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Course: NASA > Unit 3
Lesson 4: Curiosity rover: discoveries- Curiosity has landed
- Curiosity descent
- Systems check
- Curiosity's first drive
- Navigation update
- Observations
- Discovery: Streambed
- First CheMin results
- Preparation for holidays
- Calcium-rich deposits found
- Results of first drilling
- Mars' bygone atmosphere
- 'Spring Break' over: commanding resumes
- Rover ready to switch gears
- Trek to Mt. Sharp begins
- Dating younger rocks
- Curiosity completes its first martian year
- A softer trek to mount sharp
- A taste of mount sharp
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First CheMin results
Nov 1st 2012. Created by NASA.
Want to join the conversation?
- Why is the chemin camera called chemin?(1 vote)
- How could curiosity survive the landing on Mars when it is created on Earth. We don't have the materials to make it protective against its impact into Mars(2 votes)
- can curiosty go on any planet?(1 vote)
- A rover can only go on terrestrial planets that do not destroy it upon entering the atmosphere. A rover would have a hard time surviving on venus, as it is so hot and the pressure is so great the rover would get destroyed. Curiosity specifically can only go to mars, because it has no way to leave the planet, but other rovers can go to whatever terrestrial, hospitable planet their spaceship brings them.(1 vote)
- Why are some do you call areas different names. Cant you just call rocknest rocky?(0 votes)
- if someone says "Go to the rocky place" how will you know where to go?(1 vote)
- What geological events have occurred? How old is the planet?(1 vote)
- Mars about 4.5 billion years old.(0 votes)
- how do you now thare is watter on mars(0 votes)
- There is, but it's frozen under the surface of mars! Please correct me if i'm wrong.(1 vote)
Video transcript
Hi, I'm David Bish, co-investigator on the CheMin instrument on the Mars Science Laboratory and this is your Curiosity rover update. We've been spending some time in an area called Rocknest, and this week we delivered a scoop of a dune to Curiosity. CheMin performs what we call X-ray diffraction measurements on powdered rocks and soil samples. An X-ray diffraction is the best method for telling us what minerals are present in a rock or a soil because it is sensitive to the arrangements of atoms in minerals. As the X-rays strike the soil sample, CheMin shows us how mineral crystals distinctively interact with X-rays, and this image shows our first Xray diffraction results. The diffraction signals appear on the detector as rings that represent the fingerprint of the individual minerals. The rings tell us not only what minerals are present in the soil but also how abundant they are. The CheMin data provide us with distinctive signatures of the minerals: plagioclase feldspar, pyroxenes, and olivine. Peridot is a variety of olivine; just keep in mind that the olivine in the soil sample is much smaller than these crystals. Roughly half of the soil consists of poorly crystalline material, such as volcanic glass. Thus, this Martian soil appears very similar to some weathered basaltic soils that we see on Earth, in places like the flanks of Mauna Kea, Hawaii. You can appreciate how revolutionary CheMin is when you consider that instruments of this type on Earth are typically about the size of a double-wide refrigerator and the CheMin instrument on the Mars Science Laboratory is about the size of a shoebox. CheMin has been modified for use on Earth in places such as Antarctica and the Arctic. It's also been applied for the detection of counterfeit pharmaceuticals around the worlds and a modification of the instrument has been used in archeological studies to help us understand the nature of the surfaces and how we might protect them. In the coming weeks and months, we're excited to measure more X-ray diffraction data on soils and rocks to tell us much more about the geology of Gale Crater. This has been your Curiosity rover report. Stay tuned for further updates.