1. 1

2. This is the Early-Release Image of Omega Centauri, taken by WFC3/UVIS on board the Hubble Space Telescope (HST) 2

3. A close up of the central region.3

4. This image was made by combining separate red, green, and blue images.4

5. The red image is from filter F814W, which sees only very red light.5

6. The green image is from filter F336W, which sees only blue light.

7. The blue image is from filter F225W, which sees only ultra-violet light.7

8. The combined image again.8

9. The colors are so extreme because…9

10. … the red stars have almost no blue light, and the blue stars have almost no red light.10

11. The composite image again.11

12. Astronomers like to study the colors of stars in a quantitative way.12

13. Astronomers Classify stars or the sort the stars by color, putting the blue stars on the left and the red stars on the right.
13a

14. They like to sort the stars by color, putting the blue stars on the left and the red stars on the right.
13b

15. They like to sort the stars by color, putting the blue stars on the left and the red stars on the right.

16. They like to sort the stars by color, putting the blue stars on the left and the red stars on the right.
13d

17. They like to sort the stars by color, putting the blue stars on the left and the red stars on the right.
13e

18. They like to sort the stars by color, putting the blue stars on the left and the red stars on the right.
13f

19. They like to sort the stars by color, putting the blue stars on the left and the red stars on the right.
13g

20. They like to sort the stars by color, putting the blue stars on the left and the red stars on the right.
13h

21. They like to sort the stars by color, putting the blue stars on the left and the red stars on the right.
13i

22. They like to sort the stars by color, putting the blue stars on the left and the red stars on the right.
13j

23. They like to sort the stars by color, putting the blue stars on the left and the red stars on the right.
13k

24. Note that there are very few extreme stars; most stars are white, meaning they have a balanced spectrum. 14

25. Astronomers also like to characterize the stars in terms of brightness.14

26. They like to sort the stars, putting the bright stars on top, and the faint stars on the bottom.

27. They like to sort the stars, putting the bright stars on top, and the faint stars on the bottom.

28. They like to sort the stars, putting the bright stars on top, and the faint stars on the bottom.
15c

29. They like to sort the stars, putting the bright stars on top, and the faint stars on the bottom.

30. They like to sort the stars, putting the bright stars on top, and the faint stars on the bottom.

31. They like to sort the stars, putting the bright stars on top, and the faint stars on the bottom.

32. They like to sort the stars, putting the bright stars on top, and the faint stars on the bottom.

33. They like to sort the stars, putting the bright stars on top, and the faint stars on the bottom.

34. They like to sort the stars, putting the bright stars on top, and the faint stars on the bottom.

35. They like to sort the stars, putting the bright stars on top, and the faint stars on the bottom.
15j

36. They like to sort the stars, putting the bright stars on top, and the faint stars on the bottom.

37. This is called a Color-Magnitude Diagram (CMD).16

38. When Astronomers first plotted stars this way, they realized that stars don’t fall just anywhere in the diagram. 17

39. Stars tend to lie along a few well-defined sequences.18

40. The unmistakable order in diagrams like this led astronomers to develop theories to explain stellar evolution. 19

41. The vast majority of stars lie along the Main Sequence (MS).

42. MS
Stars don’t move along this sequence; rather they sit at the same place for a long time fusing their hydrogen into helium.
20b

43. MS
This is a sequence in mass. Stars at the bright end are massive, and those at the faint, red end have very low masses.
20c

44. MS
The more massive stars consume their hydrogen fuel much faster than the lower-mass stars.
20d

45. SGB MS
When fuel becomes sparse in the stellar core, stars readjust their internal structure and move red-ward along the Sub-Giant Branch (SGB). 21

46. RGB
SGB MS
They start to burn the hydrogen in a shell around the core and become big and bloated as they move up the Red Giant Branch (RGB).
22a

47. RGB
SGB MS
As the shell-burning continues, more and more helium gets deposited onto the core.
22b

48. RGB
SGB MS
When the core has enough mass, it is finally able to ignite helium into carbon.
22c

49. RGB HB
SGB MS
The star readjusts its structure again and finds itself on the Horizontal Branch (HB).
23a

50. RGB HB
SGB MS
The helium fuel is not as potent as the hydrogen, so it runs out quickly.
23b

51. RGB HB
SGB MS
That is why there are so few stars on the HB compared to the MS. Stars do not spend much time on the HB.
23c

52. RGB HB
SGB WD MS
When the helium is gone, the star has no more fuel. With nothing left to burn, it fades away into blue darkness as a White Dwarf (WD). 24

53. MS
SGB
RGB HB WD
Since a star’s color and brightness tell us its evolutionary phase, we can easily identify stars by phase in the image. 25