NASA wants its private commercial space company partners to make more Moon deliveries on its behalf: The agency just issued another request for scientific and experimental payloads that need lunar delivery sometime in 2022, in part to help pave the way for NASA’s Artemis human lunar landing mission planned for 2024.
NASA previously established its Commercial Lunar Payload Services (CLPS) program in order to build a stable of approved vendors for a special special type of service, namely providing lunar landers that would be able to handle last-mile delivery of special payloads to the Moon. It now counts 14 companies on this list of vendors, including Astrobotic, Blue Origin, Lockheed Martin, SpaceX and Firefly to name a few, who are eligible to bid on contracts it creates to take specific cargo to the lunar surface.
Already, NASA has contracted two batches of payloads under the CLPS program, which will make up four planned total launches already under contract, including Astrobotic’s Peregrine Mission One set for June 2021; Intutive Machines IM-1 for October the same year; Masten’s Mission One for December 2022; and Astrobotic’s VIPER mission for sometime in 2023.
The list of new payloads for this round include a variety of scientific instruments, including a lunar regolith (that’s the Moon equivalent of soil) adhesion testing device; X-ray imagers; a dust shield created by the interaction of electric fields; and an advanced Moon vacuum for returning surface samples to Earth for more testing.
NASA’s private partners on the CLPS list will now be able to submit bids to cary the new list of 10 experiments and demonstrations, with the goal of delivering said equipment by 2022. The agency expects to pick a winner for this latest award by the end of this year.
In a new move designed to encourage more economic and scientific collaboration between spacefaring nations, the UK and US governments have signed a new agreement that would make it possible for US companies to take part in space launches from the UK, including its many ind=-development spaceports.
The dal sounds one-way – but the nature of the agreement is designed to bolster the supply, development and customer pipeline for UK’s bourgeoning spaceport industry. The agreement now in place not only allows US companies to launch from UK spaceports, but also means that US tech companies active in any portion of the launch industry supply chain will be able to contribute to UK-based launch site setup and operation.
The goal for the UK space industry is to start active launches sometime this year, and UK regulators and government funding sources have come together to achieve this goal. The country is working on a number of spaceports, including both horizontal launch sites for launch vehicles like those operated by Virgin Orbit and Virgin Galactic, as well as vertical spaceports for more traditional rockets.
Commercial space is an increasingly lucrative market in terms of launch contracts and payload development and integration. UK companies already participate actively in the US-based private launch industry, which is already up and running thanks to private launch companies including SpaceX and Blue Origin, as well as active spaceports in the US including the Mojave Air and Spaceport from which Virgin Orbit operates.
Spaceport Cornwall is one of the sites currently in development, and launch startup Skyhrorar has also been launching from a site in Scotland as it continues its own rocket testing and certification program.
UK-based space industry organization Access Space co-founder and director Tony Azzarelli provided the following statement to TechCrunch regarding this development:
We are thrilled that the UK has signed such agreement as it would boost the space sector in the UK, both from lending a hand to US launchers, as well as increasing the importance of the UK as a launching state and thus investment from government to promote its own launch industry sector, e.g., Skyrora, Orbex, Reaction Engines, Rocket Plane, Spaceport Cornwall, Astroscale, etc.
SpaceX on Saturday launched two NASA astronauts aboard its Crew Dragon spacecraft, and the accomplishment is a tremendous one for both the company and the U.S. space agency. At a fundamental level, it means that the U.S. will have continued access to the International Space Station, without having to rely on continuing to buy tickets aboard a Russian Soyuz spacecraft to do so. But it also means the beginning of a new era for the commercial space industry – one in which private companies and individual buying tickets for passenger trips to space is a consistent and active reality.
With this mission, SpaceX will complete the final step required by NASA to human-rate its Falcon 9 and Crew Dragon spacecraft, which means that it can begin operationally transporting people from Earth essentially as soon as this mission concludes (Crew Dragon still has to rendezvous with the space station tomorrow, and make its way back to Earth with astronauts on board in a few weeks). Already, SpaceX has signed an agreement with Space Adventures, a private space tourism booking company that has previously worked with Roscosmos on sending private astronauts to orbit.
SpaceX wants to start sending up paying tourists on orbital flights (without any ISS stops) starting as early as next year aboard Crew Dragon. The capsule actually supports up to seven passengers per flight, though only four seats will ever be used for official NASA crew delivery missions for the space station. SpaceX hasn’t released pricing on private trips aboard the aircraft, but you can bet they’ll be expensive since a Falcon 9 launch (without a human rated capsule) costs around $60 million, and so even dividing that by seven works out to a high price of entry.
So this isn’t the beginning of the era of accessible private spaceflight, but SpaceX is the first private company to actually put people into space, despite a lot of talk and preparatory work by competitors like Virgin Galactic and Blue Origin. And just like in the private launch business, crossing the gulf between having a private company that talks about doing something, and a company that actually does it, will absolutely transform the space industry all over again.
SpaceX is gearing up to launch tourists as early as next year, as mentioned, and while those tourists will have to be deep-pocketed, as eight everything that SpaceX does, the goal is to continue to find ways to make more aspects of the launch system reusable and reduce costs of launch in order to bring prices down.
Even without driving down costs, SpaceX will have a market, however niche, and one that hasn’t yet really had any inventory to satisfy demand. Space Adventures has flown a few individuals by buying tickets on Soyuz launches, but that hasn’t really been a consistent or sustainable source of commercial human spaceflight, and SpaceX’s system will likely have active support and participation from NASA.
That’s an entirely new revenue stream for SpaceX to add to its commercial cargo launches, along with its eventual launch of commercial internet service via Starlink. It’s hard to say yet what kind of impact that will actually have on their bottom line, but it could be big enough to have an impact – especially if they can figure out creative ways to defray costs over successive years, since each cut will likely considerably expand their small addressable audience.
SpaceX’s impact on the launch business was to effectively create a market for small satellites and more affordable orbital payloads that simply didn’t make any economic sense with larger existing launch craft, most of which were bankrolled almost entirely by and for defence and NASA use. Similarly, it’s hard to predict what the space tourism market will look like in five years, now that a company is actually offering it and flying a human-rated private spacecraft that can make it happen.
Private spacefarers won’t all be tourists – in fact, it could make a lot more financial sense for the majority of passengers to and from orbit to be private scientists and researchers. Basically, imagine a NASA astronaut, but working for a private company rather than a publicly-funded agency.
Astronauts are essentially multidisciplinary scientists, and the bulk of their job is conducing experiments on the ISS. NASA is very eager to expand commercial use of the ISS, and also to eventually replace the aging space station with a private one of which they’re just one of multiple customers. Already, the ISS hosts commercial experiments and cargo, but if companies and institutions can now also send their own researchers as well, that may change considerably how much interest their is in doing work on orbit, especially in areas like biotech where the advantages of low gravity can produce results not possible on Earth.
Cost is a gain a significant limiting factor here, since the price per seat will be – no pun intended – astronomical. But for big pharma and other large companies who already spend a considerable amount on R&D it might actually be within reach. Especially in industries like additive manufacturing, where orbit is an area of immense interest, private space-based labs with actual rotating staff might not be that farfetched an idea.
Marketing & Entertainment
Commercial human spaceflight might actually be a great opportunity to make actual commercials – brands trying to outdo each other by shooting the first promo in space definitely seems like a likely outcome for a Superbowl spot. It’s probably not anyone’s priority just now, given the ongoing global pandemic, but companies have already discussed the potential of marketing partnerships as a key driver of real revenue, including lunar lander startup ispace, which has signed a number of brand partners to fund the build and flight of its hardware.
Single person rides to orbit are definitely within budget for the most extreme marketing efforts out there, and especially early on, there should be plenty of return on that investment just because of how audacious and unique the move is. The novelty will likely wear off, but access to space will remain rarified enough for the forseeable future that it could still be part of more than a few marketing campaigns.
Cruise probably isn’t the only one to consider the impact of a space-based motion picture project, and you can bet at least one reality show producer somewhere is already pitching ‘The Bachelor’ in space. Again, it’s not going to be within budget for every new sci-fi project that spins up, but it’s within blockbuster budget range, and that’s another market that grew by 100% just by virtue of the fact that it didn’t exist as a possibility before today.
It’s hard to fully appreciate what kind of impact this will have, because SpaceX has literally taken something that previously wasn’t possible, and made it available – at costs that, while high, aren’t so high as to be absurd. As with every other such expansion, it will likely create new and innovative opportunities that haven’t even been conceived, especially once the economics and availability of flights, etc. are clarified. GPS, another great space-based innovation, formed the bedrock of an industry that changed just about every aspect of human life – private commercial spaceflight could do the same.
NASA has finalized the payloads for its first cargo deliveries scheduled to be carried by commercial lunar landers, vehicles created by companies the agency selected to take part in its Commercial Lunar Payload Services (CLPS) program. In total, there are 16 different payloads, which consist of a number of difference science experiments and technology experiments, that will be carried by landers built by Astrobotic and Intuitive Machines. Both of these landers are scheduled to launch next year, carrying their cargo to the Moon’s surface and helping prepare the way for NASA’s mission to return humans to the Moon by 2024.
Astrobotic’s Peregrine is set to launch aboard a rocket provided by the United Launch Alliance (ULA), while Intuitive Machines’ Nova-C lander will make its own lunar trip aboard a SpaceX Falcon 9 rocket. Both landers will carry two of the payloads on the list, including a Laser Retro-Reflector Array (LRA) that is basically a mirror-based precision location device for situating the lander itself; and a Navigation Doppler Lidar for Precise Velocity and Range Sensing (NDL) – a laser-based sensor that can provide precision navigation during descent and touchdown. Both of these payloads are being developed by NASA to ensure safe, controlled and specifically targeted landing of spacecraft on the Moon’s surface, and their use here be crucial in building robust lunar landing systems to support Artemis through the return of human astronauts to the Moon and beyond.
Besides those two payloads, everything else on either lander is unique to one vehicle or the other. Astrobotic is carrying more, but its Peregrine lander can hold more cargo – its payload capacity tops out at around 585 lbs, whereas the Nova-C can carry a maximum of 220 lbs. The full list of what each lander will have on board is available below, as detailed by NASA.
Overall, NASA has 14 total contractors that could potentially provide lunar payload delivery services through its CLPS program. That basically amounts to a list of approved vendors, who then bid on whatever contracts the agency has available for this specific need. Other companies on the CLPS list include Blue Origin, Lockheed Martin, SpaceX and more. Starting with these two landers next year, NASA hopes to fly around two missions per year each year through the CLPS program.
Surface Exosphere Alterations by Landers (SEAL): SEAL will investigate the chemical response of lunar regolith to the thermal, physical and chemical disturbances generated during a landing, and evaluate contaminants injected into the regolith by the landing itself. It will give scientists insight into the how a spacecraft landing might affect the composition of samples collected nearby. It is being developed at NASA Goddard.
Photovoltaic Investigation on Lunar Surface (PILS): PILS is a technology demonstration that is based on an International Space Station test platform for validating solar cells that convert light to electricity. It will demonstrate advanced photovoltaic high-voltage use for lunar surface solar arrays useful for longer mission durations. It is being developed at Glenn Research Center in Cleveland.
Linear Energy Transfer Spectrometer (LETS): The LETS radiation sensor will collect information about the lunar radiation environment and relies on flight-proven hardware that flew in space on the Orion spacecraft’s inaugural uncrewed flight in 2014. It is being developed at NASA Johnson.
Near-Infrared Volatile Spectrometer System (NIRVSS): NIRVSS will measure surface and subsurface hydration, carbon dioxide and methane – all resources that could potentially be mined from the Moon — while also mapping surface temperature and changes at the landing site. It is being developed at Ames Research Center in Silicon Valley, California.
Mass Spectrometer Observing Lunar Operations (MSolo): MSolo will identify low-molecular weight volatiles. It can be installed to either measure the lunar exosphere or the spacecraft outgassing and contamination. Data gathered from MSolo will help determine the composition and concentration of potentially accessible resources. It is being developed at Kennedy Space Center in Florida.
PROSPECT Ion-Trap Mass Spectrometer (PITMS) for Lunar Surface Volatiles: PITMS will characterize the lunar exosphere after descent and landing and throughout the lunar day to understand the release and movement of volatiles. It was previously developed for ESA’s (European Space Agency) Rosetta mission and is being modified for this mission by NASA Goddard and ESA.
Neutron Spectrometer System (NSS): NSS will search for indications of water-ice near the lunar surface by measuring how much hydrogen-bearing materials are at the landing site as well as determine the overall bulk composition of the regolith there. NSS is being developed at NASA Ames.
Neutron Measurements at the Lunar Surface (NMLS): NMLS will use a neutron spectrometer to determine the amount of neutron radiation at the Moon’s surface, and also observe and detect the presence of water or other rare elements. The data will help inform scientists’ understanding of the radiation environment on the Moon. It’s based on an instrument that currently operates on the space station and is being developed at Marshall Space Flight Center in Huntsville, Alabama.
Fluxgate Magnetometer (MAG): MAG will characterize certain magnetic fields to improve understanding of energy and particle pathways at the lunar surface. NASA Goddard is the lead development center for the MAG payload.
Intuitive Machines Payloads
Lunar Node 1 Navigation Demonstrator (LN-1): LN-1 is a CubeSat-sized experiment that will demonstrate autonomous navigation to support future surface and orbital operations. It has flown on the space station and is being developed at NASA Marshall.
Stereo Cameras for Lunar Plume-Surface Studies (SCALPSS): SCALPSS will capture video and still image data of the lander’s plume as the plume starts to impact the lunar surface until after engine shut off, which is critical for future lunar and Mars vehicle designs. It is being developed at NASA Langley, and also leverages camera technology used on the Mars 2020 rover.
Low-frequency Radio Observations for the Near Side Lunar Surface (ROLSES): ROLSES will use a low-frequency radio receiver system to determine photoelectron sheath density and scale height. These measurements will aide future exploration missions by demonstrating if there will be an effect on the antenna response or larger lunar radio observatories with antennas on the lunar surface. In addition, the ROLSES measurements will confirm how well a lunar surface-based radio observatory could observe and image solar radio bursts. It is being developed at NASA Goddard.