Starship Asterisk*

The residue is thought to be mostly sodium carbonate and ammonium chloride from a slushy brine within or below the dwarf planet's crust.

daniel.reardon wrote: ↑Thu Jul 19, 2018 3:34 pm

The residue is thought to be mostly sodium carbonate and ammonium chloride from a slushy brine within or below the dwarf planet's crust.

The term "slushy brine" suggests the presence of liquid water. Is that right, or am I misunderstanding this? I'd have assumed that Ceres would be too cold to hold liquid water.

daniel.reardon wrote: ↑Thu Jul 19, 2018 3:34 pm

The residue is thought to be mostly sodium carbonate and ammonium chloride from a slushy brine within or below the dwarf planet's crust.

The term "slushy brine" suggests the presence of liquid water. Is that right, or am I misunderstanding this? I'd have assumed that Ceres would be too cold to hold liquid water.

Chris Peterson wrote: ↑Thu Jul 19, 2018 3:59 pm

daniel.reardon wrote: ↑Thu Jul 19, 2018 3:34 pm

The residue is thought to be mostly sodium carbonate and ammonium chloride from a slushy brine within or below the dwarf planet's crust.

The term "slushy brine" suggests the presence of liquid water. Is that right, or am I misunderstanding this? I'd have assumed that Ceres would be too cold to hold liquid water.

Depending upon the salts dissolved in the water, the freezing point can be far lower than that of pure water. Also, the interior of Ceres may still be somewhat warm from radioactive decay, allowing brine to remain unfrozen.

https://en.wikipedia.org/wiki/Geology_of_Ceres

<<Ceres's surface has an albedo of 0.09 [vs. Vesta albedo = 0.42, Pallas albedo = 0.16], which is quite dark compared to the moons in the outer Solar System. This might be a result of the relatively high temperature of Ceres's surface, the maximum temperature with the Sun overhead was estimated from measurements to be 235 K (−38 °C; −37 °F) on 5 May 1991. In a vacuum, ice is unstable at this temperature.>>

neufer wrote: ↑Thu Jul 19, 2018 4:20 pm

Chris Peterson wrote: ↑Thu Jul 19, 2018 3:59 pm

daniel.reardon wrote: ↑Thu Jul 19, 2018 3:34 pm


The term "slushy brine" suggests the presence of liquid water. Is that right, or am I misunderstanding this? I'd have assumed that Ceres would be too cold to hold liquid water.

Depending upon the salts dissolved in the water, the freezing point can be far lower than that of pure water. Also, the interior of Ceres may still be somewhat warm from radioactive decay, allowing brine to remain unfrozen.

https://en.wikipedia.org/wiki/Geology_of_Ceres

<<Ceres's surface has an albedo of 0.09 [vs. Vesta albedo = 0.42, Pallas albedo = 0.16], which is quite dark compared to the moons in the outer Solar System. This might be a result of the relatively high temperature of Ceres's surface, the maximum temperature with the Sun overhead was estimated from measurements to be 235 K (−38 °C; −37 °F) on 5 May 1991. In a vacuum, ice is unstable at this temperature.>>

http://www.dailymail.co.uk/femail/food/ ... LAKES.html

Artist wins a place in the prestigious Royal Academy exhibition for her framed collection of CORNFLAKES (but she prefers toast for breakfast)
Anne Griffiths, 54, of Wantage, Oxford

De58te wrote: ↑Thu Jul 19, 2018 5:57 pm
Ok I can understand that these bright spots formed at the bottom of a crater most likely from the collision itself. But what are the extremely dark spots made out of? They are adjacent to the bright spots, one noticeable one at the 8 and 9 o'clock position. These are much darker than the regular gray surface, because I turned my brightness control way up and still it remained darker than the surroundings. Excepting the bright spots of course.

Astronymus wrote: ↑Thu Jul 19, 2018 9:16 pm There seem fault lines nearby. I wonder if this salty mass might have been pushed out like outcrops on earth. Like exposed salt domes. Such mass doesn't need to be wet with water to flow. Maybe shrinking of the asteroids crust and shape due to an cooling core caused it.

MarkBour wrote: ↑Thu Jul 19, 2018 10:51 pm
Over the course of the last 4 billion years, for a given body in a stable orbit around the Sun, it is reasonable to believe that the Solar radiation has increased by about 40%. I wonder what such a change does to a body like Ceres. There are many other factors, of course. The internal heat sources of bodies, and in some cases, atmospheres, with their possibilities (none on Ceres). Would one expect Ceres to have steadily cooled over this time, or gone up in temperature?

• However, many (harrowing) things have changed ... even over the last 34 million years:

https://astrobob.areavoices.com/2018/07/20/finally-a-super-close-look-at-ceres-brightest-spot/ wrote:
Finally — A Super-Close Look At Ceres’ Brightest Spot
Astrobob, July 20, 2018

<<Based on crater counts, Occator Crater [i.e., 92 km wide crater was named after the Roman god of the harrow ] is estimated to be 34 million years old, but the bright spots inside are much younger, only about 4 million years old. Dawn also mapped Ceres’ gravity field and discovered that it has a rocky core and icy mantle. It’s likely that crater-forming asteroid impacts tapped into that mantle, creating the fractures and low spots that later led to the release of trapped liquids from beneath the surface.>>

bporter wrote: ↑Fri Jul 20, 2018 12:40 pm Where is the scale bar? Come on, I know they don't come preprinted on the terrain, but we don't have any idea of the scale here.

I add my voice to the cacophony pointing out that this is an ongoing problem in APOD images.

neufer wrote: ↑Fri Jul 20, 2018 4:04 am

MarkBour wrote: ↑Thu Jul 19, 2018 10:51 pm
Over the course of the last 4 billion years, for a given body in a stable orbit around the Sun, it is reasonable to believe that the Solar radiation has increased by about 40%. I wonder what such a change does to a body like Ceres. There are many other factors, of course. The internal heat sources of bodies, and in some cases, atmospheres, with their possibilities (none on Ceres). Would one expect Ceres to have steadily cooled over this time, or gone up in temperature?

Solar radiation has increased by about 30% in the last 4.5 billion years.
https://en.wikipedia.org/wiki/Sun#Main_sequence

IF nothing else has changed then Ceres would have warmed by less than 12K [or 7% = (1.3)^0.25- 1.0].

This in itself would be negligible (especially when spread out over 4.5 billion years).

• However, many (harrowing) things have changed ... even over the last 34 million years:

https://astrobob.areavoices.com/2018/07/20/finally-a-super-close-look-at-ceres-brightest-spot/ wrote:
Finally — A Super-Close Look At Ceres’ Brightest Spot
Astrobob, July 20, 2018

<<Based on crater counts, Occator Crater [i.e., 92 km wide crater was named after the Roman god of the harrow ] is estimated to be 34 million years old, but the bright spots inside are much younger, only about 4 million years old. Dawn also mapped Ceres’ gravity field and discovered that it has a rocky core and icy mantle. It’s likely that crater-forming asteroid impacts tapped into that mantle, creating the fractures and low spots that later led to the release of trapped liquids from beneath the surface.>>

CNewman wrote: ↑Fri Jul 20, 2018 6:57 pm I have a tangentially related question. This stunning photograph seduced me into perusing JPL's Dawn web site, and at https://www.jpl.nasa.gov/missions/dawn/ is a "Key Discoveries" about Dawn's visit to Vesta, which states that "Vesta has a crater more than 300 miles in diameter. In the center is a mountain more than twice the height of Mount Everest."
My question, then, is what reference is used for the height of features on non-terrestrial bodies? In such discussions about mountain heights on Earth, the reference is typically sea level, unless otherwise specified.
If the reference for that mountain on Vesta is the mountain's base, would it be better to compare it to Mauna Kea, whose height from base to peak is over 10,000 meters, according to https://en.wikipedia.org/wiki/Mauna_Kea?

CNewman wrote: ↑Fri Jul 20, 2018 6:57 pm
JPL's Dawn web site, and at https://www.jpl.nasa.gov/missions/dawn/ is a "Key Discoveries" about Dawn's visit to Vesta, which states that "Vesta has a crater more than 300 miles in diameter. In the center is a mountain more than twice the height of Mount Everest."
My question, then, is what reference is used for the height of features on non-terrestrial bodies? In such discussions about mountain heights on Earth, the reference is typically sea level, unless otherwise specified.

If the reference for that mountain on Vesta is the mountain's base, would it be better to compare it to Mauna Kea, whose height from base to peak is over 10,000 meters, according to https://en.wikipedia.org/wiki/Mauna_Kea?

https://en.wikipedia.org/wiki/List_of_tallest_mountains_in_the_Solar_System wrote:

Code: Select all

Vesta 	   Rheasilvia central peak 	22 km
Mars 	   Olympus Mons 	        21.9 km
Iapetus    equatorial ridge 	        20 km
Io 	   Boösaule Montes "South" 	17.5 to 18.2 km
Oberon 	   unnamed ("limb mountain") 	11 km
Earth 	   Mauna Kea and Mauna Loa 	10.2 km
Mimas 	   Herschel central peak 	 7 km
Venus 	   Skadi Mons 	                 6.4 km
Pluto 	   Tenzing Montes, peak "T2" 	~6.2 km
Moon 	   Mons Huygens 	         5.5 km

SeedsofEarth wrote: ↑Mon Aug 13, 2018 7:40 pm Maybe I missed it somewhere in this thread, but can someone tell me why some segments of this photo are out of focus?