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Non-Magmatic, Volcanic Ash Fragments and Condensates From the Passively Degassing Plume of Popocatepetl
Volcano, Mexico - Indicators of Active Contact Metamorphism and Related Degassing ?
Obenholzner, J.H. (+), Schroettner, H. (*), Golob, P. (*), Delgado, H. (**)
(+) Naturhistorisches Museum/Mineralogie, Postfach 417, A-1014 Vienna, Austria ([email protected])
(*) ZFE, TU-Graz, Steyrerg. 17, A-8010 Austria ([email protected])
(**) Instituto de Geofisica, UNAM, Coyoacan 04510, Mexico D.F., Mexico ([email protected])
Abstract: Magma-wall rock interaction can contribute gases to the magmatic system as well as absorb volatiles to the
country rock. These processes are happening at depth being far away from direct observation. Besides isotopic
composition of gases, if it is possible to sample gases, the micro-analytical investigation of xenoliths is a potential
instrument to study the mineralogical products of related chemical reactions. Plume-derived aerosols can be another
source to obtain information about these processes. At Popocatepetl volcano FESEM/EDS could analyse contact
metamorphosed particles as part of the volcanic ash and aerosol particles from the passively degassing plume.
Wollastonite, hercynite and glass of contact metamorphism-related origin is present in the ash. Condensates from the
passively degassing plume are rich in phosphorus, indicating a possible non-magmatic source for this element.
Keywords: SEM, FESEM; EDS, contact metamorphosed particles, volcanic ash, wollastonite, ferrobustamite,
hercynite, buchites, volcanic aerosol, gas, recent activity of Popocatepetl volcano, Mexico; carbonate platforms,
evaporites.
Micro- and nanometer-sized particles of volcanic origin are transporting various chemical elements into
different layers of the atmosphere, according to the energy of an eruption. These particles can act as a nucleus for
further condensation processes or can trigger heterogeneous chemical reactions in the atmosphere. The abundance of
chlorine in the studied particles, especially in crystallites on spherical particles, can be an underevaluated contribution
to volcanogenic ozone destruction and climate change. A review on observed and possible interdependence of
volcanism and climate change is summarized by Robock (2000).
This study presents new data of plume-derived aerosols, a chemically very distinct environment. The
analytical possibilities of state-of-the-art SEM techniques could provide a unique opportunity to cooperate between the
analyst and the modeler. Results could also be fertile for better modeling of stratospheric chemistry.
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The size of volcanic fragments, associated wall rock fragments and volcanic aerosols varies from meter-sized
blocks to smaller 1/16 mm for fine volcanic ash (1/16 mm equals 62.5 µm). Volcanic aerosol particles (fluids and
solids) are micro- to nanometer sized. Aerosol sciences classify solid particles from fume (ca. 0.001-1µm), clay
(ca.0.01-2µm), silt (2-20µm), fine sand (20-200µm) to dust (1-10000 µm). Size ranges are according to Hinds (1982).
All particles smaller than several millimeters are candidates for scanning electron microscope (SEM) analysis.
Recent developments in SEM techniques, like the very high resolution field emission gun SEM (FESEM) have
improved morphological, mineralogical and textural examinations. Modern SEM systems are equipped with an energy
dispersive X-ray detector (EDS) for chemical analysis.
A variety of contact metamorphism (CM) and related metasomatic minerals indicate the interaction of magma
with carbonate bearing rocks or other sediments. Contact metamorphic events might occur in the region of a magma
chamber, within magma storage zones at higher levels or as wall rock-magma interaction during magma ascent. These
processes can contribute CO2 (even SO2, F, Cl and other volatiles) to the original gas content of the magmatic system.
Fluffy and spherical aerosols are interpreted to be the product of complex condensation processes, leading to
the formation of fluffy, maybe semi-solid or spherical, solid particles. The latter ones are sometimes coated by
crystallites of an S-bearing Mg-chloride. The high contents of Mg are unusual as the average row of abundant cations
in a volcanic gas from a calc-alkaline magma is Na>K>Al>Fe>Ca>Zn>Mg. Usually Mg is 10-20 times lower than Na
or K. Spherical particles occur as single spheres or as coagulated spheres.
The size of studied spherical particles varies about 1 µm in diameter, coagulated spheres can show diameters
of up to 10 µm, fluffy particles vary from 1.5 to 10 µm. Smaller particles are abundant but have not been analysed yet,
according to limited FESEM time.
According to the limits of EDS (interaction volume depending on acceleration voltage and the density of the
sample), the C- and F-content of the teflon filter and the C-coating) we could characterize the chemical composition of
individual aerosols. Elements detected in fluffy aerosols are Si, Al, Ca, Na, Mg, K, Fe, Ti, P, Cu, Zn, Bi, Pb, Mo, Sn,
S, Cl, O. Most of the spherical particles do not show internal mixing (particle inside a particle) as the surfaces appear
smooth and none of the studied particles showed breakage. Only one particle contains Ti-, Pb- and Cr-rich crystallites
inside the sphere. Many of the coagulated or aggregated particles are internally mixed according to different
chemical/mineralogical components.
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Elements detected in spherical particles are Si, Al, Ca, Na, K, Mg, Fe, Ti, P, Mn, Cu, Zn, S, V, Ni, O, (Pb, Cr).
Individual spheres show also individual chemical composition. The variety of chemical composition indicate different
micro-environments in the plume and/or at the zone of mixing with the surrounding atmosphere.
Part 1: Indicators of contact metamorphism asssociated with the eruptions at Popocatepetl volcano.
Stratigraphy:
According to Fries (1965a+b) the basement of Popocatepetl volcano comprises Cretaceous carbonates (ca. 3
km) and Tertiary sediments with intercalated evaporites (ca. 500 m). The stratigraphy of the younger history of
Popocatepetl volcano is described in Siebe et al. (1996). In relation to the archeological time scale for central Mexico
the major Holocene and younger Pleistocene volcanic events at Popocatepetl are:
Present Eruption (1994-?) [CM]
Upper Ceramic Plinian Eruptive Sequence (675-1095 AD)
Intermediate Ceramic Eruptive Sequence (125-255 AD)
Nealtican andesite flow (ca. 2300 BP) [CM]
Lower Ceramic Plinian Eruptive Sequence (215-800 BC)
Upper Pre-Ceramic Plinian Eruptive Sequence (2830-3195 BC)
Plinian eruption (ca. 14.000 BP) [CM]
All age data, except for present eruptions, are bracketed by 14C analysis. [CM] refers to contact metamorphosed
xenoliths or particles observed in lava flows, pyroclastic deposits or recent volcanic ash.
Contact metamorphism indicated in past eruptions:
Past eruptions of Popocatepetl (plinian eruption, ca. 14.000 years B.P.) contain blocks of Ca-silicate rocks
with diopside, grossularite as the predominant mineral, or dolomite containing clinohumite ((Mg, Fe++) 9(SiO4)4(OH,
F)2). As the availability of F in most sediments is rather low, clinohumite probably indicates the migration of F from the
magma into the wall rock. Major explosive eruptions caused the fragmentation of the host or country rock and the
sedimentation of polymict fall and flow deposits in proximal facies .
Mm-sized inclusions in pumice of the Tocuila lahar (plinian eruption of ca. 14.000 BP, redeposited 11.000-
12.000 years B.P.) contain grossularite with droplet-shaped haüyne (Na, Ca)4-8[Al6Si6 O24](SO4,S)1-2, diopside, K-
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feldspar, quartz and sylvite. The inclusions document a homogeneous distribution of CM-altered wall rock fragments
within the vesiculating magma.
Only one sample (P 97-02) from the “ocre surge” beneath the “pink pumice” (Upper Ceramic Plinian Eruptive
Sequence, ca. 800 A.D.) contains abundant euhedral to anhedral anhydrite. Anhydrite could be formed by
hydrothermal alteration of limestone/dolomite or hydrothermal deposition inside the crater. However, a magmatic
origin of the anhydrite is possible but not proven yet.
Contact metamorphism indicated in on-going eruptions:
Ash from the eruptions of winter 1995 (01-02-1995), spring 1995 (03-20-1995 and winter 1996 (11-28-1996)
accidentially contains a variety of contact-metamorphosed rock fragments. The 11-28-1996 ash is characterized by
dome fragments and contains pseudo-vesiculated or mossy shaped aggregates of a Ca-silicate whose composition is
close to CaSiO3. The Ca-silicate is probably wollastonite. High-temperature wollastonite (pseudowollastonite: -
CaSiO3) is known in nature only in pyrometamorphosed rocks. There are two low-temperature modifications of
wollastonite (-CaSiO3 ,wo-Tc and wo-2M). A wollastonite-2M is described from highly metamorphosed ejecta of
volcanoes like Monte Somma, Vesuvius. Modern crystallographic studies could demonstrate that Fe-rich wollastonite
is identical with ferrobustamite. EDS data of analysed wollastonites document traces of manganese, which is present in
minor amounts in ferrobustamite. Only wo-15 has a MnO content (1.21 %) similar to typical ferrobustamite (see table
1.1).
Most of the observed Ca-silicates are highly herterogeneous at very small scale. Electrom microprobe analysis
would barely produce better results than EDS. For these reasons we try to model the P-T-t conditions of Ca-silicate
formation following the well studied reaction quartz + calcite <=> wollastonite and carbon dioxide. Vesicles might be
indicative for fast mineral reactions and CO2-release. High pressure experiments (1GPa) performed at the
GeoForschungsZentrum Potsdam (GDR) document CO2-filled porespace around wollastonite rims grown on quartz
(Lauterjung et al., 2000).The wollastonite particles are unusually rich in Fe; the BSE images do not show the typical
fibrous features known from light microscopy. There is no volcanic glass associated with the wollastonite particles, it
therefore might have formed without direct interaction with the melt. One microclast appears like a vesiculated glassy
fragment, but mineralogically it is SiO2, Ca-feldspar and Ca-silicate. Wollastonite aggregates contain randomly
distributed pyrite (FeS) and rare molybdenite (MoS2) occurs.
Textural and compositional differences between wollastonite types
Micro-clasts are texturally very different. Type 1 appears like an aureole-derived wollastonite (fig. 1). Veinlets
(width ca. 20µm) of massive, chemically homogeneous, non-vesiculated wollastonite are intergrown with K-feldspar
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which has inclusions of quartz. This assemblage indicates sanidinite facies of contact metamorphism. Sanidinite facies
is defined by low pressure and increased temperature. Water escapes at these temperatures and is not available for
facilitating reactions or crystallizations. The mineralogical consequences of this combination of conditions are:
“1. Chemical and thermal equilibrium are rarely attained. The number of associated minerals therefore is likely to
exceed that demand by the mineralogical phase rule.
2. High-temperature minerals appear in the mineral assemblages of the sanidinite facies.
3. Sanidine, often with a high content of soda, is a critical mineral of this facies. Whether stable or metastable at the
time of crystallization, its presence in a mineral assemblage indicates rapid cooling from an unusual high
temperature of metamorphism.
4. As a result of partial or complete fusion, glass is sometimes present in rocks of the sanidinite facies.” (Turner et al.
1960).
Insert tab. 1.1
Insert fig.1
One micro clast appears like a vesiculated glassy fragment. Mineralogically it is Si-rich, glassy(?) material,
Ca-feldspar and Ca-silicate (type 2). The wollastonite is massive, with some inclusions of quartz and rare sulfides.
Maximal width of the wollastonite is ca. 40 µm (fig. 2). One vesicle-like vug (diameter is ca. 5 µm) is surrounded by
massive, chemically homogeneous wollastonite. Other vesicle-like vugs of the glassy (?) part of the microclast are open
or filled with sulfide.
Insert fig. 2
Type 3 wollastonite is chemically heterogeneous according to Fe-content (fig. 3, 4). This type shows patchy
intergrowth of Fe-rich (FeO ca. 12%) and Fe-poor (FeO ca. 3%) wollastonite which contains randomly distributed
pyrite (FeS) and rare molybdenite (MoS2). The size of patches ranges from 1 to 10 µm in diameter. Type 3
wollastonites are pseudo-vesiculated indicating fast kinetics of the wollastonite-forming reaction with vigorous gas
release. Vesicle diameters range from 1 to 10 µm. The composition of the gas could have been CO 2 or SO3 according
to the reaction calcite + quartz = wollastonite + CO2 or anhydrite + quartz = wollastonite + SO3 (Wood 1994). Both
reactions do not explain the high Fe-content of wollastonite. An Fe-Ca-carbonate component of the Cretaceous
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carbonate protolith is more likely than a Fe-/Ca-sulfate component of an evaporitic succession or of hydrothermally
altered volcanic rocks.
Insert fig. 3
Insert fig, 4
Another type of wollastonite (type 4) is Fe-poor and occurs in a paragenesis with quartz (fig. 5). These patches
are strongly intergrown with SiO2, are chemically homogeneous, non-vesiculated and have diameters of 10 to 20 µm.
Insert fig. 5
Adjectives (A, B, C) of wollastonite refer to grain size of Nov. 96 volcanic ash: A: <65µm,>32µm; B: >20
µm; C:>20 µm (floats on water). Wollastonite (B1) is vesiculated and rounded, like the grain was tumbled. The grain
shows a reaction rim at the outermost edge, parallel to the grain boundary. Chemically this zone is slightly Mg-rich
relative to the core, maybe indicating an interaction with a fluid while tumbled. Size of the grain is 20x40 µm, vesicles
are heterogeneously distributed, max. length is 10µm. One vesicle intruding the grain from the outer rim is partially
filled with a glassy material rich in P (15-28% P2O5). Wollastonite (B2) is a vesiculated fragment with a glassy rim
(SiO2: 80-95%). At the interface between wo and glass, sphene crystals are abundant. The size of the fragment is 20x50
µm, the maximal. length of vesicles is 5 µm. Wollastonite (B3) is a subangular clast comprising vesiculated wo with
inclusions of Cl-rich glass (SiO2: 75-80%, Cl: ca. 3%), plagioclase-like inclusions and irregularly distributed Fe-oxides,
and a glass (SiO2: 60-65%) vesiculated towards the boundary with wo and a pyx inclusion. Vesicles sometimes
resemble the shape of crystals, maybe remnants of dissolved minerals. The particles rich in Ca-silicates (11-28-96 ash:)
can also contain fluorite crystals (diameter: 1µm), documenting another F-phase except of clinohumite found in
dolostone clasts of the ca. 14.000 BP eruption.
Other particles from the 11-28.96 event are Si-rich glasses of contact metamorphic origin („buchites“)
containing anhydrite crystals and inherited zircons. The vesiculation of this glass is typical bimodal with coalescing
vesicles (~10µm) and a sponge-type vesiculation (~1µm). EDS analysis of the glass is Na 2O=1.93, MgO=0.19,
Al2O3=4.37, SiO2=85.55, K2O=0.30, CaO=0.35, TiO2=0.48, MnO=0.16, FeO=0.53, P2O5=0.95, SO3=4.41, Cl=0.13.
None of the different wollastonite types show alteration (exception: B1) or indications of incipient retrograde
metamorphism like growth of hydrous lime silicates. This observation is interpretated as an indicator for the young age
of wollastonite. Rounded grains refer to tumbling in the conduit. We could detect rounded wollastonite particles (B1)
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with alteration rims due to interaction with a liquid or gas phase and rounded grains of microliths-containing volcanic
glass, also with alteration rims.
Temperatur indication for wollastonite formation
If Fe-wollastonite occurs with hedenbergite it can serve as a geothermometer indicating 500-600° C. The
formation temperature for MoS2 is reported as 480 to 570 C from fumarole experiments (Bernard 1985) and from
fumarole-wall rock alteration at about 700 C (Getahun et al. 1996). Molybdenite from fumarole incrustations can
contain minor amounts of Fe and Re (Bernard 1985). These data are in accordance with the data reported by Tilley
(1948) for the formation of Fe-wollastonite. Wollastonite is also reported as a sublimate phase from Merapi volcano
(Symonds et al. 1987).
Reported occurrences of wollastonite-bearing xenoliths from volcanoes and intrusions (selected literature)
Wollastonite had been studied extensively from country rocks of intrusions. The few reports of wollastonite
from xenoliths of volcanoes are in the best case mineralogical descriptions, ignoring the volcanological context.
Wollastonite is reported from xenoliths in lava flows of Pacaya volcano (March 1989 and July 1990 eruption – Janik et
al. 1992), Guatemala and of Popocatepetl volcano (2000 years old andesite flow; Goff et al. 2001). Wollastonite-
bearing xenoliths from volcanoes are reported from lavas of Tarumai volcano, Hokkaido (Ishikawa 1953), from
pyroclastic rocks of the 1902 eruption of La Soufrier, St. Vincent (Devine et al, 1980), from pyrometamorphic ejecta of
White Island volcano and Ruapehu, NZ (Wood 1994; Wood et al. 1996). Aramaki (1961) decribes wollastonite from
xenoliths of Asama volcano. Fe-wollastonite is reported from a xenolith of Kanpu volcano, Japan (Isshiki 1954) and
from aureoles of granite intrusions at Beinn an Dubhaich, Skye, dolerite intrusions at Scawt Hill, Co. Antrim and alkali
gabbro intrusions from Muck (Tilley 1948).
Spinel, buchites and other indicators of contact metamorphism
Hercynite (Fe-Al-spinel)-bearing particles are also recognized. Euhedral hercynite (clast 1: H1, H2; clast 2:
H3; tab 1.2) is scattered in a BSE homogeneous matrix of maybe glassy composition (clast 1: M1-4; tab. 1.2).
Insert tab. 1.2
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The sizes of individual crystals range from <1 µm to 2-3 micrometers. The spinel-shaped crystals from
clusters. Mg might partially replace Fe. The SiO2 and other element contents of H1, H2 and H3 probably derive from
background or interstitial matrix. Hercynite can be the product of a metamorphosed argillaceous rock. It is a rare
mineral because it requires an extremely Fe-Al-rich environment to grow. Baldwin (1955) has investigated the rate of
formation of hercynite from mixtures of FeO and Al2O3 at between 800° and 1300°C. Hercynite was determined from
the ca. 900°C section of a silica tube experiment from Merapi (Le Guern et al. 1982A).
Other fragments are composed of phlogopite and sphene. In between euhedral sphene crystalls very small magnetite
crystalls are widespread. Possible reactions to form sphene and phlogopite are:
TiO2 + calcite + quartz <=> sphene + CO2
2 dolomite + K-feldspar + H2O <=> phlogopite + 3 calcite + 3 CO2
In the case of active contact metamorphism, both reactions can contribute CO 2 to the fumarole gases. As most
marine limestones have 13C values close to zero, one would expect that decarbonation of the limestones would give off
CO2 with 13C-values of about +5.0 per mille (Shieh et al. 1969).
The 20 March 1995 ash contains lithic fragments. They consist mostly of euhedral pyroxenes (tab. 1.3). The crystals
are liberated from adhering melt, but there are relicts of a Si-rich homogeneous, interstitial matrix (tab.1.3). Cavities
between the pyroxene crystals host round Ni-rich minerals.
Insert tab. 1.3
The Ni-bearing minerals are heterogeneous in the BSE image. The ratios of Fe:Cu:Ni:S equal ca. 3:3:3:12
(maximum diameter is 5 µm). Very bright (in BSE image), smaller crystals are embedded in a bright matrix. The
diameter of the smaller crystals is ca. 1 µm. The relative high P2O5 contents of the matrix indicate a CM origin. Fe-Ni-
Sulfides are widespread in hornfels-type xenoliths (#95/73). On the surface of this xenolith pseudo-concentric patches
of Mn-Fe-(Ni?)-coatings are observed, showing dehydration cracks. The genesis of these patches might be related to
processes after deposition.
Further examinations of the recent ash utilizing the SEM and FE SEM could document a variety of contact
metamorphism-related particles. The 01-02-95 volcanic ash contains fragments of anhydrite crystals in a matrix rich in
Al, P and S. This matrix is heterogeneous chemically, Fe-„rich“ and Fe-„poor“ parts are intergrown in a Haring texture
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(named after Keith Haring, US artist, known for a graphical style of drawing). This texture can be interpretated as a
spinodal decomposition of an original homogeneous glass or as the product of a combustion-like process, frozen in the
state of fingering reaction-products. The size of chemically homogeneous parts of the Haring texture is 1-5µm.
Chemical analysis of this material is as precise as analytical technique (EDS): Na2O=1.93, MgO=0.69, Al2O3=48,86,
SiO2=5.35, K20=1.89, Ca0=6.95, FeO=1.32, P2O5=14.20, SO3=17.78, Cl=0.76 (oxides of Ti, Mn and Ni are 0.00).
Discussion:
As we do not have data of CM-indicators in ash emissions of the past, an interpretation of such minerals as
signals for major eruptions would be highly speculative. At this stage of investigation the occurrence of CM-related
minerals co-documents – together with dome-related fragments - a change in the recent eruptive process. Xenoliths
might be present in the extruding dome. The interpretation of the age of the CM-minerals seems to be crucial: Does
Popocatepetl erupt old CM-minerals or is CM an on-going process when magma is sitting at shallow levels?
At Vesuvius, another volcano situated on massive carbonates, at the end of some of the shorter periods of
activity wo-bearing xenoliths are reported (Zambonini 1935). For example: 1.1796-1822 (wo-bearing ejected block
1822), 2.1870-1872 (wo-bearing xenolith in lava flow of 1872) and 3.1875-1906 (wo-bearing ejected block from the
1906 eruption).This might be an effect of non-systematical sampling or of peaked occurrence of wo-bearing xenoliths
at the end of an eruption periode which terminates with a more energetic, CM clast-clearing eruption .
Wollastonite usually forms between 2 kb (=7-8 km) at >700 C and only 500 bars (=2 km) at 600 C. The
maximum of hypocenters of volcano-tectonic earthquakes between December 1994 and November 1996 had been
between 0 and -3.5 km beneath the volcanic edifice which is based at +2.5 km (Valdes et a. 1995; Arciniega-Ceballos
et al. 2000). Dacitic lavas have temperatures between 750 and 950 C. At the plutonic or magma chamber-stage
temperatures should be lower. Volcanotectonic earthquakes occur in the brittle rocks around the magma reservoire,
conduits and may involve shear linked to stress induced by magma movement or tensile failure of rocks. This can lead
to the fragmentation of surrounded rocks which may be added to the ascending magma or are being draged from wall
rocks by the magma movement (Arcienega-Ceballos, pers. comm.). All decarbonation reactions decrease the volume of
the country rock, maybe creating a network of fractures. The long lasting volcanic activity at Popocatepetl might have
formed a magmatic “karst” system. Fenitization could have progressed at rising temperature and pressure, causing
thermodynamic shattering of the micro-fabric of the surrounding country rock. Mechanical stress, however, which
generally preceeds metasomatism, can be widespread and locally intensive, and brecciation is a common feature.
Well studied aureoles, like the Ballachulish (diameter: 5.8 km) or the Monzoni complex (diameter: 2.5 km),
demonstrate that a ca. 1000°C hot Si-rich intrusions forced the limestone-rich environment to react and forming
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isogrades of decarbonation reations as far away from the contact as ca. 500 m (Masch et al. 1991; Heuss-Aßbichler et
al. 1991). The average width of hypocenters of volcano-tectonic earthquakes is ca. 10 km at a depth of –2 km.
Applying these data to the subsurface structure of Popocatepetl, a gigantic reservoire for CO2 release would be
available. The formation of wollastonite is normally approximating the highest grades of CM against the
pluton/magma, but is not next to the immediate contact with the melt. Fluids can transport ions deep into the country
rock. Examples are known like wollastonitized cherts intercalated between limestones. These cherts operated as
metamorphic aquifers (Romer et al. 1998).
The time of formation of wollastonite in aureoles can be very low. 10 mm thick aggregates of wollastonite can
grow in ca. 500 years at >800°C (Kridelbaugh 1973). The 20 µm thick aureole-like wollastonite (type 1) could grow in
ca. 1-2 years. Kalinin (1967) could synthetizes wollastonite at temperatures as low as 350 C over periods of 2 to 10
days at pressures of ca. 150-1700 bars Harker et al. (1956) could grow wollastonite in ½ hour at 660°C and ca. 340 bars
in the presence of water. Tanner et al. (1985) report replacement of calcite by wollastonite (100 µm) in 1.1 years at
850°C and 1 kb. A study to evaluate the residence time of the magma beneath Popocatepetl as suggested by Pyle
(1992) and Albarede (1993) would be an important step for further conclusions.
Goff et al. (2001) could measure CO2/SO2 excursions of normal CO2/SO2 flux, roughly 30 times higher than
typical values. These events had been interpretated as active assimilation of limestones into the magma chamber.
Contact metamorphism of evaporites is exceptionally well documented at the Werra-Fulda minig district
(GDR). Sulfur enrichment around basaltic dikes and rare CO2 explosions are described by Knipping (1989). Many
evaporite minerals start decripitating at low temperatures, like carnallite, releasing HCl. Anhydrite reacts at 1193° C to
CaO + SO2 + O. Most of the evaporite minerals melt at magmatic temperatures (Herrmann 1980).
Part 2: Volcanic aerosol particles
Aerosols are a suspension of solid or liquid particles in a gas. Aerosols are usually stable for at least a few
seconds and in some cases may last a year or more. The term aerosol includes both the particle and the suspension gas,
which is usually air. In the plume environment magmatic, non-magmatic (CM-derived) gases and entrained air are
blended together.
Aerosol particle sizes range from 0.001 to over 100 µm. The term fine particle describes a morphologically
well defined object (size < 2µm), coarse particles are larger than 2 µm in diameter (Hinds 1982). A secondary particle
is a particle formed in the air, usually by gas-to-particle conversion; also sometimes used to describe agglomerated or
redispersed particles. Dust are solid particles formed by crushing or other mechanical breakage of a parent material.
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These particles have irregular shapes and are larger than about 0.5 µm. Agglomerate is a group of particles held
together by van der Waals forces or surface tension. Aggregate is a heterogeneous particle in which the various
components are not easily broken apart. Particles can be or can contain minerals or amorphous substances. The
parameters to describe aerosols or aggregates are size, geometry, primary particle etc., surface and if possible, local
chemistry (Willeke et al. 1993, p.18).
Methods to analyse aerosols are described in Willeke et al. (1993). The authors compare the SEM/EDS with
other instruments, but do not discuss the modern, high resolution FE SEM, which had not been available at this time.
The term condensate is used in this paper to descibe the product of a gas-to-particle conversion, regardless if the
particle is solid or liquid. Solid particles formed from a gas are also called sublimates.
Sampling Procedure (H. Delgado)
Volcanic aerosols from Popocatépetl volcano were obtained by flying across the plume. This was carried out
by using a fixed-wing two engine airplane (Cessna 421), departing from Atizapán Airport (nearly 75 km northwest of
the volcano) at 2,600 masl. A couple of containers with Teflon filters (1 µm) impregnated with 3M LiOH/20 %
glycerin were set out of the lateral window (co-pilot’s window) of the craft, separated about 10 cm from the plane’s
fuselage connected by Teflon piping to an air pump controlled from inside the plane. The impregnation had been
designed to adsorb acid gases. The holders had a rigid plastic cover and the pump was off at the time of take-off. The
holders were uncovered above the volcano at about 19,000 ft (5790 masl) and the pump was turned on with an average
flow rate of 30 ml/min.
The cross section of the plume was set at the southeastern side of the volcano with an azimuth of 200º the
volcano’s plume was moving outwards with a rough direction of 290º. At this altitude the ambient temperature was - 3º
C as recorded from the aircarft’s instrumentation. Ten cross sections were made between 18500 ft and 12100 ft (5640
and 3690 masl) spaced every 400 ft in altitude (122 m). Every line had a distance of 12.7 km in preserving a direction
normal to the plume’s direction. At 18500 ft (5640 masl) the volcanic plume was detected by the correlation
spectrometer (COSPEC) yielding sulfur dioxide burdens as high as 236 ppm•m, and maximum volcanic carbon dioxide
concentrations of 0.5 µmol/mol. 1 ppm•m is the unit of SO2 measured by COSPEC, it means the total SO2 concentrated
along a line of a meter since the instrument integrates it along the optical trajectory between the instrument and the
light source.
The maximum burden of sulfur dioxide was 445 ppm•m, and maximum concentration of carbon dioxide was 8
µmol/mol, both detected at 16900 ft (5213 masl). The total output of sulfur dioxide calculated by integration of the
cross sections was 6530 ± 790 tons/day. Carbon dioxide emission rate was calculated at 13630 ± 1000 tons/day.
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Traditional analysis of volcanic aerosols (selected literature):
The production of aerosols, dust and gases is difficult to assess, because of the scarcity of data. In addition to
primary particles in the form of ash, volcanic activity produces significant quantities of reactive gases such as H2S, SO2,
or HCl. The Mt. St. Helens eruption in 1980 had given a first opportunity to carry out scientific investigation (Hidy
1984). Sampling is performed as stratospheric aerosol collection (Oberbeck et al. 1992) or tropospheric aerosol
collection, or by aircraft around non-eruptive plumes (Phlean et al. 1992). The size distribution of particles of the Mt.
St. Helens plume ranges between 10-2 and 10+2 µm in diameter (Hobbs et al. 1981). Most of the analytical studies
performed on volcanic aerosols utilized bulk chemical analysis, standard SEM analysis of solid particles (Meeker et al.
1991), or TEM analysis. Liquid aerosols from the plume of Pacaya volcano (1978) and solid/liquid aerosols from the
plume of Fuego volcano (1978) had been studied by TEM (Rose , 1980; Ammann et al., 1993). Indirect measurements
of aerosols are widely used, like spectral optical depth (Valero et al., 1992), LIDAR (Winker et al., 1992) and a variety
of satellite-hosted instruments.
Several publications are devoted to individual eruptions. For example: Mount St. Helens (Newell et al. 1982),
climatic effects of the eruption of El Chichon 1982 (several papers in Geophysical Research Letters, 10/11, 1983, the
Pinatubo eruption of 1991 (Sheridan et al. 1992, Solomon et al. 1993, Hamill et al. 1996), Kilauea: Zoller et al.,
(1983). Mt. Erebus: Meeker et al. (1991), Mount Etna: Andres et al. (1987) or Heimaey: Mroz et al. (1975). Global
effects are discussed by Handler (1989), Nriagu (1989) and Mills (2000).
Results from standard SEM analysis:
The filters had been analysed by wet chemical techniques at the Los Alamos National Laboratory (EES-1).
Only a few gases were sufficiently concentrated in spring 1997 to get results from the filter. CO 2 (2400 ppm), S (2ppm)
and Hg (1ppb) could be analysed (Counce, pers. comm.). Particles show a wide range of composition. Solid aerosols
are volcanic glass, magmatic silicates, Cl-,P- and S-bearing minerals/particles. We could identify an S-bearing mineral,
mercallite: KHSO4, known from fumaroles of Vesuvius (Imbo 1965); mercallite indicates formation temperature less
than 650 C. A Ca-chloride is present (antarcticite: CaCl2.6H2O or sinjarite: CaCl2.2H2O), also a Ca-rich particle (CaO
or Ca(OH)2). Cu- and Zn-bearing particles could be detected. Most of them also show a sulfur peak. Cu and Zn-bearing
condensates are reported by Taylor et al. (1973) from Central American volcanoes.
Galindo et al. (1998) analysed solid aerosols from an impactor filter collected at Popocatepetl. This study
utilizes standard SEM and XRF for aerosol characterization. The particles described are spherical or blocky,
fragmental, dust-like interpreted as pulverized rock. XRF analysis documents: Si, Al, Ca, S, P, Cl, K, Ni, Fe, Ti, Sc,
Cu, Zn, Mn, Sr, Cr, Co, Y, Br, Se, Ga, Rb, Hg and Pb.
12
Realizing the much better resolution of FESEM than SEM we did not continue on standard SEM
investigations. Detection limits for different elements are different for XRF and EDS, nevertheless we can add more
elements to the elements as detected by XRF and can relate elements to certain particles. Important to note is that
Galindo et al. (1998) and we worked on 2 different filters collected at different altitudes and different dates.
Results from field emission gun SEM analysis:
In a first attempt field emission gun (FE) SEM was tested to elucidate the composition of very small particles
(<5µm) on the impactor filter. The advanced resolution of the FESEM permits new insights in micro-morphology and
micro-chemistry of solid aerosols. Analytical limits are given as the filter utilized is made from teflon. EDS spectra do
not permit characterization of C- and F-peaks generated by particles. First studies taught that chemical characterization
of particles does not necessarily define minerals. As a preliminary tool to describe what can be analysed, we would like
to introduce a micromorphological classification, rather than a chemical/mineralogical. Often tiny spheres (S?) are
adhering to the surface of particles. Explanations to the tables 2.1 to 2.4: Diameter (d) and length (l) are measured in
µm. Elements listed after the “&”-sign are present in minor amounts. Elements listed are detected by a peak in the
spectrum. Further FESEM images than the presented ones can be obtained from Obenholzner and Schroettner.
Tables 2.1 to 2.4 document particles analysed by FE SEM. Most of the particles are imagined by a composite
image of BSE and SE images. Several particles are not documented as images. The category, single or aggregated
particle, describes the overall appearence according to chemical composition and morphology. Larger aggregated
particles consisting of dozens or hundreds of fragments are not mentioned in the tables. For these particles EDS
analysis is problematical as X-rays would derive from too many individual, smaller 1-5 µm fragments. Size,
morphology and chemical elements detected by EDS are listed for all other particles. Interpretation of the detected
elements refers to known minerals and their chemical composition. For most of the particles such an interpretation is
highly speculative. The morphology does not show typical crystal structures. This has to be kept in mind for all
particles categorized as fluffy, spherical or complex.
13
Complex or simple particles can be observed as aggregates or clusters.. The overall appearance is blocky or
fragmental (table 2.1).
insert tab. 2.1
As examples some particles are described in more detail. A pseudohexagonal particle shows network-like
structure in composite image. (fig. 9 c & d). Others are irregularly formed particles with rough surfaces deriving from
coagulation of thousands of small spheres building bumps and horn-like extrusions (fig. Fig. 10 c). Pop9 and Popoc18
are aggregated particles, slightly elongated (length is ca. 20 µm); these particles consists of hundreds of mineral or
glassy fragments. Popoc16 consists of ca. 2 dozens of smaller fragments, lenght is ca. 10 µm. Similar appearence is
documented by Popoc28 (diameter ca. 10 µm)). These particles are not listed in tables 2.1 to 2.4.
Further studies could demonstrate that individual particles often appear chemically homogeneous, like
minerals would do, but morphologically they are fluffy, amoeboidal, botryoidal, moss-like, flakey, spongey or gel-like.
They might be the remnants of collapsed or decrepited, short living particles.
Insert tab. 2.2
14
As examples some particles listet in table 2.2 are described in the following section. One amoeboidal particle
shows a rough surface, diameter is ca. 3 µm. The overall appearance of this particle refers to a process which
coagulated smaller spheres in a string-like manner. Individual spheres show diameters of ca. 50-100 nm. Al, Si and Fe
are the dominant elements with minor aounts of P, K, Ca and Ti. The outline of this particle shows edges, like it was
broken away from a larger particle. The particle might have been a part of a fumarole-related deposition (fig. 10 a &
b)). Popoc17 has a cloud-shape with a core surrounded by a ring. Popoc22 has a feather-like appearance (fig. 6 a).
Lenght of the particle is ca. 10 µm. Popoc25 shows 2 particles side by side. One is defined by edges the other is fluffy.
Diameter of each particle is ca. 1 µm. Popoc26 shows 2 fluffy particles side by side (fig. 6 d). Diameter of each particle
is ca. 10 µm. Popoc27 (fig. 6 b) is a fluffy particle, diameter is ca. 7 µm. Popoc10 is another fluffy particle (fig. 6 c).
Insert fig. 6
Spherical particles can have a variety of chemical compositions and might be coated with a chemically distinct
population of more or less well crystallized minerals (tab. 2.3). We do not know yet if the chemical different spheres
are hollow or massive. Processes forming spherical particles are known, but are not attributed to volcanic plumes.
Nucleation, adsorption, desorption, condensation, coagulation, condensation, evaporation or diffusion (deposition
across a boundary layer) are well modeled (Whitby et al. 1997). At this point of data collection it is difficult to imagine
processes like sintering (Seto et al. 1997) or spray pyrolysis (Jain et al. 1997) happening in plumes. Wohletz et al.
(1984) could produce spherical particles in water-melt interaction experiments. They found hollow spheres
(cenospheres) and filled hollow spheres (plerospheres). Spherical particles are also known from phreatomagmatic ash
deposits around Kilbourne Hole, New Mexico. Spherical particles from phreatomagmatic processes should be easily
characterized by similar chemical composition.
15
Fall times of spherical particles can be calculated according to Stoke´s law. As an average the time of fall for a
50µm sphere would be ca. 16-24 hours for 14.000 m. For finer grains, fall times are uncertain. Clumping due to
electrostatic forces and moisture can enhance fall rates. Fine grains that do not clump may have lower fall rates due to
lift resulting from turbulences (Riehle et al. 1994).
Le Guern et al. (1982B) could collect spherical aerosols utilizing the silica tube to condensate gases from a
lava flow of Mt. Etna. SEM investigations could demonstrate that these spherical aerosols had been droplets which
crystallized as aphthitalite (K2Na(SO4)2). The shape of the aphtitalite aggregates still resembles the droplet (diameter is
ca. 300 µm), from which fluid evaporated. Internal structures show also droplet-like features. According to the much
better resolution of the FE SEM we could detect many types of spherical particles. Important to note is that none of the
described particles in this study shows features of desiccated droplets remaining crystallized substances.
Insert tab. 2.3
One type of particle has been observed several times. Popo11 (fig. 7 a) consists of Ca, P, Mg, and Cl with
minor amounts of K, S, Si, Al, Na. A very similar morphology and composition shows popo10 (fig. 7 b). On the
surface of a Ca-phosphate (apatite or collophane = crypto-crystalline apatite-like mineral) sphere chlorides are
homogeneously scattered. The anhedral crystallites are a complex S-bearing Mg-chloride (i.e. bischofite: MgCl 2.6H2O;
carnallite: KMgCl3.6H2O; chloromagnesite: MgCl2; dansite: Na21Mg(SO4)10Cl3; kainite: MgSO4.KCl.3H2O). According
to EDS spectra a CO3-component might be present in the formula. The origin of Mg-chlorides might be related to the
reaction: MgSiO3+2HCl=MgCl2+H2O+SiO2 (Stoiber et al. 1970). Similar reactions can be assumed for the formation of
CaCl2 (CaSiO3+2HCl=CaCl2+H2O+SiO2; CaAl2Si2O8+8HCl+8H2O=CaCl2+2SiO2+2AlCl3.6H2O?). Chloraluminate is
known as sublimate at Cerro Negro volcanic fumarole (Stoiber et al. 1973).
The source for phosphorus in apatite might be related to contact metamorphism, as mobilisation of P is
documented in P-rich buchite particles. Red clayey soils deriving from volcanic detritus can be highly phosphatic
(Blackburn et al. 1969). These types of red soils can contain P2O5 between 7 and 20% and might be intercalated
between the limestones underneath Popocatepetl. It is worth mentioning that Ivlev et al. (1995) found relatively high
concentrations of S (4300-114000 ng/m³), Cl (1000-4100 ng/m³) and P (700-<4000 ng/m³), analyzing the ash collected
between Dec. 1994 and Jan. 1995) at the Hnos. Serdan airport (Mexico, D.F.).
Particles with low P-contents had also been detected at the degassing lava flow of Mt. Etna (2001), Italy. Silica
tube experiments from the fumaroles of Colima volcano, Mexico document crystallization of euhedral apatite at
temperature ranges from 600 to 650 C (Taran, pers. comm.). Data of P in volcanic gases are rare. Taran et al. (1995)
16
report 2000-30800 ppb from Kudryavy volcano, Kurile Islands, Russia. Carmichael et al. (1974) mention P from the
Showa-shinzan fumarole (Usu volcano, Japan) recalculated as P4O10 (0,0008-0,0053%). Acid gases are suspected to
leach P from older volcanic rocks or from the continental crust. The average content of P in the upper continental crust
is 665 ppm according to Wedepohl (1995).
The overall appearence of these spherical particles refers to condensation in the plume without essential
subsequent particle-particle-collision. As a model for particle formation we assume as a first step the condensation of
the Ca-phosphate, also trapping minor amounts of Si and Al. Later this sphere became the nucleus of further
condensation of a fluid phase coating the micro-sphere. The evaporation of the fluid caused the crystallization of the
Mg-chloride. These three steps of particle formation document the changes of the chemical environment inside the
plume. Changing parameters along the path of this particle had been temperature, gas chemistry, dilution, velocity of
particle and pressure. At this point of time we do not know if the three steps of formation document a descending or
ascending path of the particle in the plume.
Repeated FESEM analysis of this type of particle in 1999 by Heinrichs (Univ. Goettingen, Germany)
documented the stability of spheres and Mg-Cl-crystallites. The filter had been stored in a sealed plastic box under
prevaccum conditions in an exciccator. Electron backscatter diffraction (EBSD) on spherical particles did not provide
results due to surface roughness, shape and/or missing crystallinity.
Insert fig. 7
Other spherical particles are compositionally Fe, Si, Cl with a few Ca sulfate crystalls on top of the sphere
(popoc01, close-up: popoc02). The sphere is slightly acentrical, partially exhibiting a subsurface layer or core (Si?).
The surface layer might be an Fe-chloride. Compositionally different is a Zn-bearing sphere irregularly covered with
clustering Mg-chlorides (popoc07, close-up: popoc08; fig. 7 c and d)). This particle could be interpreted as an
apatite+anhydrite-phase sphere, trapping Si, Al and Zn during condensation.
Spherical particle (diameter ca. 1.5 µm) can enclose small crystals rich in Pb, Cr or Ti with minor amounts of
Cu, Al, Si. The particle itself seems to consist of C, also traces of Al and Si are present (pop14-1). This particle
encloses ca. 12 crystalls (fig. 8 d). Very rare CaSO4 crystals are growing on top of spherical particles (popoc01/02 – fig.
8 a and b)). This could be interpreted as a reaction between acid sulfates droplets and Ca-bearing particles (Ca-oxides, -
hydroxides, -carbonates or silicates) brought together by in-plume processes. Fig. 8 c shows another spherical particle,
composed of Na, Mg, S, and minor amounts of Ca, the diameter is 1,5 µm (pop3-1). The surface of this tiny sphere is
scattered with droplet-like objects, organized in a ring-like structure. In the center of the ring larger droplet-like objects
17
are visible (diameter ca. 100 nm). The composite image of the host-sphere refers to a homogeneous material. The
droplet objects are totally embedded in this material, some parts seem to stick out of the skin of the host-sphere.
Insert fig 8
Coagulated spheres and collapsed (?) particles are imaged in popo09 (fig. 9 b). Spheres are rich in Ca and P.
Popoc20 documents several coagulated spheres enbedded in a matrix. Lenght of the particle is ca. 1.5 µm (Fe, Zn, Si,
Mg, Al, Ca, S, Cl with minor amounts of K, Mn). Similar morphological features shows Popoc21. Spheres seem to
have coagulated to worm-like structures. Lenght of the particle is ca. 4 µm (Fe, Si, Ca, S, Cl also minor amounts of.
Mg). Popo 12 is an aggregate of tiny spheres (<2µm) and blade-like crystals (fig. 9 a). The bulk particle consists of Si,
Al, Na, S, Cl, Ca and minor amounts of Mg, P, K, Ti, Fe, Cu, Zn. Larger spherical particle can be coagulated with
smaller particles. The diameter is ca. 3 µm, it consists of P, K and minor amounts of Cu, Si, S, Cl (pop8-1). The shape
of particles can be deformed as seen in a pseudo-spherical particle, diameter is ca. 3 µm. The surface seems to be
wrinkled, maybe as an effect of desiccation (pop13 – fig. 10 d).
Insert fig. 9
Insert fig. 10
Particles resembling crystalline material. These particles appear compact, crystalline without euhedral
morphology (tab. 2.4). According to spectra they show mono- or polymineralogical composition. It was possible to
identify feldspar fragments, some are highly corroded and Fe-Ti oxides (?). Ca-rich particles are present.
18
Insert tab. 2.4
Other analysed particles are fragments of vesiculated glass with adhering dust particles. The following images
document vesiculated glass (pop16, pop17 – close-ups: pop18 and pop19, popoc19).
Metals in volcanic gas are postulated as halogen, sulphate and oxide compounds. Chloride and fluoride
compounds are considered to be the primary transporters of metals in volcanic gas. Significant correlations between
bromine content and metal concentration suggest that bromide compounds play a role in the transportation of metals in
volcanic gas (Gemmell 1987). Copper is known for its extreme partitioning into a magmatic vapor phase in
pantellerites (Italy) (Lowenstern et al. 1995). Cu, Zn and other metallic trace elements are known in fumarolic
condensates and as soluble material on ash from Central American volcanoes (Gemmell 1987, Taylor et al. 1973).
Vanadates are rare but known from sublimates (Hughes et al. 1987). Vanadium containing Na-K sulfates and V-W-Co
phases are described from Colima volcano, Mexico (Taran et al. 2000, 2001). Pb and Bi can easily be volatilized as
outlined by Stimac et al. (1996) and Symonds et al. (1987). Galena (?) and PbO (massicot) might be present in aerosol
particles, indicating temperatures <897 °C (melting temperature of massicot). Cotunnite (PbCl2) is known from recent
sublimates of Vesuvius (Houtermans et al. 1964). The Pb-contents of several particles should be kept in mind when
applying decay-series disequilibria methods.
Discussion:
Various microphysical processes affect the aerosols, for example nucleation, coagulation, growth by
condensation and sedimentation. Theoretical models of nucleation of stratospheric aerosols after a large volcanic
eruption exists on the assumption that newly formed particles are droplets of condensed sulfuric acid. The spontaneous
formation of sulfuric acid water solutions not involving any other species or any foreign surfaces is modeled by the
theory of homogeneous heteromolecular nucleation. Problems in these assumptions are discussed by Hamill et al.
(1996). The spectrum of observed particles and their chemical composition can barely be the product of such processes,
although homogeneous (gas-to-particle conversion) nucleation must have played a major role in the formation of
spherical particles. Assuming a constant growth rate (several nm per hour) for particle formation, nucleation must have
started several times to produce different size and chemical categories of particles, reflecting changing chemical and
19
physical parameters in the plume. According to limited FESEM time we could not analyze statistically size and/or
related chemical composition.
The occurrence of S- and Cl-bearing minerals/particles should be considered as a contribution to the bulk S-
and Cl-vapour budget of Popocatepetl volcano. For future studies the use of field emission gun (FE) SEM, imaging ion
microprobe or time-of-flight secondary ion mass spectrometry (TOF SIMS) is recommended. These studies should
focus on pressure and temperature conditions of mineral/particle formation to estimate the origin (magmatic or
sedimentary) of S, Cl and C (?).
Several elements observed as chemical components of analysed particles have also a crucial importance as
chemical components of volcanic gases, like S and Cl. These preliminary results do not permit a quantification of how
much S and Cl cannot be measured by open- or closed-path gas analysers. Correlation spectrometers (COSPEC) or
Fourier-transform infrared (FTIR) spectroscopy can detect only gaseous phases. The latter system is able to perform an
aerosol correction but the chemical composition of aerosols is usually not determined. Many volcanoes release gases
like SO2 at a dimension of tons/day (Bluth et al. 1993, Stoiber et al. 1987). Such estimates neglected sulfur in any other
form than gaseous SO2 (Malinconico 1987). If S in solid aerosols contributes to the total S budget of the atmosphere,
this contribution is bracketed by sedimentation of particles and chemical reactions taking place during fall time.
Goff et al. (1998) calculated that Popocatepetl released from December 1994 to November 1996 3.9 Mt SO2,
16 Mt CO2, 0.75 Mt HCl, 0.075 HF, 260 t As, 2.6 t Hg and 200 Mt H2O. Data had been obtained as a combination of
“volatile” trap chemistry (500 ml of 4N KOH as collector fluid) and SO 2 flux. Delgado et al. (2001) report 9 Mt of SO2
for the pre-eruptive periode in 1994 to Jannuary 1st 1998. These data are mainly obtained by COSPEC. Love et al.
(1998) document SiF4 detected by FTIR.
None of the analysed particles yielded a Hg or As signal. Fluorine could not be detected by EDS as the filter
utilized was made from teflon. Allmost all particles show F in their spectra, probably as a result of X-ray collection
from the filter.
EDS is not the ultimate tool for chemical analysis of single particles in the submicron region. Mass
spectrometric methods (Peter 1996), like time-of-flight secondary mass spectrometry (TOF SIMS), can analyse
isotopes or particle-induced X-ray emission (PIXE) for trace elements, if the optical resolution provides the
identification of single particles. According to the detection limits, instrumental neutron activation analysis (INAA)
would be the best instrument for chemical analysis. The disadvantage is the impossibility to focus on single particles.
However Allard et al. (2000) had been successfully analyzing bulk elements combining INAA and ICP-MS on a filter
from the plume of Stromboli. Analytical transmission electron microscopy (TEM) would be another approach, but
sample preparation is difficult. TEM analysis should be performed on several spherical particles to define the physical
20
state (crystallized or amorphous). Glass created by condensation of vapor is theoretically possible (Vogel 1994).
Progress in applying atomic force microscopy (AFM) to insulators (Pethica et al. 2001) might open new doors to study
physical and chemical properties of aerosol particles.
At Popocatépetl we discussed the possibility of P-contamination of the plume by P-fertilizer used in Mexico.
An FESEM study of the fertilizer could demonstrate, that even very small particles are always blocky. The P containing
volcanic particles are fluffy or spherical, showing smooth surfaces. A coagulation or aggregation of wind-blown,
blocky fertilizer particles can be excluded. A contamination at the molecular scale is possible, but would not lead to the
necessary concentration detected by EDS.
The fraction of elements, like S and Cl, in solid particles compared to these elements in volcanic gases is not
determined yet. A quantification of S and Cl in particles by automatic EDS analysis is possible, if the surface of the
filter is very plain. The ZFE recommends nuclepore filters. The efforts of plume and fumarole monitoring could
become veiled by ignoring the chemical composition of condensing particles. Chemical analysis of aerosol collection
on filters compared with analysis of lava leads to enrichment factors for elements in the plume. Normalizations against
highly volatile elements, like bromine, helps distinguish elements hosted in glass shards and magmatic crystals, from
elements hosted in condensates. This FESEM/EDS study detected i.e. Si and Al, typical for silicate melts and a variety
of magmatic crystals, as constituents of condensed particles, indicating the existence of SiF4 and AlF2O(?) in the plume.
CONCLUSIONS:
Recent models of the geochemical C and S cycle (Arthur 2000) do not differentiate between volcanic gases,
derived from mantle and/or subducted rocks, and gases derived from the basement of volcanoes. Volcanoes situated on
massive carbonates and/or intercalated evaporites should be treated separately in model calculations. The importance of
volcanic recycling of ancient evaporites is outlined by Risacher et al. (2001) for the 1993 Lascar eruption.
Keeping in mind that 1 kg of natural limestone contains 0, 4395 kg CO2 (reference limestone from Maria
Trost, Austria; Schoklitsch 1935), an important contribution of CO2 from decarbonation reactions can be expected. An
average density of limestone is 2.6 g/cm³. In a cylindrical model, a Monzoni-like intrusion (diameter ca. 2.5 km),
would release ca. 105 Mt of CO2, assuming a 20 m wide zone of total decarbonation around a 500 m high intrusion.
Comparing this model with the known subsurface structure of Vesuvius or Popocatepetl, these assumptions are minima
according to intrusion or magma chamber hights. These assumptions are exaggerated according to known outcrops at
Monzoni or Ballachulish, where 20 m wide, tube-like zones of total decarbonation do not exist, but decarbonation
reactions are documented as far as 500 m away from the contact. Time is another parameter limiting the value of such a
21
model, is magma stored long enough to drive the necessary decarbonation reactions? At prevailing pressures in the
realm of contact metamorphism gases might enter the magmatic system, but also can be dissolved in secondary melts
and fluids. Melt and fluid inclusion studies of skarn xenoliths are an important approach to get insights into the
complex interaction between melt and carbonate host roks, as documented from Vesuvius (Gilg et al. 2001; Fulignati et
al. 2001). Skarn lithics from the plinian Avellino, and Pompei, and the sub-plinian Pollena eruption had been studied,
but no age data of the skarn-forming process could be obtained. Although these microanalytical techniques provide
precious data, a link to the eruption history of a carbonate hosted volcano is still missing.
The critical temperature for CO2 is only 31.1°C, already attained at a normal geothermal gradient at ca. 1 km
depth. CO2-rich fluid inclusions originating from deeper or hotter environments must have been trapped in a
supercritical state, making it difficult to read the depth of formation. Density measurements might bridge the gap, but
leakage during sometimes long lasting exposure of xenoliths to atmospheric pressure conditions cannot be excluded as
mineralogical encapsulation does not provide perfect sealing, especially after being incorporated in volcanic eruptions.
The calculated and measured 16 Mt of CO2 from Popocatepetl (Dec. 1994-Nov. 1996) can be a mixture of
magmatic and basement-derived CO2. Remaining questions are, how does the input of gases from metamorphosed
country rock effect the style and the dynamics of eruptions of volcanoes situated on massive carbonate
platforms? .Could the monitoring value of CO2 become reduced by such assumptions? What is the frequency of
volcanoes to be siituated on massive carbonate platforms in the history of the plate tectonic puzzle of Earth? The
Mesozoic carbonate platforms are in a way dominant according to the now-a-days observer of the Earth‘ s surface, but
burried and/or metamorphosed carbonate and evaporite sequences could play/have played a role in contributing gases
to volcanic eruptions and as a consequence contributing gases to the atmosphere throughout Earth´s history.
„Whereas direct experimental investigations in magmatic gases, as well as extensive thermodynamic modeling
have revealed a large set of possible reaction mechanisms, very little is known about the actual plume formation
processes where the complexity of the fully heterogeneous system must be considered“ (Amann et al. 1993). More
FESEM/EDS data of particles from fumaroles, degassing lava flows and plumes are needed. Automatic sizing and
chemical analysis can reduce FESEM time. The disadvantage is a loss of information of individual particles, especially
morphological features which cannot be characterized fully by available sizing parameters. To develope SEM analysis
of volcanic ash particles and aerosol as an instrument to assess volcanic hazards and monitoring, it would be necessary
to sample in a continous, time-resolved way and set up data bases.
Phosphorus is known to exist as a compound of a variety of gaseous molecules. Remote sensing methods and
direct sampling techniques and subsequent analysis should focus on the detection of these molecules. This would help
to explain the high abundance of P in observed aerosol particles.
22
Satellite-borne aerosol data should be correlated with FESEM data on the same object. Analysis should also be
correlated according to the time of observation and sampling. Airborne sampling might be too dangerous for pilots and
planes. Small meteorological rockets could be utilized for sampling. It is necessary to develope an impactor which can
be opened and shut according to flight operation to minimize possible contamination by non-volcanic aerosol. To avoid
risks to pilots and scientists a cooperation with small rocket engineers is proposed. Rocket-borne in situ aerosol
measurements have been tested positively to study noctilucent clouds (Rapp et al. 1999). Rocket-borne data from
plumes could be an important contribution to atmospheric chemistry and volcanism and climate change.
Acknowledgements:
SEM and FE SEM studies of volcanic ash and aerosols from Popocatepetl volcano, Mexico had been sponsored by the
Naturhistorisches Museum (NHM)/Mineralogie, Vienna (part 1) and the Zentrum für Elektronenmikroskopie (ZFE),
TU Graz (part 1 and 2). Data collection was possible due to cooperation with S. Hughes, C. Siebe (UNAM), G. Kurat,
F. Brandstätter (NHM, Vienna, Austria). We are also grateful to Y. Taran (UNAM) and F. Goff (LANL), who critically
reviewed earlier versions of the manuscript.
Appendix 1:
Methodology
The field emission scanning electron microscope (FESEM) laborartory at the Zentrum für Elektronenmikroskopie
(Technische Universität Graz, Austria) – P. Golob .
FE SEM techniques had been applied partially for part 1. All aerosol studies utilized the FESEM (part 2).
Scanning electron microscopic images are generated by a thin electron beam which scans one sample line by another.
Primary electrons can go into the sample and leave the studied material as high-energetic back scattered electrons or are
emitted from near-surface layers as low-energetic secondary electrons. Detectors collect the emitted electrons and are
responsible for the brightness of a synchronous scanning beam of a screen.
The lateral resolution of a microscope is defined by the minimum distance of two objects documented as
separated identities. The capacity of resolution of an SEM is also limited by the diameter of the scanning electron beam
at the level of the sample. Conventional SEMs emit electrons from a heated cathode. The anode field accelerates the
electrons to obtain the desired (primary) energy. Inside the electron gun there is a cross-over of the electron trajectories
showing a diameter of ca. 50 µm. This cross-over is modified by electron-optical lenses to an even smaller diameter
which provides a highly focused scanning electron beam at the level of the sample.
23
Electron-optical lenses, like light-optical lenses, can show defects. These defects are responsible for the
limited availability of the beam diameter and the beam current which governs the intensity of the electron beam. If
imaging and analysis need higher beam currents the diameter of the beam is enlarged and resolution is diminished.
According to the chemical properties of the electron source the increase in beam diameter becomes more dramatic
when a low accelaertion energy is applied.. Modern instruments can reach electron-optical resolution of 5 nm utilizing
high primary energy and low beam current. High primary energy causes the primary electrons to go deeper into the
sample and resulting information is diluted by a larger sample volume from which the signals are obtained.. Therefore
resolution is diminished again, if a sample is heterogeneous at very small scale.
Field emission cathodes are characterized by a very fine tungsten tip, which emits electrons under the
influence of electrical fields. Utilizing such a device extremely small beam diameters can be produced on the surface of
a sample, therefore a high electron-optical resolution is provided by applying a low primary energy. As a result
informations for imaging and analysis can be obtained from near-surface areas. The aerosols and selected clasts of the
Popocatepetl ash had been analysed by the LEO DSM 982 Gemini microscope. This FE SEM provides lateral
resolution of ca. 1 nm at 25 keV and ca. 4 nm at 1 keV.
Applying high energy the primary electrons can interact with the atoms of the sample. The ionisation of the
electron shells of the atoms generates X-rays with characteristic energy due to the atomic source . This phenomenon
can be used to analyse the chemical composition of the source area from which X-rays are emitted. Energy-dispersive
X-ray spectrometer (EDS) are splitting the X-ray spectrum electronically. Monochromatic X-ray lines are the sources
for profiles with half-life width of ca. 150 keV, permitting a reasonable separation of lines of different elements. The
LEO DSM 982 Gemini is equipped with a Noran Voyager System, utilizing an ultra-thin window. Elements from B to
U can be analysed; resoltuion limits are in the best case at ca. 0,1 weight percents. Increasing energy of accelerating
electrons increases the intensity of the X-ray lines, leading also to a larger area of acceleration and therefore to a larger
analysed volume of the sample. This is very important for the analysis of particles. As soon as the area of acceleration
becomes larger than the particle, the substratum or the filter material is integrated in the result. After optimizing the
working conditions areas of acceleration can be obtained at a sub-µm-scale.
Correction models are needed to calculate quantitative data of the composition of a sample. X-ray intensity
and the concentration of individual elements are in a proportional relation. This relation and other parameters like the
accelerating energy are the most important factors for the correction models. These models are developed for
homogeneous samples with a flat surface. Particle analysis causes therefore a problem, simulations, like Monte-Carlo-
simulation or reference particles would be necessary. Providing these premises automated analysis is possible and
statistical data of size and composition can be obtained.
24
Except for the composition of a particle an examination of the crystal structure is needed sometimes.
Transmission electron microscopes can be used to produce diffraction patterns of selected particles. New technologies
like the electron backscattered diffraction (EBSD) permit crystal structures to be analysed in-situ in the SEM. However
analytical restrictions of this type of phase identification have to be examined by experiments. It is well known that it
can be applied to flat surfaces.
The impact of the primary electrons causes charging of the sample. To avoid this phenomenon a very thin
layer of a high-conductivity material is sputtered on top of the non- or low-conductive surface of particles and filter
material. This technique provides the charging electrons to escape and improves the imaging conditions. The teflon
filter had been coated with carbon. Carbon does not produce misleading X-ray lines and does not suppress emitting X-
rays. For imaging only Au is the best material as a coating substance as it highly improves contrast. For the aerosol
study we utilized the coating and sputtering equipment EPA 101, Leybold.
Traditional SEMs work under high vacuum. This limits the application to dry objects. New techologies like
low-vacuum systems can by-pass these problems. In these systems the sample chamber is not directly connected to the
beam-producing electron-optical equipment. The sample chamber can be flooded by a mixture of gases under different
pressures. Such a system is going to be installed at the ZFE Graz. Up to now wet samples can be analysed only in a
frozen state, utilizing cryo-preparation and cryo-transfer, which permits deep freezing, breaking and coating without
contamination (icing). Cooling of the sample and transfer to a precooled sample chamber is reducing damage to
destructable samples by primary electrons. Further Reading on electron microscopy-related literature applied to
geosciences can be found in Obenholzner et al. (1999).
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