Albéric, M., Reiche, I., Balasse, M., Brugal, J-P., Dauphin, Y., Geigl, E-M., Oberlin, C., Reiche, I., (eds.) Message d'os. Archéométrie du squelette animal et humain. Éditions des archives contemporaines Paris, 2015, 53–68.
Albéric, M., Gourrier, A., Wagermaier, W., Fratzl, P., Reiche, I., The three-dimensional arrangement of the mineralized collagen fibers in elephant ivory and its relation to mechanical and optical properties. Acta Biomater. 72 (2018), 342–351.
Anderson, P.C., A testimony of prehistoric tasks: diagnostic residues on stone tool working edges. World Archaeol. 12 (1980), 181–194.
Anderson-Gerfaud, P., Aspects of behaviour in the Middle Palaeolithic: functional analysis of stone tools from Southwest France. The Emergence of Modern Humans, Vol. 35, 1990, 389–418.
Barton, H., Torrence, R., Fullagar, R., Clues to stone tool function re-examined: comparing starch grain frequencies on used and unused obsidian artefacts. J. Archaeol. Sci. 25:12 (1998), 1231–1238.
Blee, A.J., Walshe, K., Pring, A., Quinton, J.S., Lenehan, C.E., Towards the identification of plant and animal binders on Australian stone knives. Talanta 82:2 (2010), 745–750.
Bordes, L., Prinsloo, L.C., Fullagar, R., Sutikna, T., Hayes, E., Jatmiko, Wahyu Saptomo, E., Tocheri, M.W., Roberts, R.G., Viability of Raman microscopy to identify micro-residues related to tool-use and modern contaminants on prehistoric stone artefacts. J. Raman Spectrosc. 48:9 (2017), 1212–1221.
Bordes, L., Fullagar, R., Prinsloo, L.C., Hayes, E.H., Kozlikin, M., Shunkov, M., Derevianko, A., Roberts, R.G., Raman spectroscopy of lipid micro-residues on middle palaeolithic stone tools from Denisova Cave, Siberia. J. Archaeol. Sci. 95 (2018), 52–63.
Borel, A., Ollé A., Vergès, J.M., Sala, R., Scanning Electron and Optical Light Microscopy: two complementary approaches for the understanding and interpretation of usewear and residues on stone tools. J. Archaeol. Sci. 48 (2014), 46–59.
Bradtmöller, M., Sarmiento, A., Perales, U., Zuluaga, M.C., Investigation of Upper Palaeolithic adhesive residues from Cueva Morín, Northern Spain. J. Archaeol. Sci. Rep. 7 (2016), 1–13.
Byrne, L., Ollé A., Vergès, J.M., Under the hammer: residues resulting from production and microwear on experimental stone tools. Archaeometry 48 (2006), 549–564.
Cârciumaru, M., Ion, R.M., Niţu, E.C., Ştefânescu, R., New evidence of adhesive as hafting material on Middle and Upper Palaeolithic artefacts from Gura Cheii-Râşnov cave (Romania). J. Archaeol. Sci. 39:7 (2012), 1942–1950.
Castaing, R., Electron probe microanalysis. Adv. Electron. Electron Phys. 13 (1960), 317–386.
Chadefaux, C., Vignaud, C., Menu, M., Reiche, I., Multianalytical study of palaeolithic reindeer antler. Discovery of antler traces in Lascaux pigments by TEM. Archaeometry 50:3 (2008), 516–534.
Christensen, M., Technologie de l'ivoire au Paléolithique supérieur. Hedges, J.A.E., (eds.) British Archaeological Reports, 751, 1999, Archaeopress, Oxford, 201.
Cnuts, D., Rots, V., Extracting residues from stone tools for optical analysis: towards an experiment-based protocol. Archaeol. Anthropol. Sci. 14 (2017), 1–20.
Cristiani, E., Pedrotti, A., Gialanella, S., Tradition and innovation between the Mesolithic and Early Neolithic in the Adige Valley (Northeast Italy). New data from a functional and residues analyses of trapezes from Gaban rockshelter. Documenta Praehistorica XXXVI (2009), 191–205.
Croft, S., Monnier, G., Radini, A., Little, A., Milner, N., Lithic residue survival and characterisation at Star Carr: a burial experiment. Internet Archaeol.(42), 2016, 4, 10.11141/ia.42.5.
Croft, S., Chatzipangagis, K., Kröger, R., Milner, N., Misleading residues on lithics from Star Carr: identification with Raman microspectroscopy. J. Archaeol. Sci. Rep. 19 (2018), 430–438.
Crowther, A., Haslam, M., Oakden, N., Walde, D., Mercader, J., Documenting contamination in ancient starch laboratories. J. Archaeol. Sci. 49 (2014), 90–104.
Dinnis, R., Pawlik, A., Gaillard, C., Bladelet cores as weapon tips? Hafting residue identification and micro-wear analysis of three carinated burins from the late Aurignacian of Les Vachons, France. J. Archaeol. Sci. 36:9 (2009), 1922–1934.
Fullagar, R., Residues and usewear. Balme, J., Paterson, A., (eds.) Archaeology in Practice: A Student Guide to Archaeological Analyses, 2014, Wiley, Hoboken, 232–265.
Fullagar, R., Hayes, E., Stephenson, B., Field, J., Matheson, C., Stern, N., Fitzsimmons, K., Evidence for Pleistocene seed grinding at Lake Mungo, south-eastern Australia. Archaeol. Ocean. 50:S1 (2015), 3–18.
Ge, W., Chemical analysis of starch-like mineral crystals to eliminate misidentification in ancient residue research. Archaeometry 55:6 (2013), 1122–1131.
Haslam, M., The decomposition of starch grains in soils: implications for archaeological residue analyses. J. Archaeol. Sci. 31:12 (2004), 1715–1734.
Hayes, E., and Rots, V., in press. Documenting scarce and fragmented residues on stone tools: an experimental approach using optical microscopy and SEM-EDS. Archaeol. Anthropol. Sci. https://doi.org/10.1007/s12520-018-0736-1 (Accepted October 4th, 2018).
Hayes, E., Cnuts, D., Lepers, C., Rots, V., Learning from blind tests: determining the function of experimental grinding stones through use-wear and residue analysis. J. Archaeol. Sci. Rep. 11 (2017), 245–260.
Helwig, K., Monahan, V., Poulin, J., Andrews, T.D., Ancient projectile weapons from ice patches in northwestern Canada: identification of resin and compound resin-ochre hafting adhesives. J. Archaeol. Sci. 41 (2014), 655–665.
Jahren, A.H., Toth, N., Schick, K., Clark, J.D., Amundson, R.G., Determining stone tool use: chemical and morphological analyses of residues on experimentally manufactured stone tools. J. Archaeol. Sci. 24 (1997), 245–250.
Langejans, G.H.J., Discerning use-related micro-residues on tools: testing the multi-stranded approach for archaeological studies. J. Archaeol. Sci. 38:5 (2011), 985–1000.
Langejans, G.H.J., Middle Stone Age pièces esquillées from Sibudu Cave, South Africa: an initial micro-residue study. J. Archaeol. Sci. 39:6 (2012), 1694–1704.
Lombard, M., Wadley, L., The morphological identification of micro-residues on stone tools using light microscopy: progress and difficulties based on blind tests. J. Archaeol. Sci. 34:1 (2007), 155–165.
Lynch, V., Miotti, L., Introduction to micro-residues analysis: systematic use of scanning Electron microscope and energy dispersive X-rays spectroscopy (SEM-EDX) on Patagonian raw materials. J. Archaeol. Sci. Rep. 16:May (2017), 299–308.
Monnier, G.F., Ladwig, J.L., Porter, S.T., Swept under the rug: the problem of unacknowledged ambiguity in lithic residue identification. J. Archaeol. Sci. 39:10 (2012), 3284–3300.
Monnier, G., Hauck, T.C., Feinberg, J.M., Luo, B., Le Tensorer, J.-M., Sakhel, H.A., A multi-analytical methodology of lithic residue analysis applied to Paleolithic tools from Hummal, Syria. J. Archaeol. Sci. 40:10 (2013), 3722–3739.
Monnier, G., Frahm, B., Luo, E., Missal, K., Developing FTIR microspectroscopy for the analysis of animal-tissue residues on stone tools. J. Archaeol. Method Theory 25:1 (2017), 1–44.
Monnier, G., Frahm, B., Luo, E., Missal, K., Developing FTIR microspectroscopy for analysis of plant residues on stone tools. J. Archaeol. Sci. 78 (2017), 158–178.
Pawlik, A.F., Identification of hafting traces and residues by scanning electron microscopy and energy-dispersive analysis of X-rays. Lithics in Action, 2004, 169–179.
Pawlik, A.F., Thissen, J.P., Hafted armatures and multi-component tool design at the Micoquian site of Inden-Altdorf, Germany. J. Archaeol. Sci. 38:7 (2011), 1699–1708.
Pedergnana, A., Ollé A., Building an experimental comparative reference collection for lithic micro-residue analysis based on a multi-analytical approach. J. Archaeol. Method Theory 25:1 (2018), 117–154.
Pedergnana, A., Asryan, L., Fernández-Marchena, J.L., Ollé A., Modern contaminants affecting microscopic residue analysis on stone tools: a word of caution. Micron 86 (2016), 1–21.
Power, R.C., Salazar-García, D.C., Wittig, R.M., Henry, A.G., Assessing use and suitability of scanning electron microscopy in the analysis of micro remains in dental calculus. J. Archaeol. Sci. 49:0 (2014), 160–169.
Reiche, I., Müller, K., Marqueur d'identification à micro-échelle de l'ivoire de mammouth dans les objets préhistoriques. Anthropologie 122 (2018), 316–326.
Rots, V., Hayes, E., Cnuts, D., Lepers, C., Fullagar, R., Making sense of residues on flaked stone artefacts: learning from blind tests. PLoS One, 11(3), 2016, e0150437.
Ruminski, J.K., Osipowicz, G., Neolithic adhesive from a T-shaped ornamental element excavated at the site 14 at Kowal, Kuyavia, Central Poland. Archaeometry 56:1 (2014), 129–144.
Smith, K.N., Wärmländer, S.K.T.S., Vellanoweth, R.L., Smith, C.M., Kendig, W.E., Residue analysis links sandstone abraders to shell fishhook production on San Nicolas Island, California. J. Archaeol. Sci. 54 (2015), 287–293.
Stephenson, B., A modified Picro-Sirius Red (PSR) staining procedure with polarization microscopy for identifying collagen in archaeological residues. J. Archaeol. Sci. 61 (2015), 235–243.
Su, X.W., Cui, F.Z., Hierarchical structure of ivory: from nanometer to centimetre. Mater. Sci. Eng. C 7:1 (1999), 19–29.
Vergès, J.M., Ollé A., Technical microwear and residues in identifying bipolar knapping on an anvil: experimental data. J. Archaeol. Sci. 38:5 (2011), 1016–1025.
Wadley, L., Lombard, M., Williamson, B., The first residue analysis blind tests: results and lessons learnt. J. Archaeol. Sci. 31:11 (2004), 1491–1501.
Wojcieszak, M., Wadley, L., Raman spectroscopy and scanning electron microscopy confirm ochre residues on 71 000-year-old bifacial tools from Sibudu, South Africa. Archaeometry, 2018, 10.1111/arcm.12369.
