Astronomical Motion Basics terms and concepts

1. Astronomical MotionBasics terms and concepts Force: action that changes the state of motion of an object. Inertia: the resistance of an object to the change of its state of motion. • "mass" has two meanings: • amount of matter • measure of inertia (more massive bodies are more inert)

2. Speed, Velocity and Acceleration • Speed is a scalar quantity which refers to "how fast an object is moving." • 50 mi/h • Instantaneous speed: the speed in an instant • Average speed = total distance covered / duration of travel • Velocity is a vector quantity which refers to "how fast an object is moving and to where.“ • 50 mi/h to the North • Acceleration – how does the velocity change

3. The Second Law of Newton:a = F/m, or F = ma Force a m Acceleration:the rate of change of velocity - speeding up, slowing down, or changing direction of motion "The acceleration of an object is proportional to the net force on it and inversely proportional to its mass". The bigger the force, the bigger the acceleration. The bigger the mass the smaller the acceleration.

4. Swing mass tied to a string in a circle String exerts force on the mass Without the force – motion on a straight line

5. Universal Gravitational Force Every two masses, M and m, attract each other with a force proportional to them, and inversely proportional to the square of the distance between them: M m G is the gravitational constant, measured experimentally, G=6.67x10-11 Nm2/kg2 d

6. Key Ideas • Kepler’s Laws • P 2 = a3 • Newton’s Laws • Speed, velocity, acceleration, force, inertia, mass, balanced and unbalanced forces • F= ma • Law of Universal Gravitation

7. Kepler’s Laws reconsidered Newton’s version of the Kepler’s 3rd empirical law: M m a P Units: P - in seconds, a - in meters. Allows to calculate masses

8. Newton figured out that the gravitational attraction between two objects is given by: where F is the force of attraction, G is a constant, m1 and m2 are the masses of the two objects, and r is the distance between them. If we increase the mass of the first object twice, the force will become a. 32 times weaker b. 8 times weaker c. 2 times stronger d. 8 times stronger e. none of the above is correct

9. Light Basics How does light travel? fast & straight: 300,000 km/s Macroscopic Properties of Light reflected refracted blocked absorbed and re-emitted Nature of Light electromagnetic wave particle (photon)

10. Wave pulse wave Properties of Waves • Frequency = 1/Period : f = 1/T f is measured in 1/sec, or Hz • Velocity = wavelength x frequency: v = lf • Velocity is measured in m/s • Light wave in vacuum : c = 300 000 km/s = lf • Huge range in l and f • c = lf always!!! Amplitude

11. A tsunami, an ocean wave generated by an earthquake, propagates along the open ocean at 700 km/hr and has a wavelength of 750 km. What is the frequency of the waves in such a tsunami? A) 0.933 Hz B) 0.000259 Hz C) 1.07 Hz D) 0.148 Hz Answer: B

12. Examples of Mechanical Waves tuning fork: vibrating object can produce sound Need a medium to propagate Water waves Waves in a Guitar String Pressure waves

13. Light is a special kind of wave Oscillating electric charges (for example, in antennas) => produce changing magnetic field            => which produces changing electric field => which produce changing magnetic field,   and so on…

14. Fig.06.05 Types EM waves c = lf

15. Made up of all wavelengths White Light

16. Fig. 16.9 Energy Levels for the Hydrogen atom and possible emission lines Small change in energy – redder color Spectrum Radiation of different wavelength and frequency is obtained

17. The “Fingerprint” of Different Elements Each element has its own family of unique spectral lines.

18. Three types of stellar spectra Spectra of stars 1. Lines 2. Background 1. For a particular gas: wavelengths of absorption-lines identical to wavelengths of emission lines 2. Each chemical element has its own unique spectrum 3. Same cloud of gas can produce emission or absorption spectrum

19. Different stars – different spectra

20. 1. Wien’s law 2. Stefan – Boltzmann law Fig. 7.6 T (heat) ~ random motion of particles

21. Doppler Effect λ ~ 550 nm λ ~ 600 nm Source of light receding from us at high speed

22. Doppler Effect • Christian Johann Doppler (1803-1853) • Information about the motion of the object • Calculating the Doppler Shift • Normal wavelength • Source approaching the observer: waves bunched up ahead of it – λ decreases • Source receding from the observer: waves are stretched out – λ increases

23. Refraction Reflection

24. Law of Reflection

25. The optical effect of refraction Speed of light different in different materials Vacuum – c =300 000 km/s Material – v < c Less dense to more dense – bands toward the normal line Index of refraction c/v = n >1

26. Optical Telescopes:Near Infrared and Visible Astronomy • Mirrors are better: • Lenses don’t produce clear image • Lenses absorb some light • Lenses are heavier • Lenses change shape with time reflectors (with mirrors) refractors (with lenses)

27. What is important for a telescope? • Diameter of the objective mirror (lens) • Light-gathering power • Angular resolution (in arcsec): • The Focal Lengths • Magnification

28. Yerkes Observatory

29. Atmospheric Absorption

30. Atmospheric Absorption

31. Astronomy at radio-wavelengths • Earth’s atmosphere largely transparent • Can penetrate dusty regions of interstellar space • Observations in daytime as well as at night • High resolution requires large telescopes Surface of planets (Venus) Planetary magnetic fields Structure of Milky Way and other galaxies Cosmic Background Radiation

32. The 64 meter radio telescope at Parkes Observatory, Australia

33. Fig.06.40 Arecibo Observatory, Puerto Rico Constructed in natural limestone bedrock

34. The very large array (VLA) Central New Mexico 27 independent radio dishes, 25m each, spread over large distance Better resolution

35. Near Infrared and Visible Astronomy • Earth’s atmosphere transparent to visible light, but only partly to IR light • Near IR can penetrate dusty regions of interstellar space • Surface of planets • Physical Properties of Stars • Structure of Milky Way, other galaxies and the Universe • Other Solar Systems • Searching for the first stars and galaxies

36. Existing Large Optical Telescopes 1.5-m Mt Wilson 2.5-m Mt Wilson 5.0-m Mt Palomar 6.5-m Russia 10-m Keck, Mauna Kea, Hawaii 8.2-m VLT, ESO, Chile Many 3 – 3.5 m telescopes Several 6-6.5 m telescopes One of the two Keck telescopes

37. Fig.06.26

38. Fig.06.35

39. Exploring Other Solar Systems 'Super Earth' Discovered at Nearby Star Very difficult to see small planets Need superb resolution 200 giant planets 1 rocky planet

40. “OverWhelmingly Large telescope” ~ 25 Earths At the visual range we will be able to distinguish between 2 stars 0.001 arcsec apart

41. Ultraviolet, X-ray, Gamma-ray and Far IR Astronomy • Observations must be made from space • UV and X-ray: special mirror configurations needed to form images • Gamma-rays cannot form images Stellar structure and evolution Structure of Milky Way and other galaxies

43. Fig.06.34 Mauna Kea Observatory, Hawaii

44. Fig.06.33 Cerro Tololo Inter-American Observatory

45. Basic Properties of Stars

46. Stellar parallax 1. Apparent change in the position of a star caused by the motion of the Earth around the Sun. 2. Detecting parallaxes means that Earth orbits around Sun 3. Maximum parallactic shift (two positions of the Earth’s orbit 6 months apart)

47. Earth in December Figure 2 1 b A 2 B d Earth in November 3 Earth in July A simple relationship (often called parallax-distance formula) between distance in parsecs and stellar parallax in arcseconds Proxima Centauri: distance : 4.3 LY = 4.3/3.26 pc = 1.3 pc parallax : 0.76 arcsec

48. Luminosity depends on temperature and size • Luminosity • the total amount of energy a star radiates out into space each second • Tells us how much energy is being generated within the star • Amount of generated energy is different for different stellar types Luminosity ~ T4R2 Measure of true stellar brightness !!! Same distance to both !!! !!! Same distance to both !!!

49. Apparent brightness Real Sky: • Stars of different size and color (different luminosity) • Different distances • Energy reaching us depends on distance, T, R • Apparent brightness - the true brightness affected by distance Far away Need to know stellar distances! Nearby

50. The brightness of the source of light decrease as we recede from it. • Imagine an observer located at a distance d from a 150 Watt light bulb. Let’s call the brightness of this bulb, as seen by this observer, B. When the observer recedes from the bulb, the brightness B drops off as the square of the distance d. The brightness B and the distance d are related as Inverse-square dependence