1. The Terrestrial Planets

2. Because the 4 inner planets have solid, rocky terrains…
Earth
Venus
Mars
Mercury
Because the 4 inner planets have solid, rocky terrains…

3. …they are sometimes called the “terrestrial planets”.
Earth
Venus
Mars
Mercury
…they are sometimes called the “terrestrial planets”.

4. Starting with Mercury, each planet will be discussed in detail.
Earth
Venus
Mars
Mercury
Starting with Mercury, each planet will be discussed in detail.

5. Mercury

6. The “planet” Mercury was named for the “Roman god” Mercury.

7. In Roman mythology, Mercury was the god of trade and commerce.

8. The word, “merchant” contains the same root as the word, “Mercury”.

9. Mercury was also the son of Jupiter.

10. Mercury is only slightly larger than the Earth’s Moon.

11. In order of planets away from the Sun, Mercury is the innermost planet.

12. Because it is so close to the Sun, it is often quite difficult to observe.

13. Here we see the Moon just after sunset.

14. Did you also notice Mercury in the sky?

15. Did you also notice Mercury in the sky?

16. Although Mercury is one of the brightest objects in the sky…

17. …most people, have never seen it.

18. On his deathbed, for example, Galileo lamented the fact…

19. …that he was dying without ever having seen Mercury.

20. At its greatest elongation…
greatest elongation (aphelion)
At its greatest elongation…

21. …Mercury is never found more than 28o away from the Sun.
greatest elongation (aphelion)
…Mercury is never found more than 28o away from the Sun.

22. At its least elongation…
least elongation (perihelion)
At its least elongation…

23. …Mercury is only found at 18o away from the Sun.
least elongation (perihelion)
18o
…Mercury is only found at 18o away from the Sun.

24. This means that Mercury is never far from the setting Sun.

25. This photo shows the highest position that Mercury reaches on various dates.

26. On February 8, Mercury is at its greatest elongation.

27. On this date, it should be 28o away from the setting Sun.

28. Just like Venus and the Moon…

29. …Mercury also experiences a full cycle of phases.

30. Because only 2 of those phases are visible from Earth…

31. Mercury is only visible for about 1 week at a time, twice per year.

32. Recall that distances within the solar system…

33. …are measured in “astronomical units”.

34. And that 1astronomical unit…

35. …is the average distance from the Earth to the Sun.
1 AU
…is the average distance from the Earth to the Sun.

36. Mercury’s distance, on the other hand…

37. is found at only 0.39 AUs from the Sun.

38. This makes Mercury 2.5x closer to the Sun than the Earth.
1.00 AU
_______ =
2.5 x closer
0.39 AU
0.39 AU
This makes Mercury x closer to the Sun than the Earth.

39. In being 2.5x closer to the Sun, the Sun appears to be 6.25x bigger.
0.39 AU
In being 2.5x closer to the Sun, the Sun appears to be 6.25x bigger.

40. If this is how big the Sun appears when viewed from Earth…
The Sun as seen from Earth
If this is how big the Sun appears when viewed from Earth…

41. The Sun as seen from Mercury
The Sun as seen from Earth
6.25 x bigger
…then here’s how big the Sun appears when viewed from Mercury.

42. Rotation and Revolution

43. North Pole
Mercury
equator
rotation: counter-clockwise

44. radio telescope
(satellite dish)

45. Mercury’s rotation was difficult to determine.

46. For one thing, it rotates very slowly.

47. Secondly, in being so close to the Sun, its surface is difficult to observe.

48. However, using the Doppler Effect, Mercury’s rotation was calculated.

49. Identical radio waves leave the dish with the same wavelengths.

50. From the approaching side, the returning waves are shorter.

51. Since they are shorter, this means that they are blue shifted.

52. From the receding side, however, the returning waves are longer.
blue-shifted
From the receding side, however, the returning waves are longer.

53. And since they are longer, this means that they are red shifted.
blue-shifted
And since they are longer, this means that they are red shifted.

54. It’s the amount of red and blue shift…
red-shifted
blue-shifted
It’s the amount of red and blue shift…

55. …which determines Mercury’s rate of rotation.
red-shifted
blue-shifted
…which determines Mercury’s rate of rotation.

56. The faster Mercury rotates on its axis…
red-shifted
blue-shifted
The faster Mercury rotates on its axis…

57. …the more red and blue shift will be observed.
red-shifted
blue-shifted
…the more red and blue shift will be observed.

58. The slower Mercury rotates on its axis…
red-shifted
blue-shifted
The slower Mercury rotates on its axis…

59. …the less red and blue shift
red-shifted
blue-shifted
…the less red and blue shift
will be observed.

60. Mercury revolves the Sun in only 88 days.
Revolution
00.00
Days
Mercury revolves the Sun in only 88 days.

61. Mercury revolves the Sun in only 88 days.
Revolution
05.50
Days
Mercury revolves the Sun in only 88 days.

62. Mercury revolves the Sun in only 88 days.
Revolution
11.00
Days
Mercury revolves the Sun in only 88 days.

63. Mercury revolves the Sun in only 88 days.
Revolution
16.50
Days
Mercury revolves the Sun in only 88 days.

64. Mercury revolves the Sun in only 88 days.
Revolution
22.00
Days
Mercury revolves the Sun in only 88 days.

65. Mercury revolves the Sun in only 88 days.
Revolution
29.50
Days
Mercury revolves the Sun in only 88 days.

66. Mercury revolves the Sun in only 88 days.
Revolution
33.00
Days
Mercury revolves the Sun in only 88 days.

67. Mercury revolves the Sun in only 88 days.
Revolution
38.50
Days
Mercury revolves the Sun in only 88 days.

68. Mercury revolves the Sun in only 88 days.
Revolution
44.00
Days
Mercury revolves the Sun in only 88 days.

69. Mercury revolves the Sun in only 88 days.
Revolution
49.50
Days
Mercury revolves the Sun in only 88 days.

70. Mercury revolves the Sun in only 88 days.
Revolution
55.00
Days
Mercury revolves the Sun in only 88 days.

71. Mercury revolves the Sun in only 88 days.
Revolution
60.50
Days
Mercury revolves the Sun in only 88 days.

72. Mercury revolves the Sun in only 88 days.
Revolution
66.00
Days
Mercury revolves the Sun in only 88 days.

73. Mercury revolves the Sun in only 88 days.
Revolution
71.50
Days
Mercury revolves the Sun in only 88 days.

74. Mercury revolves the Sun in only 88 days.
Revolution
77.00
Days
Mercury revolves the Sun in only 88 days.

75. Mercury revolves the Sun in only 88 days.
Revolution
82.50
Days
Mercury revolves the Sun in only 88 days.

76. Mercury revolves the Sun in only 88 days.
Revolution
Days
Days
88.00
Mercury revolves the Sun in only 88 days.

77. Mercury rotates on its axis with a sidereal period of 59 days.
Sidereal Rotation
00.00
Days
Mercury rotates on its axis with a sidereal period of 59 days.

78. Mercury rotates on its axis with a sidereal period of 59 days.
Sidereal Rotation
07.38
Days
Mercury rotates on its axis with a sidereal period of 59 days.

79. Mercury rotates on its axis with a sidereal period of 59 days.
Sidereal Rotation
14.75
Days
Mercury rotates on its axis with a sidereal period of 59 days.

80. Mercury rotates on its axis with a sidereal period of 59 days.
Sidereal Rotation
22.12
Days
Mercury rotates on its axis with a sidereal period of 59 days.

81. Mercury rotates on its axis with a sidereal period of 59 days.
Sidereal Rotation
29.50
Days
Mercury rotates on its axis with a sidereal period of 59 days.

82. Mercury rotates on its axis with a sidereal period of 59 days.
Sidereal Rotation
36.88
Days
Mercury rotates on its axis with a sidereal period of 59 days.

83. Mercury rotates on its axis with a sidereal period of 59 days.
Sidereal Rotation
44.25
Days
Mercury rotates on its axis with a sidereal period of 59 days.

84. Mercury rotates on its axis with a sidereal period of 59 days.
Sidereal Rotation
51.63
Days
Mercury rotates on its axis with a sidereal period of 59 days.

85. Mercury rotates on its axis with a sidereal period of 59 days.
Sidereal Rotation
59.00
Days
Mercury rotates on its axis with a sidereal period of 59 days.

86. Mercury rotates on its axis with a sidereal period of 59 days.
Sidereal Rotation
Days
pointing upward
59.00
Mercury rotates on its axis with a sidereal period of 59 days.

87. Mercury’s noon-to-noon, however, requires 176 days to complete.
Synodic Rotation
Days
000.00
Mercury’s noon-to-noon, however, requires 176 days to complete.

88. Mercury’s noon-to-noon, however, requires 176 days to complete.
Synodic Rotation
007.36
Days
Mercury’s noon-to-noon, however, requires 176 days to complete.

89. Mercury’s noon-to-noon, however, requires 176 days to complete.
Synodic Rotation
014.75
Days
Mercury’s noon-to-noon, however, requires 176 days to complete.

90. Mercury’s noon-to-noon, however, requires 176 days to complete.
Synodic Rotation
022.12
Days
Mercury’s noon-to-noon, however, requires 176 days to complete.

91. Mercury’s noon-to-noon, however, requires 176 days to complete.
Synodic Rotation
029.50
Days
Mercury’s noon-to-noon, however, requires 176 days to complete.

92. Mercury’s noon-to-noon, however, requires 176 days to complete.
Synodic Rotation
036.88
Days
Mercury’s noon-to-noon, however, requires 176 days to complete.

93. Mercury’s noon-to-noon, however, requires 176 days to complete.
Synodic Rotation
044.25
Days
Mercury’s noon-to-noon, however, requires 176 days to complete.

94. Mercury’s noon-to-noon, however, requires 176 days to complete.
Synodic Rotation
051.63
Days
Mercury’s noon-to-noon, however, requires 176 days to complete.

95. Mercury’s noon-to-noon, however, requires 176 days to complete.
Synodic Rotation
059.00
Days
Mercury’s noon-to-noon, however, requires 176 days to complete.

96. Mercury’s noon-to-noon, however, requires 176 days to complete.
Synodic Rotation
066.37
Days
Mercury’s noon-to-noon, however, requires 176 days to complete.

97. Mercury’s noon-to-noon, however, requires 176 days to complete.
Synodic Rotation
073.74
Days
Mercury’s noon-to-noon, however, requires 176 days to complete.

98. Mercury’s noon-to-noon, however, requires 176 days to complete.
Synodic Rotation
081.11
Days
Mercury’s noon-to-noon, however, requires 176 days to complete.

99. Mercury’s noon-to-noon, however, requires 176 days to complete.
Synodic Rotation
088.00
Days
Mercury’s noon-to-noon, however, requires 176 days to complete.

100. Mercury’s noon-to-noon, however, requires 176 days to complete.
Synodic Rotation
095.36
Days
Mercury’s noon-to-noon, however, requires 176 days to complete.

101. Mercury’s noon-to-noon, however, requires 176 days to complete.
Synodic Rotation
102.24
Days
Mercury’s noon-to-noon, however, requires 176 days to complete.

102. Mercury’s noon-to-noon, however, requires 176 days to complete.
Synodic Rotation
111.12
Days
Mercury’s noon-to-noon, however, requires 176 days to complete.

103. Mercury’s noon-to-noon, however, requires 176 days to complete.
Synodic Rotation
118.00
Days
Mercury’s noon-to-noon, however, requires 176 days to complete.

104. Mercury’s noon-to-noon, however, requires 176 days to complete.
Synodic Rotation
123.63
Days
Mercury’s noon-to-noon, however, requires 176 days to complete.

105. Mercury’s noon-to-noon, however, requires 176 days to complete.
Synodic Rotation
131.25
Days
Mercury’s noon-to-noon, however, requires 176 days to complete.

106. Mercury’s noon-to-noon, however, requires 176 days to complete.
Synodic Rotation
138.90
Days
Mercury’s noon-to-noon, however, requires 176 days to complete.

107. Mercury’s noon-to-noon, however, requires 176 days to complete.
Synodic Rotation
146.50
Days
Mercury’s noon-to-noon, however, requires 176 days to complete.

108. Mercury’s noon-to-noon, however, requires 176 days to complete.
Synodic Rotation
154.12
Days
Mercury’s noon-to-noon, however, requires 176 days to complete.

109. Mercury’s noon-to-noon, however, requires 176 days to complete.
Synodic Rotation
161.75
Days
Mercury’s noon-to-noon, however, requires 176 days to complete.

110. Mercury’s noon-to-noon, however, requires 176 days to complete.
Synodic Rotation
169.38
Days
Mercury’s noon-to-noon, however, requires 176 days to complete.

111. Mercury’s noon-to-noon, however, requires 176 days to complete.
Synodic Rotation
176.00
Days
Mercury’s noon-to-noon, however, requires 176 days to complete.

112. Mercury’s noon-to-noon, however, requires 176 days to complete.
Synodic Rotation
Days
176.00
noon
Mercury’s noon-to-noon, however, requires 176 days to complete.

113. Notice the relationship between Mercury’s noon-to-noon and its year.

114. is exactly twice as long as its year.
176 days = (88 days) x 2
Its noon-to-noon
is exactly twice as long as its year.

115. Notice also that the 176-day synodic rotation…

116. …is exactly equal to 3 sidereal rotations.
176 days = (59 days) x 3
…is exactly equal to sidereal rotations.

117. It’s merely a coincidence how these numbers relate to each other.

118. 000.00
Day Counter
Sidereal
Revolution
Synodic

119. 007.38
Day Counter
Sidereal
Revolution
Synodic

120. 014.78
Day Counter
Sidereal
Revolution
Synodic

121. 022.15
Day Counter
Sidereal
Revolution
Synodic

122. 029.52
Day Counter
Sidereal
Revolution
Synodic

123. 036.89
Day Counter
Sidereal
Revolution
Synodic

124. 044.26
Day Counter
Sidereal
Revolution
Synodic

125. 051.63
Day Counter
Sidereal
Revolution
Synodic

126. Day Counter
059.00
Sidereal
Revolution
Synodic

127. Day Counter
059.00
Sidereal
Revolution
Synodic

128. Day Counter
059.00 1
Sidereal
Revolution
Synodic

129. 059.00 1 After 59 days in orbit, Day Counter Sidereal Revolution
Revolution
Synodic
After 59 days in orbit,

130. After 59 days in orbit, Mercury completes 1 sidereal day.
Day Counter
059.00 1
Sidereal
Revolution
Synodic
After 59 days in orbit, Mercury completes 1 sidereal day.

131. Day Counter
059.00 1
Sidereal
Revolution
Synodic

132. 066.37
Day Counter 1
Sidereal
Revolution
Synodic

133. 073.74
Day Counter 1
Sidereal
Revolution
Synodic

134. 081.11
Day Counter 1
Sidereal
Revolution
Synodic

135. Day Counter
088.00 1
Sidereal
Revolution
Synodic

136. 088.00 1 After 88 days in orbit, Day Counter Sidereal Revolution
Revolution
Synodic
After 88 days in orbit,

137. After 88 days in orbit, Mercury completes 1 revolution.
Day Counter
088.00 1
Sidereal
Revolution
Synodic
After 88 days in orbit, Mercury completes 1 revolution.

138. After 88 days in orbit, Mercury completes 1 revolution.
Day Counter
088.00 1
Sidereal
Revolution
Synodic
After 88 days in orbit, Mercury completes 1 revolution.

139. After 88 days in orbit, Mercury completes 1 revolution.
Day Counter
088.00 1
Sidereal 1
Revolution
Synodic
After 88 days in orbit, Mercury completes 1 revolution.

140. Day Counter
088.00 1
Sidereal 1
Revolution
Synodic

141. 096.36
Day Counter 1
Sidereal
Revolution
Synodic

142. 103.24
Day Counter 1
Sidereal
Revolution
Synodic

143. 111.12
Day Counter 1
Sidereal
Revolution
Synodic

144. 118.00
Day Counter 1
Sidereal
Revolution
Synodic

145. 118.00 1 After 118 days in orbit, Day Counter Sidereal Revolution1
Sidereal
Revolution
Synodic
After 118 days in orbit,

146. After 118 days in orbit, Mercury completes 2 sidereal days.
118.00
Day Counter 1
Sidereal
Revolution
Synodic
After 118 days in orbit, Mercury completes 2 sidereal days.

147. After 118 days in orbit, Mercury completes 2 sidereal days.
118.00
Day Counter 1
Sidereal
Revolution
Synodic
After 118 days in orbit, Mercury completes 2 sidereal days.

148. After 118 days in orbit, Mercury completes 2 sidereal days.
118.00
Day Counter 2 1
Sidereal
Revolution
Synodic
After 118 days in orbit, Mercury completes 2 sidereal days.

149. 118.00
Day Counter 2 1
Sidereal
Revolution
Synodic

150. 123.63
Day Counter 2 1
Sidereal
Revolution
Synodic

151. 131.25
Day Counter 2 1
Sidereal
Revolution
Synodic

152. 138.90
Day Counter 2 1
Sidereal
Revolution
Synodic

153. 145.50
Day Counter 2 1
Sidereal
Revolution
Synodic

154. 154.12
Day Counter 2 1
Sidereal
Revolution
Synodic

155. 161.75
Day Counter 2 1
Sidereal
Revolution
Synodic

156. 169.38
Day Counter 2 1
Sidereal
Revolution
Synodic

157. Day Counter
176.00 2
Sidereal 1
Revolution
Synodic

158. 176.00 2 1 After 176 days in orbit, Day Counter Sidereal Revolution
Synodic
After 176 days in orbit,

159. After 176 days in orbit, 3 things happen with Mercury.
Day Counter
176.00 2
Sidereal 1
Revolution
Synodic
After 176 days in orbit, things happen with Mercury.

160. Day Counter
176.00 2
Sidereal 1
Revolution
Synodic

161. Day Counter
176.00 2
Sidereal 1
Revolution
Synodic
Mercury achieves

162. Mercury achieves its third sidereal day.
Day Counter
176.00 2
Sidereal 1
Revolution
Synodic
Mercury achieves its third sidereal day.

163. Mercury achieves its third sidereal day.
Day Counter
176.00 2
Sidereal 1
Revolution
Synodic
Mercury achieves its third sidereal day.

164. Mercury achieves its third sidereal day.
Day Counter
176.00 3
Sidereal 1
Revolution
Synodic
Mercury achieves its third sidereal day.

165. Day Counter
176.00 3
Sidereal 1
Revolution
Synodic

166. Day Counter
176.00 3
Sidereal 1
Revolution
Synodic
It also completes

167. It also completes 2 revolutions around the Sun.
Day Counter
176.00 3
Sidereal 1
Revolution
Synodic
It also completes revolutions around the Sun.

168. It also completes 2 revolutions around the Sun.
Day Counter
176.00 3
Sidereal 1
Revolution
Synodic
It also completes revolutions around the Sun.

169. It also completes 2 revolutions around the Sun.
Day Counter
176.00 3
Sidereal 2
Revolution
Synodic
It also completes revolutions around the Sun.

170. Day Counter
176.00 3
Sidereal 2
Revolution
Synodic

171. 176.00 3 2 And at the same time, Day Counter Sidereal Revolution
Synodic
And at the same time,

172. And at the same time, Mercury also completes 1 synodic day.
Day Counter
176.00 3
Sidereal 2
Revolution
Synodic
And at the same time, Mercury also completes 1 synodic day.

173. And at the same time, Mercury also completes 1 synodic day.
Day Counter
176.00 3
Sidereal 2
Revolution
Synodic
And at the same time, Mercury also completes 1 synodic day.

174. And at the same time, Mercury also completes 1 synodic day.
Day Counter
176.00 3
Sidereal 2
Revolution 1
Synodic
And at the same time, Mercury also completes 1 synodic day.

175. Day Counter
176.00 3
Sidereal 2
Revolution 1
Synodic

176. 176.00 3 2 1 Since the number “176” Day Counter Sidereal Revolution
Synodic
Since the number “176”

177. Since the number “176” is a multiple of both “88” and “59”…
Day Counter
176.00 3
Sidereal 2
Revolution 1
Synodic
Since the number “176” is a multiple of both “88” and “59”…

178. Day Counter
176.00 3
Sidereal 2
Revolution 1
Synodic

179. …then all 3 of these numbers
Day Counter
176.00 3
Sidereal 2
Revolution 1
Synodic
…then all 3 of these numbers

180. …then all 3 of these numbers changed on exactly the same day.
Day Counter
176.00 3
Sidereal 2
Revolution 1
Synodic
…then all 3 of these numbers changed on exactly the same day.

181. …then all 3 of these numbers changed on exactly the same day.
Day Counter
176.00 3
Sidereal 2
Revolution 1
Synodic
…then all 3 of these numbers changed on exactly the same day.

182. Space Probes to Mercury

183. Mercury was visited by the Mariner 10 spacecraft in 1974.

184. Mariner 10 mapped Mercury’s surface, and took the first close-up photographs.

185. In 2004 NASA launched the Mercury Messenger probe.

186. This was only the second probe ever sent to the planet Mercury.

187. In January, 2008 Messenger arrived at Mercury.

188. Messenger’s discoveries are yet to be revealed.

189. Mercury’s Interior

190. Mercury’s density is much higher than the Moon’s density.

191. This indicates that Mercury’s core has a high concentration of heavy metals.

192. 60% of Mercury’s total mass consists of an iron-nickel core.

193. The surrounding crust consists of silicate rock.
rocky crust
iron-nickel core
The surrounding crust consists of silicate rock.

194. Mercury’s rocky crust is nearly 700 km thick.
iron-nickel core
700 km
Mercury’s rocky crust is nearly 700 km thick.

195. This slide compares the cores of the Earth, Moon, and Mercury.

196. Notice that Mercury’s core is a ball of metal the size of the Moon.

197. A weak magnetic field has been detected around Mercury.

198. This indicates that some portion of the core is liquid.

199. History of Mercury
Dominated by ancient lava flows and heavy meteorite bombardment.
Radar image suggests icy polar cap.

200. Mercury shows no evidence of plate tectonics or faulting.

201. However, its surface has long creases.

202. These creases formed from wrinkling caused when Mercury cooled and shrank.

203. The Surface of Mercury Very similar to Earth’s moon:
Heavily battered with craters, including some large basins.
Largest basin: Caloris Basin
Terrain on the opposite side jumbled by seismic waves from the impact.

204. Curved cliffs, probably formed when Mercury shrank while cooling down
Lobate Scarps
Curved cliffs, probably formed when Mercury shrank while cooling down

205. The Plains of Mercury No large maria, but intercrater plains:
Marked by smaller craters (< 15 km) and secondary impacts
Smooth plains:
Even younger than intercrater plains

206. Mercury VS The Moon

207. resembles the surface of the Moon.
The surface of Mercury
resembles the surface of the Moon.

208. Can you look at the 2 photos and tell which one is Mercury?

209. Can you look at the 2 photos and tell which one is Mercury?
Moon
Can you look at the 2 photos and tell which one is Mercury?

210. Both bodies are heavily cratered.
Moon
Mercury
Both bodies are heavily cratered.

211. Both bodies are similar in size and appearance.
Moon
Mercury
Both bodies are similar in size and appearance.

212. And neither body has an atmosphere.
Moon
Mercury
And neither body has an atmosphere.

213. There are 2 reasons why Mercury has no atmosphere.

214. In the first place, the surface gravity on Mercury is too low.

215. With so little gravity, it is unable to retain an atmosphere.

216. Secondly, in being so close to the Sun…

217. …heated gases have the kinetic energy to escape Mercury and to fly off into space.

218. Look closely at the 2 crescents.

219. Which side is Mercury, and which side is the Moon?

220. If this was your guess, then you were correct.
Mercury
Moon
If this was your guess, then you were correct.

221. Here’s another one: Mercury or the Moon?

222. It’s Mercury, but it also looks like the lunar surface.

223. It’s Mercury, but it also looks like the lunar surface.
Moon
It’s Mercury, but it also looks like the lunar surface.

224. Surface Temperature

225. Mercury’s temperature range is the greatest of any planet.

226. Its daytime temperature can reach 700o Fahrenheit.

227. And its nighttime temperature can reach -100o Fahrenheit.

228. All planets without atmospheres get very cold at night.
700o F
-100o F
All planets without atmospheres get very cold at night.

229. But because Mercury is so close to the Sun…
700o F
-100o F
But because Mercury is so close to the Sun…

230. …its daytime temperatures exceed those of all other planets.

231. So Mercury ranges nearly 800o F between daytime and nighttime.
+700o F – (-100o) = 800o F
700o F
-100o F
So Mercury ranges nearly 800o F between daytime and nighttime.

232. Mercury Mercury Statistics Mass (kg) 3.303e+23
Mass (Earth = 1) e-02
Equatorial radius (km) 2,439.7
Equatorial radius (Earth = 1) e-01
Mean density (gm/cm^3) 5.42
Mean distance from the Sun (km) 57,910,000
Mean distance from the Sun (Earth = 1)
Rotational period (days)
Orbital period (days)
Mean orbital velocity (km/sec) 47.88
Orbital eccentricity
Tilt of axis (degrees) 0.00
Orbital inclination (degrees) 7.004
Equatorial surface gravity (m/sec^2) 2.78
Equatorial escape velocity (km/sec) 4.25
Visual geometric albedo 0.10
Magnitude (Vo) -1.9
Mean surface temperature 179°C
Maximum surface temperature 427°C
Minimum surface temperature -173°C
Atmospheric composition
Helium 42%
Sodium 42%
Oxygen 15%
Other 1%
The southwest quadrant of Mercury is seen in this image taken March 29, 1974, by the Mariner 10 spacecraft. The picture was taken four hours before the time of closest approach when Mariner was 198,000 km (122,760 mi) from the planet. The largest craters seen in this picture are about 100 km (62 mi) in diameter.
Mercury has been visited by only one spacecraft, Mariner 10. It flew by three times in 1974 and Only 45% of the surface was mapped (and, unfortunately, it is too close to the Sun to be safely imaged by HST). A new discovery-class mission to Mercury, MESSENGER was launched by NASA in 2004 and will orbit Mercury starting in 2011 after several flybys.