Saturday, August 20, 2016

Where basalt meets seawater


Imagine a mid-ocean ridge. Between two diverging plates, a volume of molten basalt is constantly being oozed out of the mantle. The molten basalt itself is really hot, over 1000°C. In contact with cool seawater it quenches instantaneously into volcanic glass. However, in areas (open cracks, for example) where permeable freshly erupted basalt is available, seawater reacts with it at 200-500°C. After the reaction basalts acquire new look, or we say, it becomes altered, - it has new minerals in it. From igneous and water-free rock, basalt converts to water-bearing hydrothermal mineral assemblages. These areas of hydrothermal activity are partly responsible for modern seawater chemical (and isotopic) composition and its acidity. Reacting basalt supplies Mg, Si, Ca and other elements into the seawater. In turn, the reaction with basalt sucks out other elements out of seawater, such as Na and S. I will show that at some point, reacted seawater can become pretty acidic with pH of 3.8. These underwater hot springs frequently form black smokers where unusual forms of life can exist because of the supply of heat. 
Here, I wanted to show the result of a modeled experiment. I virtually took basalt of common composition (MORB) and incrementally added it to fixed amount of seawater. Starting with very small amounts increasing step by step, I could model different situations where various amount of rock is reacting with seawater. In my imagination it simulates variable amount of space where seawater could touch basalt and react with it. From very wide open cracks to porous basalt. In terms of water-to-rock ratio, the numbers will go from very high (open crack - water dominated system) to a very low (rock-dominated situation, water only in pores). The purpose of my modeling was to predict what minerals form during the reaction between basalt and seawater. Knowing thermodynamic conditions of mineral formation, the program could tell me what minerals will be found stable. 
The graph shows concentrations of products of reaction between seawater and basalt at 300°C. The right side of the graph can be interpreted as pure seawater (very little rock added), thus the water-to-rock ratio is really high. Without any involvement of basalt, seawater is oversaturated with anhydrite and brucite. Depending on the proportion of rock in the mixture, different minerals will precipitate. Moving to the left along the horizontal axis, more rock is reacting with seawater. At very high water-rock ratios, basalt turns into a mixture mostly consisting of anhydrite, serpentine, hematite, talc and chlorite. At low water-rock ratios (basalt-dominated system), the products of reacting are albite, amphibole (mostly tremolite), zeolites, pyrite, quartz and epidote. These minerals compose a large portion of seafloor, mostly it's deeper layers because at some point they underwent high temperature hydrothermal alteration at mid-ocean ridges.

In turn, the left over seawater has modified concentrations of ion dissolved in it.
 


Again, the right side of the graph can be interpreted as pure seawater. After the reaction with basalt, seawater becomes significantly enriched with Ca, Al, reduced S and silica (SiO2 aqueous or H4SiO4). 

Here's how pH works for the seawater that is being modified along the reaction.
 
Notice how at the water-to-rock ratio, pH drops to about 3.8. The seawater becomes acidic because of formation of hydrous minerals. 
The reaction between seawater and basalt is calculated here from theoretical standpoint (thermodynamics). The assemblages found in the real-world altered basalt can indicate how much seawater reacted with the basalt and at what temperatures. The observations I found in this experiment can be easily supported by looking at a thin-section of altered submarine basalt. Here's one of my own samples of altered mafic rock, that apparently was erupted in submarine environment. The original plagioclase must've been rich in Ca, but now it is albite (Na-rich feldspar; white). Original pyroxene is now replaced by amphibole, specifically tremolite (light grey). This is supported by EDS analysis of this rock.

 

As seen in the first diagram, albite and amphibole form at low water-to-rock ratios. It's important to understand that albite formed because seawater is loaded with Na and amphibole in turn forms becuase there's a lot of Mg dissolved in seawater as well. 
 
This experimental model run is based on using program CHIM-XPT developed by Mark Reed from University of Oregon and associated research group.


2 comments:

  1. Very good and thorough information
    Frank
    Frank's Beautiful Rocks and Minerals

    ReplyDelete
  2. Very good and thorough information
    Frank
    Frank's Beautiful Rocks and Minerals

    ReplyDelete