Introduction

The role of marine and coastal diets in human adaptation has been increasingly emphasized in recent years. Consumption of marine resources among early anatomically modern humans in Africa is one of the traits commonly associated with the emergence of modern behavior (Marean et al. 2007; McBrearty and Brooks 2000). Others argue that some reliance on shellfish exploitation can already be observed in Neanderthal adaptive strategies (Cortés-Sánchez et al. 2011; Hardy and Moncel 2011) and that submersion of Pleistocene coastal sites may significantly bias our views on the exact role played by coastal resources in early hominin adaptations (Bailey and Flemming 2008). Independently of early uses of marine environments, the current archaeological evidence in several continents attests to a clear shift during the Holocene with intensified exploitation of coastal and estuarine resources (Andersen 2000; Bailey and Milner 2002; Balbo et al. 2011; Habu et al. 2011; Lombardo et al. 2013; Sandweiss et al. 1998; Waselkov 1987). In Europe, large Mesolithic shell middens and mounds are widespread along coastal and paleoestuarine margins, with increased population dependence on marine diets evident by the high δ15N values of Mesolithic individuals (Milner et al. 2007; Peyroteo Stjerna 2016; Richards and Hedges 1999; Richards and Schulting 2006; Richards et al. 2003).

Although increased evidence for shellfish consumption is now available, archaeological data on human shellfish processing behaviors is still lacking. Humans can directly ingest raw shellfish, and, indeed even today, there are several examples of consumption of uncooked mollusks. Ethnographic and ethnohistoric descriptions provide examples of raw opening of bivalves by cracking uncooked shells or using broken shells as knifes to prompt open the closed valves (e.g., McGee and Hewitt 1898 cited in Waselkov 1987). However, heat-processed mollusks are recognized to yield higher caloric values and decrease dietary risks. One of the main challenges is how to identify shellfish cooking activities in the archaeological record. Most ethnographic observations of shellfish gatherers do show the prevalence of some sort of processing through cooking (namely roasting or boiling). By exposing the fresh shellfish to heat, mollusk valves open easily, hence quickly providing access to the edible portion of the mollusk. Since either roasting or boiling entails the preparation of several specimens at once, cooking is also a substantially more cost efficient way of processing shellfish than the time consuming task of cracking each valve individually (Waselkov 1987). Questions regarding the time frame in which mollusk cooking practices started to be commonly employed by humans and differences in cooking techniques in various archaeological contexts are of great importance to our understanding of human subsistence practice and adaptation. Yet in order to answer such questions, we first need to be able to identify mollusk cooking practices in the archaeological record.

One cooking technique is boiling, which employs some type of water retaining recipient, typically ceramic containers, though other perishable materials, such as animal skins or baskets, can be used (Speth 2015). Through boiling, the shellfish is not in direct contact with fire and relatively low temperatures just above the boiling point (100 °C) are enough to cook them. Another widespread cooking technique is roasting. Direct roasting of shellfish on fires without the resource of containers is commonly described ethnographically and arguably a better analogue for pre-ceramic communities such as those from Mesolithic Europe. Several ethnographic observations report on techniques of roasting/grilling, which can be subdivided into three main types: (1) cooking directly above hot fires by placing shellfish on top of embers or ashes; (2) using shallow depressions and heated rocks in earth ovens; or (3) by roasting shellfish underneath short-lived fires (Meehan 1977; Meehan 1982; Speth 2015; Thoms 2008; Waselkov 1987). In her detailed ethnographic study, for instance, Meehan describes the expedient technology used by the Anbarra Australian aborigines to cook shellfish underneath fires:

“A clean area of sand (…) is selected, cleared of rubbish and made smooth. The shells are then stacked carefully against each other with their lips in the sand, hinges uppermost. (…) Small sticks and dead grass are placed on top of this phalanx of shells and ignited. (…) These fires are designed to be fast and hot and usually burn for a few minutes only. Sizzling and ‘plopping’ noises indicate that the shells are open and that the ‘milk’ or juices are escaping. What is left of the fire is immediately removed and the uppermost parts of the shells are swept clean with a bunch of fresh green leaves. The shells are then removed from their cooking position, placed on a pile of fresh green leaves until they cool, and are then eaten. A few shells usually get tossed around the hearth but they are normally left for the time being in discrete piles where they have been consumed, many pairs of valves remaining attached by gristle.” (Meehan 1982 p. 86–87).

These fires were often done directly in the beach near the collecting sites (Meehan 1982). What seems to be characteristic from such ethnographic and ethnohistoric observations is the ephemeral duration of such cooking events, often lasting just a few minutes and requiring little preparation of the cooking area (Waselkov 1987). We can question, therefore, what would be the archaeological visibility of such expedient procedures, even if they were performed at the main habitation site. One expected evidence would be visual and/or compositional alteration of burned shells. Depending on the temperature range and degree of shell surface exposure to fire, thermal alteration can result in visible physical (crazing, cracking, etc.) and color modifications (d’Errico et al. 2013; Godino et al. 2011; March 1999a; March et al. 2014; Villagran 2014a; Villagran et al. 2011a). More pronounce changes can occur at the molecular level due to temperature induced mineralogical transformations of calcium carbonate polymorphs (Gaffey et al. 1991; Toffolo and Boaretto 2014; Weiner 2010; Yoshioka and Kitano 1985). Such transformation depends on the original bivalve shell mineralogy, which is most commonly aragonite, with some species having calcite or a mixture of calcite and aragonite in their shells (Addadi et al. 2006; Lowenstam and Weiner 1989; Weiner 2010). Since aragonite is metastable at earth surface pressures, aragonite to calcite transformation can be a useful proxy to reconstruct temperatures of archaeological hearth contexts (Godino et al. 2011; Mentzer 2014; Villagran 2014a). Another possible evidence for shellfish cooking would be the identification of sediments and artifact dispersion produced by these activities. Previous studies have investigated the effects of heating shellfish and experimental fires in shell midden contexts (e.g., March 1999a; March et al. 2014; Villagran 2014a, 2014b; Villagran et al. 2011a), yet our understanding of the microstratigraphic signatures (depositional and taphonomic) of shellfish roasting activities is still limited.

Here, we report on a series of experimental fires targeting shellfish roasting activities and controlled heating of selected mollusks, specifically, the common cockle (Cerastoderma edule) and peppery furrow (Scrapularia plana). Field cooking experiments were complemented by soil micromorphology, Fourier transform infrared spectroscopy (FTIR), X-ray diffraction (XRD), thermogravimetric analysis (TGA), and charcoal analyses. The goals of this paper can be described as twofold: on one hand to gather data on temperatures reached during shellfish roasting procedures and their possible impact on the threshold for mineral transformation of CaCO3 polymorphs (aragonite > calcite) in biogenic valves, and, on the other hand, to explore the microstratigraphic and discard signatures associated with shellfish roasting in pre-pottery contexts. These experiments add to the growing research on microarchaeological experimentation references and explore the role of sediments and taphonomic analyses to address past human behavior.

Materials and methods

Experimental design

As mentioned above, for the experiments reported here, we selected two types of shellfish: the common cockle (from here onwards designated as cockle) and peppery furrow, since both bivalve species have shells exclusively composed by aragonite (Peacock 2009; Santos et al. 2012)—see also SI for XRD analyses of specimens used in the current study. Both species are commonly exploited in prehistoric and historic contexts, namely in European Mesolithic sites (Andersen 1989; Diniz and Arias 2012; Gutiérrez-Zugasti et al. 2011; Peacock 2009), and, in particular, in the Portuguese Mesolithic shell mounds (Aldeias and Bicho 2016) where one of the authors (VA) is currently conducting geoarchaeological oriented research. In order to address the microarchaeological signatures of shellfish roasting activities, we have conducted both controlled heating of individual shells in a muffle and experiments with several ways of cooking using wood-fueled fires.

Controlled muffle experiments—for these experiments, a total of 56 individual fresh shells of cockle and peppery furrow were heated at several temperatures as shown in Table 1. The muffle was set to the desired temperature and, once that temperature was reached, ceramic crucibles containing the samples were placed inside and left for durations of either 5 or 20 min. The heated crucibles were then taken out and the heated shellfish specimens wrapped in foil. These heating times were chosen to mimic two extremes: a duration of 5 min at temperatures normally reached during wood fires is sufficient to open the bivalves and cook the flesh, whereas longer exposures of 20 min often result on the burning of the mollusks making them uneatable (i.e., burned). Note that near the threshold for mineral transformation, smaller temperature intervals of 50 °C and only short heating times (5 min) were applied in order to investigate the exact threshold associated with aragonite-calcite transformation for each shellfish type (Table 1).

Table 1 Macroscopic and FTIR (transmission and ATR) mineral transformations of peppery furrow and cockle shells from controlled muffle experiments heated for 5 min at different temperatures

Fire cooking experiments—the goal of these experimentations was to investigate microstratigraphic signatures and mineralogical changes produced through different ways of roasting shellfish without the use of containers. We used three main experimental settings (see Fig. 1 and Table 2 for details), all of which employed Pinus pinaster wood or needles as fuel (see below). Experimental names are designated by the letter “C” for pebble cuvette type of experiments, “Fa” for experiments with fire above the shellfish, and “Fb” for the experiment with fire bellow the shellfish; each of these designations are followed by a sequential number and the type of shellfish used is indicated in parenthesis (either cockle or peppery furrow, Ck and PF respectively). Therefore, experiment Fa1 (Ck) corresponds to the first experiment with fire above using cockles.

Fig. 1
figure 1

Summary of the field cooking experiments performed and associated human actions involved for each experimental subtype

Table 2 Summary of results from the fire cooking experiments

Experimental fires with a pebble cuvette were conducted by excavating a shallow basin-depression (on average ∼ 15 cm deep at its center) that was subsequently coated with quartzite and quartz pebbles. A fire was then lit on top of the pebbles and was left to burn for some time (see Table 2). Once the flame reduced, we removed all the fire residues (embers, ashes, and charcoals) and added the shellfish directly on top of the now hot stones. In one experiment, C1 (Ck), the shellfish was immediately covered with sand, creating an anaerobic environment, and left cooking for 35 min. This experiment was performed only once since the shellfish cooked this way were covered in sand and hardly edible. In all other pebble cuvette experiments (C2 and C3), the shellfish were cooked in aerobic environment by lightly covering the surface of the cuvette structure surface with animal skins. A total of six pebble cuvette repetitions were done, and, on average, the shellfish were left inside this structure for 11 min. This cooking technique can be described as an earth stone oven, and similar types of cook stone technology are described ethnographically (see, for instance, Thoms 2008).

The experiment performed with fire below (Fb) was conducted by lighting a pine fuel fire and let it reduce to embers. Once no more flames were observed, the charcoal and smoldering wood logs were gently spread out in order to create a small contained area in the center of the fire to which cockles were added directly on top of the hot embers and ash (Fig. 1). After 20 min, one could directly collect the shells and eat the mollusks. A similar type of cooking was described to be routinely used by indigenous societies in North and South America (Waselkov 1987 and references cited therein).

Finally, several experiments were conducted with fire above (Fa). These experiments were performed by first organizing the shellfish on a surface with their umbos down (which minimizes the fall of the overlying fire residues when the bivalve opens, and follows ethnographic descriptions done by Meehan 1977, 1982). Subsequently, fuel was added to the top of the shellfish and the fire was lit. Fire events tended to be fast, lasting between 3 and 17 min. For these experiments, we used three different types of fuels: small pine wood twigs and logs (experimental subtypes Fa1 and Fa2), pine needles (Fa3 and Fa4), and hot embers relocated to the top of the mollusks from a nearby pine wood fire (Fa5 and Fa6). These experiments (each repeated at least two times) follow roasting shellfish techniques similar to the ones of Aboriginal Australian communities describes by Meehan (1977, 1982).

During all of the experimental events, temperatures were systematically recorded at 1-min intervals with a PCE-T390 contact thermometer device attached to several k-type thermocouple probes (B+B Thermo-Technik GmbH, Donaueschingen, Germany). For the pebble cuvette experiments, probes were positioned at three locations: directly underneath the base of the pebbles; in the center of the cuvette on top of the pebbles; at the center of the fire itself (that is, few cm above the pebbles surface) and, once the fire residues were taken out, this same probe was positioned at the center of the shellfish being cooked. In the fire above and fire below experiments, probes recorded the temperatures at three locations: the center of the shells (placed on the ground between the shells), directly on the fire itself (placed on top of the shells), and ∼2 cm below the surface.

Sampling strategy and analytical methods

Sampling strategy

After each fire cooking experiment, we collected several samples for laboratory analyses, namely cooked shells, bulk samples of charcoal and ashes. Intact blocks of sediments were collected from the center of some of the experimental fires for soil micromorphology analysis (see below).

Analytical methods

Fourier transform infrared spectrometry

Infrared analyses were carried out in order to determine the mineralogical composition of shellfish and evaluate aragonite to calcite transformation due to exposure to high temperatures at ambient pressures (Jamieson 1953; Johannes and Puhan 1971; Yoshioka and Kitano 1985). Three shells were randomly selected from each type of fire cooking experiment. From the controlled muffle experiments, one shell from each species was analyzed from the different heating durations and temperatures performed. Infrared measurements were collected in transmission (FTIR) and attenuated total reflection (FTIR-ATR) mode. For transmission mode, about 0.3 mg of sample was homogenized in an agate mortar and pestle, then mixed with ∼40 mg of IR grade KBr powder and pressed into a pellet using a manual hydraulic press (Wasserman). Spectra were recorded in transmission mode with an Agilent 660 FTIR Spectrometer (Agilent Technologies) with a DTGS detector, at 4 cm−1 resolution and averaging of 32 scans between 4000 and 400 cm−1 using Resolution Pro software (Agilent Technologies). Spectra obtained from FTIR-ATR mode were performed on ground samples using an Agilent 660 FTIR Spectrometer (Agilent Technologies) fitted with a detachable accessory GladiATR™ (Pike Technologies) with a diamond crystal. Spectra were recorded at 4 cm−1 resolution and averaging of 32 scans between 4000 and 400 cm−1. The obtained spectra were evaluated and compared with reference publications and libraries (Lafuente et al. 2015; Weiner 2010).

X-ray powder diffraction

XRD analyses were carried out to determine the mineralogical composition of the two shellfish species and confirm that they were composed exclusively of aragonite. XRD patterns were recorded on a STOE STADI MP diffractometer (STOE&Cie GmbH) at room temperature using Cu − Kα1 radiation (emission wavelength 1.54059 Å).

Thermogravimetric analysis

TGA analysis was conducted on fresh shells of cockle and peppery furrow in order to determine the organic fraction through weight loss in the shell matrix. The shells were ground, placed in sealed aluminum crucible, and measured in a Netzsch F1 (Phoenix Netzsch-Gerätebau GmbH) with the following conditions: air flow (30 mL/min) with heating rates of 10 K/min up to 800 °C. For the buoyancy correction, a baseline was recorded using roughly 40 mg of dry Al2O3 and subtracted from the sample measurements. Experiments were performed in triplicate sequentially in a room with 56 % relative humidity.

Soil Micromorphology—intact blocks for soil micromorphology analyses were collected from the fire above and fire below field cooking experimentations. Given the large size of the components and removal of fire residue procedures, it was impractical to collect micromorphology samples from the center of pebble cuvette experiments. It is also important to note that in order to process these samples, we had to remove the organic flesh of the mollusks. The empty shells were then repositioned on the surface sediments, which implied movement from the original cooking placement. Consequently, no interpretations based on shell orientations or imbrications are made based on thin section analyses. The sampled sediment blocks were wrapped with soft paper and carefully tightened using plastic tape. Thin section preparation was performed by Spectrum Petrographics (Vancouver, WA, USA) by oven drying the samples for several days and then impregnating them with epoxy mixed with styrene and a catalyst. The indurated blocks were then cut, mounted to a 5 × 7.5 cm glass, and grinded to a standard thickness of 30 μm. In addition, Spectrum Petrographics also prepared smaller-sized 2.7 × 4.6-cm thin sections for individual shells heated in the controlled muffle experiments. All thin sections were analyzed under plane- and cross-polarized light (PPL and XPL, respectively) using an Olympus BX51 petrographic microscope at magnifications ranging from ×20 to ×400.

Charcoal analyses—analyses of wood charcoal focused on taphonomic alterations during the combustion of P. pinaster fuel in the fire cooking experiments. Samples were recovered by hand-picking charcoal fragments after each cooking event. A total of 50 charcoals were examined by randomly selecting five fragments from pebble cuvette (C1 and C2), fire below (Fb), fire above with pine wood (Fa1 and Fa2), and fire above with pine embers fuels (Fa5 and Fa6). The combustion of pine needles does not produce suitable samples, and this experiment was therefore excluded from these analyses. Analyses of the conserved cellular structure and identification of taphonomic alterations were performed by examining each fragment under a microscope (Leica DM 2500 P) at ×100 and ×200 magnifications. Transversal (T), longitudinal radial (R), and longitudinal tangential (Tg) sections were observed for each fragment and all the alterations observed recorded.

Results

Controlled muffle experiments—visual and structural changes

A summary of the visual and mineral transformations from the controlled muffle heated shells is shown in Table 1. Results of thin section analyses of selected heated shells are shown in Fig. 2. For both species, obvious alterations are visible at 550 °C, even after very short heating episodes of 5 min. These microscopic alterations are seen in the change from high birefringence (3rd order interference) colors associated with aragonite to duller interference colors, which are mineralogically associated with the complete transformation to calcite (see below). At higher temperatures of 700 °C, the shells tend to present several macro and microscopic vertical cracks as well as parallel fissures. The latter tend to be well developed for the thinner peppery furrow specimens (Fig. 2).

Fig. 2
figure 2

Photomicrographs of muffle heated cockles (Ck) and peppery furrow (PF) at different temperatures (100, 550, and 700 °C) and heating durations (5 and 20 min). Left: microphotographs in PPL, scale is 1 mm; middle: microphotographs in XPL, scale is 1 mm; and right: detailed microphotographs in XPL, scale is 200 μm. Note that at 100 °C, both species have aragonitic shells expressed by extremely high birefringence even after 20 min. Duller interference colors are seen at temperatures of 550 °C, and at 700 °C several cracks are developed in cockles (yellow arrows) and common fissures in peppery furrow specimens (red arrows)

Since no differences were observed between mineral transformations related to heating durations of 5 versus 20 min, only the FTIR spectra associated with 5-min durations are presented here. Figure 3 also provides a comparison of spectra from FTIR transmission and FTIR-ATR, showing that these two collection modes produce similar results. Only a peak distortion and shift are observed for the FTIR-ATR spectra when compared with transmission spectra.

Fig. 3
figure 3

Comparison between FTIR spectra of controlled muffle experiments for both shellfish types (cockles and peppery furrow), using FTIR transmission and ATR collection modes. (a, b) FTIR transmission spectra of cockle and peppery furrow shells; (c, d) FTIR-ATR spectra cockle and peppery furrow shells. Unheated samples present the major absorption peaks for aragonite: 1475 cm−1, 1082 cm−1, 860 cm−1 and the doublet at 714 and 700 cm−1 (respectively, at 1465 cm−1, 1082 cm−1, 856 and 712 and 700 cm−1 in ATR). With heating the transformation of aragonite to calcite is visible by the appearance of the major absorptions peaks for calcite, specifically at 1427 cm−1, 876 cm−1, and 714 cm−1 (respectively, at 1405 cm−1, 874 cm−1, and 712 cm−1 in ATR)

In respect to mineralogical transformations, results from unheated shells present FTIR spectra of aragonitic calcium carbonate (CaCO3) similar to published data (Llave et al. 2006; Loftus et al. 2015; Weiner 2010). Despite some inconsistency in the literature on the exact positioning of aragonite and calcite peaks obtained by conventional FTIR methods (see, for instance, Andersen and Brecevic 1991), both FTIR spectra of the unheated samples present the typical vibrational modes of the C-O band of carbonate ion (CO32−) for aragonite: the ν3 asymmetric stretch at 1475 cm−1, the ν1 symmetric stretch at 1082 cm−1, the ν2 out of plane bending at 860 cm−1 and the ν4 in plane bending doublet at 714 and 700 cm−1 (respectively, at 1465 cm−1, 1082 cm−1, 856 and 712 and 700 cm−1 in ATR). With heating, the transformation of aragonite to calcite is visible by the appearance of the peak at 876 cm−1 (the ν2 out of plane bending for calcite) and the broadness of the peak at 1475 cm−1—a stage designated here as “aragonite transforming to calcite”. This transformation starts at different temperatures in the analyzed shells, specifically around 250 °C for cockle and around 350 °C for peppery furrow. Complete transformation to calcite occurs at 500 °C for cockle and 400 °C for peppery furrow, identified by the present of only the typical vibrational modes of the C-O band of carbonate ion (CO32−) for calcite: the ν3 asymmetric stretch at 1427 cm−1, the ν2 out of plane bending at 876 cm−1, and the ν4 in plane bending at 714 cm−1 (respectively, at 1405 cm−1, 874 cm−1, and 712 cm−1 in ATR).

It is interesting, therefore, to note that for cockles the transformation of aragonite into calcite starts at a lower temperature, but the complete transformation to pure calcite also takes longer to occur when compared to peppery furrow. Cockles heated to 450 °C present all the characteristics calcite peaks, but traces of aragonite are still visible by the presence of the additional peak at 860 cm−1 (in a stage designated here as “calcite with traces of aragonite”), whereas peppery furrow shows already a complete transformation to calcite at the same temperature (Fig. 3). At 900 °C, a peak at 3640 cm−1 for both shellfish is also visible (see supplementary information). This peak can be attributed to the O-H stretching of calcium hydroxide (Ca(OH)2), produced by the heating of calcite that transformed into quicklime (CaO) and CO2, which afterwards reacts with atmospheric moisture to form calcite and calcium hydroxide, Ca(OH)2 (Toffolo and Boaretto 2014).

Fire cooking experiments

Roasting shellfish: temperatures and charcoal analyses

Table 2 summarizes temperature values, durations of heating, and results of shell mineralogy from our field cooking experiments with roasting shellfish. Temperature changes associated with the three main types of experiments are illustrated in Fig. 4—all other temperature readings and charcoal analyses summary are available in the Supplementary Information.

Fig. 4
figure 4

Temperatures reached during field cooking experiments: a in a pebble cuvette experiment; b in the fire below experiment (no temperature reading available for the substrate underneath the fire); c, d with pine wood fuel and pine needles fueled fire above

Since our experimentation protocol was more actualistic in nature than highly controlled experimentation (see discussion in Lin et al. 2016), there is considerable variation in temperatures, even in repetitions of the same experimental type. It should be made clear that our goal with these repetitions was not to exactly replicate the same experimental setting but instead provide some degree of variation for each type of cooking events. Consequently, the range of experimental durations and temperatures achieved result from dependent variables not being maintained constant (such as input temperature variations within each wood fire, or amount of time the fuel was left to burn, etc.).

Overall, and despite fire temperature fluctuations, readings of the thermocouples positioned at the base of the shellfish being cooked never reach values above 170 °C, with average maximum temperatures around the 95 °C (Table 2). The experiments with pebble cuvette systematically reached the highest and stable cooking temperatures, whereas the fast fires kindled with pine needles and embers had the lowest registered cooking temperatures at the base of the shellfish. Interestingly, it is in the fire below and fire above experiments that we observed macroscopic alterations of some shells, with brown to black colored domains and occasional fractures, namely in the uppermost exposed area of the shells’ umbos section. Such modification seems to result from localized hot spots where the shellfish was in direct contact with flames. For instance, particularly in the experiments where pine wood fuel was used (Fa1 and Fa2), it was hard to maintain homogeneous temperatures throughout the entire shellfish surface, and in some areas, the direct contact with embers and burning wood was more accentuated than in others. It is important to note that temperature of the fires, which was in contact with the shells, was high enough to reach the threshold for aragonite to calcite transformation, and this has important implications for shell mineralogical transformations as it will be discussed below. In the pebble cuvette fires, the shellfish were not in direct contact with fire, rather they were roasted on top of hot quartzite and quartz pebbles. Macroscopic color alterations were not observed in these shells, whereas the underlying pebbles did show significant color alterations, with a few pebbles fracturing with each experimental run (Fig. 5). In experiment C2 (Ck), we can observe that the pebble’s surface reached a maximum temperature of 647 °C in response to fire temperatures commonly above 700 °C (Fig. 4a).

Fig. 5
figure 5

Macroscopic alteration of pebbles and shells during field cooking experiments: a general and b detailed view of a pebble cuvette where color modifications and two fire-cracked pebbles are visible (red arrows). Note also the remnants of fire residues between the pebbles (white ashes and charcoals); c thermal alteration of peppery furrow shells after a fire above experiment fueled with pine wood with darkening of part of the shells and occasional fractures, the latter are preferentially present in the uppermost sections of the shells (yellow arrows); d thermal alteration, namely darkening and some “flaking,” of cockle shells after a fire above experiments fueled with pine needles

In terms of the amount of thermal alteration expected in the subsurface, our temperature readings just below the pebbles show that the amount of heat transfer to ∼2 cm depth is directly dependent on fire duration, with higher temperatures accumulating during longer events. We obtained maximum temperatures of 307, 158, and 182 °C for experiments lasting for 124, 31, and 40 min, respectively (Table 2). This range of temperatures shows that higher substrate temperatures can easily be reached in events lasting longer than the fires performed here (Aldeias et al. 2016). Consequently, thermal alteration can occur in the sediments underlying a pebble cuvette cooking structure (March et al. 2014) and of course with fire below type of experiments. In contrast, substrate temperatures were constantly at values below 100 °C in fire above experiments (Fig. 4c, d), which entails little or no alteration of underlying deposits for similar fire types and durations.

In terms of the fires themselves, the combustion of P. pinaster fuels recorded substantial variance in maximum temperatures. These ranged from 922 to 488 °C (an average maximum temperatures of 797 °C) in experiments with pebble cuvette, fire below, and fire above with pine wood and lower maximum average temperatures of 417 °C in the fire above with pine embers (Table 2). This combustion process resulted in wood charcoal alterations in the form of vitrification and cracks (see Supplementary Information). In high levels of vitrification, the intense alteration observed lead to an almost complete elimination of the original cell morphology. Such levels of vitrification can significantly bias the observation of the cellular structure (e.g., Gale and Cutler 2000; Prior and Alvin 1983; Py and Ancel 2006). Vitrification tends to be more visible and intense in radial and tangential sections. Low to high levels of vitrification were observed on samples from all experiments, with low vitrification levels meaning that vitrification is identified but there was not a substantial damage to the cellular structure. Low levels of vitrification were particularly observed in charcoal fragments from one of the pebble cuvette runs (first repetition of C2 (Ck)), though this was not the case for all the pebble cuvette experiments, and therefore probably linked with probability sampling and intrinsic experimental variation. What this data does highlight is that repetitions of the same experimental procedures are very important in actualistic experiments such as the ones commonly performed in experimental archaeology. Finally, the presence of cracks on charcoal is evident in at least one fragment from each experiment. Although this alteration is not as frequent as vitrification, it is still abundant and cracks tend to co-occur in fragments where vitrification is also present.

Roasting shellfish: mineralogy-associated transformations

The results of the FTIR analysis are summarized in Table 2. Shells analyzed from the pebble cuvette experiments (C1-C3), where the shells did not come into direct contact with the fire, were still composed solely of aragonite. Similar results were consistently obtained from the experiments with fire above using pine embers (Fa5 and Fa6) where the maximum fire temperature was lower than in all other experiments (average of 417 °C, see Table 2), although since this temperature should allow at least partial mineralogical transformation, this result might be due to small sample size.

A more complex picture emerges from the experiments using fire below and fire above with pine wood or needles as fuel, with the mineralogical compositions of the shells varying in a number of these experiments. Several of the analyzed shells retain an aragonite composition, while others are already transformed to calcite. It is interesting to note that in experiments Fa2 and Fb, a few of the analyzed cockle shells have spectra associated with aragonite transforming to calcite, showing that such specimens had to be subject to temperature ranges roughly between 250 and 350 °C, as shown by our controlled muffle heating results discussed above.

Roasting shellfish: what are the microstratigraphic traces?

In Table 3, we synthesize the macro- and microscopic observations concerning the sedimentary and taphonomic signatures produced during our shellfish roasting experiments.

Table 3 Summary of observations from the fire cooking experiments and notes on their potential archaeological visibility

Of the three types of cooking tested, only the fire below experiment produced a microstratigraphic arrangement typical of in situ hearths, that is, a thermally altered substrate overlain by fire residues with abundant charcoals and ashes. For the most part, however, the employed cooking methods involved the partial or complete removal of the majority of fire residues prior to cooking (see Fig. 1). Even in the fire below experiment, part of the embers and ashes were pushed aside in order to create a central area where the shellfish was placed. This action resulted in an external rim with a relatively thicker accumulation of chaotically organized, cm-sized pieces of carbonized wood tissues, ashes, and charcoals. Locally, these deposits may or may not overly altered substrate, depending on how far they were dispersed from the original location. At the center of the hearth, that is, where the shellfish were cooked, the accumulation of fire residues is thinner (1–2 cm thick), though with some degree of structural organization as seen microscopically by the presence of articulated ashes overlying a thin rubefied substrate (Fig. 6).

Fig. 6
figure 6

Photomicrographs of key components and micromorphological features of field cooking experiments: a view of sediments produced in experiment Fb where it is possible to see the lateral accumulation of ashes, charcoal (Ch), and several shell fragments (S), the latter embedded in a loose microgranular structure, in PPL. Scale is 1 mm. b Close-up view of area marked by square in (a) where we can observe the contact between the calcitic ashes and the aragonitic cockle shell, in XPL. Scale is 500 μm. c Micrograph of pine wood ash with laminated bundles of alternating white and dark gray calcitic pseudomorphs of calcium oxalate cells mixed with quartz grains and rounded silty clay aggregates, in XPL. Scale is 200 μm. d Detailed view of rhombic pseudomorphs after calcium oxalate of pine wood cells in anatomical connection, in XPL. Scale is 100 μm. e Micrograph of fire above experiment Fa3 where pine needles were used as fuel. Note the black hook-shape of the pine needles cross-section and their internal porosity, in PPL. Scale is 500 μm. f Same as (e) but in XPL. Note the presence of calcitic ash domains around the carbonized pine needles (arrows)

In all other experiments, the cooking procedure entailed the removal, spreading, and dumping of fire residues outside the actual cooking area. In the case of the pebble cuvette hearths, the large pieces of carbonized wood and charcoals were removed and the remaining finer fraction blown out in order to exposed the surfaces of the hot pebbles. We could observe that smaller size fractions of ashes and charcoals had accumulated and rested in the spaces between pebbles, namely at the deepest part of the basin-shaped depression (Fig. 5). The actual fire residues were quickly dumped nearby this feature and presented a chaotic organization of large-sized components in a loose, open structure, overlaying a non-altered substrate. The “path” of deposits removal could be traced by the spreading of finer ashes from the pebble feature to the main dumping area. This type of fragile deposits and organization, however, are unlikely to survive archaeologically. The most conspicuous element of this type of cooking is obviously the structuring of the cooking area with the sedimentary depression and arrangement of the pebble cover. During our several repetitions, only a few of the pebbles were thermally fractured, whereas the central pebbles typically showed some type of color modifications, from reddish to black hues (Fig. 5). Although we could not sample these deposits for micromorphology, the temperature readings of the substrate directly underneath the cuvette do show that these deposits reached temperatures between 200 and 300 °C. This type of cooking has, therefore, the potential to produce some thermal alteration of underlying artifacts and sediments (e.g., resetting of thermoluminescence signal, charring of organic matter, rubefication), and such modifications may be identifiable in archaeological contexts (Aldeias et al. 2016; Canti and Linford 2000; Linford and Platzman 2004; March et al. 2014).

One of the most striking aspects of the fire above cooking experiments is the lack of association between the fire, its residues, and the surrounding deposits. These fast fires kindled on top of shellfish were fairly short-lived—otherwise, the mollusk was not cooked but rather burned. Subsequently, all the ashes and charcoals were quickly swept and blown out from the top of the shells and these were removed from their cooking location and consumed. Therefore, in all of our experiments, there is little or no visible macro- or microscopic alteration of the substrate underlying the cooking location. The swept out fire residues tended to be fairly dispersed, namely in the case of the fires fueled with the fragile pine needles. Some thicker accumulation of charcoals and partially carbonized wood pieces overlying unaltered substrates were produced in the pine wood-fueled experiments, namely in those were the fires were not left to burn to completion.

In the thin sections from fire above experiments, there are few diagnostic features, especially if we consider that the shells themselves would have been removed from their cooking arrangement and probably tossed somewhere else after the mollusk was eaten. Therefore, only the discrete presence of charcoals, charred pine needles, and rare domains with calcitic wood ashes indicate the presence of fire activities. In contrast, however, it was during these fire above experiments that significant physical and color modifications were produced in the shells themselves, since these were directly exposed to heat from the superimposing fire. Macroscopically, we could see that quite a few shells tended to have burned black to brown domains, with some of the more fragile peppery furrow shells also showing cracking and fissuring (Fig. 5). These cracks and burning is preferentially located in the uppermost umbos sections, which in our cooking arrangement were positioned upwards and in direct contact with the fires.

Discussion

Temperature threshold for mineralogical transformation of cockles and peppery furrow shells

Before discussing the specific effects of temperature on structural modification of CaCO3 polymorphs, our use of both FTIR transmission and ATR collection modes allow us to directly compare and discuss results obtained with these two procedures. As shown in Fig. 3, despite minor shifts in peak positions, we have similar results when using FTIR and FTIR-ATR. Both methods were equally able to detect the process of aragonite transforming to calcite and the complete change to a calcite structure at higher temperatures (Table 1 and Fig. 3). One of the often mentioned shortcomings of FTIR-ATR is that penetration depth increases at lower wavenumbers (Miller 2002), which means that peak intensities at higher wavenumbers are much lower than in transmission spectra affecting absorptions in this region. Despite this effect, however, it is important to observe that the O-H stretching vibration of calcium hydroxide (Ca(OH)2) at 3640 cm−1 is equally identifiable by both methods in the samples heated to 900 °C (see supplementary information). When comparing the two methods regarding sample preparation and convenience, the FTIR-ATR procedure is somewhat faster and easier. For both methods, some grinding of the sample is needed, but while this is the only requirement for FTIR-ATR, one should in addition prepare a KBr pellet for FTIR. Due to the KBr hydrophilic nature, a heat lamp to keep the KBr dry is also required. Therefore, although the FTIR method is more sensitive at higher wavenumbers, FTIR-ATR collection mode may be easier to operate, especially in humid environments. All these factors should be taken into consideration, especially in archaeological excavations when laboratory techniques can be brought into the field.

Concerning the results from our controlled muffle experiments, infrared analyses revealed that the transformation from aragonite to calcite started around 250 °C for cockles and at 350 °C for peppery furrow, with complete transformation occurring around 500 and 450 °C, respectively. These results show that, in the range of temperatures between the start of the transformation until the shell is completely transformed, we should expect various amounts of the two polymorphs—in stages that we designated as “aragonite transforming to calcite” and “calcite with traces of aragonite.” This mixed composition is seen in Fig. 3 with the appearance of the calcite ν2 absorbance band at 876 cm−1 (874 cm−1 in ATR) alongside with the aragonite absorbance band at 860 cm−1 (856 cm−1 in ATR), and the ν3 absorbance bands at 1427 cm−1 (1405 cm−1 in ATR) overlapping with the aragonite main peak at 1475 cm−1 (1465 cm−1 in ATR), thus resulting in a wider absorption peak in this area.

Previous studies on high temperature aragonite transformation to calcite from biogenic sources (corals and shells) show that biogenic aragonites tend to turn completely calcitic ∼400 °C or even at lower temperatures of 280–320 °C (see Table 4 and references therein). Conversely, our results show that one of the species studied here (cockles) was exclusively calcitic only at 500 °C, with these structural transformations occurring after merely 5 min of heating. In general, biogenic aragonite starts transforming at lower temperatures (200 to 500 °C) than geogenic or synthesized inorganic aragonite (Yoshioka and Kitano 1985). It has been suggested that this results from higher incorporated water and organic matter in the lattice of biogenic aragonite, which makes it less stable (Gaffey et al. 1991; Yoshioka and Kitano 1985). Gaffey et al. (1991) also suggested that high amount of lattice defects may be another possible explanation for the lower stability of biogenic aragonite. Varied water content and organic matter were confirmed by our TGA results, where we can observe the relatively higher amount of organic matter in peppery furrow than in cockles (see supplementary information). This difference might help explain the distinct rates and temperature thresholds observed for complete transformation to calcite in these two species.

Table 4 The range of temperatures for complete transformation of aragonite to calcite from different sources

Overall, the available evidence highlights the diversity of temperature dependent aragonite transformation between different biogenic sources. Although quantitative estimations are difficult to obtain (though see Loftus et al. 2015), an assessment of the relative amounts of aragonite versus calcite may help determine the range of temperatures to which a shell was exposed. We should take into consideration that such mixed compositions (like the transformation stages of “aragonite transforming to calcite” and “calcite with traces of aragonite” obtained in our study) might not preserve in the archaeological record, since pyrogenic and biogenic sources of aragonite and calcite are relatedly disordered at the atomic level and tend to recrystallize as more ordered mineral phase after dissolution (Weiner 2010). In geology, the phenomenon of replacement of aragonite with calcite in high temperature/high pressure conditions (e.g., in carbonate rocks) and the instability of aragonite at surface pressures is well known. However, this type of replacement operates at a larger geological timescale and not generally affecting archaeological associated chronologies. Yet, since aragonite is less stable than calcite at ambient temperatures and pressures, it is more soluble and hence more affected by other types of diagenesis which can affect the archaeological record. In general, both CaCO3 polymorphs are relatively soluble, and when dissolved, a more stable phase will precipitate, in the case of the aragonite it would usually be the more stable/ordered calcite (Weiner 2010). The tendency of aragonitic shells to re-precipitate as calcitic in the fossil record can be used as a proxy for accessing the mineralogical preservation state in archaeological sites (Namdar et al. 2011; Weiner et al. 2002). This has special relevance in the use of aragonite > calcite transformation based on biogenic shells as specific temperature proxies for past archaeological fires, or ceramic firing, suggesting that precise studies on temperature thresholds for the analyzed species first need to be attested.

Mineralogical transformations associated with roasting of shells

When considering the range of temperatures in which aragonite transforms to calcite in the two species studied here (Table 1), together with the temperatures recorded in our fire cooking experiments and the mineralogical composition of the cooked shells (Table 2), the following patterns can be pointed out:

  1. 1.

    In all the pebble cuvette experiments, the cooked shells maintained an aragonitic composition. This is expected since the shells did not come in direct contact with the fire and therefore were exposed to lower temperatures (Fig. 4 and Supplementary Information). Similar results would also be expected in any form of cooking though boiling.

  2. 2.

    In both fire above and fire below experiments, there was some degree of direct contact between the shells and the fire/embers. Therefore, the probabilities of some shells reaching the temperature threshold increase substantially. Accordingly, our results do show that for the majority of these experiments, we had varying degrees of structural changes, from fresh aragonitic shells, to fully calcite and/ or aragonite transforming to calcite. It is important to note that these results occur even though readings from the thermocouple laid on the ground between the shells recorded temperatures that were not high enough to reach the threshold for aragonite to calcite transformation (Table 2). However, given the high values and temperature oscillations of the fire itself, there were locally high enough temperatures to transform at least part of the assemblage, and the positioning of one single thermocouple does not detect these spatial fluctuations. The rapid nature of the cooking events and the patchy contact between the fire and the shells resulted in the identified mixed mineralogical composition in the cooked shells.

These two observations suggest that, when dealing with cooking events in containers, no mineralogical transformation of the shells should be expected. However, any cooking technique that involves direct contact with fire could lead to a mixed assemblage with both aragonitic and calcitic shells regardless of how ephemeral the cooking events were. Therefore, in an archaeological site where the carbonate minerals are well preserved, we would expect to find either aragonitic or both aragonitic and calcitic shells when dealing with assemblages related to cooking activities of similar types of mollusks.

Conversely, in situations where an originally aragonitic shell assemblage shows complete transformation to calcite mineralogy, two possible interpretations can be inferred: either it has been subjected to significant diagenesis, with dissolution of aragonite and calcite recrystallization or it was exposed to high temperatures such as those produced by a hearth. In the latter situation, the maintenance of temperatures high enough to result in the widespread transformation of shells from aragonite to calcite is more consistent with hearths unrelated to cooking. Such complete burning might happen if the shells were thrown into an active fire (Villagran 2014b) or if the shells were part of the substrate underlying a fire, with experimental work estimating that such temperatures can be reached in sediments buried up to 6 cm in depth (Aldeias et al. 2016). As we have shown, roasting shellfish events are primarily fast fires, and while the temperature of the fires themselves can oscillate between ∼400 and ∼900 °C, only locally do temperatures above 400 °C occur in association with the shellfish being cooked. Overall, much lower temperatures are required; otherwise, the shellfish is burned instead of cooked. This work suggests that we can now separate between mixed mineralogical assemblages, which imply cooking, and completely transformed assemblages, which imply in situ burning (i.e., hearths on top of shell rich matrix) and should be interpreted as fire places rather than shell roasting hearths.

Microstratigraphic signatures of roasting shellfish and their archaeological visibility

The cooking experiments described above suggest that we should not expect to encounter “well- preserved” combustion features related to similar shell roasting in the archaeological record since part of these cooking procedures involved spreading of fire residues. In fact, some degree of scattering is an essential step of all of the roasting methods presented here, with fuel residues dumped outside the cooking area and largely overlying unburned substrates (Fig. 7). Such spreading and dumping results in either almost invisible cooking events, such as roasting with pine needles (which leaves no trace in the substrate and only fine ashes with weak archaeological preservation) or “disconnected” cooking events in which fire residues are spread outside the actual combustion locus. Only in roasting experiments with fire below could we expect to locally find a microstratigraphic structure resembling in situ hearths, with ashes and charcoals partially overlying thermally altered substrates—for example, with reddened (rubefied) sediments, charred organic matter, or burned clays, depending on fire temperature/duration and composition of the substrate (see Aldeias et al. 2016). However, even in these experiments, the center of the hearth was disturbed by gently scattering of combustion materials. This action resulted in some disruption of the original sedimentary association, creating thicker external rims of unorganized accumulation of ashes and charcoals (Fig. 7). Such mixed deposits can easily be misinterpreted as a disturbed hearth in archaeological contexts, whereas they actually reflect the expected outcome of in place roasting shellfish events. The produced microstratigraphy is distinct from that expected from an in situ, undisturbed hearth (see the experimental hearth reported in Villagran 2014b).

Fig. 7
figure 7

Illustration of the final stages of three main types of roasting shellfish procedures (left), with the annotated plan view showing macroscopic observations of sedimentary and artifact dispersion features and their idealized visibility in profile view (right)

Cooking using earth oven methods, such as our pebble cuvette experiments, would have the highest likelihood of archaeological visibility. Even though fire residues were equally scattered and, if preserved, would be found outside of the cuvettes themselves (Fig. 7), the dug basin and the shattered thermoclasts have higher chances to be found in situ, possibly with ashes and microcharcoals between the pebbles. In optimal preservations, it might be possible to identify the accumulation of dumped combusted material. These sediments have a loose and chaotic organization, with ashes being intrinsically mixed with charcoals and with an absence of associated burned sediments (either underlying it or as pieces of rubefied material mixed with the combusted deposits). Although technically in a secondary position, such accumulations reflect anthropogenically reworking actions and are expected outcomes of cooking roasting fires.

Conclusions and future directions

Despite increased interest in the role of marine resources in human evolution, our knowledge regarding behavioral traits linked to shellfish processing and their visibility in the archaeological record is still limited. Based on ethnographic evidence, it is often assumed that the expediency of shellfish cooking can leave little or no trace on the archaeological record. Furthermore, sediments and shells can also be burned in events unrelated to shellfish cooking activities, for instance if a fire is lit on top of shell-rich matrix, which makes it even harder to identify shell cooking events in the archaeological record (March 1999b; Villagran 2014a). In this paper, we explored microarchaeological signatures produced by experimental roasting shellfish activities in order to improve our ability to identify such events. Our experimental procedure focused both on controlled heat-induced mineralogical transformations of aragonitic shells (cockles and peppery furrow species) and on a series of shellfish roasting fires.

The obtained data showed that initial mineralogical transformations from aragonite to calcite starts already after 5-min exposures to 250 °C on cockles and at 350 °C on peppery furrow shells. Complete transformation to calcite occurs at 500 °C and at 400 °C in cockles and peppery furrows, respectively. Visual, macro- and microscopic changes were associated with this transformation with shells of both species presenting distinct calcitic microscopic birefringence, macroscopic crazing, and color transformations related to temperature exposures above ∼500 °C. Similar alterations were observed in a small percentage of the experimental roasted shells, specifically when cooked in direct connection with active fires as in experiments fire below and fire above with pine wood and pine needle fuels. These experiments produced an assemblage of mixed mineralogical compositions ranging from pure aragonitic shells to complete transformation to a calcite structure. No mineral transformation was observed in experiments without a direct contact with burning fuel (that is, pebble cuvette type of cooking) or when pine embers were used (probably due to the small sample size tested). Hence, based on these results, the presence of mixed mineralogical assemblages can imply a type of cooking, whereas we would argue that completely transformed assemblages tend to imply in situ secondary burning of shells (i.e., hearths on top of shell rich matrix). The latter should be interpreted as fire places rather than shell roasting events.

Shellfish roasting fires tended to be ephemeral in nature and cooking process involved the removal, spreading, and dumping of combusted materials. These actions largely resulted in the absence of well-preserved microstratigraphies associated with in situ hearths and the creation of anthropogenically reworked deposits of dumped ashes and charcoals overlying sediments not affected by heating. The identification of such deposits in the archaeological record might be associated, therefore, with human behavioral activities and not necessarily with poorly preserved or naturally reworked fire features. Earth oven cooking procedures were tested through our pebble cuvette structures, and these could entail a higher archaeological visibility both through the identification of the dug basin and the presence of thermally altered pebbles. Some degree of thermal alteration of underlying substrate can occur with pebble cuvette and fire below cooking techniques, while such alterations were virtually invisible in the substrates of fire above roasting.

Finally, another important component of roasting fires would be the discard of consumed shells. Once heated, the valves opened, and the mollusks consumed, the cooked shells would have been thrown away, and we could expect that such discarding would entail accumulations of shells. We could expect the accumulation of discrete piles, though it is difficult to envision the preservation of such fragile structures in the archaeological record (with the exception of exceptional preservation conditions). Notwithstanding, the identification of deposits interpreted as discrete tossing events in Mesolithic shell mounds (Aldeias et al. 2016) and ethno historic sites (Balbo et al. 2010; Villagran et al. 2011b) might provide some interesting research avenues for signatures of discarding, especially if such accumulations are investigated for mineralogy and thermal alteration patterns.

By exploring the microstratigraphy and discard signatures associated with shellfish roasting fires, the experiments reported here add to experimentation references contributing to the validation of microstratigraphic observation of archaeological fire features. Future experiments should aim to explore heat-induced transformation of aragonitic shells (due both to cooking and to secondary burning) versus calcite composition derived from diagenesis. Our data suggests that, first, characteristic visual changes of the burnt shells might be of use, and, second, since formation pathways are different, it might be possible to distinguish between the two types of alterations by their level of atomic order (see Regev et al. 2010), but more systematic work on the topic is still needed. In the future, we hope to further test the observations reported here by both continued experimentation on food processing fires and by investigating their applicability on archaeological deposits and features.