Ucf research laying groundwork for off-world colonies watts up with that gas yoga


“We’re delighted we could get such a high-fidelity simulant,” Metzger said. “The fact that we were able to replicate those eight properties with such high fidelity tells us that these simulants will be very valuable for companies doing asteroid mining, doing tests of constructions of facilities and landing pads, metal extraction and more.”

“I think we did a good job of producing a simulant electricity generation by source that mimics the parent asteroidal material pretty well,” Britt said. “The limitations are really expense and safety, as some components can be toxic, so we use a lower-fidelity alternative. This gives the meteorite and space resources communities material that they can experiment on with some assurance that it is close to the real thing. That way they are not constrained by the scarcity of meteorite material or its high price.”

Metzger said the research team will continue to grade simulants created in the Exolith Lab as well as offer their grading system to simulants created in other labs. They will also be receiving feedback from the community about improvements in the grading system and will work with the American Society of Civil Engineers for consensus on having the grading electricity definition wikipedia standards adopted.

Co-authors of the study included Stephen Covey, retired director of research and development with Deep Space Industries (now Bradford Space); Cody Schultz, a UCF mechanical engineering graduate; Kevin M. Cannon, a postdoctoral scholar working with the Exolith Lab; Kevin D. Grossman, a materials science and engineering scientist with NASA; James G. Mantovani, a planetary scientist with NASA; and Robert P. Mueller, a senior technologist with NASA.

Founded in 1963 with a commitment to expanding opportunity and demanding excellence, the University of Central Florida develops the talent needed to advance the prosperity and welfare of our society. With more than 68,000 students, UCF is one of the nation’s largest universities, offering more gas bike alley than 220 degree programs at its main campus in Orlando and more than a dozen other locations in Central Florida and online. For more information, visit ucf.edu.

It seems we have no shortage of dubious future technology forecasts, along with dubious earth doom scenario forecasts! Predicting how much economic activity there will be off earth by 2100 is sort of like trying to predict how many truly self driving cars there will be by then. One is always assuming fundamental practical advances that might or might not ever go the way that enthusiasts predict.

As “a modest proposal”, start, say, by building a radio telescope array on the far side, and maybe also work on technology for providing an in space source of rocket fuels from lunar materials? If possible, an in-space fuel source could be helpful for expanding the use of communications satellites, and/or getting around in space a bit more cheaply. There is some prospect we could use lunar solar, lunar water and/or nitrogen compounds, etc., to do something along *that* line, why not, say, hypergolic propellants from lunar resources?

Anyway, the nice thing about the moon is that if your rocket transportation is working, you can at least expect to be able electricity outage austin to get back to the earth in a reasonably short time if necessary — just 4 days travel time, to get back to where there are such handy resources as a real atmosphere, etc. Not so much of a “back door” available if you are stuck on Mars electricity projects in pakistan! I mean, if your life support systems started to pack it in when you are weeks or months away from earth, you could just about begin your approved “kiz yur az goodbye”, your Last Rites, or whatever, immediately, it seems to me.

I’m very much in agreement with, and in the same camp with Joel O’Bryan. Like Joel imagined a Mars astronaut, “Oh boy, I get to put on this super stinky suit, now full of my dead skin cells, and covered in Martian dust, to go out and somewhat look at this dead, cold rock one more time. I can only smell my own stink, I can’t feel wind or sun on my skin, and I can’t even scratch my nose when it itches or rub my eyes. Even sneezing and coughing are major problems. Farting? Don’t even go there, although it is a change from having to smell the normal odor inside this suit”.

Mars has no magnetosphere, so any atmosphere and water (exception – some ice) it ever had has been blown out into space by the solar wind. Without a magnetosphere, Mars is unprotected from Solar and Interstellar radiation; a very real problem. Without a magnetosphere, there is no hope of ever “terraforming” Mars; not with anything close to current known technologies. Its atmosphere is 1/100 that of Earth, and is comprised of 95+% CO2. Its gravity is 1/3 that of Earth. It is colder than the Antarctic most of the time. There is no life in the ground electricity towers in japan, so it is dirt and not soil, and therefore cannot support plants. It may be rich in minerals, but without the micro-organic life found in Earth’s soils, plants won’t natively grow there.