Submitted by rhinotomus t3_y23ytd in askscience
Or do currents/other factors make the difference negligible at best?
Comments
Chlorophilia t1_is1o5bf wrote
> As the name suggests this circulation is driven almost entirely by changes in temperature and salinity
This is one of these 'facts' that are often repeated, but are actually false, and it's simple to explain why. Aside from mixing within the ocean interior, all processes that affect the density of water (e.g. evaporation, precipitation, and sea-ice formation) occur at the surface. As a result, whilst it's possible to form dense waters at the surface of the ocean (which can sink), there is no process that can reduce the density of the resulting deep waters, and thereby bring them back to the surface. In other words, it is energetically impossible for the 'thermohaline circulation' to be driven by changes in temperature and salinity.
In actual fact, the more-accurately-named meridional overturning circulation is chiefly driven by a combination of winds in the Southern Ocean, and interior mixing (e.g. Gnanadesikan (1999), Johnson et al. (2007)). The formation of dense water masses is a necessary condition to have strong overturning, but it isn't the driver.
jellyfixh t1_is1t12y wrote
Thank you for the correction, I had never heard of the mechanical input to the MOC. So it seems density drives the initial formation but mechanical energy is needed to have the water circulate back to surface?
Chlorophilia t1_is1ugnv wrote
Yes exactly. As you completely correctly wrote, the parts of the ocean with the right conditions to create very dense water masses (e.g. the marginal seas of the North Atlantic and Southern Ocean) are the parts of the ocean where deep water formation occurs. You can't have an overturning circulation without deep water formation. But this isn't an energy source, because no energy input is required for dense waters to sink below lighter waters. The problem is that, in order to have vigorous overturning, these dense waters have to somehow be returned to the surface (and at a significant rate). There's no process in the deep-ocean that adds (non-negligible) freshwater or heat, so the deep waters can't rise buoyantly. As a result, the only way water can return to the surface is by being dragged up by wind-induced upwelling, or (probably to a lesser extent) mechanically mixed up, probably mainly due to tides. What exactly are the key processes that determine the strength of the AMOC is an active research question, and the freshening of the North Atlantic is absolutely capable of reducing the AMOC strength (because if you're generating deep water at a lower rate, you're also going to upwell less deep water), but the point is that deep water formation isn't a driver (or energy source) of the overturning.
Bear_Wills t1_is1xafc wrote
>There's no process in the deep-ocean that adds (non-negligible) freshwater or heat, so the deep waters can't rise buoyantly.
Freshwater makes sense, but do geothermal vents in the deep-ocean not add non-negligible heat? (Apologies if that is a silly question, just found the conversation very interesting as someone with little knowledge in this area, but that part stood out to me)
Chlorophilia t1_is1yzjg wrote
This is a good point! Geothermal vents are too localised to be significant, but there is a geothermal heat flux everywhere on the ocean floor (due to heat escaping from the Earth's interior). However, this heat flux is on the order of 0.1W/m^2. By contrast, the heat flux at the ocean surface from the sun is of order 100W/m^2. So for the heat budget of the ocean as a whole, the geothermal heat flux is negligible. Locally, at the ocean floor, it has been argued that the geothermal heat flux could be non-negligible. However, this is not routinely incorporated into ocean or climate models (I will admit that I didn't even know this had been properly looked into before your comment made me look it up!) and, whilst it's possible that it could have some second-order effect, it's orders of magnitude too small to drive the kind of large-scale overturning we see in the modern Atlantic.
phantasmagorical_owl t1_is28geh wrote
I can't speak for other ocean or climate models, bit geothermal heating is included in NASA's ECCO ocean models and state estimates. Its magnitude is small relative to ocean surface heat fluxes but geothermal heating does help maintain a more realistic deep ocean state by reducing the drift in deep temperatures.
Chlorophilia t1_is28uwa wrote
> I can't speak for other ocean or climate models, bit geothermal heating is included in NASA's ECCO ocean models and state estimates.
That's good to know! I was not aware of this.
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Bear_Wills t1_is23268 wrote
Really interesting, thanks for taking the time to answer!
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Aeellron t1_is24aot wrote
Man the facts about the sun just never cease to amaze.
Orders of magnitude more heat introduced than geothermal vents.
As soon as you think about it it makes sense.
Shaetane t1_is2zdnv wrote
We really aint nothing without our resident well-distanced, well-temperatured, star
salsashark99 t1_is39c04 wrote
What is the range of salinity of ocean water?
Chlorophilia t1_is3aa0f wrote
Most of the ocean is between 32-36g/L (so quite a tight range!). You can get more extreme values in some marginal seas, and of course places like lagoons and estuaries.
Swiss_cake_raul t1_is3xvlq wrote
I actually knew this fact already but reading it written as g/L instead of ppt just made me realize it's the same ratio of salt:water as my sourdough recipe!
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phantasmagorical_owl t1_is299zb wrote
Wouldn't one expect local Ekman pumping (wind induced upwelling) and internal tidal mixing to be indifferent to the rate of remote deep water formation? The properties of the upwelled deep waters certainly vary based on what their surface properties when they descended.
Chlorophilia t1_is2agyq wrote
The processes of deep water formation, and return pathways to the surface, are closely coupled because of conservation of volume. Unless you have an enormous expansion of abyssal water masses, Ekman suction + tidal mixing cannot be independent of deep water formation rates. The point is that, regardless of the buoyancy forcing taking place in locations of deep water formation, they're fundamentally limited by the amount of water that you're (mechanically) returning to the surface. You can create as much dense water in the North Atlantic as you want but, if there's no return pathway to the surface, you're not going to generate deep water at a significant rate.
phantasmagorical_owl t1_is2l9ad wrote
Ekman suction and tidal mixing are independent of deep water formation rates. Deep water formation by surface buoyancy forcing at high latitudes is not the only way that abyssal waters can be renewed. A thought experiment: an isothermal isohaline ocean is subjected to ekman pumping from surface wind stress in one region. Upwelled water would subsequently redistribute away. Conservation of volume dictates that the upwelled waters are replaced, and of course they are by surrounding waters at depth, possibly many depths. An overturning circulation will become established, with waters away from the upwelling site "sinking" to replace the upwelled waters, although the sinking is more akin to falling, as there is a decrease in the volume of waters below. Possibly the sinking would occur uniformly over the entire non-upwelling basin, or it might be confined to an area around to upwelling, but the resulting overturning circulation would look different than our current MOC.
The rate of surface water transformation depends only on local buoyancy forcing and initial seawater properties, it doesn't know about remote upwelling rates. However, if upwelling ceases, the abyss would eventually fill up with dense transformed water and the rising isopycnal of that "deep water" would eventually limit the depth to which the newly formed dense water sinks. So, in that sense, the rate of deep water formation does eventually depend on there being upwelling or tidal mixing elsewhere.
Chlorophilia t1_is2mosd wrote
> Ekman suction and tidal mixing are independent of deep water formation rates.
I think you're misunderstanding what I'm saying, because I'm not disagreeing with you - I'm not saying that Ekman suction and tidal mixing are a function of deep water formation rates. I'm saying that deep water formation rates are (to first-order) a function of Ekman suction and diapycnal mixing. As you say, at equilibrium, the rate of deep water formation is limited by the available return pathways. If upwelling ceases, it is not possible to maintain deep water formation.
ReynAetherwindt t1_is32r7a wrote
I don't mean to be obtuse but "deep water formation" sounds like the result of a flood, like, "That there's some deep water, and it weren't there before."
What the heck does it actually mean?
Chlorophilia t1_is3561q wrote
It's a good question. The uppermost layer of the ocean is called the 'mixed layer'. As the name suggests, it's a well-mixed layer where the properties are set (over short timescales) by the atmospheric conditions above and, because of weaker stratification at higher latitudes, it tends to be shallow at low latitudes and deep at high latitudes, particularly in the winter. When we talk about a water mass being formed, this usually refers to water leaving the mixed layer, and thereby no longer having its properties directly forced by the atmosphere. This can either occur through a time-mean vertical velocity, or horizontal currents (if the mixed layer profile is sloped). Deep water formation specifically refers to the formation of a water mass that is deep (where "deep" usually means "below the thermocline").
phantasmagorical_owl t1_is2mtfl wrote
Also, see this tank experiment (link below). As far as I can tell, in those pumping and suction experiments the water has uniform density and there is no specific site of dense water formation, yet overturning does occur.
http://weathertank.mit.edu/links/projects/ekman-pumping-suction-introduction
TheProfessorO t1_is2x0b0 wrote
Eddy flow over the bottom produces larger vertical velocities than the mean wind driven upwelling
Chlorophilia t1_is2ym6p wrote
Eddy velocities are by definition zero in the Eulerian time-mean, so that in itself isn't going to result in a time-mean vertical transport. Eddies in the Southern Ocean actually counteract Ekman suction but I'm not sure on what basis you're arguing that eddies are responsible for most upwelling in the Southern Ocean? Can you provide a study supporting this?
TheProfessorO t1_is38c7h wrote
I was not talking about any ocean in particular. The eddy vertical velocity is proportional to the eddy horizontal velocity dotted with the topographic gradient. So the average eddy vertical velocity can be nonzero when the mean eddy horizontal velocity is zero. The importance of this term for mesoscale ocean dynamics was shown by Tom Rossby and a student in the late 80s.
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DonArgueWithMe t1_is26xdb wrote
Wouldn't underwater heat vents, volcanoes and such be methods of adding energy back to the water and cycling that back up?
Chlorophilia t1_is277gq wrote
Technically yes, but these heat sources are extremely small compared to the heating at the surface of the ocean, see this response.
eaglessoar t1_is266ol wrote
> no process that can reduce the density of the resulting deep waters
so if i had some salty water below and some fresh water flowed over it that fresh water would not become salty at all?
Chlorophilia t1_is28nvb wrote
It depends on how thick the layers of fresh and salty water are, and whether there's anything mixing them together. The molecular diffusivity of salt in water is about 10^-9 m^(2)/s, which means that the distance salt can diffuse is roughly sqrt(10^(-9)t), where t is the time in seconds. So, for instance, if you had a 100m thick layer of freshwater lying on top of a 100m thick layer of saltwater, it would take well over 100,000 years for molecular diffusion to fully mix them.
In practice, in the ocean, there is mechanical forcing that causes mixing (e.g. the winds, tides, turbulence, etc). A typical value for the real, effective vertical diffusivity in the ocean (taking into account mechanical mixing) is 10^-5 m^(2)/s but, even then, it would take several decades to mix these layers together. And 100m is pretty small compared to the thickness of deep-ocean water masses.
eaglessoar t1_is2948e wrote
Wow I would've thought it was much faster! Thanks for the reply
AlkaliActivated t1_is2oc2c wrote
You can use this to do science demonstrations in classrooms: A golf ball will float on saturated salt water, but sink in fresh water. You can partially fill a container with saturated salt water, then carefully fill the remainder with tap water, and the golf ball will float at the boundary between the two for a while. IIRC it can last a few weeks.
regular_modern_girl t1_is2xubu wrote
>As a result, whilst it’s possible to form dense waters at the surface of the ocean (which can sink), there is no process that can reduce the density of the resulting deep waters, and thereby bring them back to the surface.
Is this why those mini-brine lakes form on the seafloor in some areas? Like will the densest, most saline waters end up all coalescing together deep in the ocean until the salt content is so concentrated that it approaches saturation? Or are those brine pools the result of something geological instead? (I know that that they’re associated with methane cold seeps)
Chartarum t1_is35oyz wrote
Wouldn't underwater volcanic activity and thermal vents be able heat up at least some deep water and lower its density causing it to rise? At least on a local scale?
Or is the amount of heat/energy released in such areas and processes just too small to matter in any significant way?
Chlorophilia t1_is36q3w wrote
Locally yes, and these plumes can be biologically and geochemically important. But if we're thinking about the large-scale overturning circulation of the ocean, these heat sources are negligibly small (not to mention the fact that there's no direct correlation between where these vents are and where upwelling of deep waters occurs).
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darkest_irish_lass t1_is2m8un wrote
Thank you for this excellent explanation! Do you know what happens at thermal vents and undersea volcanoes? Will the heated water rise or just 'flow' away from the volcano?
Chlorophilia t1_is2n0mc wrote
Yes, it will rise is a buoyant plume, until it has lost enough heat to surrounding water through mixing to reach a neutral density, e.g. see this acoustic image from a survey of a hydrothermal vent field.
bagonmaster t1_is2stci wrote
Wouldn’t the water eventually getting cold enough or under the right pressure conditions to freeze make it less dense so it would float up?
Chlorophilia t1_is2v3ah wrote
No, because:
- Any water capable of sinking into the deep ocean must be liquid (otherwise it wouldn't be dense enough to sink), so in other words, all deep water is above the freezing point (of seawater). So if all of your surrounding water is above freezing, and the sea-floor is above freezing (which is generally the case), how are you going to cool below the freezing point?
- If you look at the phase diagram of water, you'll see that, at 0C, you'd have to reach a pressure of ~1GPa to reach the freezing point, which is equivalent to a water depth of ~100km, ~10x deeper than the deepest part of the ocean. This phase diagram is for pure water, not seawater, but it's still not possible for water to naturally freeze in the ocean through pressure changes alone.
GammaFork t1_is4odr2 wrote
Though you do get funky pressure effects on liquid freshwater released from deep subsurface ice shelf grounding lines and subsequently refreezing onto the base of the ice shelf as it floats up to lower pressures!
bagonmaster t1_is2wcno wrote
There are some faulty assumptions in there though, the biggest of which is assuming that solid water has to be less dense than water which it doesn’t. The ice that would form at 0C and 1GPa would almost certainly be denser than liquid water
Chlorophilia t1_is2x37d wrote
> solid water has to be less dense than water
This is completely correct within the physical conditions that exist in the ocean. I have no idea what the density of ice is at 1GPa, but it's irrelevant, because these pressures do not exist in the ocean. The only way that you could physically generate ice in the deep ocean is by either (1) reducing the salinity, or (2) refrigeration, neither of which naturally occur in the deep ocean.
brunswick t1_isahr46 wrote
To add onto this about the pressures that exist in the ocean, pressure at any given depth is equal to the density of water * g * h. Let's say we have a water column consisting exclusively of pretty dense water with a density of 1029 kg/m^3. To get 1GPa, the ocean would have to be 99 km deep which is far far deeper than the deepest part of the ocean.
bagonmaster t1_is2xu6y wrote
The pressures in the deepest parts of the ocean are absolutely high enough to create different states of ice that would be denser than water. If there’s ice there it wouldn’t float.
It’s absolutely possible that the salinity changes at that depth or the pressure of the water above changes, the water doesn’t have to get colder to freeze.
Chlorophilia t1_is2y6mm wrote
> The pressures in the deepest parts of the ocean are absolutely high enough to create different states of ice that would be denser than water.
Do you have any evidence for ice ever being observed forming in the deep ocean?
> It’s absolutely possible that the salinity changes at that depth
How? What source of freshwater are you proposing exists in the abyssal ocean?
> or the pressure of the water above changes
How?
GammaFork t1_is4p2rk wrote
Basal melt at the deep back of ice shelves produces freshwater at depths >1000 m locally or more. This then flows up the underside of the ice shelf and becomes locally supercooled, leading to basal refreezing. Admittedly there are entrainment effects too, but a key driver is the pressure influence on the local freezing point. Ref: https://agupubs.onlinelibrary.wiley.com/doi/10.1029/2006JC003915
bagonmaster t1_is2yyzf wrote
A storm can change the pressure and temperature of the water above it. The salinity can change from a number of factors from organisms to changes in environment changing the solubility causing some to precipitate out.
We still know very little about the deepest parts of our ocean and until we can more easily explore them I don’t see how you could say with any certainty there’s no ice down there.
Chlorophilia t1_is30czg wrote
> A storm can change the pressure and temperature of the water above it.
The difference between the highest and lowest atmospheric pressure ever recorded on earth is about 25kPa. That is over 1000 times smaller than the pressure at the bottom of the average ocean depth. Even a large wave would have a larger effect on pressure than that (but still negligibly small compared the pressure at a depth of >>1km).
> I don’t see how you could say with any certainty there’s no ice down there.
Because as I've already stated, it is physically impossible to naturally form ice at depth in the ocean. There is no way to cool the water below the freezing point below the surface. Pressures >> 0.1GPa do not exist in the ocean. There is no known source of freshwater in the deep ocean, nor is there any proposed mechanism for how such a source could exist, nor is there any evidence suggesting this exists.
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regular_modern_girl t1_is3sxqp wrote
Just to be charitable to the user who’s arguing with you, I suppose it’s maybe possible they’ve seen pictures of methane clathrate deposits on the seafloor, which does look a lot like ice and is sometimes even (erroneously) referred to as “methane ice”. I could see how someone might see photos of a methane cold seep in NatGeo or something, see people on boats topside holding samples of what looks like ice, and possibly getting confused over the text referring to it as an ice-like substance at the bottom of the ocean.
However, methane clathrate is obviously not actually ice (or at least it’s not usually classed as one of the forms of water ice and is really kind of its own thing chemically), and I might be assuming too much good faith here . In any event, this other user needs to admit that they’re probably not going to win an argument about basic physical properties of seawater with an actual expert on the physical properties of oceans.
TheHecubank t1_is3iw71 wrote
> We still know very little about the deepest parts of our ocean and until we can more easily explore them I don’t see how you could say with any certainty there’s no ice down there
We've been to the deepest point of the Ocean. We know what the pressure is there.
We also know what pressures are required to form the kinds of Ice you are discussing because we have made them in a lab.
The pressure difference between the two nearly 10 times greater than the pressure difference between the bottom of the ocean and the vaccum of space. It's not even close.
Edit: to help more with scale, the pressure under question (1 GPa) is roughly the pressure range we expect for the Mohorovičić discontinuity - the boundary between the Earth's crust and mantle. If Ocean water could come up with that kind of pressure, there wouldn't be an ocean floor - because the pressure would push it into the mantle.
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TheHecubank t1_is3i46v wrote
Nothing in the ocean gets even close to the pressures required to result in high pressure variants of ice. Even the highest pressure of Challenger Deep is still an order of magnitude short of that.
The ice that forms at the point described (0 C and 1 GPa) would indeed be less that of water at the same point. It would be a mixture of Ice V and Ice VII, since that is the transition point. Neither of those forms of Ice naturally exist on Earth.
We do have a tiny amount of extremely high pressure Ice on Earth - specifically, Ice VII. It needs a much higher pressure to form than the water in the ocean can provide: thus far, we have found it in exactly one place on the planet (outside a lab) - tiny inclusions inside diamonds.
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regular_modern_girl t1_is3mrx1 wrote
ice-Ih (the only form of water ice that occurs naturally in terrestrial conditions) is a weird solid in that it’s actually by definition significantly less dense than its liquid phase, due to peculiarities of its crystal structure.
This actually leads to a number of peculiarities when it comes to ice (the common earthly form of it, at least), such as that it floats on liquid water, it takes up more volume than liquid water, and that higher pressures actually generally melt it by lowering its freezing point (the exact opposite of how most crystalline solids work).
If we were talking about almost any substance other than water here (or talking about very different conditions than Earth) then what you’re saying here would be largely correct, but water (and especially ice-Ih) is just really weird like this.
EDIT: I forgot that ice-Ic (the cubic crystal form of ice-I) is hypothesized to occur naturally in tiny amounts in the upper atmosphere, and trace amounts of ice-VII (one of the high-pressure variants) have been found as natural inclusions in diamonds as a user below just informed me, but obviously neither of these things are really relevant to the argument at hand. Ice-Ih is still the only one we encounter in daily life, and the only one to occur in substantial quantities in nature here on Earth. The full water ice “zoo” that we’ve managed to synthesize in lab conditions up to this point consists of something like 20 or so different crystalline forms (I think depending somewhat on how exactly you distinguish some of the structures), as well as non-crystalline amorphous ice (which has a disordered molecular structure like glass, occurs in very low pressure conditions, and might actually be the most common form of water across the universe).
StatusSea5409 t1_is30591 wrote
Idk according to NASA it seems to be a mix of both.
https://mynasadata.larc.nasa.gov/basic-page/ocean-circulation
jaxdraw t1_is34791 wrote
Are tidal forces completely absent at depth? I would have assumed that water, being non compressible, would be impacted throughout based on tidal forces.
Chlorophilia t1_is34fm8 wrote
Tidal forces are absolutely present at depth, and they're actually the source of much of the mechanical energy that drives mixing in the ocean interior.
Kandiru t1_is354d8 wrote
Presumably geothermal vents can heat up water which can send it rising?
Chlorophilia t1_is35fnb wrote
Yes, but geothermal vents are highly localised and have a negligible contribution to the whole-ocean heat budget. Plumes associated with hydrothermal vents are important biologically and geochemically, but not for ocean physics as a whole.
HeIsSparticus t1_is3hcae wrote
Is it possible that there is any osmotic forces at play that encourage mixing / movement of neighboring bodies of water of differing salinity? No idea if this would be the case.
Focker_ t1_is3xacs wrote
Soooo, Yes or No?
YVRJon t1_is1av5c wrote
I love the terms spicy and minty for ocean water!
hippotank t1_is1klqz wrote
Wow “spicy” or “minty” - we humans are a funny bunch
mypcrepairguy t1_is1k9x6 wrote
Wow, that was a very interesting read. Thanks for that!
axolotle_emperor t1_is1o9gg wrote
I've seen the deep pools that look like another surface of water underneath the water in videos. Is that ultra salty water or is it just brine or something like that?
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falco_iii t1_is1rtsf wrote
I recall learning that there is a huge "river" of super cold but pretty fresh water that travels along the bottom of the ocean from Antarctica to the equator. Is that accurate & what is that called?
alligatorislater t1_is2ja13 wrote
There is relatively cold and deep water current called Antarctic bottom water (AABW) that travels up along the western edge of the south Atlantic from Antarctica, but it is very salty, as when seawater freezes into ice it ‘salts out’ increasing the salinity of the remaining seawater. It is also relatively oxygen rich, which isn’t the norm for deep waters. This water mass is one of the densest there is, which is why it creeps along the bottom.
There is also the Antarctic intermediate water (AAIW), which is not very salty, and it is formed from Ekman transport processes around Antarctica (…and it’s formation seems to still be a big point of research)
Crede777 t1_is1k4wo wrote
What are the immediate and longterm projected impacts of climate change on thermohaline circulation and the underlying ecologies based on this process?
jellyfixh t1_is1mdsc wrote
The major concern is the slowing or stopping of the AMOC, the major deep water current that runs through the atlantic. Since one of the only places on earth that can make very cold and salty deep water is off the coast of greenland, and the glacier on greenland have been melting, there is much concern that this freshwater run off will cause the water near greenland to be more bouyant, causing deep water circulation to slow down or halt altogether. The consequences of this are speculative but none of them are good, as the AMOC brings important oxygen to deep water and slowing that down could cause the deep ocean to get progressively more oxygen depleted and acidic.
Accurate_Pie_ t1_is1mcmk wrote
Fascinating! Thank you for this comprehensive answer!!!
kbeaver83 t1_is2m7vd wrote
I'm on the RV Atlantis about to take the dsv Alvin out to the middle of the Gulf where some scientists are going to observe and gather data on brine pools on the bottom of the ocean.
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Decapentaplegia t1_is3e3ug wrote
> There’s actually fun terms in oceanography for this, spicy and minty, meaning water that is either warm and salty or cold and fresh.
Looking it up, I see these terms are used occasionally. But I have never encountered them in any textbook, or heard them used at conferences. Mostly people just refer to the density, at least in my experience.
GammaFork t1_is4i4m6 wrote
They're typically used in thermodynamics when talking about changes along isopycnals, when obviously referring to density is unhelpful. They're not super common but a quick Google of ocean spice in scholar finds you a bunch of articles.
brunswick t1_isairue wrote
Here's a paper from just this year that uses spice. The GSW package included with TEOS-10 includes functions for calculating spiciness. It's definitely a term that gets used. Here's the paper that gives the mathematical definition of spiciness that's used in TEOS-10. It is different from density in certain ways.
Croconeer t1_is1p3jj wrote
Is there a noticeable interaction of warmer water being able to have a higher solubility limit of salts that may make it stratified lower? Or is that change in solubility not significant enough?
Chlorophilia t1_is1tjmx wrote
In most of the ocean, the water is not saturated with respect to salt (even at 0C, the solubility of salt - or specifically NaCl - is over 350g/L, whereas the typical salinity of seawater is 35g/L). Perhaps this has some effect in hypersaline water bodies such as lagoons or the Dead Sea, but I don't think this would have any meaningful effect in most of the ocean. There are some other interesting interactions between temperature and salinity in the ocean though, such as double diffusive convection!
Croconeer t1_is1un1n wrote
Thanks for the reply; so an order of magnitude off from saturation then. That could be interesting for those halocline phenomenons. I have things to read. Also that double diffusive convection phenomenon is hawt.
TroyandAbedAfterDark t1_is1xk96 wrote
Follow up question: does water temperature increase the deeper you go due to pressure increasing? Or does it just get colder due to darkness and lack of thermal energy from the sun? I’m assuming water does heat near volcanic openings in the crust and such.
jar4ever t1_is30yz3 wrote
The surface layer is warmest, followed by a rapid decrease in temperature in the area called the thermocline. After that, the temperature is mostly constant as you get deeper, but will tend to get slightly colder as you go deeper. The effects of lack of solar energy dominate any increase from pressure or thermal vents.
BowwwwBallll t1_is25yn1 wrote
Awesome answer. I have a follow-up question: during coverage of the Ironman World Championships in Kona, HI, this past weekend, the commentators said a couple of times that the swim course was "some of the saltiest water in the world." Is such a statement true, and how is such a thing measured/known/predicted?
Ady42 t1_is2ok2a wrote
Research ships deploy instruments called [CTDs](https://en.m.wikipedia.org/wiki/CTD_(instrument)) that collect seawater. There are sensors on the CTD that measure the salinity of the seawater (along with other things of interest). The collected seawater is also measure to calibrate the sensors on the CTD.
There are also [ARGO floats](https://en.m.wikipedia.org/wiki/Argo_(oceanography)) that move around the ocean taking regular measurements of the seawater for things such as the salinity.
At a glance the seawater around Hawaii looks a bit saltier than in some other places, but not the saltiest there is.
BowwwwBallll t1_is2qbsq wrote
That's really cool! Thanks!
regular_modern_girl t1_is42e64 wrote
They might have meant “saltiest seawater in the world”, but yeah, there are endorrheic lakes or pools that are magnitudes more saline than any part of the ocean.
The average salinity of the ocean is about 3.5% iirc, the southern portion of the Great Salt Lake is about 5%, while the northern portion is as much as 20% (they’ve been separated by a railroad causeway since the 1950s, hence the drastic difference in water chemistry), the Dead Sea is about 30%, Lake Assal in Djibouti is 35%, and Don Juan Pond in Antarctica (the most saline known body of water on Earth, unless you count the concentrated brine pools that sometimes form deep in the ocean) has been measured at over 40% iirc.
CopprRegendt t1_is2sgpe wrote
Very interesting!
you think it's all just water and water is water but if you could see in infrared and also see dissolved minerals as colors, it would look like the painted desert.
and we think some animals like octopi and the things that eat them can see this!
24North t1_is338lx wrote
This is way more technical than my non-scientist self could get but as a diver I’ve seen this in action before. You can actually go through a thermocline underwater where there is a distinct difference in temperature separated like oil and water would be. Your feet can be cold and your top half just fine. You can see it in the water too, it looks blurry for lack of a better description.
You can also get haloclines in some of the springs in FL (others too I’m sure, I just know FL) where you’ll have a saltwater layer and a freshwater layer. It makes for some weird effects sometimes.
SufficientUndo t1_is1nxv0 wrote
Is there a reason they say spicy rather than, IDK - salty?
Chlorophilia t1_is1s8kg wrote
Because, as they explained, 'spicy' water is salty and warm. There is a correlation between salinity and temperature in the ocean, but they can be independently modified. In some situations, talking about spiciness might be useful, whereas in other situations (and more commonly) you'd discuss temperature and salinity independently.
SufficientUndo t1_is1t920 wrote
Awesome - thanks!
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cannondave t1_is1v8zu wrote
I heard water originally came from within, hydrogen and oxygen spewing out from within. If this happens near a deep sea bed, it means the water is not salty nor cold, which means it's less dense than surrounding water, and should flow upwards. Will this create a plume of fresh water slowly smoking upwards to shallower waters?
Chlorophilia t1_is1x7jg wrote
On the timescales over which ocean circulation processes occur (i.e. up to ~1000 years), there are no significant sources of water within the deep ocean. However, what you're describing (plumes of low-density water) does occur at one particular setting, namely deep-sea hydrothermal vents. Extremely hot water (which can be well above 100C because the boiling point of water increases with pressure) enters the ocean at these vents and, because the water is so hot, it has a lower density and therefore rises up in a plume (e.g. see this figure, from acoustic imagery of a hydrothermal vent). The plume continues to rise until the plume water has mixed and cooled sufficiently to reach a neutral density. Note that the water exiting from hydrothermal vents isn't "new" water, it's primarily water that has either been circulating through fissures in the seafloor and heated up due to the high geothermal gradient and through proximity with melt pockets.
Byanl t1_is1zvdi wrote
With countries like Israel being at the forefront of desalination for drinking water, if more countries use desalination will that have any effect on oceanic salinity? Or is it too small to have any impact at all?
semnotimos t1_is253z2 wrote
There can be an environmental hazard when waste salt is dumped resulting in toxic levels of salinity locally but overall increase in ocean salinity is negligible.
On the flipside, desalination might very well pay for itself in the future when paired with operations like the harvesting of lithium, hydrogen and chlorine from ocean water. https://www.intelligentliving.co/desalination-device-harvests-lithium-h2-from-seawater/amp/
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provocateur133 t1_is2ng9t wrote
What is the average composition of ocean salt water? Does it vary depending on which ocean?
DrTwilightZone t1_is2tnhh wrote
This is a quite lovely explanation. Thanks for sharing!
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BlackRobedMage t1_is3m1v3 wrote
> Most deep ocean water gets there in only two ways, forming either near Greenland or Antarctica when water gets sufficiently cold and salty to “sink”.
Hypothetically, if I wanted to pour water into the ocean and be assured it would sink to the bottom of the ocean, what volume of water and how cold / salty would it need to be to get there?
DrSmirnoffe t1_is35b49 wrote
> spicy water
I love that spicy water is actually an oceanographic term. Mainly because it reminds me of "Twials of Mana".
I won't post the video here, since some mod will probably get sand in their craw over it being off-topic, but just search for it on YouTube. If you find "Twials of Mana Five Times In A Row", with a girl holding a bottle of "spicy water", that's the one I'm thinking of.
his_rotundity_ t1_is1rcg3 wrote
Cooled water from the poles sinks as a result of both its salinity and temperature profile. Cooler water is denser than warmer water. Cooler water with high amounts of salt is even more dense. So it sinks and is replaced by less dense and less saline (fresher) water. So yes, the salinity of water increases with depth. See this.
GammaFork t1_is4j6lc wrote
Though oddly the densest, deepest class of global water, Antarctic Bottom Water, is actually fresher than the overlying Circumpolar Deep Water or North Atlantic Deep Water!
CroStormShadow t1_is76unb wrote
What makes that possible?
brunswick t1_isaflbs wrote
The density of seawater is affected by both temperature and salinity. The exact relationship is pretty complicated, but fresher water can be denser than more saline water if it's considerably colder. That's why physical oceanography has a concept of spiciness. Warm and salty water is 'spicy' while cold and fresher water is 'minty.' Because density is affected by both salinity and temperature, minty and spicy water can potentially have exactly the same density.
Here are a couple of figures I pulled from Talley's Descriptive Physical Oceanography textbook. Here's a map showing the temperature and the salinity of the circumpolar deep water around Antarctica. If you compare it to the Antarctic bottom water, you can see that the Antarctic bottom water is a little fresher than the CDW, but it's considerably colder.
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Gorstag t1_is4kzj5 wrote
Intuitively I would think the opposite would be true. For example sweet tea is heated to add more sugar. Your explanation allowed me to logically see why the phenomenon occurs with salt in the ocean. Kudos.
Fun_Wind7710 t1_is55xj6 wrote
Different compounds have different temperatures where they have peak solubility in water. Oxygen is more soluble in cold water, for example.
TrueBeluga t1_is5h47b wrote
That’s because oxygen is a gas. Gases are more soluble in cold water, solids more soluble in hot water.
kawaiisatanu t1_is5cd22 wrote
No, the real answer is that salt (sea salt is mostly just NaCl) has a solubility way higher than the amount of salt in the sea, so of course you can have saltier colder water than less salty warm water.
UtsuhoMori t1_is5dyd4 wrote
iirc it's more about the state of matter of the molecules being dissolved; As in oxygen is more soluble in cold water because it's a gas at room temp and salt is more soluble in hot water because it's a solid at room temp.
Excess heat energy in a liquid allows gas to escape easier, reducing solubility of gas in hot water. On the other hand, excess heat energy is needed in order to free more molecules from a solid like sodium chloride and keep them in solution.
atomfullerene t1_is7rlm6 wrote
Heating things does let you dissolve more into it, but the ocean isn't near the maximum amount of salt that could be dissolved in it.
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Chlorophilia t1_is1r77a wrote
As mentioned by /u/jellyfixh, most of the processes that modify the salinity of water (e.g. evaporation, precipitation, riverine inputs, and sea-ice formation) occur at the surface. As a result, to a reasonable approximation (ignoring the effects of mixing), you can assume the salinity of a water parcel is roughly constant once it leaves the surface of the ocean. In other words, understanding the salinity structure of the deep ocean is completely dependent on the three-dimensional circulation of the ocean interior, because the salinity of a deep water parcel is set by where that water parcel came from.
A good example of this is the Atlantic Meridional Overturning Circulation, or AMOC (which is sometimes misleadingly called the thermohaline circulation). Simply put, intense cooling and salinification in the subpolar North Atlantic results in water becoming fairly cold and very salty, which then sinks to a depth of around 2km (we call this resulting water North Atlantic Deep Water (NADW)). This water then travels south, mixing a little on the way, but mostly being dragged up towards the surface (upwelling) in the Southern Ocean, around Antarctica. There, some of the water gets pushed towards the north by the winds, freshening due to precipitation, but eventually being forced down as it sinks below the warmer, lighter waters to the north, settling at intermediate depths of around 1km (called the Antarctic Intermediate Water (AAIW)). However, some of the water upwelling around Antarctica instead moves south, freshening somewhat, but cooling intensely and forming an extremely dense water mass that sinks to the bottom of the ocean (called Antarctic Bottom Water (AABW)).
Have a look at this diagram, showing a cross-section of salinity in the Atlantic (North Atlantic on the right, South Atlantic on the left). Orange represents saltier water, blues represent fresher water. That big orange blob that goes from the surface to a depth of around 2km and moving southward is the NADW. The blue (fresh) tongue of water moving northwards and settling above the NADW is the AAIW. Finally, the blue(ish) (fresh(ish)) tongue of water sinking to the bottom of the ocean at the far left is AABW.
In the Pacific, by contrast, no deep-water formation occurs (contrary to the Atlantic). As a result, the depth-structure of salinity in the Pacific is more-or-less set by the depth-structure of salinity of deep waters entering the Pacific from other ocean basins so, whilst salinity does vary in the (subsurface) Pacific in depth, the lateral variations are fairly small compared to the Atlantic.
InternationalBunch22 t1_is4a8z6 wrote
I don’t know what I expected but the oceans are a more intricate that I thought. Thank you for your time and energy spent writing that, I seriously appreciate you and your knowledge.
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Kills-to-Die t1_is4ava5 wrote
That's really cool. I never even really thought about it, thanks!
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ProDigit t1_is4d16m wrote
Add to that, that most of the rain water on oceans (being fresh desalinated) is added to the top layers.
While the waters do mix over time with the more salty, deeper down waters, the addition of fresh water nearly daily to the top layers adds to the effect of the 'top fresh, bottom salty' water theory.
TheSwills t1_is20yi5 wrote
Submariners enter the chat…
Fun fact, salinity is one of the factors (other being temperature and pressure) in how sound (I.e sonar) propagates in the ocean so the Navy has done much of the research in this space.
Salinity also plays a factor in depth control for submarines (because it changes the density of the water). There is a big salinity change going between the Mediterranean and the Atlantic Ocean that causes… problems if a submarine isn’t carefu
WiseRevise t1_is2f8yn wrote
There is actually a depth that submarines can hide in because the salinity/temperature trap/reflect sonar. There’s a special name for it that Destin at SmarterEveryDay covered during a deep dive on a US nuclear sub. It’s an amazing series for anyone looking for something to watch.
Another fun fact from that same video is we actually developed rescue devices that would explode at that special depth, and microphones around the world could triangulate where a downed pilot was.
Haphazard-Finesse t1_is2red4 wrote
The SOFAR channel. Another fun fact: Project Mogul was a top secret program to use high-altitude balloons equipped with microphones to listen for soviet nuclear testing, based on the assumption of similar sound channels existing in the upper atmosphere.
The Roswell UFO incident was likely spurred by one of these weird-ass-looking balloons with a bunch of specialized surveillance equipment crashing, and nobody having any idea what it was.
BluudLust t1_is3lkxd wrote
Similar effects happen in air too. There's a phenomenon where car lights can be seen magnified in the sky. Very interesting read.
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doomgiver98 t1_is3ohcw wrote
...Were you unable to finish your sentence because you weren't careful? Hello? Are you there?
neoncp t1_is287je wrote
the smarter everyday series on submarines really emphasized how much specialized knowledge is required
WiseRevise t1_is2flg3 wrote
His new series on the Coast Guard is interesting. Not nearly as interesting to me as the sub series though!
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Duke_Cedar t1_is26val wrote
Retired FT (last boat was 21) and I was going to chime in but you did a great job kinda explaining SVP.
GoddessOfRoadAndSky t1_is3rnil wrote
That is fascinating. It makes me wonder about marine animals that use echolocation. They must have some way to compensate for changes in salinity/temperature/pressure? Or does the scale they use (compared to a submarine using sonar) make it negligible?
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vulcandeathwatch t1_is3skbj wrote
If this interests you, you can find places to download (I couldn’t find without trial, fee, etc.) the RP-33. Fleet oceanographic acoustic reference manual. It’s unclassified and will tell you all the things about salinity in water columns.
LearnedGuy t1_is3z6mp wrote
The costal areas along Vietnam has much lower salinity due to the Monsoon rains. The corals don't like that so they disappesf. No corals, no fish. The coasts are mostly barren sand. Harvard is looking in to low-salinity corals, but it's still early in that research. Tuburtity is also a concern because the silica cuts the fishes gills.
Gab83IMO t1_is3rwa2 wrote
As far as I know, the ocean has separated layers collectively called a Halocline (halo = salt, 'cline' as in slope/grade). Water can hold more if its cold and therefor heavy, thus sinks (more pressure). Warm water rises upward and can't hold onto things, thus less dense on the surface. The "cline" here is the separated vertical levels (like layers) that differ in salinity. So generally, cold, dense water holds more salt at the bottom and warm, non-dense, less-salty water at the top.
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No_Music9049 t1_is795w1 wrote
It constantly changes in minute ways from rainfall runoff ad evaporation. I actually believe that underwater "salinity" currents may be produced from the sources mentioned above. Think about it...cause and effect. Very simple. I'm positive that what we think we know about the physics of aquatic life is just the tip of the iceberg. Changes in salinity have an effect on tides just as much as tides have an effect on salinity. Push and pull. That being said I also think evaporation itself has an effect on tides. Water one one side of the earth is being vaporized while on the other side it is being condensated. Must make some push and pull, however insubstantial. I wonder of anybody has just done mathematics on this....
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