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PUMACEOUS POTTERY: AN INSIGHT INTO THE ANCIENT GUANGALAN
PEOPLE VIA CERAMIC TEMPER ANALYSIS
Niki Apollonia Buechel, Sabrina Rose Casavechia, Matthew Christopher Guido, Gabrielle
Hoang, Abhiram Karuppur, Sangho Andrew Lee, Heather Amelia Newman, Dorothy Yingtao
Qu
Advisor: Dr. Maria Masucci
Assistant: Kaushaly Patel
ABSTRACT
The Guangala people of southwest Ecuador have a relatively unknown culture. However,
recent research has shown that the Guangala had a profound knowledge of ceramic technology.
Analysis of the Guangala ceramics reveals an extensive use of pumice as an inclusion to make
finely decorated pottery, though the pumice was not available locally to the Guangalan potters.
There are different hypotheses that describe the reasoning and source behind the presence of
pumice in the ceramics. One hypothesis contends that the pumice was derived from ashfall from
explosions of volcanoes in the Andes mountains. Another hypothesis details that the pumice was
obtained through trade from people inhabiting the Highland areas surrounding the volcanoes.
Evidence from analysis of Guangala ceramics using optical petrography, a technique used to
analyze the mineralogical contents of ceramics, supports trade in pumice. These results will help
in determining the relationship between the Guangala and other contemporaneous cultures and
will shed light on the activities and technology of a relatively unknown society.
INTRODUCTION
The Guangala were an indigenous people who inhabited southwest Ecuador from 200
BC- AD 800 (1). While little information is known about the Guangala, studying their unique
ceramics can lend insights into technology, culture, and their interactions with other ancient
peoples. Archaeologists often pursue provenance studies in order to reach these ends, and in this
study, a particularly puzzling question of provenance with respect to ancient ceramics is
encountered. Namely, the ceramics of the Guangala people (Figures 1, 2) appear to be tempered
with pumaceous ash, and yet geological studies of the area have not identified pumice in the
region where the Guangala lived. This material is present in the volcanically active Ecuadorian
Highlands 249 km from the Guangala region (1). Identifying the source of the pumice found in
Guangala ceramics is the motivation of this provenance study, in which three possibilities for
acquiring the pumice temper will be investigated: trade, direct procurement, and ashfall. Using
optical petrography, the project analyzes Guangala ceramic samples, to be compared with
pumice and ash samples and experimental samples of clay with pumice and ash.
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By attempting to determine the source of the pumice found in ancient Guangala pottery
new information can be offered on the ancient ceramic technology of coastal Ecuadorian people.
In addition, the findings could offer information on trade, economy, and cultural practices of the
ancient Guangala as well as possible relationships between the Guangala and groups from other
geographical regions. The research could also contribute to archaeological methods by
demonstrating the utility of petrographic analysis for studying artifacts and materials. From a
global standpoint, the results of the study could add new comparative information to research
done on other ancient peoples such as the work of Anabel Ford of the University of California at
Santa Barbara on the Mayans in El Pilar, Belize. Ford contends that volcanic ash, a volcaniclastic
material related to pumaceous ash, is present in Mayan pottery and was derived from ashfall
from volcanic eruptions, rather than trade or direct procurement (2). In the present study, Ford’s
hypothesis is tested as one potential explanation for the source of the material in Guangala
ceramics. This case is tested only on a comparative basis, as the case of the Maya and Guangala
are not identical. The research done on the Guangala ceramics could either serve to reinforce
Ford’s hypothesis or serve as a contrasting case if a difference in type of source is found. An analysis of archaeological and experimental samples was undertaken to consider the
likelihood of the three explanations. By comparing type samples of volcanic materials,
experimental ceramic samples made by mixing clay with various pumaceous tempers, and a
sample of archaeological ceramics spanning the Guangala time period, it may be possible to
determine the specific origin of the pumice found in the Guangala ceramics as well as the means
by which it was procured over several centuries. This study leads to the postulation that the
pumice was obtained through trade from the highlands. It is unlikely that the Guangala would
travel to the Highlands to mine the pumice through direct procurement; the mining regions in the
Highlands were inhabited, and these people likewise have been linked to trade with the
Lowlands already, through obsidian. Moreover, the volcanic expulsion model is unlikely as
Figure 1. Guangala masculine figurine
whistle with engraved body decoration and
hammered gold earrings. From the
collection of the Museo del Banco Central
del Ecuador, Guayaquil. (MBCG No. GA
2-2164-82; photograph from Valdez and
Veintimilla 1992: Figure 65). (4)
Figure 2. Guangala polychrome bowl
with geometric decoration. (Private
collection; photograph from Valdez and
Veintimilla 1992: Figure 70). (4)
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pumice would have to reach El Azúcar Valley (Figure 3), where the Guangala inhabited,
regularly enough to account for the abundance of pumice found in ceramics spanning the entirety
of the Guangala time period. Also, this ashfall is unlikely, because of the generally northward
wind patterns in Ecuador (3). In order to test the trade hypothesis, ceramic petrography was used
to compare the experimental samples, whose sources of temper are known, with the
archaeological samples of the Guangala people. By obtaining this information, it will be possible
to further characterize a relatively unknown people who demonstrated a profound knowledge of
ceramic technology. These results will help in uncovering the process used by the Guangala
people to create their pottery and will also help in detailing the environment of El Azúcar Valley
and the trading networks of the region. In addition, knowledge of the ceramic production
methods of the Guangala people may aid other provenance studies in pre-Columbian ceramics,
such as Ford’s investigation of ancient Maya pottery.
Figure 3. Map of Ecuador adapted from Reitz and Masucci, showing the Guangala area of
interest, El Azúcar, and northwestern wind patterns (5).
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BACKGROUND
Geology
The geology of Ecuador itself is the result of a Mesozoic-Tertiary age (250-2.6 mya)
volcanic belt, which formed at the convergence of the oceanic Nazca tectonic plate and the
continental South American plate forming the Andean mountain chain (7). Ecuador contains one
of the most volcanically active zones of Latin America and is an ideal location for finding
volcanic materials. Pyroclastic materials like pumice, however, are concentrated only near the
volcanic zones in the highlands. The geology of El Azúcar Valley within the Santa Elena
Peninsula region, which is the source of the Guangala ceramics in the study, is characterized by
sedimentary materials including chert and sandstone, among which the minerals include varying
quartz, feldspar, and muscovite; neither ash nor pumice is found (7).
El Azúcar Valley is in the lowlands, less than 30 km from the ocean and 25 km south of
the coastal hill range referred to as the Chongon-Colonche hills. The hills expose igneous rocks
of the Pinon and Cayo Formations. The Pinon contains basaltic lavas and phenocrysts such as
plagioclase, augite and Fe-Ti oxides, and the Cayo contains volcanic breccias, tuffs and basaltic
lavas. The Chongon-Colonche hills are composed of volcanic and volcaniclastic rocks, and these
sediments do reach the lower coastal valleys but they are intrusive igneous materials and not
pyroclastic materials such as pumice (8). The presence of these volcaniclastic rocks affects the
clays of El Azúcar Valley, but would not result in the presence of pumice or ash naturally in the
clays. This distinction indicates that pumice would have to be intentionally added from a
separate source. Samples of El Azúcar clays were tested in previous research to confirm the
absence of natural pumice (7).
It is important to make the distinction between the igneous rocks available to the
Guangala people only kilometers away at the Chongon-Colonche hills, and the pumice and ash
in the ceramics. The latter materials would only be available through active volcanic activity, i.e.
ash and phenocrysts ejected and transported by wind, and rock formations found at the base of
the volcano. For example, volcanoes such as Tungurahua have the proper igneous rocks that
would be added to fine pottery, however Tungurahua is greater than 250 km from El Azúcar
Valley (Figure 4). Figure 5 illustrates the ash and pumice deposits of Ecuador in the Qc region.
Figure 4. A map showing the major volcanoes in Ecuador, the closest of which is Tungurahua (6).
El Azúcar
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Figure 5. A geological map of Ecuador. The yellow-brown region labelled Qc represents the
highland region which is a possible locus of trade from which the Guangala may have obtained
the pumice that is widespread throughout their ceramics. The map also shows that pumice
deposits are not local to El Azúcar (8).
Culture
During the Guangala era, the people of Ecuador were going through a phase of regional
development, where each region obtained a unique identity. One way people marked or showed
this identity was through fine paste decorated pottery. The Guangala made some of the most
beautiful and colorfully decorated pottery in Ecuador, creating black “sombreware” and two and
three colored “bichrome” and “polychrome” pottery (1, 9). This pottery was an innovation of the
El Azúcar
Valley
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Guangala, although little is known of how they created their ceramics. Accordingly, this
innovative pottery feature unique to the Guangala disproves the theory that the Guangalan
pottery could have be traded from other sources, e.g. the Highlands, as the ceramic style of the
pottery being studied is unique to the Azúcar region.
The Guangala people inhabited a stretch of the coastal plain of Ecuador which included
El Azúcar Valley, which lies southwest of the present day city of Guayaquil. Numerous
Guangala settlements have been found and excavated in this valley (1) as well as neighboring
valleys (10). Research into Guangala ceramic technology identified possible pumice or
pumaceous ash in the decorated ceramics, but was unable to determine its source (9).
In order to gain a complete sense of the options available to the Guangala in procuring
the pumaceous ash used as a tempering agent in their pottery, it is necessary to detail the
characteristics of their economy. The economy of the Lowlands region was agricultural-based,
but complemented by fishing and hunting practices (5). Crops produced included maize, squash,
and beans. Fisherman were known for their shallow and deepwater shellfish, marine fish and
shark, while hunters commonly brought home deer, armadillos, turtles, and various monkeys.
The Guangala also had domesticated guinea pig. For much of Guangala history, there was a
marked division of labor, with occupational specialization and personal identity based on the
distinctions between being a farmer, fishermen, etc. However, ties were formed between these
different occupational circles through the exchange of foodstuffs. As the different groups went
through natural cycles of production and struggle, they became increasingly dependent on one
another, offering early examples of trade and collaboration in Southwestern Ecuador (5).
During the early years of Guangala society, trade was typically a private affair between
select and prestigious people. Soon, a number of new products and practices made more complex
trade possible, including wooden canoe building and the development of tools such as chisels,
axes, scrapers, and knives. The economy of ancient Ecuador evolved, becoming more complex
and organized, with trading routes linking many different areas (10). These trade routes led to
greater interaction and a flow of ideas between different areas. Evidence exists that obsidian (a
hard, dark, glasslike volcanic rock formed by the rapid solidification of lava without
crystallization) was traded from the Highlands to the Lowlands, including to the Guangala region
(10). It may seem dubious that two societies 250km away would trade, especially without
amenities such as draft animals, however chemical sourcing of obsidian artifacts found in
Guangala sites with obsidian sources in the Highlands prove that trade between these peoples did
happen. Given the obsidian trade demonstrated to have occurred, it seems possible that pumice
could also have accompanied the trade of obsidian from the highlands to the lowlands, especially
since obsidian weighs more than pumice, thereby giving no reason to doubt the viability of trade
of pumice. In addition, pumice is found near sources of obsidian, as they are both the result of
volcanic eruptions. In another instance, it is evident that salt, which can be much heavier than
both pumice and obsidian, was traded by way of canoes and by foot from the Lowlands to the
Highlands (11). This trade opens the possibility that pumice and volcanic ash could have made
the trip down from the Highlands in a similar manner as other products that were transported to
the Highlands. Besides salt, the Lowlands had flint, cotton, cocoa, marine fish, shellfish and
marine shell ornaments to provide the Highlands in exchange for the pumice (11). Based on this
evidence of Guangala trade with the Highlands and the nature and sophistication of the Guangala
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economy, it is possible that pumice was traded from the Highlands to the Lowlands to the
Guangala potters.
Ceramic Technology
Clay contains a very fine lateral crystalline structure which takes on plasticity when
mixed with water and can then be pressed into shapes. In addition, incorporating grains of rock,
salt, organic matter, and other non plastic materials into the clay can serve various purposes,
from color to plasticity to help the forming and firing process of pottery. Thin-walled, fine paste
pottery is particularly difficult to form and fire as, without non-plastics, the objects often shrink
or break in the firing. This occurs because the clay undergoes stages of change after it is put into
the kiln for a firing. First, the water vaporizes and exits the clay, decreasing the plasticity and
making the matrix more porous. Then, the various minerals in the clay chemically react and
oxidize. In the vitrification stage, the matrix hardens, tightens, and the clay partially converts into
glass. These stages occur at different temperature ranges and can occur simultaneously. In this
process a plastic object becomes a hard ceramic (12).
Artificial inclusions, or temper, in the clay matrix prevent excessive shrinking of the
matrix during drying and firing. By making the matrix more porous, it facilitates even drying and
resists cracking in the clay. Volcanic ash materials such as pumice are fine, naturally angular
shaped-materials that provide all the advantages of rock temper to strengthen clay for forming
and firing, but are lightweight and occur naturally in small particle sizes (12).
The use of pumice as a tempering agent is innovative and sophisticated on a technical
level. Its introduction to fine paste pottery by the Guangala appears to have allowed the potters to
create the thin walled decorated pottery, which identifies these people and their culture. Pumice
is advantageous as an added inclusion in the clay matrix because, as a light and airy material, it
will not add weight or thickness to vessels and it is not volatile in low firing temperatures,
thereby enabling the thin-walled pottery characteristic of the Guangala (12).
Comparative Case
The Guangala were not the only ancient culture to discover the properties and advantages
of volcanic ash materials for ceramic technology. The Late Classic Maya of El Salvador traded
volcanic ash for use as a ceramics temper, and were able to transport large quantities of ash
through sea and river routes (13). This provides evidence of long distance trade involving
volcanic ash by civilizations with similar capabilities.
Other research on the Lowland Classic Maya by Anabel Ford has reached a different
conclusion with respect to the source of the ash used in their pottery. Similar to the difficulty
encountered in definitively determining the source of pumice in Guangala ceramics, there is a
question of source with respect to the volcanic ash found in the ceramics of the Lowland Maya.
The material in the Maya ceramics, however, refers more to glass shards than to pumaceous
volcaniclastic material (2).
Anna O. Shepard, using petrographic thin section analysis, first identified the volcanic
ash in the Maya ceramics (12). Ford also has used petrographic studies of Maya ceramics, but
she concludes that the source of the ash is in the Guatemalan Highland volcanic chain. The
ubiquity of ash in the Maya ceramic vessels, combined with the impediments and impracticality
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associated with its long-distance procurement, have led Ford to investigate ashfall as the possible
explanation for the means by which the Maya acquired ash for habitual use in ceramic vessels.
This hypothesis, however, is conditional on the assumption that consistent volcanic activity in
the Guatemala Highlands would have to have occurred in order to account for the ash present in
ceramics spanning the entirety of the Late Classic Period (600-900 AD). Furthermore, the
employment of volcanic ash as a tempering agent in both elite and utilitarian/domestic vessels
strengthens the assumption that volcanic ash was widely available and obtainable across many
social echelons. It is, however, improbable that the nonlocal volcanic ash constituting the
ceramics from the Late Classic Period derived from a single ashfall, as this circumstance would
be inconsistent with the short-term planning paradigm common to most societies.
Several weaknesses in Ford’s model are identified when applied to the Guangala study of
ceramics. In the Guangala study, in contrast to Ford’s hypothesis, trade between the Highlands
and Lowlands is already known for another volcanic material, obsidian, and therefore it may
have transpired for ash and pumice as well. It is important to note that while striking parallels
exist between this provenance study and Ford’s research, the latter is only intended as a means of
comparison rather than as an identical situation. Nonetheless, Ford’s data points on which her
ashfall hypothesis is built are useful for testing against the hypothesis of the present study; that
raw material arrived via trade, not from the sky. For this reason, the characteristics used by Ford
were selected and evaluated in the Guangala archaeological ceramics and experimental samples.
These characteristics are shape, homogeneity, the presence of phenocrysts, and the size of
inclusions, though it must be noted that these characteristics may not necessarily be revealing of
temper source, despite their use as a main support for Ford’s ashfall hypothesis (2). Although
Ford viewed these characteristics as indicative of ashfall, some may also be characteristic of
mined or traded material. This point will be discussed further below in Methods and Results.
MATERIALS AND METHODS
The methodology employed in this study was designed to determine the source of the
pumice found in the pottery of the Guangala people. There are three hypotheses for the source of
the pumice: (i) the ash utilized “fell from the sky” (carried by wind from volcanic eruptions in
the Ecuadorian highlands); (ii) the potters traded for it with the dwellers of the highlands; or (iii)
the vessels were produced in the highlands and traded to El Azúcar. To test these three
hypotheses, the methodology focused first on defining the test implications for each model. For
the first hypothesis, ashfall characteristics defined by Ford and stated by her to be indicative of
ashfall were used and compared with the appearance of inclusions in the Guangala
archaeological ceramic samples. For the second, trade from the highlands, the methodology
focused on examining potential raw materials as well as creating experimental samples with
different pumice and pumice related materials, including materials from the Highlands to
compare their appearance with the appearance of the inclusions in the archaeological samples.
For the third, that the vessels were produced in the Highlands, the conditions for this model (i.e.
pottery color, style and cultural characteristics of the Highlands were present) were evaluated. In
this way, the source of the pumaceous ash could be determined based on which hypothesis had
the support of the data.
Optical petrography of thin sections was used as the primary method to analyze and
examine the characteristics of the rock materials and the inclusions in the experimental samples
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and the archaeological ceramics. This method was introduced to American Archaeology by Anna
O. Shepard and provides insight into the mineralogical and material makeup of ceramics as they
are a type of fired geological material. Petrographic analysis allows pottery to be examined as a
geological material, focusing on mineral and rock fragment content and microstructure (14).
Petrographic microscopes employ polarized light microscopy through the use of polarizing filters
and analyzers and a rotating stage. Minerals also polarize light, and when viewed through this
type of microscope the light rays combine and interfere in unique patterns, revealing the
crystalline structure unique to each particular mineral and rock fragment being viewed. Both
plain polarized light and crossed polarized light were used, as each identifies different
components of the minerals and rock fragments under examination. The use of plain and crossed
polarized light in juxtaposition allows for identification of isotropic vs. anisotropic minerals. For
example, iron is known to be anisotropic, so when a large black or red Figure under the
microscope looks the same under both plain and crossed polarized light, one can confidently
identify the Figure as iron. Furthermore, isotropic minerals, such as pumice, do depend on the
direction of light, and will look different under both light filters.
The first step in our procedures to test the above hypothesis was to establish what pumice
and related pumice-like materials look like in thin section. Previously prepared thin sections of
rock and mineral types were examined, and their general characteristics under polarized and
plain polarized light were noted (Table I). The inclusions in the Guangala ceramics had been
fired and therefore would likely have been altered by the firing process. Therefore, the second
step in our procedures was to create experimental ceramics with known inclusions of pumice and
pumice-like materials.
Table I: A log documenting the mineralogical contents of the type samples examined.
Eight different test material samples were ground individually with a mortar and pestle.
Great care was taken to avoid cross contamination between samples, as this could have caused a
misidentification of materials. The test samples were made using a commercial clay, which did
not naturally contain pumice or ash. A control without any test materials was made to ensure that
neither pumice nor ash was present. Two briquettes were formed from each sample in case one
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was destroyed in the firing, and each set was rolled in one of eight tempers (the human-added
inclusions). Each pair of briquettes was placed in a separate petri dish to prevent contamination.
Furthermore, to permit easy identification of the samples after they were fired, the clay briquettes
were etched with a label. The inclusions were listed in the sample log spreadsheet, along with the
name of the sample, the label used, and notes about the sample.
One clay briquette of each temper and one control briquette were placed in the kiln, a
Barnstead Thermolyne 1300 Furnace. Rapid firing of clay can cause a build-up of steam and
concurrent explosion of clay objects. To avoid this result, a gradual firing schedule was devised;
the kiln was originally set to 100 degrees Celsius, and the briquettes were fired over a two hour
and fifteen minute period. Every fifteen minutes, the temperature was raised 100 degrees Celsius,
culminating with a final temperature of 650 degrees Celsius. The highest temperature was
determined by information on the temperatures for low-fired ancient pottery of the Guangala
which estimates temperatures between 600-800 degrees Celsius (8). The lower temperature range
was selected because industrial clays often contain fluxes that lower the temperature at which
chemical changes occur in firing. Small sections of the briquettes were needed for thin section
(.03mm in size) preparation; therefore, a Ray Tech Jem Saw 45 was used to cut the briquettes
into flat, rectangular sections. The samples were sent to the National Petrographic Service to be
prepared as thin sections, as thin section analysis allows for the identification of minerals and
rock fragments. Preparation standards were requested of impregnation with clear epoxy due to
the friable nature of low fired ceramics and a coverslip to reduce cost and the difficulties of
polishing friable ceramics (Table II).
Table II: A log documenting observations of the experimental samples. The ground pumice
samples from Cotopaxi National Park are labelled C97-1, C97-2, and C97-3; the ground burned
clay sample is labelled “100”; the El Azúcar 2010 ash fall collection from the Tungurahua
volcanic eruption is labelled “Ash Fall”; the ground pumice rock from the Rock Collection is
labelled “Rock Box 40”; and ground pumice found in an excavation is labelled B5-9.
Guangala archeological samples were selected from collections of ceramics from a site in
El Azúcar Valley. Nine of these samples were selected for analysis. Three were sombreware
(black pottery), the Early Guangala fineware, three were bichrome, and three were polychrome,
constituting a representative sampling of Guangala fineware pottery. An iPhone with a Proscope
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Micro Mobile was used to photograph the flat side of each piece of pottery. The samples were
identified in the sample log under the subsection "archaeological samples" (Table III). Thin
sections of each archaeological sample were available and were analyzed under the petrographic
microscope, magnification 40x, with crossed polarized light (xpl) as well as plain polarized light
(ppl) to identify inclusions. Pumice was identified in all of the archaeological samples. Pumice,
as seen in the type samples and also observed in the ceramics, is isotropic black-gray in xpl, but
has a bubbled and vitreous as well as transparent appearance in ppl. Other minerals as well as
voids (pores) could be confused with pumice due to their black-gray color in xpl. Feldspar
exhibits twinning (pieces of feldspar alternately turning black and white as the slide was rotated),
and quartz displays extinction (quartz disappearing from view), when the stage is rotated. Voids
show no change when the stage is rotated.
Eight photographs of the field of view with pumice for each sample were taken using an
Apple iPad (with a styrofoam eyepiece adaptor): two under ppl with 40x, two under xpl with 40x,
two under ppl with 100x, and two under xpl with 100x. In addition, the pumice fragments once
identified were analyzed for the presence of phenocrysts or volcanic crystals, which according to
Ford were present in the volcanic ashfall she identified in Maya ceramics. Attributes of
appearance, shape, size, density, and presence or absence of phenocrysts for the pumice
inclusions were documented in the sample log spreadsheet, for purposes of relative
compositional analysis (Table III). On this basis, the pumice inclusions in the experimental
samples (where the source of the temper was known) could be compared to those in the
archeological samples to establish or eliminate possible sources of the pumice found in Guangala
ceramics.
A similar procedure was followed for examining and recording the test tempers in the
experimental fired clay samples in order to allow comparison and help verify the identity of the
materials in the archaeological samples. Attributes recorded were limited, however, to
appearance, shape, and presence or absence of phenocrysts because we did not control for the
size or density of the test materials when they were added to the industrial clay.
The final step in the procedure was to compare the attributes of the pumice inclusions
identified and analyzed in the archaeological ceramics with the attributes of the raw materials in
thin section and the attributes of the test tempers in the experimental clay briquettes. The
attributes in the archaeological samples were also compared with characteristics defined by Ford
in order to allow us to test the ashfall hypothesis. The data recorded on inclusions is summarized
in Table III and discussed below.
RESULTS
The archaeological and experimental samples provided a window into the composition of
Guangala ceramics. All nine archaeological samples contained inclusions of pumice (Table III,
Figure 6). All of these inclusions were identified as pumice based on their isotropy and their
vacuous appearance with small black “bubbles” which is a part of their larger volcanic “flow
structure”; this flow structure is exemplified in Figure 9. Pumice stone itself is characteristic of
“flow structure”, yet flow structure is not necessarily indicative of pumice stone. Figure 10
juxtaposes both pumice stone and the burnt clay, both of which demonstrate macroscopic flow
structure; notwithstanding, burnt clay proved to be incompatible with the Guangalan temper
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because even though microscopically the burnt clay did demonstrate a flow structure, it was not
parallel with the pumice’s and it also was anisotropic.
Table III: A log documenting the characteristics of the archaeological samples as a means of
testing against the ashfall hypothesis
All pumice inclusions were evenly spaced, which is also known as “well sorted”,
throughout the ceramic paste. Nine of the samples had a pumice density between 0-10%, while
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one had a density of 10-15%. In addition, while the pumice inclusions in the archaeological
samples were of variable shapes, mainly subrounded and subangular, the sizes remained fairly
consistent, averaging approximately 0.02 mm, (Figure 6). Phenocrysts were present in a minority
of the observed inclusions but this was not a common characteristic of the pumice inclusions in
the archaeological samples. The material identified in the archaeological samples as pumice or
pumaceous ash is a very distinctive material. Pumice is formed from the rapid cooling of gas
filled lava. Pumice can be exploded from the volcano or form in beds near a volcano. The
materials which travel in the air and are exploded from a volcano can include pumice but also
can include a range of “pyroclastic” or exploded molten materials (e.g., crystals of different
compositions or phenocrysts, glass shards or ash; 15).
Figure 6. Archaeological samples imaged using optical petrography. Images represent thin
sections of Guangala ceramics with inclusions of pumice. (ppl, 1.6mm field of view at 100x)
Looking at the experimental samples (Table II, Figure 7), the first observation was that
the control contained inclusions of mica, which can make it difficult to distinguish inclusions due
to the bright colors of the mica under the petrographic microscope. A non-mica industrial clay
would have been easier to analyze. After careful examination it was determined that the control
sample, and therefore, the industrial clay, did not contain pumice. The scoria sample contained
iron-rich glass, which indicates that the scoria vitrified during the firing process and it did not
have any characteristics which would make it appear to be pumice or pumice-like even though in
hand-specimen it has a bubbly, vesicular appearance. The three pumice samples from Cotopaxi
National Park underwent the vitrification process during the firing process, but only fused with
the clay and were still visible as pumice-like, bubbly with a vesicular appearance. All three
samples under the microscope contained identifiable pumice inclusions that were angular and
subangular, and were all relatively large when compared to the inclusions in the archaeological
samples (>0.02 mm, Figure 7).
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Figure 7. Experimental samples imaged using optical petrography. Left image represents a thin
section of ashfall-tempered industrial clay. Right image represents a thin section of industrial
clay tempered with pumice from Cotopaxi National Park. (ppl, 1.2mm field of view at 100x)
Figure 8, however, images how pumice can completely vitrify within the firing process.
This experimental sample illustrates the flat, glass appearance that some phenocrysts can take,
and even though we know it was originally pumice, the image is not indicative of pumice. The
burnt piece of mud-brick, although it looked like pumice in hand specimen due to its bubbly,
vesicular appearance, did not contain any pumice-like inclusions in the fired experimental clay
thin section and instead appeared brown and vitrified in the industrial clay. The sample with
ashfall which was collected after “falling from the sky” in El Azúcar after travelling from
Tungurahua, a volcano in Ecuador, appeared to be the most promising. However, close
observation of this sample in the fired experimental clay thin section revealed that there was no
evidence of pumice in the sample and instead there were only pieces of gray clay (Figure 7). It
appears that the material as noted in the thin section which was made of this material is primarily
glassy ash fragments and phenocrysts but no bubbly, vesicular material is present. The rock
which had been identified as pumice in a reference collection from GeoScience Industries called
“Rocks, Minerals, and Gemstones” fused with the clay and appeared angular in the sample and
did not have the vesicular, bubbly appearance typical of pumice. Finally, a fragment of vesicular
like material which could have been pumice found in the Guangala excavation also fused with
the clay and did not appear like the material in the archaeological samples.
Figure 8. Experimental sample imaged using optical petrography. Image represents vitrification
of pumice. (ppl, 1.6mm field of view at 100x)
[6-15]
Figure 9: Experimental sample made by Dr. Masucci of Ecuadorian clay and added pumice. (ppl,
3.0 mm field of view at 40x)
Figure 10: Macroscopic images of pumice stone (on the top) and burnt clay (on the bottom), by
hand lens.
DISCUSSION
Comparison and analysis of the type, archaeological, and experimental samples reveals a
number of insights into the characteristics of Guangala pottery and furthers understanding of the
source of the pumice inclusions.
The experimental sample with “ashfall” temper (the material which fell from the sky in
El Azúcar in 2010 from the Tungurahua volcanic eruption) contained no pumice or material with
a vesicular, bubbly appearance, while the archaeological samples all contained pumice (Figure 7).
The ashfall consisted primarily of glass and glass shards with occasional phenocrysts such as
biotite (15). This decreases the possibility of ashfall as a viable option to explain the pumice
inclusions in Guangala pottery. Had ashfall been a source of the archaeological temper material,
the sample collected should have had at least some fragments of pumice. Also, the material in the
ceramics is only pumice, not pumice mixed with other pyroclastic materials, and therefore the
ashfall would have had to be “pure pumice.” This decreases the likelihood of Ford’s hypothesis
[6-16]
as a viable explanation for the pumice temper in Guangala ceramics and opens the door for
alternative hypotheses such as trade.
Pumice fragments found in the Ecuadorian pots were of a relatively consistent small size
and similar shape with only extremely small and rare phenocrysts. This clear pattern of size and
shape within the different archaeological samples indicates a consistent and similar source of
pumice with similar physical properties. This would argue for consistent trade with Highland
pumice sources which would facilitate such consistent material size, shape and nature as
observed in the archaeological samples. Of course the consistent size is most likely due to the
potters’ preparation and selection of a size range but the consistency of the type of material could
not be selected out of a mixed source such as an ashfall.
The industrial clay used in the project and the clay used by the Ecuadorians were
different, as was the firing process. These factors could have accounted for the vitrification
observed in some of the experimental samples including the fusing of inclusions to the clay.
Chemical interactions due to the chemistry of the industrial clay and the use of a modern kiln
could have affected the inclusions differently than those of an open pit firing and the Ecuadorian
clays used by the Guangala potters. The different tools used in the crushing of the pumice could
have been a factor as well. Regardless, the closest match to the archaeological pumice tempers
and our experimental test types both as a raw material in thin section and fired in an industrial
clay and observed as thin section were the highland pumice samples from Cotopaxi National
Park. Ground commercial pumice added to an Ecuadorian clay from previous research is also a
close match.
Future studies should include the origin of the use of pumice in the Guangala pottery which
could help further the study of its source. It is possible that migrations of highland peoples
fleeing volcanic eruptions might have brought use of highland materials to the lowland cultures.
In addition, continued investigation into former trade routes of other goods which existed
between Highland and Lowland communities could open the door for understanding the
exchange of pumice.
CONCLUSION
The Guangala was a group of people that lived hundreds of years ago in southwest
Ecuador. Although not much is known about the ancient civilization, most archaeologists believe
their use of pottery technology was very advanced compared to other pottery technology used by
similar civilizations during this time period. The use of pumice as a temper to make very thin,
finely decorated pottery is one of their technological innovations. However, the lowlands in
which the Guangala people lived showed no abundant source of pumice. The only possibilities
that may explain as to how there was pumice is if the pumice was transported through ash fall
from highland volcanoes or if the pumice was traded with the people from the highlands. The
contemporaneous people living in the highlands did not produce pottery similar to that of the
Guangala and therefore it is unlikely that they produced Guangala pottery to be traded. Because
the origin of the pumice is unknown, the goal of the project was to try and determine the source
of the pumice. The experiment included eight different substances that could potentially have
been the pumice used by the ancient Guangala. Industrial clay was mixed with each substance,
and fired to a specific temperature to mimic how the Guangala made their pottery. These
[6-17]
materials were then compared with the pumice in the archaeological samples using thin section
petrography.
The project’s results showed that out of the eight experimental tempers tested, only four
were pumice or contained pumice. Three of the four experimental samples came from an
extensive pumice deposit in Cotopaxi National Park; the pumice looked very similar to the
pumice used in the Guangala pottery. This material is ancient and would have been available to
ancient inhabitants of the highlands contemporaneous with the Guangala. However, there were
some differences. Although there was pumice, all three samples included subangular-looking
pumice, while the actual pumice from the ancient pottery was more subrounded. The pumice
shape was very different. The pumice in the experimental fired clay also seemed to have melted
into the clay during the firing, while the actual Guangala pumice was not. The clay used in the
experiment is not, however, the same clay used by the Guangala people, which may have skewed
the results. Further research in this area should mimic exact temperatures for the firing of the
clay and the temper while also using attempting to use a clay local to the Guangala area. Ford examined one explanation, claiming that the ash used in Maya ceramics “fell from
the sky”; the hypothesis encompasses the possibility that wind currents carry ash clouds from
volcanic eruptions to coastal areas. The 2010 Tungurahua volcano eruption in El Azúcar
produced an ash fall that could have carried pumice particles to the Guangala area. The ash was
tested during this experiment to see if any pumice was found; there were none, demonstrating
that it is highly unlikely that the pumice came from the sky. The most plausible possibility as to
where the pumice could have been obtained is trade.
ACKNOWLEDGMENTS
We would like to thank Dr. Maria Masucci, Dr. Adam Cassano, Dr. Steve Surace, Anna Mae
Dinio-Bloch, Janet Quinn, New Jersey Governor’s School in the Sciences and Drew University.
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