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Our astronauts will be settling on Mars indefinitely. It's not feasible to send water, oxygen and food from Earth to the astronauts: they will produce those on Mars.

On Mars, water can be extracted from the soil. The rover will select the location for the settlement primarily based on the water content in the soil. We expect this to be at a latitude of between 40 and 45 degrees North latitude. Water extraction will be performed by the life support units. The rover will deposit soil into a water extractor in the life support units. The water extractor will heat the soil until the water evaporates. The evaporated water will be condensed and stored, the dry soil expelled, and the process repeated to extract more water.About 1500 liters of reserve water will be stored in each life support unit, which will be consumed primarily at night, and during periods of protracted low power availability, for example during dust storms.

Since Mars has gravity, water can be used in the same way as on Earth. Each astronaut will be able to use about 50 liters of water per day. The water will be recycled, which takes much less energy than extracting it from the Martian soil. Only water that can not be recycled will be replaced by water extracted from the soil.

Oxygen can be produced by splitting water into its constituent parts, hydrogen and oxygen. The oxygen will be used to provide a breathable atmosphere in the living units, and a portion will be stored in reserve for conditions when there is less power available, for example at night, and during dust storms.

The second major component of the living units' atmosphere, nitrogen, will be extracted directly from the Martian atmosphere by the life support unit.

When the astronauts land on Mars, there will be storable food from Earth waiting for them to use. The storable food from Earth will only serve as emergency rations, which means the astronauts will try to eat as much fresh food that they produce on Mars as possible. It is likely that algae and insects will also be part of the diet on Mars.

Food production will occur indoor under artificial lighting. In total, there will be approximately 80 m2 available for plant growth in the original habitat. The first crew will also be able to use the habitat of the second crew to grow food because the hardware for the second crew lands only a few weeks after the first crew lands.

A thick layer of Martian soil on top of the inflatable habitat will protect the plants (and the astronauts) from radiation. CO2 for the plants is available from the Mars atmosphere and water is available through recycling and the soil on Mars. Nutrients for the plants could come from recycling human waste or could be imported from Earth.

Any plant production surplus will be stored as emergency rations for the second crew and for emergencies. Non-edible parts of the plants will be recycled or stored until more advanced recycling equipment is shipped from Earth.

Mars One will investigate the volume requirements for food production in the simulation outpost and the crews will be trained for many years to operate the greenhouse equipment. The aim is for colony to be independent from the food they receive from Earth. There will always be enough emergency rations in storage, locally produced or from Earth, to survive until the next supply mission comes.

Mars One released aconceptual design report of the Surface Habitat Environmental Control and Life Support Systems (ECLSS) performed by Paragon Space Development Corporation. The ECLSS will create a safe environment for the Mars inhabitants, supplying them with clean air and water while recycling wastes. A concise abstract of the independent Paragon report can be found here:How to keep humans alive on Mars - Abstract Surface Habitat ECLSS Conceptual Design.

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Will the astronauts have enough water, food and ... - Mars One

In many cases astronomical phenomena viewed from the planet Mars are the same or similar to those seen from Earth but sometimes (as with the view of Earth as an evening/morning star) they can be quite different. For example, because the atmosphere of Mars does not contain an ozone layer, it is also possible to make UV observations from the surface of Mars.

Mars has an axial tilt of 25.19, quite close to the value of 23.44 for Earth, and thus Mars has seasons of spring, summer, autumn, winter as Earth does. As on Earth, the southern and northern hemispheres have summer and winter at opposing times.

However, the orbit of Mars has significantly greater eccentricity than that of Earth. Therefore, the seasons are of unequal length, much more so than on Earth:

In practical terms, this means that summers and winters have different lengths and intensities in the northern and southern hemispheres. Winters in the north are warm and short (because Mars is moving fast near its perihelion), while winters in the south are long and cold (Mars is moving slowly near aphelion). Similarly, summers in the north are long and cool, while summers in the south are short and hot. Therefore, extremes of temperature are considerably wider in the southern hemisphere than in the north.

The seasonal lag on Mars is no more than a couple of days,[1] due to its lack of large bodies of water and similar factors that would provide a buffering effect. Thus, for temperatures on Mars, "spring" is approximately the mirror image of "summer" and "autumn" is approximately the mirror image of "winter" (if you consider the solstices and equinoxes to be the beginnings of their respective seasons), and if Mars had a circular orbit the maximum and minimum temperatures would occur a couple of days after the summer and winter solstices rather than about one month after as on Earth. The only difference between spring temperatures and summer temperatures is due to the relatively high eccentricity of Mars's orbit: in northern spring Mars is farther from the Sun than during northern summer, and therefore by coincidence spring is slightly cooler than summer and autumn is slightly warmer than winter. However, in the southern hemisphere the opposite is true.

The temperature variations between spring and summer are much less than the very sharp variations that occur within a single Martian sol (solar day). On a daily basis, temperatures peak at local solar noon and reach a minimum at local midnight. This is similar to the effect in Earth's deserts, only much more pronounced.

The axial tilt and eccentricity of Earth (or Mars) are by no means fixed, but rather vary due to gravitational perturbations from other planets in the Solar System on a timescale of tens of thousands or hundreds of thousands of years. Thus, for example Earth's eccentricity of about 1% regularly fluctuates and can increase up to 6%, and at some point in the distant future the Earth will also have to deal with the calendrical implications of seasons of widely differing length and the major climate disruptions that go along with it.

Aside from the eccentricity, the Earth's axial tilt can also vary from 21.5 to 24.5, and the length of this "obliquity cycle" is 41,000 years. These and other similar cyclical changes are thought to be responsible for ice ages (see Milankovitch cycles). By contrast, the obliquity cycle for Mars is much more extreme: from 15 to 35 over a 124,000-year cycle. Some recent studies even suggest that over tens of millions of years, the swing may be as much as 0 to 60.[2] Earth's large Moon apparently plays an important role in keeping Earth's axial tilt within reasonable bounds; Mars has no such stabilizing influence and its axial tilt can vary more chaotically.

The normal hue of the sky during the daytime is a pinkish-red; however, in the vicinity of the setting or rising sun it is blue. This is the exact opposite of the situation on Earth. However, during the day the sky is a yellow-brown "butterscotch" color.[3] On Mars, Rayleigh scattering is usually a very small effect. It is believed that the color of the sky is caused by the presence of 1% by volume of magnetite in the dust particles. Twilight lasts a long time after the Sun has set and before it rises, because of all the dust in Mars' atmosphere. At times, the Martian sky takes on a violet color, due to scattering of light by very small water ice particles in clouds.[4]

Generating accurate true-color images of Mars's surface is surprisingly complicated.[5] There is much variation in the color of the sky as reproduced in published images; many of those images, however, are using filters to maximize the scientific value and are not trying to show true color. Nevertheless, for many years, the sky on Mars was thought to be more pinkish than it now is believed to be.

As seen from Mars, the Earth is an inner planet like Venus (a "morning star" or "evening star"). The Earth and Moon appear starlike to the naked eye, but observers with telescopes would see them as crescents, with some detail visible.

An observer on Mars would be able to see the Moon orbiting around the Earth, and this would easily be visible to the naked eye. By contrast, observers on Earth cannot see any other planet's satellites with the naked eye, and it was not until soon after the invention of the telescope that the first such satellites were discovered (Jupiter's Galilean moons).

At maximum angular separation, the Earth and Moon would be easily distinguished as a double planet, but about one week later they would merge into a single point of light (to the naked eye), and then about a week after that, the Moon would reach maximum angular separation on the opposite side. The maximum angular separation of the Earth and Moon varies considerably according to the relative distance between the Earth and Mars: it is about 25 when Earth is closest to Mars (near inferior conjunction) but only about 3.5 when the Earth is farthest from Mars (near superior conjunction). For comparison, the apparent diameter of the Moon from Earth is 31.

The minimum angular separation would be less than 1, and occasionally the Moon would be seen to transit in front of or pass behind (be occulted by) the Earth. The former case would correspond to a lunar occultation of Mars as seen from Earth, and because the Moon's albedo is considerably less than that of the Earth, a dip in overall brightness would occur, although this would be too small to be noticeable by casual naked eye observers because the size of the Moon is much smaller than that of the Earth and it would cover only a small fraction of the Earth's disk.

Mars Global Surveyor imaged the Earth and Moon on May 8, 2003 13:00 UTC, very close to maximum angular elongation from the Sun and at a distance of 0.930 AU from Mars. The apparent magnitudes were given as 2.5 and +0.9.[8] At different times the actual magnitudes will vary considerably depending on distance and the phases of the Earth and Moon.

From one day to the next, the view of the Moon would change very differently for an observer on Mars than for an observer on Earth. The phase of the Moon as seen from Mars would not change much from day to day; it would match the phase of the Earth, and would only gradually change as both Earth and Moon move in their orbits around the Sun. On the other hand, an observer on Mars would see the Moon rotate, with the same period as its orbital period, and would see far side features that can never be seen from Earth.

Since Earth is an inner planet, observers on Mars can occasionally view transits of Earth across the Sun. The next one will take place in 2084. They can also view transits of Mercury and transits of Venus.

The moon Phobos appears about one third the angular diameter that the full Moon appears from Earth; on the other hand, Deimos appears more or less starlike with a disk barely discernible if at all. Phobos orbits so fast (with a period of just under one third of a sol) that it rises in the west and sets in the east, and does so twice per sol; Deimos on the other hand rises in the east and sets in the west, but orbits only a few hours slower than a Martian sol, so it spends about two and a half sols above the horizon at a time.

The maximum brightness of Phobos at "full moon" is about magnitude 9 or 10, while for Deimos it is about 5.[9] By comparison, the full Moon as seen from Earth is considerably brighter at magnitude 12.7. Phobos is still bright enough to cast shadows; Deimos is only slightly brighter than Venus is from Earth. Just like Earth's Moon, both Phobos and Deimos are considerably fainter at non-full phases. Unlike Earth's Moon, Phobos's phases and angular diameter visibly change from hour to hour; Deimos is too small for its phases to be visible with the naked eye.

Both Phobos and Deimos have low-inclination equatorial orbits and orbit fairly close to Mars. As a result, Phobos is not visible from latitudes north of 70.4N or south of 70.4S; Deimos is not visible from latitudes north of 82.7N or south of 82.7S. Observers at high latitudes (less than 70.4) would see a noticeably smaller angular diameter for Phobos because they are farther away from it. Similarly, equatorial observers of Phobos would see a noticeably smaller angular diameter for Phobos when it is rising and setting, compared to when it is overhead.

Observers on Mars can view transits of Phobos and transits of Deimos across the Sun. The transits of Phobos could also be called partial eclipses of the Sun by Phobos, since the angular diameter of Phobos is up to half the angular diameter of the Sun. However, in the case of Deimos the term "transit" is appropriate, since it appears as a small dot on the Sun's disk.

Since Phobos orbits in a low-inclination equatorial orbit, there is a seasonal variation in the latitude of the position of Phobos's shadow projected onto the Martian surface, cycling from far north to far south and back again. At any given fixed geographical location on Mars, there are two intervals per Martian year when the shadow is passing through its latitude and about half a dozen transits of Phobos can be observed at that geographical location over a couple of weeks during each such interval. The situation is similar for Deimos, except only zero or one transits occur during such an interval.

It is easy to see that the shadow always falls on the "winter hemisphere", except when it crosses the equator during the vernal and the autumnal equinoxes. Thus transits of Phobos and Deimos happen during Martian autumn and winter in the northern hemisphere and the southern hemisphere. Close to the equator they tend to happen around the autumnal equinox and the vernal equinox; farther from the equator they tend to happen closer to the winter solstice. In either case, the two intervals when transits can take place occur more or less symmetrically before and after the winter solstice (however, the large eccentricity of Mars's orbit prevents true symmetry).

Observers on Mars can also view lunar eclipses of Phobos and Deimos. Phobos spends about an hour in Mars's shadow; for Deimos it is about two hours. Surprisingly, despite its orbit being nearly in the plane of Mars's equator and despite its very close distance to Mars, there are some occasions when Phobos escapes being eclipsed.

Phobos and Deimos both have synchronous rotation, which means that they have a "far side" that observers on the surface of Mars can't see. The phenomenon of libration occurs for Phobos as it does for Earth's Moon, despite the low inclination and eccentricity of Phobos's orbit.[10][11]Due to the effect of librations and the parallax due to the close distance of Phobos, by observing at high and low latitudes and observing as Phobos is rising and setting, the overall total coverage of Phobos's surface that is visible at one time or another from one location or another on Mars's surface is considerably higher than 50%.

The large Stickney crater is visible along one edge of the face of Phobos. It is easily visible with the naked eye from the surface of Mars.

Since Mars has an atmosphere that is relatively transparent at optical wavelengths (just like Earth, albeit much thinner), meteors will occasionally be seen. Meteor showers on Earth occur when the Earth intersects the orbit of a comet, and likewise, Mars also has meteor showers, although these are different from the ones on Earth.

The first meteor photographed on Mars (on March 7, 2004 by the Spirit rover) is now believed to have been part of a meteor shower whose parent body was comet 114P/Wiseman-Skiff. Because the radiant was in the constellation Cepheus, this meteor shower could be dubbed the Martian Cepheids.[12]

As on Earth, when a meteor is large enough to actually impact with the surface (without burning up completely in the atmosphere), it becomes a meteorite. The first known meteorite discovered on Mars (and the third known meteorite found someplace other than Earth) was Heat Shield Rock. The first and the second ones were found on the moon by the Apollo missions.[13][14]

On October 19, 2014, Comet Siding Spring passed extremely close to Mars, so close that the coma may have enveloped the planet.[15][16][17][18][19][20]

Auroras occur on Mars, but they do not occur at the poles as on Earth, because Mars has no planetwide magnetic field. Rather, they occur near magnetic anomalies in Mars's crust, which are remnants from earlier days when Mars did have a magnetic field. Martian auroras are a distinct kind not seen elsewhere in the Solar System.[21] They would probably also be invisible to the human eye, being largely ultraviolet phenomena.[22]

The orientation of Mars's axis is such that its north celestial pole is in Cygnus at R.A. 21h 10m 42s Decl. +5253.0 (or more precisely, 317.67669 +52.88378), near the 6th-magnitude star BD +52 2880 (also known as HR 8106, HD 201834, or SAO 33185), which in turn is at R.A. 21h 10m 15.6s Decl. +533348.

The top two stars in the Northern Cross, Sadr and Deneb, point to the north celestial pole of Mars.[23] The pole is about halfway between Deneb and Alpha Cephei, less than 10 from the former, a bit more than the apparent distance between Sadr and Deneb. Because of its proximity to the pole, Deneb never sets in nearly all of Mars's northern hemisphere. Except in areas close to the equator, Deneb permanently circles the North pole. The orientation of Deneb and Sadr would make a useful clock hand for telling sidereal time.

Mars's north celestial pole is also only a few degrees away from the galactic plane. Thus the Milky Way, especially rich in the area of Cygnus, is always visible from the northern hemisphere.

The South celestial pole is correspondingly found at 9h 10m 42s and 5253.0, which is a couple of degrees from the 2.5-magnitude star Kappa Velorum (which is at 9h 22m 06.85s 5500.6), which could therefore be considered the southern polar star. The star Canopus, second-brightest in the sky, is a circumpolar star for most southern latitudes.

The zodiac constellations of Mars's ecliptic are almost the same as those of Earth after all, the two ecliptic planes only have a mutual inclination of 1.85 but on Mars, the Sun spends 6 days in the constellation Cetus, leaving and re-entering Pisces as it does so, making a total of 14 zodiacal constellations. The equinoxes and solstices are different as well: for the northern hemisphere, vernal equinox is in Ophiuchus (compared to Pisces on Earth), summer solstice is at the border of Aquarius and Pisces, autumnal equinox is in Taurus, and winter solstice is in Virgo.

As on Earth, precession will cause the solstices and equinoxes to cycle through the zodiac constellations over thousands and tens of thousands of years.

As on Earth, the effect of precession causes the north and south celestial poles to move in a very large circle, but on Mars the cycle is 175,000 Earth years[24] rather than 26,000 years as on Earth.

As on Earth, there is a second form of precession: the point of perihelion in Mars's orbit changes slowly, causing the anomalistic year to differ from the sidereal year. However, on Mars, this cycle is 83,600 years rather than 112,000 years as on Earth.

On both Earth and Mars, these two precessions are in opposite directions, and therefore add, to make the precession cycle between the tropical and anomalistic years 21,000 years on Earth and 56,600 years on Mars.

As on Earth, the period of rotation of Mars (the length of its day) is slowing down. However, this effect is three orders of magnitude smaller than on Earth because the gravitational effect of Phobos is negligible and the effect is mainly due to the Sun.[25] On Earth, the gravitational influence of the Moon has a much greater effect. Eventually, in the far future, the length of a day on Earth will equal and then exceed the length of a day on Mars.

As on Earth, Mars experiences Milankovitch cycles that cause its axial tilt (obliquity) and orbital eccentricity to vary over long periods of time, which has long-term effects on its climate. The variation of Mars's axial tilt is much larger than for Earth because it lacks the stabilizing influence of a large moon like Earth's Moon. Mars has a 124,000-year obliquity cycle compared to 41,000 years for Earth.

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Astronomy on Mars - Wikipedia

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If you let NASA tell the story, some of the people walking around on this planet right now may end up taking a stroll on the surface of Mars during their lifetimes.

People such as Elon Musk believe well colonize the red planet entirely and become a two-planet species. And this could be one of humankinds most important endeavors after all, who knows when another asteroid the size of the one that may have taken out the dinosaurs is going to hit again.

It could also be far more complex than NASA or SpaceX has actually considered.

Were going to need a way to grow food, store water, and produce breathable air in order for humans to survive on Mars.

But colonizing a harsh world is about more than just not dying. In order for humankind to grow and prosper on Mars as we have on Earth, were going to need good old-fashioned Earth viruses. And lots of em.

Thats according to the director of Arizona State Universitys Beyond Center for Fundamental Concepts in Science, Professor Paul Davies.

Davies recently discussed the importance of viruses in an interview published in The Guardian:

Viruses actually form part of the web of life. I would expect that if youve got microbial life on another planet, youre bound to have if its going to be sustainable and sustained the full complexity and robustness that will go with being able to exchange genetic information.

As Davies and myriad other scientists suspect, its possible that viruses are not just part of Earths biome but an essential component of evolution.

This is because of a fascinating aspect of evolutionary growth called horizontal gene transfer.

During horizontal gene transfer a species is believed to get certain traits through exposure from viruses rather than the traditional genetic route. According to Davies, some scientists believe most of the human genome is derived from viral sources.

In other words: humans are still evolving. Its possible our further evolution will require access to viruses that modify our genome over vast periods of time.

If we were to successfully colonize Mars (which would involve solving innumerable problems in its own right), those people who lived, procreated, and died there could potentially diverge from the human race.

Its conceivable that, after a certain number of generations of Martian colonists have been born, the human race could split into an Earth species and a Mars one solely based on exposure to viruses.

These are probably far-future problems, but the rate at which politicians and private-sector companies are attempting to conduct crewed missions to Mars with the expressed purpose of building a colony is alarming.

Its impossible to know the ramifications of colonizing a planet without our Earthbound viruses most of which are actually good, theyre not all COVID-19.

And its also impossible to know the ramifications of intentionally transporting and unleashing our planets diseases on the rest of the cosmos.

The good news, according to Davies, is that any aliens out there almost certainly have their own biomes and viruses that sustain their life. And, typically speaking, a virus is only harmful to the host it evolved to attack.

So, space viruses probably arent harmful to humans. But what happens when an alien virus and an Earth virus start mixing things up? And what happens to humanity when we leave our Earth viruses behind?

Its obvious that theres more to colonizing another world than just hauling supplies and figuring out how future generations can eventually terraform a barren wasteland. Heres hoping the people authorizing these projects are listening to more than just billionaires and engineers.

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Scientist says viruses may be the key to colonizing other planets - The Next Web

Any current review of Countdown: Inspiration4 Mission to Space is inherently incomplete, since the five-part Netflix docuseries is aiming to debut in real time alongside the event its depicting: the Sept. 15 launch of SpaceXs Inspiration4, which will be the first all-civilian flight to orbit the Eartha feat itll accomplish multiple times during its three-day journey, at speeds of 17,500 mph and at a height greater than that of the International Space Station. Consequently, the only episodes available to press at the moment are its first two prologue installments (premiering Sept. 6); chapters three and four will hit the streaming service on Sept. 13, and a feature-length finaledetailing the actual missionis set to land in late September, shortly after the Inspiration4 touches back down on Earth.

Those concluding segments will no doubt deliver up-close-and-personal footage from inside the Inspiration4 Crew Dragon capsule that will house its four amateur astronauts, who will be launched into space via a previously used Falcon 9 rocket. In its maiden passages, however, Countdown: Inspiration4 Mission to Space is basically a long-winded promotional video crafted to stoke excitementand offer justificationsfor the endeavor, which just about everyone here touts as a history-making project that will help us get closer to answering the most profound questions about existence and serve as the first step in mankinds quest to become a multi-planetary species. Its an aggressive sales pitch masquerading as a typical Netflix non-fiction venture, helmed by The Last Dances Jason Hehir with all the dewy-eyed melodrama, swelling music, and rousing headshots that a 45-minute episode can contain.

Countdown: Inspiration4 Mission to Space insistently pushes its message from the get-go. According to Times chief science editor Jeffrey Kluger, Inspiration4 is a hinge point in history, and will kick the doors open to space for the rest of us. Thats because, by sending non-professional astronauts into space, the undertaking will pave the way for more commercial flights, as well as further the goal of reaching deeper into the cosmos, where we might someday colonize distant worlds. This is a goal of dubious worth, but its one that Hehirs docuseries champions with a chin-held-high sort of confidence. At the same time, it also has SpaceX founder Elon Musk address the main criticism of the Inspiration4 flight, and similar ones recently spearheaded by Richard Branson and Jeff Bezosnamely, that these are joy-ride stunts designed to feed the egos of billionaires.

I think we should spend the vast majority of our resources solving problems on Earth. Like, 99 percent-plus of our economy should be dedicated to solving problems on Earth, says Musk in one of his few obligatory on-screen appearances. But I think maybe something like 1 percent, or less than 1 percent, could be applied to extending life beyond Earth. His motivation is colonizing Mars, and the exciting, inspiring future of multi-planetary habitation. After all, he proclaims, If life is just about problems, whats the point of living? In this context, Inspiration4 isnt just an expensive lark; its the next big pioneering phase in mankinds evolution, and thus deserving of the private investment required to make its Jetsons-style dreams a reality.

Musks brief comments aside, however, Countdown: Inspiration4 Mission to Space does very little to take a critical look at this enterprise. At least in its initial pair of installments, the docuseries plays like a PR product, casting everything in glowing terms, including its portraits of the missions four astronauts. That group is led by Jared Isaacman, a billionaire whose history of entrepreneurship, risk-taking and fighter jet-piloting made him the ideal driving force behind Inspiration4. Isaacman is an amiable and eloquent guy whose every comment is tailor-made to hit on a particular talking point and, as he explains, a guiding motivation behind his SpaceX relationship was an initiative he developed with St. Jude Childrens Research Hospital to raise $200 million for cancer research. Putting his money where his mouth is, hes already given his own, separate $100 million donation to the organization.

St. Jude also provided Inspiration4 with two of its passengers: Hayley Arceneaux, a pediatric cancer survivor and current St. Jude physicians assistant, and Christopher Sembroski, who won his ride by entering into a raffle promoted by SpaceXs Super Bowl commercial. The fourth crew member is Sian Proctor, a 51-year-old entrepreneur (whod previously trained for space flight) who earned her spot through a viral-video competition. Together, as Isaacman explains, they represent the four pillars of the Inspiration4 mission: Leadership (Isaacman), Hope (Arceneaux), Generosity (Sembroski), and Prosperity (Proctor). This is as cheesy as it sounds, like something produced for a marketing brochure and a press release. And though all four of these individuals seem genuinely thrilled about their opportunity, the docuseries vignettes on their backstories are as cornily handled as the scenes in which they announce to friends (in person, and via Zoom) that theyre going to spacemoments that awkwardly strain for astonishment and euphoria.

This is as cheesy as it sounds, like something produced for a marketing brochure and a press release.

One can imagine Countdown: Inspiration4 Mission to Spaces more timely later episodes supplying greater suspense. Yet in its early goingwhich involves repeatedly underlining SpaceXs connection to the history and ethos of the American space programthe entire affair mostly comes across as prepackaged corporate publicity. Some authentic emotion does occasionally sneak in, as with a brief snapshot of Sembroskis wife breaking down in nervous tears while visiting SpaceXs Cape Canaveral HQ to watch the Crew-2 flight take off in April 2021. Yet even the shows discussion about the dangers of space travelreplete with recaps of the 1986 and 2003 space shuttle disastersseem less interested in grappling with the cost/benefit of these missions than in raising the proceedings suspenseful dramatic stakes.

Those hazards are, of course, real, and theyll certainly be front-and-center as Inspiration4 makes its way from the planning stages to the launchpad. The notion that Netflix viewers will get a front-row seat for this journeybe it a triumph or a failureremains an intriguing prospect. Yet one hopes that, as its subjects enter orbit, Countdown: Inspiration4 Mission to Space quiets down about its own importance, and lets its action speak for itself.

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Netflix Strokes Elon Musk's Otherworldly Ego With 'Countdown: Inspiration4 Mission to Space' - The Daily Beast

The Below & Beyond DLC for Surviving Mars launched today on Steam. The DLC lets players explore and expand their colony into the caves and lava tubes of the Martian surface. Surviving Mars is a sci-fi builder about colonizing Mars and surviving the process. Mining resources and building structures are some of the many things players will have to do to ensure the survival and improvement of the Colony.

With the DLC, players will be able to go below the surface and mine resources, construct special rocket-propelled buildings, and find exotic minerals and data samples. Besides the new areas, players will now be able to unlock additional buildings, vehicles, upgrades, and locales. They will also be able to unlock asteroid mining and tunnel colonization.

The Surviving Mars Below & Beyond DLC brought some free updates for players, improving the UI, balancing some mechanics, and more, so players will have a better experience overall. If you want to read the full patch notes you can go to the official game website. There you will find all the information you need.

Surviving Mars is available now on PC, PS4, and Xbox One.

- This article was updated on September 7th, 2021

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Surviving Mars Below & Beyond DLC Launches Today, Here's What's New - Attack of the Fanboy

The increasing frequency of both natural and man-made catastrophes such as worldwide pandemics and climate catastrophes has re-validated the urgency to establish humanity as a multi-planet species. Indeed, the founding ethos of Elon Musk's private spaceflight company SpaceX was to make life multi-planetary, partly motivated by existential threats such as large asteroid strikes capable of wiping out life on our planet. However, one of the biggest challenges to making this dream a reality is how to get to distant stars and planets within a human lifetime.

Consider that with conventional fuel rockets, it takes about seven months just to get to Mars, and a ridiculous 80,000 years to get to the nearest star, Proxima Centauri, using our fastest rockets. This means that ordinary rockets are simply out of the question for interstellar travel, and something a little bit more out there is needed.

Luckily, we might now have the answer to this space travel conundrum.

Once the exclusive province of science fiction films, space colonization has been moving closer to becoming a reality thanks to major advances in astronautics and astrophysics; rocket propulsion and design, robotics and medicine. Trekkies, along with the otherworldly technology featured in the Star Trek series, have helped define the science fiction universe. One of the most mind-boggling of these technologies from those shows is the "Impulse Drive," a propulsion system used on the spaceships of many species to get across the galaxy in amazingly short timeframes measured in months or a few years rather than centuries or millennia.

And now scientists have unveiled the Holy Grail of Space Travel: A real-life Impulse Drive system able to achieve sub-light velocities using zero fuel propellants. After 30 years of tinkering and fine-tuning, a pair of scientists might finally be close to turning science fiction into science fact.

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And, NASA is taking the idea seriously.

MEGA Drive

Conventional spaceships burn rocket fuel to achieve escape velocities, maneuver, and even land, in the case of SpaceX rockets. But what if you could build a spaceship that runs entirely on electricity?

That's exactly what the Mach Effect Gravity Assist (MEGA) drive does.

Jim Woodward, a physics professor emeritus at California State University, Fullerton, and Hal Fearn, a physicist at Fullerton, have developed the Mach Effect Gravity Assist (MEGA) Drive propulsion based on what they say is peer-reviewed, technically credible physics.

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With the help of a NASA Innovative Advanced Concepts (NIAC) grant, the two scientists have developed MEGA Drive based on the physics described in Einstein's theory of relativity. MEGA Drive--which is showing excellent promise in early testing and is already in phase two testing--is pretty much the holy grail of space travel and space science because it could power not only local travel within our solar system, but also interstellar travel that is currently undoable using available technologies.

So, how does MEGA Drive work?

It's a well-known Newtonian law that an object at rest stays at rest, and an object in motion stays in motion at a constant speed unless an external force acts on it. All objects resist changes to their state of motion or rest due to inertia.

In 1872, Austrian physicist Ernst Mach made a conjecture that these forces of inertia result from the gravity of objects in the distant universe. This became known as the controversial Mach's principle. While most experts have now dismissed it, Woodward and Fearn think the idea is simply misunderstood and have built their impulse engine based on it.

The MEGA Drive applies the Mach principle. There are several textbook definitions of the Mach principle; however, the two scientists think of it as the ability of distant matter to influence things up close. To get your head around it, they use this old analogy of how matter bends space-time.

If you put a heavy object on a trampoline, it falls in and curves the rubber sheet. Now, if you roll a ball on the trampoline, it will keep orbiting the heavy mass in the center. That's how a planet behaves when it's attracted by the gravity of a star. The thing is, for the rubber sheet to act that way, it has to be stretched or under tension. So these scientists are basically saying that the distant matter of the universe is what's pulling the space-time and making it taut and causing it to act like a stretched rubber sheet loaded with potential energy. And according to the team's understanding of the Mach principle, so is space-time, meaning they think there's a big gravitational potential out there, and the MEGA Drive can actually tap into that potential energy.

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The MEGA Drive works by making a stack of piezoelectric crystals alternately heavier and lighter by applying electric current to them. Actually, this is not some kind of New Age healing crystals; piezoelectric crystals do expand and contract under the influence of electricity, essentially interacting with what Einstein says are universal inertial fields in the universe, caused by gravity. By making an object heavier one instant and lighter the next, you can create thrust by using the very same Newtonian every-reaction-causes-an-equal-and-opposite-reaction principle used by rocket engines by throwing matter behind them to move forward.

MEGA Drive's main kicker: Unlike a conventional rocket that ejects burnt gases to create thrust, the MEGA Drive does not permanently lose its energy-producing crystals by actually throwing them away; You simply push them when heavy, and pull them back when light, thus creatingmomentum to move forward.

"If you now have a double frequency mechanical oscillation, you can push on it when it's more massive and pull it back when it's less massive. You've got propelling, but you don't have to throw it over and say goodbye. You get to throw it over when it's more massive and then because of this interaction with this inertial gravitational field, you can let it become less massive and then pull it back in," says Woodward.

Woodward says each Mach Effect drive unit can generate about a hundred millinewtons of force. As currently built, the Mach Effect engines are six-centimeter cubes just over two inches per side. By making them more efficient, Woodward says you'd get more power from each. And, by stacking as many of them as you want on your ship, you can generate enough forward momentum to power your ship.

Then it's just a question of how much electricity you can feed the drives, with a nuclear power plant mooted as a possible source of electricity.

According to Woodward, you can generate ~10 newtons of force for every kilowatt of electricity fed into the Mach Effect engines. Early applications would be in satellites used in chemical rockets to maintain orbits and alignment with the engines fueled by electricity, vastly extending their useful lifespans. Indeed, in this case, solar panels could provide all the necessary energy to power the drives.

Another interesting finding: The team has calculated that the smaller the device, the larger the force it can generate. So instead of scaling up, they hope that arrays of thousands of tiny MEGA Drives powered by a nuclear battery could one day be deployed to accelerate large probes into interstellar space. Indeed, the scientists claim that the drives are sufficient to power a human-crewed starship to nearby stars such as Proxima Centauri located some 4.25 light-years away from the sun and back in some reasonable fraction of the human lifetime.

That sounds pretty futuristic, of course, and relies on peer review and replication of Woodward's results. To be clear, it will take a healthy dose of dogged persistence to replicate Woodward's feat. Indeed, Mike McDonald, an aerospace engineer at the U.S. Naval Research Laboratory contracted by NASA to verify Woodward's work, gives it a rather unnerving 1 in 10 to a 1 in 10 million chance --but it's a shot, nevertheless.

And if MEGA Drive proves viable, it will become one of the rare instances when science fiction is vindicated and transformed into scientific fact.

By Alex Kimani for Oilprice.com

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