area than Mercury’s orbit around the Sun). Each star’s gravity doesn’t perturb the others too much, like they could if their orbits were tilted in different directions.
But while their orbits will likely remain stable for millions of years, “no one lives here,” Rappaport said. “We think the stars formed together from the same growth process, which would have disrupted planets from forming very closely around any of the stars.” The exception could be a distant planet orbiting the three stars as if they were one.
As the inner stars age, they will expand and ultimately merge, triggering a supernova explosion in around 20 to 40 million years.
In the meantime, astronomers are hunting for triple stars with even shorter orbits. That’s hard to do with current technology, but a new tool is on the way.
Images from NASA’s upcoming Nancy Grace Roman Space Telescope will be much more detailed than TESS’s. The same area of the sky covered by a single TESS pixel will fit more than 36,000 Roman pixels. And while TESS took a wide, shallow look at the entire sky, Roman will pierce deep into the heart of our galaxy where stars crowd together, providing a core sample rather than skimming the whole surface.
“We don’t know much about a lot of the stars in the center of the galaxy except for the brightest ones,” said Brian Powell, a co-author and data scientist at Goddard. “Roman’s high-resolution view will help us measure light from stars that usually blur together, providing the best look yet at the nature of star systems in our galaxy.”
And since Roman will monitor light from hundreds of millions of stars as part of one of its main surveys, it will help astronomers find more triple star systems in which all the stars eclipse each other.
“We’re curious why we haven’t found star systems like these with even shorter outer orbital periods,” said Powell. “Roman should help us find them and bring us closer to figuring out what their limits might be.”
Roman could also find eclipsing stars bound together in even larger groups — half a dozen, or perhaps even more all orbiting each other like bees buzzing around a hive.
“Before scientists discovered triply eclipsing triple star systems, we didn’t expect them to be out there,” said co-author Tamás Borkovits, a senior research fellow at the Baja Observatory of The University of Szeged in Hungary. “But once we found them, we thought, well why not? Roman, too, may reveal never-before-seen categories of systems and objects that will surprise astronomers.”
Source: NASA.Gov
****
NASA GSFC
Wednesday, October 02, 2024
The Latest Update on Humanity's Second Most-Distant Interstellar Probe...
NASA / JPL - Caltech
NASA Turns Off Science Instrument to Save Voyager 2 Power (News Release - October 1)
The mission has been working to postpone the shut-off for as long as possible. Four other instruments aboard the interstellar spacecraft continue to operate.
Mission engineers at NASA have turned off the plasma science instrument aboard the Voyager 2 spacecraft due to the probe’s gradually shrinking electrical power supply.
Traveling more than 12.8 billion miles (20.5 billion kilometers) from Earth, the spacecraft continues to use four science instruments to study the region outside our heliosphere, the protective bubble of particles and magnetic fields created by the Sun. The probe has enough power to continue exploring this region with at least one operational science instrument into the 2030s.
Mission engineers have taken steps to avoid turning off a science instrument for as long as possible because the science data collected by the twin Voyager probes is unique. No other human-made spacecraft has operated in interstellar space, the region outside the heliosphere.
The plasma science instrument measures the amount of plasma (electrically-charged atoms) and the direction it is flowing. It has collected limited data in recent years due to its orientation relative to the direction that plasma is flowing in interstellar space.
Both spacecraft are powered by decaying plutonium and lose about 4 watts of power each year. After the twin Voyagers completed their exploration of the giant planets in the 1980s, the mission team turned off several science instruments that would not be used in the study of interstellar space. That gave the spacecraft plenty of extra power until a few years ago.
Since then, the team has turned off all onboard systems not essential for keeping the probes working, including some heaters. In order to postpone having to shut off another science instrument, they also adjusted how Voyager 2’ voltage is monitored.
Monitoring Results
On September 26, engineers issued the command to turn off the plasma science instrument. Sent by NASA’s Deep Space Network, it took 19 hours to reach Voyager 2, and the return signal took another 19 hours to reach Earth.
Mission engineers always carefully monitor changes being made to the 47-year-old spacecraft’s operations to ensure that they don’t generate any unwanted secondary effects. The team has confirmed that the switch-off command was executed without incident and the probe is operating normally.
In 2018, the plasma science instrument proved critical in determining that Voyager 2 left the heliosphere. The boundary between the heliosphere and interstellar space is demarcated by changes in the atoms, particles and magnetic fields that instruments on the Voyagers can detect. Inside the heliosphere, particles from the Sun flow outward, away from our nearest star.
The heliosphere is moving through interstellar space, so at Voyager 2’s position near the front of the solar bubble, the plasma flows in almost the opposite direction of the solar particles.
The plasma science instrument consists of four “cups.” Three cups point in the direction of the Sun and observed the solar wind while inside the heliosphere. A fourth points at a right angle to the direction of the other three and has observed the plasma in planetary magnetospheres, the heliosphere, and now, interstellar space.
When Voyager 2 exited the heliosphere, the flow of plasma into the three cups facing the Sun dropped off dramatically. The most useful data from the fourth cup comes only once every three months, when the spacecraft does a 360-degree turn on the axis pointed toward the Sun. This factored into the mission’s decision to turn this instrument off before others.
The plasma science instrument on Voyager 1 stopped working in 1980 and was turned off in 2007 to save power. Another instrument aboard Voyager 2, called the plasma wave subsystem, can estimate the plasma density when eruptions from the Sun drive shocks through the interstellar medium, producing plasma waves.
The Voyager team continues to monitor the health of the spacecraft and its available resources to make engineering decisions that maximize the mission’s science output.
Source: NASA.Gov
****
NASA / JPL - Caltech
Tuesday, October 01, 2024
L-Minus 3 Days Before the Vulcan Centaur Rocket Takes Off on Its Second Flight Test into Space...
United Launch Alliance
Cert-2: Dress Rehearsal of Vulcan Launch Day Planned (News Release)
The United Launch Alliance (ULA) Vulcan rocket rolled out to the Space Launch Complex (SLC) 41 pad at Cape Canaveral Space Force Station on September 30 to undergo an extensive practice countdown ahead of its second Certification (Cert-2) flight test.
Known as a Wet Dress Rehearsal (WDR), ULA is preparing to conduct a full day-of-launch test to ensure that the new rocket, pad systems and launch team are ready for the second Vulcan mission. The WDR exercises the hardware, procedures and the people to reduce the risk of a delay on launch day.
The rehearsal follows the tightly-scripted sequence by rolling the Vulcan from Vertical Integration Facility-G (VIF-G) to SLC-41 and performing the entire countdown operation to fuel the rocket with cryogenic propellant.
The countdown begins before sunrise under the guidance of the ULA launch conductor from the Advanced Spaceflight Operations Center (ASOC), located about four miles (6.4 km) from the pad.
The rocket stages are powered up, avionics tested and final preps to ground systems accomplished. That enables the ULA launch director to give approval for the fueling process.
The launch team configures the Vulcan Centaur for cryogenic loading and approximately one million pounds (454,000 kg) of methane, liquid oxygen and liquid hydrogen flow into the rocket's tanks using the same procedures that will be executed on the actual launch day.
With the rocket filled up, permission will be given to enter terminal count at T-minus 7 minutes. The final phase of the countdown pressurizes the rocket, arms various systems and transitions the vehicle to internal power. The count finishes just prior to ignition time.
The rocket is then safed and cryogenic tanks drained. The thorough data will be performed before moving into the countdown for launch. Liftoff is targeted for no earlier than October 4.
The highly-instrumented rocket will carry a non-deployable inert payload into space, run unique experiments and conduct a series of detailed test objectives to collect performance data while fulfilling ULA’s certification obligations to the nation.
Source: United Launch Alliance
****
3,2,1...our practice countdown has culminated as planned for the #VulcanRocket's Wet Dress Rehearsal. Activities will continue into this evening as propellants are drained and our teammates begin reviewing all the data collected today to ensure #Cert2 is ready to fly. pic.twitter.com/L6jfRRLHr0
— ULA (@ulalaunch) October 1, 2024