Jackson Pollock’s Number 1A, 1948: a non-invasive study using macro-x-ray fluorescence mapping (MA-XRF) and multivariate curve resolution-alternating least squares (MCR-ALS) analysis

Springer Science and Business Media LLC - 2016
Ana Martins1, James Coddington1, Geert Van der Snickt2, B.A. van Driel3, Chris McGlinchey1, Donald B. Dahlberg4, Koen Janssens2, Joris Dik3
1The Museum of Modern Art, 11 W53rd Street, New York, NY, 10019, USA
2Department of Chemistry, University of Antwerp, Universiteitsplein 1, 2610, Wilrijk, Belgium
3Department of Materials Science and Engineering, Delft University of Technology, Mekelweg 2, 2628CD, Delft, The Netherlands
4Department of Chemistry, Lebanon Valley College, 101N College Ave., Annville, PA, 17003, USA

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Newman R, Derrick M. Scientific examination of the paint on nine matter paintings. In: Landau EG, Cernuschi C, editors. Pollock Matters. Boston: McMullen Museum of Art Boston College; 2007. p. 105.

Cappitelli F. THM-GCMS and FTIR for the study of binding media in Yellow Islands by Jackson Pollock and Break Point by Fiona Banner. J Anal Appl Pyrolysis. 2004;71:405–15.

Lake S, Ordonez E, Schilling M. A technical investigation of paints used by Jackson Pollock in his drip or poured paintings. In: Roy A, Smith P, editors. Modern Art, New Museums: Contributions to the 20th International Institute of conservation congress in Bilbao. 2004. p. 137–41.

Lake S. The challenge of preserving modern art: a technical investigation of paints used in selected works by Willem de Kooning and Jackson Pollock. MRS Bull. 2001;26:56–60.

Szafran Y, Rivers L, Phenix A, Learner T. Jackson Pollock’s Mural: myth and substance. In: Szafran Y, Rivers L, Phenix A, Learner T, Landau E, Martin S, editors. Jackson Pollock’s Mural, the transitional moment. Los Angeles: Paul Getty Museum; 2014. p. 31–85.

Eastaugh N, Gorsia B. What it says on the Tin: a preliminary study of the set of paint cans and the floor in the Pollock–Krasner Studio. In: Landau EG, Cernuschi C, editors. Pollock Matters. Boston: McMullen Museum of Art of Boston College; 2007. p. 143–53.

McGlinchey C. Handheld XRF for the examination of paintings: proper use and limitations. In: Shugar AN, Mass JL, editors. Handheld XRF for art and archaeology (studies in archeological sciences), 1st edn, vol. 4. Leuven: Leuven University Press; 2013. p. 131–58.

Delaney JK, Zeibel JG, Thoury M, Littleton R, Palmer M, Morales KM, de la Rie ER, Hoenigswald A. Visible and infrared imaging spectroscopy of Picasso’s Harlequin Musician: mapping and identification of artist materials in situ. Appl Spectrosc. 2010;64:584–94.

Legrand S, Alfeld M, Vanmeert F, de Nolf W, Janssens K. Macroscopic Fourier transform infrared scanning in reflection mode (MA-rFTIR), a new tool for chemical imaging of cultural heritage artefacts in the mid-infrared range. Analyst. 2014;139:2489–98.

Rosi F, Miliani C, Braun R, Harig R, Sali D, Brunetti B, Sgamellotti A. Noninvasive analysis of paintings by mid-infrared hyperspectral imaging. Angew Chem Int Ed. 2013;52:5258–61.

Dooley KA, Lomax S, Zeibel JG, Miliani C, Ricciardi P, Hoenigswald A, Loew M, Delaney JK. Mapping of egg yolk and animal skin glue paint binders in early renaissance paintings using near infrared reflectance imaging spectroscopy. Analyst. 2013;138:4838–48.

Ropret P, Miliani C, Centeno SA, Tavzes Č, Rosi F. Advances in Raman mapping of works of art. J Raman Spec. 2010;41:1172–7.

Dik J, Janssens K, Van Der Snickt G, van der Loeff L, Rickers K, Cotte M. Visualization of a lost painting by Vincent van Gogh using synchrotron radiation based X-ray fluorescence elemental mapping. Anal Chem. 2008;80:6436–42.

Alfeld M, Siddons DP, Janssens K, Dik J, Woll A, Kirkham R, Wetering E. Visualizing the 17th century underpainting in Portrait of an Old Man by Rembrandt van Rijn using synchrotron-based scanning macro-XRF. Appl Phys A. 2013;111:157–64.

Alfeld M, Van der Snickt G, Vanmeert F, Janssens K, Dik J, Appel K, van der Loeff L, Chavannes M, Meedendorp T, Hendriks E. Scanning XRF investigation of a Flower Still Life and its underlying composition from the collection of the Kröller-Müller Museum. Appl Phys A. 2013;111:165–75.

Howard DL, de Jonge MD, Lau D, Hay D, Varcoe-Cocks M, Ryan CG, Kirkham R, Moorhead G, Paterson D, Thurrowgood D. High-definition X-ray fluorescence elemental mapping of paintings. Anal Chem. 2012;84:3278–86.

De Nolf W, Dik J, VanderSnickt G, Wallert A, Janssens K. High energy X-ray powder diffraction for the imaging of (hidden) paintings. J Anal At Spectrom. 1011;26:910–6.

Alfeld M, Janssens K. Strategies for processing mega-pixel X-ray fluorescence hyperspectral data: a case study on a version of Caravaggio’s painting Supper at Emmaus. J Anal At Spectrom. 2015;30:777–89.

Modern paints uncovered. In: Learner T, Smithen P, Krueger JW, Schilling MR, editors. Proceedings from the modern paints uncovered symposium, May 16–19, 2006. Tate Modern, London. Los Angeles: The Getty Conservation Institute; 2008.

Issues in contemporary oil paint. In: van den Berg KJ, Burnstock A, de Keijzer M, Krueger J, Learner T, de Tagle A, Heydenreich G, editors. Berlin: Springer; 2014.

Gottsegen MD. A manual of painting materials and techniques. Scranton: Harpercollins College Division; 1987. p. 184.

de Juan A, Jaumot J, Tauler R. Multivariate curve resolution (MCR). Solving the mixture analysis problem. Anal. Methods. 2014;6:4964–76.

Martins A, Albertson C, McGlinchey C, Dik J. Piet Mondrian’s Broadway Boogie Woogie: non invasive analysis using macro X-Ray fluorescence mapping (MA-XRF) and multivariate curve resolution-alternating least square (MCR-ALS). Herit Sci. 2016;4:22.

Alfeld M, Wahabzada M, Bauckhage C, Kersting K, Wellenreuther G, Falkenberg G. Non-negative factor analysis supporting the interpretation of elemental distribution images acquired by XRF. J Phys Conference Series. 2014;499:012013.

Santos HC, Caliri C, Pappalardo L, Catalano R, Orlando A, Rizzo F, Romano FP. Identification of forgeries in historical enamels by combining the non-destructive scanning XRF imaging and alpha-PIXE portable techniques. Microchem J. 2016;124:241–6.

Ordonez E. Analytical Report. Conservation records. New York: The Museum of Modern Art; 1999.

Lake S. Analytical Report. Conservation records. New York: The Museum of Modern Art; 1998.

Alfeld M, Pedroso JV, van Eikema M, Hommes G, van der Snickt G, Tauber G, Blaas J, Haschke M, Erler K, Dik J, Janssens K. A mobile instrument for in situ scanning macro-XRF investigation of historical paintings. J Anal At Spectrom. 2013;28:760–7.

Bright DS, Newbury DE. Maximum pixel spectrum: a new tool for detecting and recovering rare, unanticipated features from spectrum image data cubes”. J Microscopy. 2004;216:186–93.

Keenan MR, Kotula PG. Optimal scaling of TOF-SIMS spectrum images prior to multivariate statistical analysis. Appl Surf Sci. 2004;231–232:240–4.

Bro R, Smilde AK. Principal component analysis, tutorial review. Anal Methods. 2014;6:2812–31.

Golub GH, Reinsch C. Singular value decomposition and least squares solutions. Numer Math. 1970;14:403–20.

Windig W. Two-way data analysis: Detection of the Purest Variables. In: Brown S, Tauler R, Walczak R, editors. Comprehensive chemometrics, vol. 2. Oxford: Elsevier; 2009. p. 275–307.

Gallagher NB, Shaver JM, Martin EB, Morris J, Wise BM, Winding W. Curve resolution for multivariate images with applications to TOF-SIMS and Raman, Chemom. Intell Lab Syst. 2004;73:105–17.

Bro R, de Jong S. A fast non-negativity-constrained least squares algorithm. J Chemom. 1997;11:393–401.

Windig W, Shaver JM, Keenan MR, Wise BM. Simplification of alternating least squares solutions with contrast enhancement, Chemom. Intell Lab Syst. 2012;117:159–68.

Eastaugh N, Walsh V, Chaplin T, Siddall R. Pigment compendium, a dictionary and optical microscopy historical pigments, Butterworth-Heinemann. Burlington: Elsevier; 2004.

Meyers D. The color of art site map—Pigments, Paints and Formulas; 2013. http://www.artiscreation.com . Accessed May 2016.

CAMEO: The conservation and art materials encyclopedia online, Museum of Fine Arts, Boston. http://cameo.mfa.org . Accessed May 2016.

Gemperline PJ, Cash E. Advantages of soft versus hard constraints in self-modelling curve resolution problems. Alternating least squares with penalty functions. Anal Chem. 2003;75:4236–43.

Busa P. Quoted in Sidney Simon, Concerning the beginnings of the New York School: 1939–1943, Art International 11, no. 6 (summer 1967): 17.

Coddington J. No Chaos Damn It. In: Varnadoe K, Karmel P, editors. Jackson Pollock new approaches. New York: The Museum of Modern Art; 1999.

Conservation records. The Museum of Modern Art, New York.

Comment, The New Yorker, April 26, 1958. p. 23, http://www.newyorker.com/magazine/1958/04/26/comment-4537 . Accessed June 2016.

Otieno-Alego V, Hodgeman J, Creagh DC. Micro-Raman identification of bloom formed on a historical print artifact. JAIC. 2001;40:35–41.

Personal communication with Anny Aviram. Paintings conservator. New York: The Museum of Modern Art; 2016.

Coddington J, Hickey J. MoMA’s Jackson Pollock Conservation project: bringing the project to conclusion: restoration of Number 1A, 1948, Inside/Out, a MoMA-PS1 Blog. New York: The Museum of Modern Art. https://moma.org/explore/inside_out/2014/01/13/momas-jackson-pollock-conservation-project-bringing-the-project-to-conclusion-restoration-of-number-1a-1948 . Accessed Jun 2016.

Winter J, West FitzHugh E. Pigments based on carbon, in artist’s pigments, a handbook of their history and characteristics, Vol 4. In: Berrie BH, editors. National Gallery of Art, Washington. London: Archetype Publications; 2007.

Helwig K. Iron oxide pigments. In: Berrie BH, editor. Artist’s Pigments: a handbook of their history and characteristics, vol. 4. National Gallery of Art: Washington, Archetype Publications, London; 2007.

Van Gorkum R, Bouwman E. The oxidative drying of alkyd paint catalysed by metal complexes. Coord Chem Rev. 2005;249:1709.

Feller RL. Barium sulfate—natural and synthetic. In: Feller Robert L, editor. Artists’ pigments: a handbook of their history and characteristics, vol. 1. National Gallery of Art: Washington, Oxford University Press; 1987.

Wilkinson KH. Lithopone. In: Lewis PA, editor. Pigment handbook, properties and economics, vol. 1. New York: John Wiley & Sons Inc; 1973. p. 59.

Herbst W, Hunger K. Industrial organic pigments, production, properties, applications. 3rd ed. Weinheim: VCH; 1993.

Accorsi G, Verri G, Acocella A, Zerbetto F, Lerario G, Gigli G, Saunders D, Billinge R. Imaging, photophysical properties and DFT calculations of manganese blue (barium manganate(VI) sulphate)—a modern pigment. Chem Commun. 2014;50:15297–300.

de Keijzer M. A choice of colour: modern synthetic inorganic artists’ pigments, Restauratorenblätter Band 30, Works of Art from the 20th and 21st century: Problems and Perspectives, Verlag Stift Klosterneuburg; 2011.pp 33–42.

Roy A. Cobalt Blue, In: Berrie BH, editor. Artists’ pigments: a handbook of their history and characteristics, National Gallery of Art, Washington. London: Archetype Publications Ltd, vol. 4, p. 151. A manual of painting materials and techniques, Gottsegen MD. Harpercollins College Division. 1987.

Laver M. Titanium dioxide whites, in artist’s pigments. In: Berrie BH, editor. A handbook of their history and characteristics, Vol 4. National Gallery of Art, Washington. London: Archetype Publications; 2007.

Buxbaum G. Industrial inorganic pigments, 2nd edn. Weinheim: Wiley-VCH; 1998. p. 99.

Fiedler I, Bayard M. Cadmium yellows, oranges and reds. In: Feller RL, editor. Artists’ Pigments: A handbook of their history and characteristics, Vol. 1, National Gallery of Art, Washington. Oxford: Oxford University Press; 1987.

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