The Space Environment

1. The Space Environment

2. The Space Environment • The Cosmic Perspective • Where Is Space? • The Solar System • The Cosmos • The Space Environment and Spacecraft • Challenges of the Space Environment • Gravity • Atmosphere • Vacuum • Micrometeoroids and Space Junk • The Radiation Environment • Charged Particles • Living and Working in Space • Hazards to Humans in Space • Free Fall • Radiation and Charged Particles • Mental and Emotional Effects Unit 1, Chapter 3, Lesson 3: The Space Environment

3. Packing for a Trip • Where’d you go on Spring Break? • Would you have packed differently if you were going to Alaska? • It is vital to know something about the environment you visit in order to know what you’re up against

4. The Cosmic Perspective “Cosmos” = orderly arrangement (Greek) • Where is space? • The solar system • The cosmos Unit 1, Chapter 3, Lesson 3: The Space Environment SECTION 3.1

5. Where Is Space? • No clear definition of where space begins • US Air Force’s Astronaut Wings awarded for those who achieve 92.6 kilometers (57.6 miles) • For astronautics, space begins when an object can maintain an orbit for a short time about 130 kilometers (81 miles) altitude • Perspective for low-Earth orbit: if the Earth were a peach, most satellites would be just above the “fuzz” • Spaceship One: 328,000’ WHERE EARTH’S ATMOSPHERE ENDS Unit 1, Chapter 3, Lesson 3: The Space Environment

6. The Solar System: The Sun • The Sun generates every second enough energy to supply the U.S. for 624 million years • 600 million tons of hydrogen burned per second in nuclear fusion Unit 1, Chapter 3, Lesson 3: The Space Environment

7. The Sun: Radiation • Sun sends energy in the form of electromagnetic (EM) radiation • Radiation travels in waves • Sun’s EM radiation has many wavelengths: radio waves, infrared (heat), visible light, ultra-violet, x-rays and gamma rays Unit 1, Chapter 3, Lesson 3: The Space Environment

8. Electromagnetic (EM) Radiation • We classify Electromagnetic radiation in terms of the wavelength (or frequency) of the energy Electromagnetic (EM) Radiation Unit 1, Chapter 3, Lesson 3: The Space Environment

10. The Sun: Charged Particles • The intense heat from nuclear fusion breaks atoms into basic building blocks: • Protons • Electrons • Neutrons (quickly decay into an electron and a proton) • The Sun’s magnetic field propels these particles toward us at high speed: solar wind The Atom Unit 1, Chapter 3, Lesson 3: The Space Environment

11. The Sun: Solar Flares • Areas of the Sun’s surface sometimes erupt in solar flares • Flares can extend as far as the Earth’s orbit • Generate more energy than many nuclear weapons 11 year cycles: next peak in 2011 Unit 1, Chapter 3, Lesson 3: The Space Environment

12. The Planets • Aside from the Sun, other players in the solar system are • Planets • Moons • Asteroids • For most space missions, Earth is the primary player • Gravitation • Atmosphere • Magnetic field Unit 1, Chapter 3, Lesson 3: The Space Environment

13. The Cosmos • Solar system is part of the Milky Way Galaxy—about half way from the center • Galaxy rotates once every 240 million years • Next closest star in the galaxy—Proxima Centauri—is 4.22 light years away Galactic Distances = One Cosmic Year Unit 1, Chapter 3, Lesson 3: The Space Environment

14. The Cosmos • What is a light year? • Distance light can travel in one year • An interplanetary probe traveling at 35,000 m.p.h. would take 80,000 years to get to Proxima Centauri Unit 1, Chapter 3, Lesson 3: The Space Environment

15. Stellar Distances • Sun is marble 1 inch in diameter: in Denver, Colorado • Nearest star Proxima Centauri is 932 miles away: in Chicago, Illinois • Milky Way Galaxy is 21 million miles across Stellar Distances Unit 1, Chapter 3, Lesson 3: The Space Environment

16. Challenges of the Space Environment • Gravity / Free fall • Atmosphere • Vacuum • Micrometeoroids and Space Junk • Electromagnetic Radiation • Charged Particles Unit 1, Chapter 3, Lesson 3: The Space Environment SECTION 3.2

17. Gravity and Free-fall • Not “zero gravity” • Low-Earth orbit is about 91% of gravity at sea level • Physical impacts on equipment • Methods to measure quantities on Earth not effective • Plumbing must be pressurized—no “gravity feed” • Advantages • Opportunity to develop super alloys and pharmaceuticals • Heavier ingredients in materials won’t settle to the bottom Unit 1, Chapter 3, Lesson 3: The Space Environment

18. Drag • Spacecraft slow down when they run into particles in the upper atmosphere • Slower speeds mean less energy and smaller orbit • If uncorrected, will eventually re-enter The Atmosphere: Drag • Shuttle depends on drag to slow down from orbital speed to landing speed • Few particles above 600 kilometers altitude (375 miles) Unit 1, Chapter 3, Lesson 3: The Space Environment

19. RUST OXIDATION Unit 1, Chapter 3, Lesson 3: The Space Environment

20. The Atmosphere: Oxygen Most oxygen near Earth’s surface in the form of “O2” (two oxygen atoms bound together) Oxygen in upper atmosphere has trouble finding a “partner,” so it exists as “O” (monatomic oxygen) Weakens structures Changes thermal properties of coatings Degrades sensors LDEF Refer to P. 91 in book Unit 1, Chapter 3, Lesson 3: The Space Environment 20

21. Pressure 14.696 psi How do aircraft account for decreased pressures with altitude? Unit 1, Chapter 3, Lesson 3: The Space Environment 21

22. Impact of a Near-Vacuum • Outgassing • Gasses kept inside materials by atmosphere’s pressure may be “coaxed” out by near-zero pressure • Escaping gasses can cloud sensors • Spacecraft are “baked” in hot vacuum chambers before being launched into space Thermal vacuum chamber Unit 1, Chapter 3, Lesson 3: The Space Environment

23. Impact of a Near-Vacuum (cont’d) • Cold Welding • No air layer between contacting parts • Moving parts tend to bind • Limited Heat Transfer • Convection and conduction are options to transfer heat only within the spacecraft • Radiation is the only means to transfer heat into and out of the satellite Unit 1, Chapter 3, Lesson 3: The Space Environment

24. Conduction • Heat flows by conduction through an object from the hot end to the cool end. • Spacecraft use conduction to remove heat from hot components. Unit 1, Chapter 3, Lesson 3: The Space Environment

25. Convection • Boiling water on a stove shows how convection moves heat through a fluid from the fluid near a hot surface to the cooler fluid on top. • Special devices on spacecraft use convection to remove heat from hot components Unit 1, Chapter 3, Lesson 3: The Space Environment

26. Radiation • Radiation is the only way to transfer heat out of the spacecraft because there is no liquid (air) to tranfer it via conduction. Unit 1, Chapter 3, Lesson 3: The Space Environment 26

27. Micrometeoroids and Space Junk • Natural Sources • 20,000 tons of debris bombard Earth annually • Vary in size from dust-like particles to large asteroids • Artificial Sources • Old satellites, parts of launch vehicles • Tools, paint chips • Small Objects at High Speed (lots of momentum) Unit 1, Chapter 3, Lesson 3: The Space Environment

28. NEWS LAST NIGHT What was the boom and flash in the skies last night? Unit 1, Chapter 3, Lesson 3: The Space Environment 28

29. Micrometeoroids and Space Junk Cerise spacecraft lost a 6-foot boom from a collision with a piece of space junk Crater in Space Shuttle Challenger’s window from collision with a paint chip Unit 1, Chapter 3, Lesson 3: The Space Environment

30. http://orbitaldebris.jsc.nasa.gov/photogallery/beehives.html#leohttp://orbitaldebris.jsc.nasa.gov/photogallery/beehives.html#leo Unit 1, Chapter 3, Lesson 3: The Space Environment 30

31. The Radiation Environment • Primarily from the Sun • Mainly visible light and infrared (heat) • X-rays and gamma radiation also present • Impact: • Photons good for generating electrical power (solar panels) • Heat radiation (infrared) heats spacecraft • Ultra-violet radiation can damage electronic equipment, disrupt communications • Photons striking surfaces can impart a force: solar pressure Unit 1, Chapter 3, Lesson 3: The Space Environment

32. Solar Max Spacecraft • Spacecraft with large surface areas, such as solar panels, must correct for the pressure from solar radiation that may change their altitude Unit 1, Chapter 3, Lesson 3: The Space Environment

33. Charged Particles • Sources: • Solar wind and flares • Galactic cosmic rays (solar wind from distant stars, remnants of Big Bang) • Van Allen Radiation Belts—regions of the Earth’s magnetic field Van Allen Radiation Belts Unit 1, Chapter 3, Lesson 3: The Space Environment

34. Charged Particles (cont’d) • Effects on Spacecraft • Charging • Similar: cross a carpeted room and touch a door knob • Rapid and unpredicted discharges can “fry” equipment • Sputtering • Wearing down of spacecraft surfaces by continual bombardment of particles • Similar to sandblasting • Single Event Phenomenon (SEP) • Electronic disruptions caused by deeply penetrating charged particles • “Bit-flip”: changing of a zero to a one or vice-versa Unit 1, Chapter 3, Lesson 3: The Space Environment

35. Living and Working in Space • Free Fall • Radiation and Charged Particles • Mental and Emotional Effects Unit 1, Chapter 3, Lesson 3: The Space Environment SECTION 3.3

36. Living and Working in Space • Free Fall • Fluid shift • Fluids equalize (no longer concentrated in lower body) • Edema • Dehydration • Increased heart rate Unit 1, Chapter 3, Lesson 3: The Space Environment

37. Space Environment Effects on Humans • Free fall (cont’d) • Motion sickness • Reduced load on weight-bearing tissues • Decalcifies bones • Reduces production of blood cells • Weakens bones and muscles Unit 1, Chapter 3, Lesson 3: The Space Environment

38. Space Environment Effects on Humans (cont’d) • Radiation and Charged Particles • Measurement of exposure • Dosages of radiation add up over time • Cumulative effects over time • Prolonged exposure to radiation means higher dosages • Total effect depends on biological impact of the dosages Unit 1, Chapter 3, Lesson 3: The Space Environment

39. Space Environment Effects on Humans (cont’d) • Mental and Emotional Effects • Excessive workload • Isolation, loneliness, depression • Careful screening and busy schedules help prevent problems. Unit 1, Chapter 3, Lesson 3: The Space Environment

40. Summary • The Cosmic Perspective • Where is Space? • The Solar System • The Cosmos • The Space Environment and Spacecraft • Challenges of the Space Environment • Gravity • Atmosphere • Vacuum • Micrometeoroids and Space Junk • The Radiation Environment • Charged Particles • Living and Working in Space • Hazards to Humans in Space • Free Fall • Radiation and Charged Particles • Mental and Emotional Effects Unit 1, Chapter 3, Lesson 3: The Space Environment

41. Next • Now that you know about the conditions you and your spacecraft can encounter in space, we’re ready to start discussing the basics of orbital motion. Unit 1, Chapter 3, Lesson 3: The Space Environment