Timing and duration of mare volcanism in the central region of the northern farside of the Moon

被引:0
作者
Tomokatsu Morota
Junichi Haruyama
Makiko Ohtake
Tsuneo Matsunaga
Taichi Kawamura
Yasuhiro Yokota
Chikatoshi Honda
Jun Kimura
Naru Hirata
Hirohide Demura
Akira Iwasaki
Takamitsu Sugihara
机构
[1] Japan Aerospace Exploration Agency,Institute of Space & Astronautical Science
[2] National Institute for Environmental Studies,Center for Global Environmental Research
[3] University of Aizu,Center for Planetary Science
[4] Hokkaido University,Research Center for Advanced Science and Technology
[5] The University of Tokyo,Center for Deep Earth Exploration
[6] Japan Agency for Marine Science and Technology,undefined
来源
Earth, Planets and Space | 2011年 / 63卷
关键词
Moon; mare volcanism; lunar farside; Feldspathic Highland Terrane; the South Pole-Aitken basin; crater size-frequency measurement;
D O I
暂无
中图分类号
学科分类号
摘要
Age determinations of lunar mare basalts are essential for understanding the thermal evolution of the Moon. In this study, we performed new crater size-frequency measurements in mare deposits in the central region of the northern farside, consisting of Lacus Luxuriae, Buys-Ballot, Campbell, and Kohlschutter, using high-resolution images obtained by SELENE (Kaguya) Terrain Camera. The estimated model ages of the mare deposits range from 2.7 to 3.5 Ga. On the basis of model ages for all investigated mare deposits in the central part of the northern farside, considering the results of previous studies, we concluded that mare volcanism in this region began at least as early as 3.9 Ga and continued until ∼2.6 Ga. From a comparison of model ages in the region and the South Pole-Aitken basin, we found that mare volcanism in these regions ended at the same time, suggesting that the South Pole-Aitken basin formation impact had a minor effect on mare volcanism in the region.
引用
收藏
页码:5 / 13
页数:8
相关论文
共 283 条
[1]  
Allen C C(1979)Large lunar secondary craters—Size-range relationships Geophys, Res. Lett. 6 51-54
[2]  
Antonenko I(1995)Criteria for the detection of lunar cryptomaria Earth Moon Planets 69 141-172
[3]  
Head J W(2009)Lunar global shape and polar topography derived from Kaguya-LALT laser altimetry Science 323 897-900
[4]  
Mustard J F(1974)Effect of a giant impact on the thermal evolution of the Moon Moon 9 183-209
[5]  
Hawke B R(1979)Standard techniques for presentation and analysis of crater size-frequency data Icarus 37 467-474
[6]  
Araki H(1984)Lunar dark-haloed impact craters: origins and implications for early mare volcanism J. Geophys. Res. 8 6899-1147
[7]  
Tazawa S(2008)Compositional and temporal investigation of exposed lunar basalts in the Mare Imbrium region Icarus 197 1-18
[8]  
Noda H(1987)Isotopic analysis of basaltic fragments from lunar breccia 14321-chronology and petrogenesis of pre-Imbrium mare volcanism Geochim. Cosmochim. Acta. 51 3241-3254
[9]  
Ishihara Y(2007)Rays and secondary craters of Tycho Icarus 186 31-40
[10]  
Goossens S(2004)Magmatic effects of the lunar late heavy bombardment Earth Planet. Sci. Lett. 222 17-27
12345678910