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We can repurpose retired coal plants to produce green energy

New Scientist Space - Cosmology - Tue, 08/05/2025 - 5:00pm

Piles of dirt can cheaply store renewable energy as heat – and that stored energy can reactivate the machinery of retired coal power plants, letting them provide backup power for the electricity grid

Categories: Astronomy

We can repurpose retired coal plants to produce green energy

New Scientist Space - Space Headlines - Tue, 08/05/2025 - 5:00pm

Piles of dirt can cheaply store renewable energy as heat – and that stored energy can reactivate the machinery of retired coal power plants, letting them provide backup power for the electricity grid

Categories: Astronomy

NASA awards Firefly Aerospace $177 million for 1st multi-rover mission to moon's south pole

Space.com - Tue, 08/05/2025 - 5:00pm

NASA has awarded Firefly Aerospace a $176.7 million contract to deliver a pair of rovers and three scientific instruments to the moon's south pole.

Categories: Astronomy

Curiosity Blog, Sols 4618-4619: The Boxwork Structures Continue to Call to Us

NASA News - Tue, 08/05/2025 - 4:58pm

Curiosity Navigation

3 min read

Curiosity Blog, Sols 4618-4619: The Boxwork Structures Continue to Call to Us NASA’s Mars rover Curiosity acquired this image using its Left Navigation Camera on Aug. 1, 2025 — Sol 4616, or Martian day 4,616 of the Mars Science Laboratory mission — at 03:36:56 UTC.NASA/JPL-Caltech

Written by Ashley Stroupe, Mission Operations Engineer and Rover Planner at NASA’s Jet Propulsion Laboratory

Earth planning date: Friday, Aug. 1, 2025.

Now that we have reached August, our “landiversary” (anniversary of landing — Aug. 5 PDT) is less than a week away! The team is looking forward to being able to celebrate the milestone of our rover becoming a teenager at 13. Today’s image is a beautiful back-lit late afternoon image of the nearby mountains and the distant crater rim. These views make working on Mars never get old!

The first sol of today’s plan is very busy because we will only have data from the first sol down in time for planning on Monday. Today I was working as a Rover Planner, supporting both arm and drive activities. We start first thing with arm activities; we DRT brush and do APXS integration on the target “San Cristóbal,” which is a bedrock target, and the only place in the workspace smooth and flat enough for us to brush.

After a brief nap, we have an extensive imaging campaign. We take Mastcam images of the AEGIS target from the previous plan and two potential vein targets “Rio Satja” and “Río Ichilo.” We then take Mastcam stereo mosaics of boxwork targets “Pontezuelo” and “Catedrales de Tara.” Additionally we have stereo mosaics of “Llanos de Challe,” a transition between the bedrock in the boxwork hollow and the boxwork ridge, a nearby light-toned exposure, and some additional troughs and ridges. ChemCam then takes a LIBS observation of “Airport Domes,” which is another hollow in the boxworks. Finally, we take a ChemCam RMI and a Mastcam of Pontezuelo.

After finishing all the imaging, we continue with the rest of the arm activities. We split the arm activities to accommodate conflicting constraints — both APXS and ChemCam both need to be as early as possible. In this set of arm activities, we begin with MAHLI imaging of the two targets, San Cristóbal and “Salar de Agua Amara,” which consists of delicate branching structures likely made by groundwater.

After another short nap, we do a small adjustment in our position to get another interesting piece of bedrock ridge in our workspace. In order to approach it at a good angle, we first drive parallel to the ridge to be lined up with the target, and then we turn and drive straight to it. Due to constraints on how we like to park at targets, sometimes these shorter drives can be more complicated than longer ones — but today it was simpler. After completing the drive, we unstow the arm to get a clear view of our workspace for Monday’s planning as well as our standard post-drive imaging and then Curiosity goes to sleep for the night.

The second sol of the plan is a bit more leisurely. Around midday, Curiosity will be taking some atmospheric observations, including a Navcam dust-devil survey and a south-facing suprahorizon movie, followed by an AEGIS activity where the rover gets to pick targets and observe them herself. Then, early the next morning, Curiosity will wake up to take some additional atmospheric observations, including Navcam zenith and suprahorizon movies, Navcam line-of-sight toward the crater rim, and a Mastcam solar tau to measure dust in the atmosphere. Finally, she’ll get a short nap before waking up to start the next plan.

Learn more about Curiosity’s science instruments For more Curiosity blog posts, visit MSL Mission Updates Share Details Last Updated Aug 05, 2025 Related Terms

Blogs

Explore More 4 min read Curiosity Blog, Sols 4616-4617: Standing Tall on the Ridge Article 1 day ago 2 min read Curiosity Blog, Sols 4614-4615: Driving Along the Boxwork Article 7 days ago 3 min read Spheres in the Sand Article 7 days ago Keep Exploring Discover More Topics From NASA Mars

Mars is the fourth planet from the Sun, and the seventh largest. It’s the only planet we know of inhabited…

All Mars Resources

Explore this collection of Mars images, videos, resources, PDFs, and toolkits. Discover valuable content designed to inform, educate, and inspire,…

Rover Basics

Each robotic explorer sent to the Red Planet has its own unique capabilities driven by science. Many attributes of a…

Mars Exploration: Science Goals

The key to understanding the past, present or future potential for life on Mars can be found in NASA’s four…

Categories: NASA

Curiosity Blog, Sols 4618-4619: The Boxwork Structures Continue to Call to Us

NASA - Breaking News - Tue, 08/05/2025 - 4:58pm

Curiosity Navigation

3 min read

Curiosity Blog, Sols 4618-4619: The Boxwork Structures Continue to Call to Us NASA’s Mars rover Curiosity acquired this image using its Left Navigation Camera on Aug. 1, 2025 — Sol 4616, or Martian day 4,616 of the Mars Science Laboratory mission — at 03:36:56 UTC.NASA/JPL-Caltech

Written by Ashley Stroupe, Mission Operations Engineer and Rover Planner at NASA’s Jet Propulsion Laboratory

Earth planning date: Friday, Aug. 1, 2025.

Now that we have reached August, our “landiversary” (anniversary of landing — Aug. 5 PDT) is less than a week away! The team is looking forward to being able to celebrate the milestone of our rover becoming a teenager at 13. Today’s image is a beautiful back-lit late afternoon image of the nearby mountains and the distant crater rim. These views make working on Mars never get old!

The first sol of today’s plan is very busy because we will only have data from the first sol down in time for planning on Monday. Today I was working as a Rover Planner, supporting both arm and drive activities. We start first thing with arm activities; we DRT brush and do APXS integration on the target “San Cristóbal,” which is a bedrock target, and the only place in the workspace smooth and flat enough for us to brush.

After a brief nap, we have an extensive imaging campaign. We take Mastcam images of the AEGIS target from the previous plan and two potential vein targets “Rio Satja” and “Río Ichilo.” We then take Mastcam stereo mosaics of boxwork targets “Pontezuelo” and “Catedrales de Tara.” Additionally we have stereo mosaics of “Llanos de Challe,” a transition between the bedrock in the boxwork hollow and the boxwork ridge, a nearby light-toned exposure, and some additional troughs and ridges. ChemCam then takes a LIBS observation of “Airport Domes,” which is another hollow in the boxworks. Finally, we take a ChemCam RMI and a Mastcam of Pontezuelo.

After finishing all the imaging, we continue with the rest of the arm activities. We split the arm activities to accommodate conflicting constraints — both APXS and ChemCam both need to be as early as possible. In this set of arm activities, we begin with MAHLI imaging of the two targets, San Cristóbal and “Salar de Agua Amara,” which consists of delicate branching structures likely made by groundwater.

After another short nap, we do a small adjustment in our position to get another interesting piece of bedrock ridge in our workspace. In order to approach it at a good angle, we first drive parallel to the ridge to be lined up with the target, and then we turn and drive straight to it. Due to constraints on how we like to park at targets, sometimes these shorter drives can be more complicated than longer ones — but today it was simpler. After completing the drive, we unstow the arm to get a clear view of our workspace for Monday’s planning as well as our standard post-drive imaging and then Curiosity goes to sleep for the night.

The second sol of the plan is a bit more leisurely. Around midday, Curiosity will be taking some atmospheric observations, including a Navcam dust-devil survey and a south-facing suprahorizon movie, followed by an AEGIS activity where the rover gets to pick targets and observe them herself. Then, early the next morning, Curiosity will wake up to take some additional atmospheric observations, including Navcam zenith and suprahorizon movies, Navcam line-of-sight toward the crater rim, and a Mastcam solar tau to measure dust in the atmosphere. Finally, she’ll get a short nap before waking up to start the next plan.

Learn more about Curiosity’s science instruments For more Curiosity blog posts, visit MSL Mission Updates Share Details Last Updated Aug 05, 2025 Related Terms

Blogs

Explore More 4 min read Curiosity Blog, Sols 4616-4617: Standing Tall on the Ridge Article 1 day ago 2 min read Curiosity Blog, Sols 4614-4615: Driving Along the Boxwork Article 7 days ago 3 min read Spheres in the Sand Article 7 days ago Keep Exploring Discover More Topics From NASA Mars

Mars is the fourth planet from the Sun, and the seventh largest. It’s the only planet we know of inhabited…

All Mars Resources

Explore this collection of Mars images, videos, resources, PDFs, and toolkits. Discover valuable content designed to inform, educate, and inspire,…

Rover Basics

Each robotic explorer sent to the Red Planet has its own unique capabilities driven by science. Many attributes of a…

Mars Exploration: Science Goals

The key to understanding the past, present or future potential for life on Mars can be found in NASA’s four…

Categories: NASA

NASA Selects Six Companies to Provide Orbital Transfer Vehicle Studies

NASA News - Tue, 08/05/2025 - 4:09pm

Rendering of Quantum’s Ranger spacecraft engineered for rapid maneuverability and adaptability, enabling multi-destination delivery for missions from low Earth orbit to cislunar space.Credit: Arrow Science and Technology/Quantum Space Rendering of Blue Ring, a large high-mobility space platform providing full-service payload delivery, on-board edge computing, hosting, and end-to-end mission operations.Credit: Blue Origin Rendering of Firefly’s Elytra Dark orbital vehicle deploying Firefly’s Blue Ghost lander into lunar orbit.Credit: Firefly Aerospace Mira, a high-thrust, highly maneuverable spacecraft for payload hosting and deployment.Credit: Impulse Space Helios, a high-energy kick stage to rapidly deliver payloads to medium Earth orbit, geosynchronous orbit, and beyond.Credit: Impulse Space Pictured, two spacecraft for NASA and the University of California at Berkeley’s Space Sciences Laboratory’s ESCAPADE (Escape and Plasma Acceleration and Dynamics Explorers) mission. The spacecraft are based on Rocket Lab’s Explorer spacecraft, a configurable, high delta-V interplanetary platform.Credit: Rocket Lab Rocket Lab’s reusable rocket Neutron, a medium-lift class rocket designed for reuse and launch frequency to deliver cost-effective, reliable, and responsive launch for commercial and government missions.Credit: Rocket Lab

NASA has selected six companies to produce studies focused on lower-cost ways to launch and deliver spacecraft of various sizes and forms to multiple, difficult-to-reach orbits.

The firm-fixed-price awards comprise nine studies with a maximum total value of approximately $1.4 million. The awardees are:

Arrow Science and Technology LLC, Webster, Texas
Blue Origin LLC, Merritt Island, Florida
Firefly Aerospace Inc., Cedar Park, Texas
Impulse Space Inc., Redondo Beach, California
Rocket Lab, Long Beach, California
United Launch Services LLC, Centennial, Colorado

“With the increasing maturity of commercial space delivery capabilities, we’re asking companies to demonstrate how they can meet NASA’s need for multi-spacecraft and multi-orbit delivery to difficult-to-reach orbits beyond current launch service offerings,” said Joe Dant, orbital transfer vehicle strategic initiative owner for the Launch Services Program at NASA’s Kennedy Space Center in Florida. “This will increase unique science capability and lower the agency’s overall mission costs.”

Each of the six companies will deliver studies exploring future application of orbital transfer vehicles for NASA missions:

Arrow will partner with Quantum Space for its study. Quantum’s Ranger provides payload delivery service as a multi-mission spacecraft engineered for rapid maneuverability and adaptability, enabling multi-destination delivery for missions from low Earth orbit to lunar orbit.

Blue Origin will produce two studies, including one for Blue Ring, a large, high-mobility space platform providing full-service payload delivery, on-board edge computing, hosting, and end-to-end mission operations. It uses hybrid solar-electric and chemical propulsion capability to reach geostationary, cislunar, Mars, and interplanetary destinations. The second is a New Glenn upper stage study.

Firefly’s line of Elytra orbital vehicles offers on-demand payload delivery, imaging, long-haul communications, and domain awareness across cislunar space. Firefly’s Elytra Dark is equipped to serve as a transfer vehicle and enable ongoing operations in lunar orbit for more than five years.

Impulse Space will produce two studies. The company provides in-space mobility with two vehicles, Mira and Helios. Mira is a high-thrust, highly maneuverable spacecraft for payload hosting and deployment, while Helios is a high-energy kick stage to rapidly deliver payloads from low Earth to medium Earth orbits, geostationary orbits and beyond.

Rocket Lab’s two studies will feature the upper stage of the company’s Neutron rocket, as well as a long-life orbital transfer vehicle based on its Explorer spacecraft. Both vehicles are equipped with their own propulsion systems and other subsystems for missions to medium Earth and geosynchronous orbit and deep space destinations like the Moon, Mars, and near-Earth asteroids.

United Launch Alliance will assess the cislunar mission capabilities of an extended-duration Centaur V upper stage. Centaur would be capable of directly delivering multiple rideshare spacecraft to two different orbital destinations in cislunar space, avoiding the need for an additional rocket stage or orbital transfer vehicle.

The studies will be complete by mid-September. NASA will use the findings to inform mission design, planning, and commercial launch acquisition strategies for risk-tolerant payloads, with a possibility of expanding delivery services to larger-sized payloads and to less risk-tolerant missions in the future.

NASA’s Launch Services Program selected providers through the agency’s VADR (Venture-Class Acquisition of Dedicated and Rideshare Launch Services) contract, which helps foster growth of the U.S. commercial launch market, enabling greater access to space at a lower cost for science and technology missions.

For more information about NASA’s Launch Services Program, visit:

https://www.nasa.gov/launch-services-program

-end-

Josh Finch
Headquarters, Washington
202-358-1100
joshua.a.finch@nasa.gov

Leejay Lockhart
Kennedy Space Center, Florida
321-747-8310
leejay.lockhart@nasa.gov

Share Details Last Updated Aug 06, 2025 LocationKennedy Space Center Related Terms

Categories: NASA

NASA Selects Six Companies to Provide Orbital Transfer Vehicle Studies

NASA - Breaking News - Tue, 08/05/2025 - 4:09pm

Rendering of Quantum’s Ranger spacecraft engineered for rapid maneuverability and adaptability, enabling multi-destination delivery for missions from low Earth orbit to cislunar space.Credit: Arrow Science and Technology/Quantum Space Rendering of Blue Ring, a large high-mobility space platform providing full-service payload delivery, on-board edge computing, hosting, and end-to-end mission operations.Credit: Blue Origin Rendering of Firefly’s Elytra Dark orbital vehicle deploying Firefly’s Blue Ghost lander into lunar orbit.Credit: Firefly Aerospace Mira, a high-thrust, highly maneuverable spacecraft for payload hosting and deployment.Credit: Impulse Space Helios, a high-energy kick stage to rapidly deliver payloads to medium Earth orbit, geosynchronous orbit, and beyond.Credit: Impulse Space Pictured, two spacecraft for NASA and the University of California at Berkeley’s Space Sciences Laboratory’s ESCAPADE (Escape and Plasma Acceleration and Dynamics Explorers) mission. The spacecraft are based on Rocket Lab’s Explorer spacecraft, a configurable, high delta-V interplanetary platform.Credit: Rocket Lab Rocket Lab’s reusable rocket Neutron, a medium-lift class rocket designed for reuse and launch frequency to deliver cost-effective, reliable, and responsive launch for commercial and government missions.Credit: Rocket Lab

NASA has selected six companies to produce studies focused on lower-cost ways to launch and deliver spacecraft of various sizes and forms to multiple, difficult-to-reach orbits.

The firm-fixed-price awards comprise nine studies with a maximum total value of approximately $1.4 million. The awardees are:

Arrow Science and Technology LLC, Webster, Texas
Blue Origin LLC, Merritt Island, Florida
Firefly Aerospace Inc., Cedar Park, Texas
Impulse Space Inc., Redondo Beach, California
Rocket Lab, Long Beach, California
United Launch Services LLC, Centennial, Colorado