Depending on the weather, New Shepard’s 23rd mission, a dedicated payloads flight, will fly 36 payloads from academia, research institutions, and students across the globe. The original Aug. 31 launch window was scrubbed due to rain. A new target launch time was set for this morning.
This mission brings the total number of commercial payloads flown on the vehicle to more than 150. Two of the payloads will fly on the exterior of the New Shepard booster for ambient exposure to the space environment. Eighteen of the payloads on this flight are funded by NASA, primarily by the Flight Opportunities program.
Twenty-four payloads are from K-12 schools, universities, and STEM-focused organizations, including the American Institute of Aeronautics and Astronautics (AIAA), American Society for Gravitational and Space Research (ASGSR), and SHAD Canada STEM Foundation, among others. This is double the number of education-focused payloads from previous payload flight manifests. In many cases, these payloads expose students as young as elementary school to STEM skills like coding, environmental testing, and CAD design often not taught until college.
Among the NS-23 payloads are tens of thousands of postcards from Blue Origin’s nonprofit, Club for the Future, whose Postcards to Space program gives people across the world access to space on New Shepard. The Club’s mission is to inspire future generations to pursue careers in STEM for the benefit of Earth. The postcards on this mission come from 19 Club for the Future grant recipients and their partners, including Guayaquil’s Space Society in Ecuador, the U.S. Space and Rocket Center, students who participated in STEM NOLA and Kenner Planetarium events in New Orleans, and schools across Kentucky.
This will be the fourth flight for the New Shepard program this year, the first dedicated payload flight since NS-17 in August 2021, and the ninth flight for this vehicle, which is dedicated to flying science and research payloads to space. To date, the New Shepard program has flown 31 humans to space.
NS-23 Flight Manifest Highlights:
•Infinity Fuel Cell:AMPES
Infinity Fuel Cell’sAMPES experiment demonstrates the operation of hydrogen fuel cell technology in microgravity. The company is collaborating with NASA’s Johnson Space Center in Houston to develop a scalable, modular, and flexible power and energy product utilizing new manufacturing methods to reduce cost and improve reliability. The technology could be used for lunar rovers, surface equipment, and habitats. NASA’s Space Technology Mission Directorate Tipping Point program provided funding.
Honeybee Robotics: ASSET-1
ASSET is a testbed designed to study the strength of planetary soils, called regolith, under different gravity conditions. ASSET-1 is the experiment’s first flight on New Shepard and will be tested in microgravity to help determine the soil strength of asteroids, for example. ASSET and its future iterations can also be used to study parameters such as particle sizes and different loading conditions. This experimental payload was developed by Honeybee Robotics in Altadena, Calif., which was acquired by Blue Origin earlier this year, and is funded by NASA’s Flight Opportunities program.
•University of Florida: BISS
Principal investigators Rob Ferl and Anna-Lisa Paul adapted technology that was originally designed for the International Space Station to suborbital uses with their experiment, “Biological Imaging in Support of Suborbital Science” (BISS). Through hardware developments and enhancing the way data is collected during the spaceflight, the FLEX fluorescence imaging system enables increasingly precise and dynamic understanding of biological responses to suborbital missions. This will be the fifth flight of the technology development series on New Shepard and includes science collaboration with the University of Wisconsin. Funding was provided by the NASA Flight Opportunities andBiological and Physical Sciences programs.
•NASA Armstrong Flight Research Center: CFOSS
CFOSS is a space-rated Fiber Optic Sensing System (FOSS) technology to measure temperature and strain data to accelerate technology readiness levels before a low-Earth orbit launch. Developed at NASA Armstrong Flight Research Center, this experiment will be the first spaceflight for NASA’s fiber optics-based instrumentation for structural health monitoring. These measurements can enable the monitoring of additional parameters such as structural deformation and cryogenic liquid level estimations.
ENGARTBOX is a project that integrates engineering, science, and art by attempting to overcome the engineering and scientific challenges of producing a painting in a non-gravity environment. The payload was developed by students and teachers at Anatolia College in Thessaloniki, Greece, in the new Anna Papageorgiou STEM Center of the school, in conjunction with Dr. Takis Papadopoulos. The experiment is sponsored by ΒΕΤΑ CAE andHigas, and managed by Dr. OlympiaKyriopoulos from OLYMPIASPACE.
•NeoCity Academy:WoS (Wings of Steel)
A group of six high school students fromNeoCity Academy in Kissimmee, Florida, is sending a three-minute experiment into microgravity to test the effects of gravity on ultrasonic sound waves. Investigating ultrasonic sound waves and their behavior in space could lead to further future discoveries about other types of waves.
•Johns Hopkins University Applied Physics Laboratory: JANUS-APL
The Johns Hopkins Applied Physics Laboratory (APL) will mount its JANUS payload on the New Shepard Propulsion Module for the first time to measure conditions outside the crew capsule and enable access to the space environment. This new capability will provide important insight into a critical but difficult to study region of Earth’s atmosphere as well as facilitate lower cost instrument/technology testing for missions to Earth’s orbit and beyond. APL already has multiple follow-on flights on New Shepard to expand this capability to accommodate telescopes, cameras, and the deployment of very small sensors.
•MIT Media Lab: WAX CASTING
The WaxCasting experiment will test how cleaner propellants such as paraffin and beeswax can be fabricated in space in the future. The goal of the experiment is to visualize what happens when two liquids, melted candlewax and a similar liquid called Heptadecane, are rotated. By rotating these liquids in tubes, researchers can begin to understand how a process to form wax into fuel grains could be effective in future hybrid propulsion systems that combine solid fuel with gaseous oxidizers. Many traditional solid space fuels are harmful to people and the environment, whilewax is affordable and non-toxic. The payload was developed by researchers at the MIT Media Lab’s Space Enabled Research Group with support from Tec-Masters, Inc. of Huntsville, AL. Funding was provided byNASA’s Space Technology Mission Directorate.
•Titan Space Technologies: T-2 MissionArroway
Titan Space Technologies is testing their latest advanced AI capabilities on this mission by continuously analyzing data across multiple sensors and adapting their experiment in real time. These results will help Titan advance the development of their AI-powered platform for space experimentation. Titan designed and executed the payload in fewer than 60 days.
•Creare, LLC and Dartmouth University: VARD
The VARD payload will demonstrate a novel sensor that measures the volume of liquid in a flexible bladder in microgravity. The sensor and payload were developed atCreare and tested in collaboration with the Geisel School of Medicine at Dartmouth. Funding to develop the sensor was provided by NASA’s Small Business Technology Transfer (STTR) Program.