How do we currently protect astronauts and spacecraft from radiation? [duplicate]
up vote
2
down vote
favorite
This question already has an answer here:
How did Apollo missions solve the cosmic radiation problem?
5 answers
What are current ways in which astronauts and spacecrafts are protected from radiation? Are their any new ways/ideas to limit the amount of exposure to radiation?
radiation
New contributor
marked as duplicate by Dr Sheldon, DarkDust, Jan Doggen, Amar, Brian Tompsett - 汤莱恩 14 hours ago
This question has been asked before and already has an answer. If those answers do not fully address your question, please ask a new question.
|
show 1 more comment
up vote
2
down vote
favorite
This question already has an answer here:
How did Apollo missions solve the cosmic radiation problem?
5 answers
What are current ways in which astronauts and spacecrafts are protected from radiation? Are their any new ways/ideas to limit the amount of exposure to radiation?
radiation
New contributor
marked as duplicate by Dr Sheldon, DarkDust, Jan Doggen, Amar, Brian Tompsett - 汤莱恩 14 hours ago
This question has been asked before and already has an answer. If those answers do not fully address your question, please ask a new question.
One of the main methods is time. I don’t think we’ve really solved the radiation protection problem fully, so limiting exposure is the best way to protect them. If i’m not mistaken, i think the general way to protect astronauts is to let radiation transmit through them rather than using a shield that absorbs or reflects it. I’m not sure about spacecraft though.
– Paul
Nov 24 at 20:30
Thanks Paul, but aside from time, what can we physically utilize to assist astronauts. Such an pills etc....
– PlusModel Cheryl Joseph
Nov 24 at 20:32
Related: space.stackexchange.com/questions/31820/…
– Paul
Nov 24 at 20:33
Also related (it looks like hydrogen can be used as a shield when necessary) space.stackexchange.com/questions/1/…
– Paul
Nov 24 at 20:38
Sola dosis facit venenum. The dose makes the poison.
– RonJohn
Nov 25 at 0:33
|
show 1 more comment
up vote
2
down vote
favorite
up vote
2
down vote
favorite
This question already has an answer here:
How did Apollo missions solve the cosmic radiation problem?
5 answers
What are current ways in which astronauts and spacecrafts are protected from radiation? Are their any new ways/ideas to limit the amount of exposure to radiation?
radiation
New contributor
This question already has an answer here:
How did Apollo missions solve the cosmic radiation problem?
5 answers
What are current ways in which astronauts and spacecrafts are protected from radiation? Are their any new ways/ideas to limit the amount of exposure to radiation?
This question already has an answer here:
How did Apollo missions solve the cosmic radiation problem?
5 answers
radiation
radiation
New contributor
New contributor
edited Nov 24 at 20:25
New contributor
asked Nov 24 at 20:13
PlusModel Cheryl Joseph
142
142
New contributor
New contributor
marked as duplicate by Dr Sheldon, DarkDust, Jan Doggen, Amar, Brian Tompsett - 汤莱恩 14 hours ago
This question has been asked before and already has an answer. If those answers do not fully address your question, please ask a new question.
marked as duplicate by Dr Sheldon, DarkDust, Jan Doggen, Amar, Brian Tompsett - 汤莱恩 14 hours ago
This question has been asked before and already has an answer. If those answers do not fully address your question, please ask a new question.
One of the main methods is time. I don’t think we’ve really solved the radiation protection problem fully, so limiting exposure is the best way to protect them. If i’m not mistaken, i think the general way to protect astronauts is to let radiation transmit through them rather than using a shield that absorbs or reflects it. I’m not sure about spacecraft though.
– Paul
Nov 24 at 20:30
Thanks Paul, but aside from time, what can we physically utilize to assist astronauts. Such an pills etc....
– PlusModel Cheryl Joseph
Nov 24 at 20:32
Related: space.stackexchange.com/questions/31820/…
– Paul
Nov 24 at 20:33
Also related (it looks like hydrogen can be used as a shield when necessary) space.stackexchange.com/questions/1/…
– Paul
Nov 24 at 20:38
Sola dosis facit venenum. The dose makes the poison.
– RonJohn
Nov 25 at 0:33
|
show 1 more comment
One of the main methods is time. I don’t think we’ve really solved the radiation protection problem fully, so limiting exposure is the best way to protect them. If i’m not mistaken, i think the general way to protect astronauts is to let radiation transmit through them rather than using a shield that absorbs or reflects it. I’m not sure about spacecraft though.
– Paul
Nov 24 at 20:30
Thanks Paul, but aside from time, what can we physically utilize to assist astronauts. Such an pills etc....
– PlusModel Cheryl Joseph
Nov 24 at 20:32
Related: space.stackexchange.com/questions/31820/…
– Paul
Nov 24 at 20:33
Also related (it looks like hydrogen can be used as a shield when necessary) space.stackexchange.com/questions/1/…
– Paul
Nov 24 at 20:38
Sola dosis facit venenum. The dose makes the poison.
– RonJohn
Nov 25 at 0:33
One of the main methods is time. I don’t think we’ve really solved the radiation protection problem fully, so limiting exposure is the best way to protect them. If i’m not mistaken, i think the general way to protect astronauts is to let radiation transmit through them rather than using a shield that absorbs or reflects it. I’m not sure about spacecraft though.
– Paul
Nov 24 at 20:30
One of the main methods is time. I don’t think we’ve really solved the radiation protection problem fully, so limiting exposure is the best way to protect them. If i’m not mistaken, i think the general way to protect astronauts is to let radiation transmit through them rather than using a shield that absorbs or reflects it. I’m not sure about spacecraft though.
– Paul
Nov 24 at 20:30
Thanks Paul, but aside from time, what can we physically utilize to assist astronauts. Such an pills etc....
– PlusModel Cheryl Joseph
Nov 24 at 20:32
Thanks Paul, but aside from time, what can we physically utilize to assist astronauts. Such an pills etc....
– PlusModel Cheryl Joseph
Nov 24 at 20:32
Related: space.stackexchange.com/questions/31820/…
– Paul
Nov 24 at 20:33
Related: space.stackexchange.com/questions/31820/…
– Paul
Nov 24 at 20:33
Also related (it looks like hydrogen can be used as a shield when necessary) space.stackexchange.com/questions/1/…
– Paul
Nov 24 at 20:38
Also related (it looks like hydrogen can be used as a shield when necessary) space.stackexchange.com/questions/1/…
– Paul
Nov 24 at 20:38
Sola dosis facit venenum. The dose makes the poison.
– RonJohn
Nov 25 at 0:33
Sola dosis facit venenum. The dose makes the poison.
– RonJohn
Nov 25 at 0:33
|
show 1 more comment
2 Answers
2
active
oldest
votes
up vote
3
down vote
So currently we don't actually do anything to protect them from radiation (if we exclude the basics like UV shields and being able to alter the attitude of the craft to place the highest density of metal/solar arrays/whatever in the direction of the incoming radiation) As Paul mentioned, limiting the amount of time spent in space is pretty much it. NASA have researched the use of various shields such as water etc, but the mass cost is still prohibitive.
Those astronauts who have spent long terms on the ISS are extensively studied to understand the impact on them, but they aren't protected.
I think that ISS has procedures for solar events such as CMEs, but I don't know if those have any radiation-mitigating effect or if they just address problems if electronic systems fail. Possibly related: space.stackexchange.com/a/1040/12102
– uhoh
Nov 25 at 0:24
1
I think you are correct @uhoh - all I can find indicates electronic system resilience
– Rory Alsop
Nov 25 at 10:01
add a comment |
up vote
2
down vote
The ISS orbits between 205-270 miles (330-435 km) above the Earth at an inclination of 51.64 degrees. That's low enough that it can get by with minimal (read: basically no) shielding, because Earth provides all that it needs. For deep space settlements, roughly 7 tons of water per m^2, or 11 tons of lunar regolith per m^2, is required to shield something outside of Earth's protection against every type of radiation. The Van Allen belts themselves stretch from ~400 miles (650 km) to 36,000 miles (58,000 km), so a habitat located below the belts can use minimal shielding, while one above would require the full protection (and thus considerable added mass, potentially in the millions of tons). The International Commission on Radiation Protection sets the limit for yearly exposure to radiation at 20 milliSieverts, and for pregnant women, the limit is 6.6 milliGrays (Grays are a measure of radiation absorbed). Polyethylene is also an option for radiation shielding, and is slightly better than water.
Sources:
- ISS article on Wikipedia
The High Frontier: An Easier Way - chapter titled: Al Globus: An Easier Way
add a comment |
2 Answers
2
active
oldest
votes
2 Answers
2
active
oldest
votes
active
oldest
votes
active
oldest
votes
up vote
3
down vote
So currently we don't actually do anything to protect them from radiation (if we exclude the basics like UV shields and being able to alter the attitude of the craft to place the highest density of metal/solar arrays/whatever in the direction of the incoming radiation) As Paul mentioned, limiting the amount of time spent in space is pretty much it. NASA have researched the use of various shields such as water etc, but the mass cost is still prohibitive.
Those astronauts who have spent long terms on the ISS are extensively studied to understand the impact on them, but they aren't protected.
I think that ISS has procedures for solar events such as CMEs, but I don't know if those have any radiation-mitigating effect or if they just address problems if electronic systems fail. Possibly related: space.stackexchange.com/a/1040/12102
– uhoh
Nov 25 at 0:24
1
I think you are correct @uhoh - all I can find indicates electronic system resilience
– Rory Alsop
Nov 25 at 10:01
add a comment |
up vote
3
down vote
So currently we don't actually do anything to protect them from radiation (if we exclude the basics like UV shields and being able to alter the attitude of the craft to place the highest density of metal/solar arrays/whatever in the direction of the incoming radiation) As Paul mentioned, limiting the amount of time spent in space is pretty much it. NASA have researched the use of various shields such as water etc, but the mass cost is still prohibitive.
Those astronauts who have spent long terms on the ISS are extensively studied to understand the impact on them, but they aren't protected.
I think that ISS has procedures for solar events such as CMEs, but I don't know if those have any radiation-mitigating effect or if they just address problems if electronic systems fail. Possibly related: space.stackexchange.com/a/1040/12102
– uhoh
Nov 25 at 0:24
1
I think you are correct @uhoh - all I can find indicates electronic system resilience
– Rory Alsop
Nov 25 at 10:01
add a comment |
up vote
3
down vote
up vote
3
down vote
So currently we don't actually do anything to protect them from radiation (if we exclude the basics like UV shields and being able to alter the attitude of the craft to place the highest density of metal/solar arrays/whatever in the direction of the incoming radiation) As Paul mentioned, limiting the amount of time spent in space is pretty much it. NASA have researched the use of various shields such as water etc, but the mass cost is still prohibitive.
Those astronauts who have spent long terms on the ISS are extensively studied to understand the impact on them, but they aren't protected.
So currently we don't actually do anything to protect them from radiation (if we exclude the basics like UV shields and being able to alter the attitude of the craft to place the highest density of metal/solar arrays/whatever in the direction of the incoming radiation) As Paul mentioned, limiting the amount of time spent in space is pretty much it. NASA have researched the use of various shields such as water etc, but the mass cost is still prohibitive.
Those astronauts who have spent long terms on the ISS are extensively studied to understand the impact on them, but they aren't protected.
edited Nov 25 at 10:38
Uwe
8,61322649
8,61322649
answered Nov 24 at 22:28
Rory Alsop
9,67324272
9,67324272
I think that ISS has procedures for solar events such as CMEs, but I don't know if those have any radiation-mitigating effect or if they just address problems if electronic systems fail. Possibly related: space.stackexchange.com/a/1040/12102
– uhoh
Nov 25 at 0:24
1
I think you are correct @uhoh - all I can find indicates electronic system resilience
– Rory Alsop
Nov 25 at 10:01
add a comment |
I think that ISS has procedures for solar events such as CMEs, but I don't know if those have any radiation-mitigating effect or if they just address problems if electronic systems fail. Possibly related: space.stackexchange.com/a/1040/12102
– uhoh
Nov 25 at 0:24
1
I think you are correct @uhoh - all I can find indicates electronic system resilience
– Rory Alsop
Nov 25 at 10:01
I think that ISS has procedures for solar events such as CMEs, but I don't know if those have any radiation-mitigating effect or if they just address problems if electronic systems fail. Possibly related: space.stackexchange.com/a/1040/12102
– uhoh
Nov 25 at 0:24
I think that ISS has procedures for solar events such as CMEs, but I don't know if those have any radiation-mitigating effect or if they just address problems if electronic systems fail. Possibly related: space.stackexchange.com/a/1040/12102
– uhoh
Nov 25 at 0:24
1
1
I think you are correct @uhoh - all I can find indicates electronic system resilience
– Rory Alsop
Nov 25 at 10:01
I think you are correct @uhoh - all I can find indicates electronic system resilience
– Rory Alsop
Nov 25 at 10:01
add a comment |
up vote
2
down vote
The ISS orbits between 205-270 miles (330-435 km) above the Earth at an inclination of 51.64 degrees. That's low enough that it can get by with minimal (read: basically no) shielding, because Earth provides all that it needs. For deep space settlements, roughly 7 tons of water per m^2, or 11 tons of lunar regolith per m^2, is required to shield something outside of Earth's protection against every type of radiation. The Van Allen belts themselves stretch from ~400 miles (650 km) to 36,000 miles (58,000 km), so a habitat located below the belts can use minimal shielding, while one above would require the full protection (and thus considerable added mass, potentially in the millions of tons). The International Commission on Radiation Protection sets the limit for yearly exposure to radiation at 20 milliSieverts, and for pregnant women, the limit is 6.6 milliGrays (Grays are a measure of radiation absorbed). Polyethylene is also an option for radiation shielding, and is slightly better than water.
Sources:
- ISS article on Wikipedia
The High Frontier: An Easier Way - chapter titled: Al Globus: An Easier Way
add a comment |
up vote
2
down vote
The ISS orbits between 205-270 miles (330-435 km) above the Earth at an inclination of 51.64 degrees. That's low enough that it can get by with minimal (read: basically no) shielding, because Earth provides all that it needs. For deep space settlements, roughly 7 tons of water per m^2, or 11 tons of lunar regolith per m^2, is required to shield something outside of Earth's protection against every type of radiation. The Van Allen belts themselves stretch from ~400 miles (650 km) to 36,000 miles (58,000 km), so a habitat located below the belts can use minimal shielding, while one above would require the full protection (and thus considerable added mass, potentially in the millions of tons). The International Commission on Radiation Protection sets the limit for yearly exposure to radiation at 20 milliSieverts, and for pregnant women, the limit is 6.6 milliGrays (Grays are a measure of radiation absorbed). Polyethylene is also an option for radiation shielding, and is slightly better than water.
Sources:
- ISS article on Wikipedia
The High Frontier: An Easier Way - chapter titled: Al Globus: An Easier Way
add a comment |
up vote
2
down vote
up vote
2
down vote
The ISS orbits between 205-270 miles (330-435 km) above the Earth at an inclination of 51.64 degrees. That's low enough that it can get by with minimal (read: basically no) shielding, because Earth provides all that it needs. For deep space settlements, roughly 7 tons of water per m^2, or 11 tons of lunar regolith per m^2, is required to shield something outside of Earth's protection against every type of radiation. The Van Allen belts themselves stretch from ~400 miles (650 km) to 36,000 miles (58,000 km), so a habitat located below the belts can use minimal shielding, while one above would require the full protection (and thus considerable added mass, potentially in the millions of tons). The International Commission on Radiation Protection sets the limit for yearly exposure to radiation at 20 milliSieverts, and for pregnant women, the limit is 6.6 milliGrays (Grays are a measure of radiation absorbed). Polyethylene is also an option for radiation shielding, and is slightly better than water.
Sources:
- ISS article on Wikipedia
The High Frontier: An Easier Way - chapter titled: Al Globus: An Easier Way
The ISS orbits between 205-270 miles (330-435 km) above the Earth at an inclination of 51.64 degrees. That's low enough that it can get by with minimal (read: basically no) shielding, because Earth provides all that it needs. For deep space settlements, roughly 7 tons of water per m^2, or 11 tons of lunar regolith per m^2, is required to shield something outside of Earth's protection against every type of radiation. The Van Allen belts themselves stretch from ~400 miles (650 km) to 36,000 miles (58,000 km), so a habitat located below the belts can use minimal shielding, while one above would require the full protection (and thus considerable added mass, potentially in the millions of tons). The International Commission on Radiation Protection sets the limit for yearly exposure to radiation at 20 milliSieverts, and for pregnant women, the limit is 6.6 milliGrays (Grays are a measure of radiation absorbed). Polyethylene is also an option for radiation shielding, and is slightly better than water.
Sources:
- ISS article on Wikipedia
The High Frontier: An Easier Way - chapter titled: Al Globus: An Easier Way
answered Nov 25 at 23:03
Snoopy
1624
1624
add a comment |
add a comment |
One of the main methods is time. I don’t think we’ve really solved the radiation protection problem fully, so limiting exposure is the best way to protect them. If i’m not mistaken, i think the general way to protect astronauts is to let radiation transmit through them rather than using a shield that absorbs or reflects it. I’m not sure about spacecraft though.
– Paul
Nov 24 at 20:30
Thanks Paul, but aside from time, what can we physically utilize to assist astronauts. Such an pills etc....
– PlusModel Cheryl Joseph
Nov 24 at 20:32
Related: space.stackexchange.com/questions/31820/…
– Paul
Nov 24 at 20:33
Also related (it looks like hydrogen can be used as a shield when necessary) space.stackexchange.com/questions/1/…
– Paul
Nov 24 at 20:38
Sola dosis facit venenum. The dose makes the poison.
– RonJohn
Nov 25 at 0:33