The story of a pyroclast

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Pyroclastic deposits result from the sedimentation of pyroclasts through the atmosphere plume during an explosive eruption. Pyroclast - from Greek pyros (fire) and clastic (broken) represent fragmentary material ejected during a volcanic eruption.

The objective of this module explore the journey of a pyroclast from the magma chamber to its sedimentation on the ground and, through this, review the range of processes that generate tephra deposits. In another module, we will then learn what we can learn from these deposits.

Objectives

The objective of this lessons are to understand:

How tephra is generated, transported and deposited on the ground
The nature of the physical processes taking place along this journey
How tephra fall deposits are formed

General concepts

Pyroclast and tephra

Pyroclast and tephra are more or less synonyms, but tephra is more frequently used in the scientific literature.

Why are tephra deposits important?

Tephra deposits are a direct reflection of the eruptive conditions occurring in the plume (Figure 1). By studying, mapping and characterizing these deposits, we can reconstruct the dynamics of eruption and estimate important eruption source parameters (ESP). Following the general idea that "the past is the key to the future", this ability is critical to reconstruct the eruptive history of volcanic systems from their stratigraphic record and, in turn, constrain their potential future activity.

strati — Figure 1: Tephra deposits (right) are a direct consequence of the plume dynamics. On the left, the plume associated with the 2015 eruption of Calbuco, Chile (Picture: AFP). On the right, a tephra deposit associated with a Plinian eruption of Cotopaxi volcano, Ecuador (Picture: S. Biass).

Below are some examples of tephra deposits.

La PalmaKīlaueaVulcanoChangbaishanTaupō

Figure 3: Proximal outcrop of the Golden Pumice deposit of Kīlauea volcano in Hawaii. This deposit is associated with episodes of intense fountaining (Picture: S. Biass).

vulcano — Figure 4: Deposit associated with the 1888-1890 eruption of La Fossa volcano, Italy. This section represents years of unsustained, pulsatory Vulcanian activity (Picture: S. Biass).

cbs — Figure 5: Deposit associated with the AD 946–947 Plinian Millenium eruption of Changbaishan volcano (China/North Korea). The airborne deposit lies on a lahar deposit (Picture: S. Jenkins).

taupo — Figure 6: Complex stratigraphy associated with the Oranui eruption of Taupō volcano, New Zealand. This is the largest eruption of the past 70,000 years, with a VEI of 8 (Picture: S. Biass).

What is tephra?

Pyroclast and tephra more or less describe the same thing. Tephra was first defined by Sigurður Þórarinsson¹ following the 1947 eruption of Hekla volcano in Iceland as:

Definition

The fragmental material produced by a volcanic eruption regardless of composition, fragment size, or emplacement mechanism.

Tephra particles are typically described in terms of their componentry and size.

Componentry

Tephra fragments - or pyroclasts - can be classified in two main families depending on their origins:

Juvenile clasts, which consider all clasts originating from fresh magma (e.g., pumice, ash)
Lithic clasts, which represent dense clasts generally sourcing in country rocks.

Grain size

Individual tephra particles are also subdivided in term of their size:

	bombs / blocks	lapilli	coarse ash	fine ash
Diameter	> 64 mm	(64 mm–2 mm)	( >2 mm–63μm)	<63μm
Residence time	≈ sec	≈ min	≈ hours to few days	several days
Travel distance	proximal <10km	medial <50 km	distal <100 km	very distal <1000 km

Following a sedimentology approach, particles size is generally described in \(\Phi\) units:

\[ \Phi = log2(d [mm]) \]

AshLapilliBomb

ash — Ash from the 2021 Cumbre Vieja eruption covering a sport field (Picture: S. Biass).

Golden Pumice deposit from Kīlauea, grading from coarse ash (bottom) to coarse lapilli (top). Notice Pelee's hair at the top (Picture: S. Biass).

Grain size distribution

Rather than the size of individual particles, what interests us most is the size distribution within an outcrop. Grain size distributions summarise the percentage of weight represented by the particles in each \(\Phi\) bin. We mostly describe two parameters²³⁴:

Median or \(Md \Phi\): The 50th percentile (\(\Phi 50\)) of the distribution
- → Small (even negative) \(Md \Phi\) values describe coarse deposits
- → Large \(Md \Phi\) values describe fine deposits
Sorting or \(\sigma \Phi\): The graphical standard deviation (\((\Phi 84 - \Phi 16)/2\))
- → Small \(\sigma \Phi\) values describe well-sorted deposits
- → Large \(\sigma \Phi\) values describe poorly-sorted deposits

sorting — Example of variably-sorted deposits.

Which is the finest GSD?

med

Solution

→ The left distribution has a \(Md \Phi\) of -1 (i.e., 2 mm) and is therefore coarser than the right distribution (\(Md \Phi\) of 1, or 0.5 mm).

Which is the better-sorted GSD?

med

Solution

→ The left distribution has a \(\sigma \Phi\) of 1 and is therefore well-sorted. The right distribution (\(\sigma \Phi\) of 1) is poorly-sorted. Note that both distributions have the same \(Md \Phi\).

How are tephra deposits emplaced?

Look at the following two pictures and formulate hypotheses about emplacement dynamics:

Mayon 1982Sarychev 2009

Hint

Is emplacement horizontal or vertical?

Solution (?)

Well, maybe a bit of both...

We can consider two main mechanisms of emplacement:

If the plume is buoyant, it will rise and become wind-advected, carrying tephra that will then sediment vertically, producing fall deposits.
If, for any reason, the plume is not (or not anymore) buoyant (→ bulk density exceeds that of the ambient atmosphere), pyroclastic density currents (or PDC) will spread laterally, producing flow deposits. PDC are complex mixtures of hot gases and particles that can be generated in several ways giving rise to several facies, the end-members of which being surges and flows.

Fall and flowsTypes of PDC

carey

Schematic representation of fall (left) and flow (right) emplacement mechanisms (Source: Carey and Bursik 2015⁵). In the left case, the plume is sufficiently buoyant to extend upwards. In the right case, this buoyant state is not initially reached, and a lateral momentum develops to produce directed flows. Note that in some cases, PDC can re-entrain air and become buoyant after some runoff (bottom right), giving rise to co-PDC plumes.

dufek

PDC can be generated from a wide range of eruptions varying many scales, from small events (e.g., dome collapse) to large caldera-forming eruptions, which can produce welded deposits (i.e.; ignimbrites) (Source: Dufek et al. 2015⁶).

Lahars

We are starting to make a distinction between vertical (→ fall) and lateral (→ flow) emplacement mechanisms. There is however another flow emplacement mechanism: Lahar

Block-and-ash flow

Small volume pyroclastic density current deposit composed of mostly dense to moderately vesicular juvenile blocks in medium to coarse ash matrix. Mostly generated during collapse of lava domes.

References

Thorarinsson, S., 1954. The eruption of Hekla, 1947-48, 3, The tephra-fall from Hekla, March 29th, 1947. Visindafélag ĺslendinga 1:3. ↩
Inman, D.L., 1952. Measures for describing the size distribution of sediments. Journal of Sedimentary Research 22, 125–145. ↩
Walker, G., 1971. Grain-Size Characteristics of Pyroclastic Deposits. The Journal of Geology 79, 696–714. ↩
White, J.D.L., Houghton, B.F., 2006. Primary volcaniclastic rocks. Geology 34, 677–680. https://doi.org/10.1130/G22346.1 ↩
Carey, S., Bursik, M., 2015. Volcanic Plumes, in: Sigurdsson, H., Houghton, B.F., McNutt, S., Rymer, H., Stix, J. (Eds.), The Encyclopedia of Volcanoes. Academic Press, pp. 571–585. https://doi.org/10.1016/B978-0-12-385938-9.00032-8 ↩
Dufek, J., Esposti Ongaro, T., Roche, O., 2015. Pyroclastic Density Currents. in: Sigurdsson, H., Houghton, B.F., McNutt, S., Rymer, H., Stix, J. (Eds.), The Encyclopedia of Volcanoes. Academic Press, pp. 617–629. https://doi.org/10.1016/B978-0-12-385938-9.00035-3 ↩