New Mars Forums

Could a single rocket landing redefine the balance of power in commercial spaceflight? Blue Origin’s New Glenn has just completed its first operational mission, delivering a payload to low-Earth orbit and returning its first stage to a drone ship matching capability that, until now, belonged exclusively to SpaceX.

The mission carried NASA’s ESCAPADE twin satellites, Blue and Gold, which Rocket Lab built to study how Mars lost its atmosphere. Each spacecraft, roughly the size of a copy machine, will fly in tandem around the Red Planet to capture a stereo view of how the solar wind strips away atmospheric particles. This dual-satellite approach, enabled by miniaturization trends in spacecraft engineering, offers redundancy and higher data resolution while keeping mission costs to a modest $80 million.

New Glenn’s success is rooted in years of engineering development. The rocket stands at 320 feet, nearly a third taller than SpaceX’s Falcon 9, and can lift up to 45 tons to low-Earth orbit almost double Falcon 9’s capacity. Its BE-4 engines, fueled by liquid natural gas and liquid oxygen, power a first stage designed for at least 25 reuses. In returning to the drone ship Jacklyn positioned 375 miles offshore, precise guidance, navigation, and control systems were needed to manage reentry dynamics, aerodynamic loads, and landing leg deployment on a moving platform.

Recovery of drone ships for orbital-class rockets is a complicated choreography: Jacklyn’s station-keeping thrusters hold position against ocean currents, while onboard tracking systems guide the descending booster onto a reinforced landing pad. This capability enables recovery from missions without fuel margin for a return-to-launch-site landing, increasing operational flexibility while lowering per-launch costs.

The destination of the payload adds another layer of technical achievement-the planet Mars. ESCAPADE will follow an innovative trajectory, first traveling to the Sun-Earth L2 Lagrange point to collect solar data before slingshotting back past Earth for a gravity assist toward Mars. This route reduces propellant mass to about 65% of the spacecraft’s total, compared to the 80-85% typical for direct transfers, and offers more flexible departure windows than the traditional Hohmann transfer.

While this mission demonstrated New Glenn’s orbital delivery and sea-based recovery, the next challenge for Blue Origin will be the Blue Moon Mark 1 lunar lander. The uncrewed Mk.1 will be powered by BE-7 engines burning liquid hydrogen and liquid oxygen and is designed to take cargo to the surface of the Moon on a single New Glenn flight. Already, the company is stacking the aft, mid and forward modules of the Mk.1 in Florida in preparation for thermal vacuum testing at NASA’s Johnson Space Center. Future variants, such as the crewed Mk.2 lander, would need orbital refueling via a Lunar Transporter technology which will require mastery of cryogenic propellant storage and transfer in space.

hat development comes as NASA has reopened its Artemis 3 Human Landing System contract, which awarded a noncompetitive contract to SpaceX over a year ago, due to delays in the Starship program. The over-50-meter-tall Starship HLS must still demonstrate orbital propellant transfer, targeted now for 2026, before carrying astronauts to the lunar surface. Blue Origin is positioning itself as a credible alternative with its proven New Glenn launch vehicle and advancing lunar lander program.

From a manufacturing standpoint, scaling reusable rocket operations will be crucial. The SpaceX Falcon 9 has executed a high operational tempo with its 516 landings and 484 reflights to date. To compete with SpaceX on price and cadence, Blue Origin must first ramp up production of New Glenn first stages, refine refurbishment workflows, and integrate rapid turnaround processes. The economics of reusability depend on minimizing inspection and repair cycles without compromising safety-an engineering challenge that will define the next phase of this rivalry.

With New Glenn’s first operational mission complete, Blue Origin has moved from proof-of-concept to active competitor. The ability to deliver payloads to orbit and recover boosters at sea is no longer a SpaceX monopoly, with implications for launch pricing, government contracts, and deep space missions that are immediate. We’ve entered a new era in the reusable rocket market, one in which the contest for dominance will be fought not just in the skies, but in the engineering labs and production lines that make these feats possible.

For SpaceNut re link to topic about buried domes...

Just FYI ... I have tried to bring up bedrock, but so far I haven't seen any mention of the importance of setting the base of a massive building on bedrock.  At present, we humans have very limited ability to know where bedrock is on Mars.  There may be some data collected by satellites that could be helpful, but I'll bet no one has sifted that data looking for bedrock.

(th)

The depth of Martian bedrock varies, with the crust reaching up to \(23\) miles (\(37\) kilometers) in some areas and potentially being multi-layered, while the shallow subsurface is about \(200\) meters (\(656\) feet) deep in certain plains. The deepest bedrock layers can be up to \(37\) kilometers thick and contain water in some regions, with a shallow sedimentary layer sandwiched between solidified lava flows just below the surface. 

Crustal and shallow subsurface depth Crust:
The overall thickness of Mars' crust is estimated to be between \(12\) miles (\(20\) kilometers) and \(23\) miles (\(37\) kilometers), depending on the number of sub-layers it has.Shallow subsurface: Studies of plains like Elysium Planitia have revealed a shallow subsurface about \(200\) meters (\(656\) feet) deep, which includes a layer of basaltic rock (cooled lava flows) and an intermediate layer of low seismic velocity.

Layered subsurface:
The shallow subsurface is not a single layer of bedrock but appears to be multi-layered, with a sedimentary layer between lava flows in some locations. Deeper bedrock and water Deepest crust: The deepest parts of the crust are estimated to be as deep as \(23\) miles (\(37\) kilometers).

Water in the crust:
Some models suggest that the mid-crust, around \(10\)-\(20\) kilometers (\(6\)-\(12\) miles) deep, may be porous and cracked, with enough water to form a global ocean \(1\)-\(2\) kilometers deep if collected. 

Other depths Surface layers:
The very top layer of the crust (first \(5\) meters) is thought to be a porous granular material, while the next layer down, from \(5\)-\(180\) meters, could be porous volcanic/sedimentary rock or consolidated volcanic rock.

Polar deposits:
In the polar regions, layered deposits of CO2 and water ice extend to a depth of \(1\) kilometer (\(0.6\) miles).

Bedrock on Mars generally refers to the underlying solid rock of the planet's crust, which varies significantly in depth depending on location and local geology.
The Bedrock Depth on Mars
Varies by location: The depth to bedrock can be very shallow in some areas, potentially just a few meters or less from the surface, especially in specific crater rims or outcrops.
Deep in other areas: In other regions, particularly where significant layers of regolith (soil and loose rock) have accumulated, the bedrock may be much deeper.
Crustal Thickness: The overall Martian crust (which is all bedrock) ranges in thickness from about 6 to 30 miles (10 to 50 kilometers). Data from the NASA InSight mission at its landing site suggested the crust was approximately 20 kilometers or 39 kilometers thick in two potential layers.
Scientists study the depth and composition of the bedrock using data from orbiters, landers, and rovers, which employ tools like ground-penetrating radar, cameras, and drills to analyze the surface and subsurface

Class A construction bricks are a type of engineering brick known for their high compressive strength and low water absorption. These durable bricks, often called Staffordshire Blues, are used in demanding civil and commercial projects requiring extreme resistance to water and frost, such as retaining walls, sewers, and tunnels.
They have a compressive strength of over \(125N/mm^{2}\) and a water absorption rate of less than 4.5%. 
Characteristics and specifications Compressive Strength:
Greater than \(125N/mm^{2}\) (approximately over \(18,000\) psi).

Water Absorption: Less than 4.5%.

Composition:
Typically made from clay that is fired at very high temperatures to create a dense, strong, and non-porous material.
Appearance:
Often a dark blue color due to the high-temperature firing process, though other colors may be available. Aesthetics are less important than their physical properties. 

Common applications 
Below-ground structures exposed to high moisture and frost.
Retaining walls.
Sewer systems.
Manholes.
Tunnels.
Damp proof courses.
Severe exposure applications and contrasting detailing in brickwork

Classification/Grade: Class A construction bricks
Key Properties:
[] Compressive Strength: High (typically around 125 N/mm²)
[] Water Absorption: Low (typically less than 4.5%)
Typical Applications:
[] Structural applications
[] Foundations
[] Tunnels
[] Below-ground work

There is no established "Class A" construction brick for Mars, but scientists are developing several promising alternatives to build habitats using in-situ resources. These methods include using Martian soil (regolith) compacted under pressure, with iron oxide acting as a natural binder, or creating binding agents from organic materials like potato starch, or through synthetic biology with biominerals and fungal mycelium.
Methods for creating Mars bricks
Compacted Martian soil:
Researchers have found that Martian soil simulant, when compacted under pressure alone, can form durable, strong bricks.
The iron oxide in the soil acts as a natural binding agent, and the bricks are reportedly stronger than steel-reinforced concrete.
This method is compatible with additive manufacturing, where layers of soil are compacted to build structures.
Starcrete (starch-based binder):
A material called Starcrete uses potato starch, salt, and Martian soil as a binding agent.
This method allows for the on-site production of building materials, avoiding the need to transport them from Earth.
It is stronger than regular concrete.
Biomineralization:
This method uses self-growing blocks created by agents like cyanobacteria and fungi to produce biominerals (e.g., calcium carbonate) and biopolymers.
These agents bind the regolith particles together to form building materials.
This is a "living bricks" concept where the materials are self-creating and require no human input for production, as discussed in SciTechDaily.
Other binding agents:
Scientists have also explored using protein from blood as a binder for Martian soil, similar to a concrete, as described in Stanford University's news.
Research has been conducted on using human blood, urine, and feces to create construction materials.
Sulfur cement and other types of cement substitutes are also being considered for use on Mars.
Key takeaway
While no official "Class A" designation exists, the primary goal is to use in-situ resources to create a sustainable building material for Mars habitats, with many different methods being explored and developed by researchers worldwide

No single "epoxy" product exists for Mars temperatures,

but

researchers are developing specialized polymer composites using epoxy resins mixed with simulated Martian soil (regolith) and other local materials. These composites are designed for high physical properties and thermal stability in extreme Martian conditions, with some examples including modifications with tetraethoxysilane (TEOS) or the use of thermoplastic polymers for enhanced durability and UV resistance.

Epoxy and polymer composites for Mars
Polymer composites:
Researchers are creating polymer composites that use local regolith as a filler in epoxy resins.
High physical properties: These composites are being developed to achieve high physical properties, including mechanical strength and thermal stability, for use as building materials.
Modified fillers:
Chemical modification of the Martian regolith filler, such as with TEOS, can significantly enhance the properties of the final composite, notes this study from Cambridge University Press & Assessment.
Other considerations
Thermoplastics:
In addition to traditional epoxy, advanced thermoplastics are also being explored for their UV resistance and recyclability, which are crucial for space environments, according to this article from SpringerLink.
Sulfur concrete:
Another research avenue is the development of sulfur-based concrete, which uses sulfur as a bonding agent and is recyclable, notes this article from ScienceDirect.
Waterless concrete:
Given the lack of liquid water on Mars, many of these new building materials, including the epoxy-based composites, are being designed to be waterless.
Geopolymer cement:
Other research is focused on creating geopolymer bricks by mixing Martian soil with a high-pH solution to create a strong, cement-like material, according to University of Delaware.

Technical and political obstacles block collaboration following suspected space debris strike on craft
SpaceX and Elon Musk are once again being called upon to rescue spacefarers — this time, the Chinese crew of Shenzhou-20, delayed on China's Tiangong space station after suspected space debris damage.…

The three-person crew including Chen Dong, Chen Zhongrui, and Wang Jie, arrived in April and were supposed to return in November after a handover with the Shenzhou-21 crew. That return has been postponed while engineers assess potential damage from what reports describe as "a tiny piece of space debris."

SpaceX fans quickly began calling for a rescue mission. Earlier this year, US President Donald Trump instructed Musk to "go get" the crew of Boeing's Starliner spacecraft, whom Trump claimed were "virtually abandoned" by the Biden administration. Rather than correct the misunderstanding, Musk pledged SpaceX would bring back the "stranded" astronauts.

A Chinese rescue mission is improbable as the Shenzhou-20 crew faces no immediate danger and China could simply launch Shenzhou-22 earlier as a replacement, if needed.

The situation is not without precedent. In 2022, a Soyuz spacecraft attached to the International Space Station (ISS) was struck by a micrometeor, and an uncrewed replacement vehicle was launched to ferry the 'nauts back to Earth. At the time, NASA explored the possibility of bringing the Soyuz crew back on a SpaceX spacecraft, but the option was deemed unnecessary.

Is a rescue mission for the Shenzhou-20 team using a Crew Dragon even feasible? The next Crew Dragon launch is currently scheduled for around March or April 2026 - the NASA Crew-12 mission to the ISS. The following one, set for June 2026, is to service the Vast-1 space station. One of those missions would need to be rescheduled to free up a spacecraft, as SpaceX does not have a fleet on standby in case of an emergency.

Then there is docking. Despite claims China copied the docking system used by SpaceX and the ISS - published international standards are readily available - China's orbital implementation likely won't mate with Crew Dragon hardware.

So a spacewalk then? SpaceX demonstrated EVA capability in 2024 when Jared Isaacman exited through Crew Dragon's nose. However the Chinese crew's launch suits aren't spacewalk-rated, and while Tiangong has Feitian EVA suits, they're incompatible with SpaceX systems — and might not even fit through Crew Dragon's hatch.

Then there is the whole political heat such a mission would generate. It is difficult to imagine a US rocket company and China cooperating in this way.

If Shenzhou-20 can't fly, it is more likely Shenzhou-22 will be launched as a replacement. The Tiangong space station was not designed to host a crew of more than three for extended stays.

The incident, which comes less than a year after SpaceX's "rescue" of the Boeing crew, underscores two increasingly critical issues: spaceflight systems need to be standardized to enable cross-nation rescues, and space debris is becoming impossible to ignore.

The irony wouldn't be lost on Reg readers if the debris that - possibly - struck Shenzhou-20 originated from a Chinese anti-satellite weapon (ASAT) test years ago.