That's math. I don't do math. However, consider the weight difference between a cubic meter of ice and a cubic meter of lead. The weight savings would allow a greater depth of shielding to be carried for the same energy expenditure.BillTre said:But, how thick would be sufficient?
Definitely would be a good idea. And I suspect H2O is one of the most common chemical compounds in this universe.BillTre said:Maybe they could pick some up in space and not have to launch it up.
Pathfinder died on Mars because it couldn't fix itself. EOM Mark Watney (theoretically) survived on Mars because he could fix things. He completed the mission (as seen in the extended cut). Mission accomplished.Rubidium_71 said:The easiest solution is the one we already use - you end Moon missions in 1972 and stop sending people beyond low Earth orbit and let robots go exploring while everyone stays home. People have talked about human missions for 44 years, but they never actually do anything. The only extended human space missions are in TV and the movies and, in my opinion, it's likely to stay that way for a very long time.
The mission was intended to last between a week and a month. Pathfinder had a good run, it made almost made it to three months. When one robot "dies" we just send another, better machine to take it's place anyway.Noisy Rhysling said:Pathfinder died on Mars because it couldn't fix itself.
As I pointed out, the only success of this type we've seen so far is in fiction. When Mr. Damon has used his punctured glove to fly through space in real life and grabs Jessica Chastain's flailing hand in orbit around the real planet Mars, let me know.Noisy Rhysling said:EOM Mark Watney (theoretically) survived on Mars because he could fix things.
And they'll continue to die for possibly trivial reasons. Humans can do better.Rubidium_71 said:The mission was intended to last between a week and a month. Pathfinder had a good run, it made almost made it to three months. When one robot "dies" we just send another, better machine to take it's place anyway.
Before I wore khakis I was in charge of fixing things that broke on my ship. I saw Matt as doing the same thing on Mars. It's really not that different. "You just begin."As I pointed out, the only success of this type we've seen so far is in fiction. When Mr. Damon has used his punctured glove to fly through space in real life and grabs Jessica Chastain's flailing hand in orbit around the real planet Mars, let me know.
This pretty much underlines the reality of the situation, either we send a robot like Pathfinder (which excludes risking a human's life) or we declare victory in the realm of fiction. Either way, humanity has it's preferred solutions to extended the space travel concept. The public seems satisfied whether it's actual scientific data from a robot - "Hey! Pluto has got a heart on it!" OR people are satisfied with speculation from the realm of science fiction "Hey! There's green women living somewhere in the constellation of Orion!"
Not theoretically, fictionally. Very different things.Noisy Rhysling said:... EOM Mark Watney (theoretically) survived on Mars ...
The analogies are way off. One does not examine the problem of crossing the ocean and conclude swimming has a shot because they have great determination. Setting foot on Mars and coming back is not like fixing a ship.Noisy Rhysling said:And they'll continue to die for possibly trivial reasons. Humans can do better.
Before I wore khakis I was in charge of fixing things that broke on my ship. I saw Matt as doing the same thing on Mars. It's really not that different. "You just begin."
You get half a hair, I get the other half.mheslep said:Not theoretically, fictionally. Very different things.
Okay then.mheslep said:The analogies are way off. One does not examine the problem of crossing the ocean and conclude swimming has a shot because they have great determination. Setting foot on Mars and coming back is not like fixing a ship.
Fiction and theory? Half a mountain.Noisy Rhysling said:You get half a hair, I get the other half.
I think it's more like fiction gets half a hair, theory get half a mountain.mheslep said:Fiction and theory? Half a mountain.
The hairs are fully split.mheslep said:Fiction and theory? Half a mountain.
Humans have been doing better, we've built better machines that have been more successful as technology progresses.Noisy Rhysling said:And they'll continue to die for possibly trivial reasons. Humans can do better.
Yeah, what he said !mheslep said:Astronaut Chris Hadfield: "My prediction, we will never go to Mars with the engines we have right now"
Hadfield objects to the transit time with existing tech as far too long thus too complex thus too risky.
NASA has a rather extensive Technical Memorandum on the subject you might find interesting.wolram said:This paper states that extended space travel would be harmful for astronauts, how would future space travel over come cosmic radiation
https://www.sciencedaily.com/releases/2016/10/161010052832.htm
Many Asteroids are full of ice..lasso one..put it in lunar orbit only three days away..put a spacecraft with appropriate mechanism too attach ice..proceed on journey.Noisy Rhysling said:Definitely would be a good idea. And I suspect H2O is one of the most common chemical compounds in this universe.
The gravity well penalty is a large part of what's keeping us from full-bore expansion into space now. Any way we can work around that is worth more than its weight in gold.
Accelerating a lot of ice will need a huge amount of energy. You can convert ice to fuel, but only with a huge array of solar cells or with a nuclear reactor.Learner60 said:Many Asteroids are full of ice..lasso one..put it in lunar orbit only three days away..put a spacecraft with appropriate mechanism too attach ice..proceed on journey.
Rubidium_71 said:The easiest solution is the one we already use - you end Moon missions in 1972 and stop sending people beyond low Earth orbit and let robots go exploring while everyone stays home.
I agree with you. I'm just pointing out that due to people being shortsighted (among other things) that's not what's happening. It should happen, but it is currently unlikely.somebodyelse said:I don't think that is acceptable if we think of the survival of the human species. Sooner or later humans *need* to settle on another planet to avoid accidental extinction.
Is there really any point in bringing Hollywood into this discussion? Any message you get from a feature film is out of the director's head. It's not real, you know.Noisy Rhysling said:Pathfinder died on Mars because it couldn't fix itself. EOM Mark Watney (theoretically) survived on Mars because he could fix things. He completed the mission (as seen in the extended cut). Mission accomplished.
This is a very optimistic statement. The reaction of humans to disasters in general is not to think 'long term', it's more likely that any serious thread will be dealt with after the fashion of the population of Easter Island - virtual self destruction, instead of dealing with the problem of lack of resources. (That example is, of course only the view of some anthropologists but it's a very reasonable scenario).somebodyelse said:Sooner or later humans *need* to settle on another planet to avoid accidental extinction
Cosmic radiation is a form of high-energy radiation that originates from outside our solar system. It is made up of protons, electrons, and other atomic nuclei. In space, there is no protection from Earth's atmosphere, magnetic field, or other shielding materials, so astronauts are exposed to higher levels of cosmic radiation than they would be on Earth. This can have detrimental effects on their health, including an increased risk of cancer and damage to their DNA.
Currently, astronauts on the International Space Station (ISS) are protected from cosmic radiation by the Earth's magnetic field, as well as the structure of the ISS itself. The ISS also has a shield made of aluminum and polyethylene, which helps to reduce the amount of radiation that reaches the astronauts. However, for longer missions, such as a journey to Mars, additional shielding and countermeasures will be necessary.
One potential solution is to develop better shielding materials, such as using water or liquid hydrogen as a barrier against radiation. Another solution is to create artificial magnetic fields around spacecraft to mimic the protection of Earth's magnetic field. Additionally, medications and supplements that can repair damaged DNA and cells may be used to mitigate the effects of radiation.
Cosmic radiation can also damage spacecraft and equipment. For example, it can cause electronic malfunctions and damage to solar panels, which are crucial for providing power to the spacecraft. To protect against this, spacecraft are often equipped with shielding materials and redundant systems to minimize the risk of damage.
Conducting research on cosmic radiation in space presents several challenges. One of the main challenges is the difficulty in measuring and quantifying the amount of radiation that astronauts are exposed to. Another challenge is the cost and logistics of conducting experiments in space. Additionally, the effects of cosmic radiation on living organisms may vary based on factors such as age and gender, making it difficult to draw definitive conclusions from research results.