Difference between revisions of "April 27, 2004"

From LPOD
Jump to: navigation, search
Line 48: Line 48:
 
----
 
----
 
===COMMENTS?===  
 
===COMMENTS?===  
Click on this icon [[image:PostIcon.jpg]] at the upper right to post a comment.
+
Register, and click on the <b>Discussion</b> tab at the top of the page.

Revision as of 15:20, 11 January 2015

A Penetrating View of Imbrium

["javascript:;" onMouseOver="MM_swapImage('main_image',,'images/LPOD-2004-04-27b.jpeg',1)" onMouseOut="MM_swapImgRestore()" LPOD-2004-04-27.jpeg]
Image Credit: Bruce Campbell

A Penetrating View of Imbrium

We observe the Moon with our green-sensitive eyeballs, red-sensitive ccd cameras, multi-spectral spacecraft sensors and also with radar of various wavelengths. Each view provides somewhat different information about the top layers of the Moon. Each detector provides information to a depth about equal to a few times the wavelength used. Optical sensors probe the top microns of the lunar surface, but this 70-cm radar image (from the giant Arecibo radio telescope in Puerto Rico) penetrates several meters into the lunar soil. Optical images provide 2-dimensional surface information but radar tells about volume. Bruce Campbell of the Smithsonian Institution is using these radar images as probes of the depth properties of the lunar regolith (or soils). For example, the northern part of the ejecta blanket of Plato is quite distinct here, where it is less so in optical and shorter-wavelength radar images. Presumably this is due to radar scattering from subsurface blocky ejecta. The difference in brightness across Mare Imbrium probably relates to the amount of titanium in the lava flows - compare this image with a multi-spectral view.

Chuck Wood

Technical Details:

Attached is a better view of the whole area at 70-cm wavelength; sinusoidal projection. The data were collected at Arecibo in 2000, and have a full spatial resolution of 400 m per pixel (this image is downsampled). The polarization is "opposite sense circular (LR)"; no scattering law has been removed. We use a fully focused radar processing approach to obtain high spatial resolution over relatively long integration times.

Related Links:
Lunar Radar Mapping

Tomorrow's LPOD: LRO - Our Future on the Moon


Author & Editor:
Charles A. Wood

Technical Consultant:
Anthony Ayiomamitis

A service of:
ObservingTheSky.Org

Visit these other PODs:
Astronomy | Mars | Earth

 


COMMENTS?

Register, and click on the Discussion tab at the top of the page.