Congratulations to Our 2024 Grand Prize and First Place Winners!

NETrolyze, a novel immunotherapy for triple-negative breast cancer (TNBC), was named the $25,000 grand prize winner at a live finalist round held November 15 in New York. The first-in-class therapeutic injectable gel prevents the spread of TNBC, one of the most aggressive cancer types, enabling patients to avoid toxic chemotherapy and expensive treatments – potentially transforming their lives. Click here for the full list of 2024 winners. Also see the Top 100 highest scoring entries.

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Since Tech Briefs magazine launched the Create the Future Design contest in 2002 to recognize and reward engineering innovation, over 15,000 design ideas have been submitted by engineers, students, and entrepreneurs in more than 100 countries. Join the innovators who dared to dream big by entering your ideas today.

Read About Past Winners’ Success Stories

Special Report spotlights the eight top entries in 2023 as well as past winners whose ideas are now in the market, making a difference in the world.

Click here to read more

A ‘Create the Future’ Winner Featured on ‘Here’s an Idea’

Spinal cord injury affects 17,000 Americans and 700,000 people worldwide each year. A research team at NeuroPair, Inc. won the Grand Prize in the 2023 Create the Future Design Contest for a revolutionary approach to spinal cord repair. In this Here’s an Idea podcast episode, Dr. Johannes Dapprich, NeuroPair’s CEO and founder, discusses their groundbreaking approach that addresses a critical need in the medical field, offering a fast and minimally invasive solution to a long-standing problem.

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Thank you from our Sponsors

“At COMSOL, we are very excited to recognize innovators and their important work this year. We are grateful for the opportunity to support the Create the Future Design Contest, which is an excellent platform for designers to showcase their ideas and products in front of a worldwide audience. Best of luck to all participants!”

— Bernt Nilsson, Senior Vice President of Marketing, COMSOL, Inc.

“From our beginnings, Mouser has supported engineers, innovators and students. We are proud of our longstanding support for the Create the Future Design Contest and the many innovations it has inspired.”

— Kevin Hess, Senior Vice President of Marketing, Mouser Electronics

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Microwave Extraction of Water for Space Propellant

Votes: 2
Views: 10426

Space exploration is EXTREMELY EXPENSIVE. We live in the deep valley of Earth’s gravitational well. Very large rockets are required to put small payloads into space. Launch mass must be reduced to create a sustainable future in space. A large fraction of spacecraft mass is propellant for in-space propulsion. Large reductions in launch mass will come from production of in-space rocket propellant from in-space water. Vast quantities of water are present at the lunar poles, on Mars, comets, and some asteroids. Using the in-space resource, solar energy, in-space water can be split into hydrogen and oxygen for propellant. Molecular water can even be used for the reaction mass ejecta with ion engines for missions to Mars and beyond. Returning from the surface of Mars will REQUIRE in-situ production of propellant. A manned Mars mission might need ~200 tons of propellant. With Earth launch costs of ~$10,000 per pound, space produced propellant could save billions of dollars that could be used to bootstrap the development of water extraction and rocket propellant production. This would go far to help develop the “cis-Lunar Space” architecture, ”The Transcontinental Railroad” of the 21st century.

We have been developing methods for microwave heating and water extraction for several years. Microwaves will penetrate the low thermal conductivity permafrost regolith to sublime subsurface water ice with subsequent recondensation of the water in an external cold trap. This simple vapor transport process could eliminate the need to excavate the soil and reduce the complexity of surface operations. But most importantly, it could greatly reduce the mass of mining equipment to be transported to the surface of the moon and to other planetary bodies.

Microwave extraction laboratory experiments and numerical simulations over the past 7 years demonstrate the utility of these innovative processes. FEM Multiphysics numerical analysis is being used to model laboratory experiments as well as to simulate possible space experiment scenarios of microwave heating of lunar, Martian, and asteroidal regolith. Different scientific experiments and mining scenarios have been simulated for different frequencies, power, heating times, water concentrations, and for regolith with different dielectric properties. Numerical simulations of energy beamed at the surface as well as delivery of energy down bore holes illustrate possible ways to determine spatial water concentration and subsequent mining operations. Simulations at high frequencies and low power demonstrate possible volatiles science experiments with decomposition of compounds at high temperatures to release chemically bound volatiles in asteroids. Ongoing simulation of water sublimation and vapor transport through regolith will permit the estimation of extraction engineering efficiency metrics. Future simulations of the different microwave processes will permit the design of space experiments, recommendations of potential spacecraft hardware requirements, and optimization of water extraction equipment and operations.

In order to create this new future in space, we need a paradigm shift to utilization of in-space resources, especially water, to leverage the sustainable and growing presence in space for scientific exploration, planetary protection, space debris mitigation, satellite servicing, and even space tourism to help “Create The Future” in Space.

  • Awards

  • 2013 Aerospace & Defense Category Winner
  • 2013 Top 100 Entries

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  • ABOUT THE ENTRANT

  • Name:
    Edwin Ethridge
  • Type of entry:
    individual
  • Profession:
    Scientist
  • Software used for this entry:
    COMSOL
  • Patent status:
    patented