Metamorphism: Pressure-Temperature-time paths

Schematic P-T-t paths for Barrovian metamorphism
Schematic P-T-t paths for Barrovian metamorphism
Pressure-Temperature-time paths

This post is in the middle of a series on metamorphism.

Concepts such as metamorphic facies or grade all allow us to link a metamorphic rock to a particular set of conditions, under which it was metamorphosed. This is a simplification, of course. Hold a piece of schist in your hand: we know that it was once sediment at the earth’s surface and we also know it got back to the earth’s surface again, to catch a geologist’s roving eye. It’s been on a journey. Calling it a greenschist facies rock tells us about a single point on its journey, but not the whole picture. Being romantic souls, geologists often refer to this journey as the rock’s Pressure-Temperature-time path, or P-T-t path. Pressure and temperature are the things we can measure, because we understand how they affect metamorphic reactions.

So how can we discover more about the journey, what is a typical journey and why do concepts such as grade still make sense?

How to create a P-T-t path

Metamorphic rocks are complicated. Take this beauty from Connemara, Ireland:

Thin section of Connemara schist

Thin section of Connemara schist, field of view is 14mm across

The big gray lumps are garnet, the orange stuff is biotite. The big area a third of the way from the right is a sheaf of muscovite, containing yellow staurolite. These minerals tell us its an amphibolite grade rock. Some investigations of mineral chemistry could allow us to quantify that a bit more and put a big cross onto a plot of Pressure and Temperature, representing peak conditions.

There is more information to had from this rock, though. A transect through the garnet would show that the Mn, Fe, Mg and Ca values vary systematically from the core of the garnet to the edge. We know that the garnet would have started small and grown bigger, so the values from the core are earlier than the ones at the rim. The garnet therefore contains a trace of the journey the rock has been on. Often we can infer that the conditions were of lower pressure and temperature when the garnet started growing. So, we can draw an arrow up and along towards our cross marking peak conditions. This arrow we call the prograde path, the portion of the journey before the most extreme conditions.

Look at the lowest big garnet, see the greenish patch just above it? (OK, maybe not, but it is very clear down the microscope). The green is a patch of chlorite, which is associated more with greenschist conditions. Is this another part of the prograde path? No, as the chlorite can be seen as patches within biotite, showing that it grew later. The chlorite is part of the retrograde path, another line we can draw going from the peak conditions back to the surface. We have drawn a P-T-t path.

This is a simple example but I hope it illustrates the general point. The best sorts of rocks for determining P-T-t paths have more dramatic features in them, such as pseudomorphs, where minerals have gone, but their shape remains, or mineral coronas, where a whole new retrograde mineral assemblage was created around the edges of the peak minerals. Also, different samples within a package of rock may preserve different peak assemblages. Put these together and a thorough may allow us to build up a more detailed view of the P-T-t path shared by a package of rocks.

Some types of P-T-t path

Geologists have been creating quantitative P-T-t paths for some time now. What do they look like?

In the roots of ancient (or even active) mountains, Barrovian metamorphism is characteristic.

Schematic P-T-t paths for Barrovian metamorphism
Schematic P-T-t paths for Barrovian metamorphism

I’ve taken a standard diagram of metamorphic facies and drawn on roughly some typical P-T-t paths. The upper red line is the prograde path, the lower the retrograde. Different rocks reach different peak temperatures, varying from lower grade greenschist rocks up to granulite facies gneisses. This is pattern seen in Scotland and if you read my earlier post, you might think of the lowest temperature loop as the Laphroaig one, the highest as the Macallan.

Rather nicely, if you use mathematical models to predict what happens if you form mountain belts by thrusting rocks sheets over and over, you predict very similar P-T-t paths. Initially pressure is increased faster than temperature, eventually, perhaps because thrusting ceases, the line flattens off as temperature increases (thrusting buries cooler rocks). Eventually a maximum temperature is reached, which is likely where the peak assemblage is formed, as many metamorphic reactions are most sensitive to temperature increases.

Different rocks are buried to different depths, and reach higher or lower grade but they all follow a similar type of P-T-t path. So via modelling based on geophysics, we can now link observations in the field to a tectonic mechanism and explain multiple pieces of evidence. This is proper science.

What of subduction zones, where rocks are thrust down to great depth?

P-T-t paths characteristic of subduction
P-T-t paths characteristic of subduction

Compared to rocks in mountain zones, subduction zone rocks are buried and returned to the surface before they have a chance to heat up. One remarkable aspect is how deep some of these rocks go. In the 1990s, the recognition of the quartz pseudomorph coesite in continental eclogitic rocks from China and Norway demonstrated that they had been buried to extraordinary depths (>70km). This is literally off the scale of the diagram above (* see below). In Norway these rocks are found just below large extensional faults and shear-zones that have sheared sediments on their top surface. The contact is not a sedimentary one, the rocks were exhumed all the way to the surface by tectonic processes. This is a reminder that the retrograde path is not necessarily just a record of slow erosional unroofing, but can have drama and excitement too.

Why is grade still a useful concept?

All metamorphic rocks are unstable; leave them in the rain long enough and they will turn into sediments. Their journey is never ending, but always controlled by their physical conditions, and often by the presence of water.

My example schist above shows a little evidence for the retrograde path, but is dominated by the minerals that grew when it was at its hottest. The concept of metastability is key here. Diamonds don’t grow at the surface and so ‘aren’t stable’. The carbon atoms would ‘like’ to be in the form of graphite, (or to put it another way, this would minimise their Gibb’s free energy). But they are tightly packed into a crystalline lattice and, even on someone’s finger, quite cold. So, at surface conditions, they are metastable.

The peak assemblage minerals in my example schist are like this. They were metastable all the way down the retrograde path. It takes energy to initiate reactions and in a cooling rock, this tends not to happen.

Also my sample schist was likely quite dry as it cooled. Water is very important in metamorphic reactions as a participant in many important metamorphic reactions (those involving devolatilisation). It also is a solvent and can be a catalyst for metamorphic reactions. Atoms can zip around in the fluid phase and so are more likely to find places they prefer, compared to having to diffuse through mineral lattices.

Eclogites are often found as pods within lower grade (blue/greenschist) rocks. Compared with Barrovian rocks, retrogression is more important. This may be because they still contain a lot of water, also the retrograde path passes through more pressure-sensitive reactions. In comparison, a high-grade Barrovian rock has little water left and many of the reactions it is passing through require the addition of water. The retrograde path is therefore much less obvious in the rock.

So now you know. P-T-t does not mean a cup of Darjeeling made from Irish bog water** but instead a reminder that the lump of schist in your hand has been places you’ll never go.

Note * Depth relates to pressure depending on the density of the rock, as the weight of the rock above is providing the pressure. It varies, but 0.25 kbar per km is a good rule of thumb so top of the diagram (20kbar) is about 80km depth. Note that as well as showing the Pressure-temperature diagram in different ways (sometimes with pressure increasing downwards), the units can also vary. The diagram above has kbar, which is kilobars, which is 1000 bars. A bar is 100,000 pascals and is about the pressure of the air you’re breathing. A pascal is a Newton per square meter and is the pukka SI unit for pressure. Therefore we should use pascals (Pa), but since the pressures we are dealing with are so high, we need a billion of them, written GPa for giga-Pascal. A kbar is 100,000,000 Pascals and so 0.1 of a GPa. So a more properly labelled version of the graph above would have 2GPa at the top. Aren’t you glad I left this bit to the end so you could ignore it?

Note ** “peaty tea”. Sorry, I’ll stop now.

23 comments

  1. Where did you get the 2.5km per kbar rule of thumb? I do have P/T diagrams for one of my projects which shows pressure on the left and depth on the right, but I got the numbers from a diagram in a colleague’s paper and never actually made the time to ask upon what the depths were based, but now I think that I should have.

  2. Aaaaaaaagh. You’re right, I meant 0.25 kbar per kilometre. Let me a be warning against late-night blogging. I’ll correct the text.

    Thanks for paying attention.

    BTW my rule of thumb assumes a constant density and is very rough. Your colleague’s graph is bound to be based on a more sophisticated analysis.

  3. lol! I didn’t notice it was an error, I certainly didn’t compare that number to the graph I’d mentioned, I literally did just want to know where you found your rule of thumb, as I have no idea where to look for such.

  4. My rule of thumb is based on the physics.
    PRESSURE = DENSITY x DEPTH x ACCELERATION OF GRAVITY
    As you can see, this equation allows you to related pressure with depth, given values for density and acceleration of gravity (G). I took an average value for the density of the crust and the value of G at the surface (G) to get my rule of thumb.

    This assumes these values are themselves constant with depth, which they are not. Density varies a lot and tends to increase with depth. The value of G also varies with depth and this in turn varies with the variation in density. A sensible scale relating P to depth should take all this into account.
    Hope that helps.

  5. The guidelines you contributed here are rather precious. It was such a pleasurable surprise to get that looking forward to me after i woke up this very day. They are usually to the point plus easy to interpret. Thank you so much for the innovative ideas you’ve got shared above.

  6. Hello, what conditions would have to prevail for the occurrence of isothermal decompression in rocks?

    1. Hi Joe,
      The simplest and most excellent case is where kilometres of rock are suddenly removed. This causes isothermal decompression in the rocks below. It doesn’t happen often, but it did in the core of the Vredefort Dome in South Africa. I modestly propose my own post as an introduction: http://all-geo.org/erratics/2011/03/impacts-and-geology-deep-peace/

      Alternatively, the closest case is where you have exhumation of eclogites. They seem to be brought back to the surface relatively quickly. The temperature will change on the way, but the decompression is the dominant feature. This is basically the retrograde part of the subduction zone diagram above, but if the rocks are buried very deep the gradient of the P-T-t path will be very steep – the closest you get to isothermal decompression outside of the Vredefort Dome.
      The tectonic mechanisms of exhuming eclogites are fascinating. *makes mental note*

  7. Thanks for this! I have an exam and this year has been tight so literally have 5 days to study the whole 2nd yr metamorphic module!

    You have a P-T-t diagram for Barrovian metamorphism but not one for Buchan metamorphishm? I know that the pressure is overall less in Buchan but what kind of P-T-t path should I expect? Would it be similar just lower pressure passing all the same facies?

    1. Buchan paths would be pretty much as you say: lower pressure but still a loop into higher temperatures and back. I’m not aware of a consensus as to the cause of Buchan metamorphism, so it’s not as clear as for Barrovian ones.
      Best of luck!

      1. Ahh thanks very much 🙂

        I do have another question, if you don’t mind:

        Do P-T-t paths vary for large-sclae geological events such as intrusions, formation of basins, overthrusting etc. Or would they follow the same as a orogenic fold mountain belt? I ask this because I understand that processes vary quite significantly in these regions especially subduction zones. If they do what kind of path be typical of such events

  8. Like Chetan, I am faced with an assignment and you’ve answered some of my questions in one article. I was wondering if I could reproduce your Barrovian diagram for my university assignment, with appropriate attribution of course. I am studying with the Open University in the UK.
    Now I’ve found your website I have become a fan!
    all the best.

    1. Hi Paula,

      I don’t mind you reproducing my diagram – with attribution. Anything for a fan!
      All the best.

  9. I think I will prefer pressure increasing downward, so that temperature is up and not down

  10. Hi….
    is it possible that at particular point during exhumation of an eclogite rock encounters comparatively high temperature(e.g 815C) as compared to peak metamorphic conditions during eclogite facies metamorphism(e.g 750C) ??

    if yes ! then why?

  11. I was incredibly glad to identify this site.I required to take pleasure in this excellent read through! ! I undoubtedly getting enjoyment in every little it and this i perhaps you have saved to check out website you distribute

    1. Hi Shahid,

      It’s a little like making a piece of ceramic – a pot or a plate. Clay minerals mixed with water are heated and turn into other minerals that make up the ceramic. All the water is removed and the pot quickly cooled, leaving the ceramic stable at low temperatures. If you left the piece of pot outside it would (eventually, over thousands of years) turn back into clay minerals.
      For metamorphic rocks, the minerals that form under peak metamorphic conditions are often formed by reactions that release water, which escapes. As it cools, the rock is drier and so less likely to change its minerals again. It’s interesting that eclogitic rocks, which aren’t heated so much are much more likely to react into lower pressure minerals as they return to the surface. Often eclogitic minerals recording peak conditions are relatively rare within the rock – most shows lower pressure minerals that grew later than the peak.
      Simon

  12. Hello
    Are the agents of metamorphism just limited to temperature,pressure and chemically active fluid or are there more agents

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