Synergistic use of Py–THM–GCMS, DTMS, and ESI–MS for the characterization of the organic fraction of modern enamel paints


Kokkori et al. Herit Sci  (2015) 3:30 
DOI 10.1186/s40494-015-0058-x

R E S E A R C H A R T I C L E

Synergistic use of Py–THM–GCMS, DTMS, 
and ESI–MS for the characterization of the 
organic fraction of modern enamel paints
Maria Kokkori1*, Ken Sutherland1, Jaap Boon2, Francesca Casadio1 and Marc Vermeulen3

Abstract 
Introduction: In this study, mass spectrometric techniques (THM–Py–GCMS, DTMS and ESI–MS) have been used to 
characterize the organic fraction of early twentieth century oil-based enamel paints. Analysis has been carried out 
on dry and liquid samples from historical reference paints, and on color swatches from commercial paint brochures, 
with a special focus on Ripolin. This renowned French brand of enamel paints, manufactured for household and other 
uses since 1897, was reportedly used by many avant-garde artists. Confirming the presence of enamel paint such as 
Ripolin in early twentieth century artworks scientifically through binding medium analysis is challenging because, 
until the end of the Second World War, the most widely used house paints were oil-based and chemically similar to 
artists’ oil paints. In addition, artists often modified/reformulated materials including oils, driers, industrial and house 
paints to customize their handling and optical properties. The challenge of identifying oil-based enamel paints on the 
basis of chemical composition is illustrated by the analysis of samples from two paintings by Wassily Kandinsky and 
Pablo Picasso.

Results: Analysis demonstrated that the organic fraction of Ripolin paints is typically composed of heat-bodied 
linseed oil in mixture with variable amounts of diterpene (Pinaceae) resin, in accordance with the industrial technical 
literature of the time. Comparative analyses of Lefranc artists’ tube paints suggested a more variable composition with 
respect to the type(s) of oil and their pre-treatment, and showed the presence of Pinaceae resin at trace levels only in 
two cases. Beeswax was detected in one of the tube paints tested.

Conclusions: The results of this study indicate that complementary information can be obtained from the study of 
liquid paint from cans and dried paint-outs, while the media of painted brochures may differ from the original formu-
lation as those were designed for expediency of drying and aesthetics. The results also elucidate how formulations 
and processing technology influence the physical and drying properties of oil-based enamel paints, in comparison 
with contemporary artists’ oil tube paints. Further research on a broader range of reference materials should help in 
the development of refined strategies for characterizing oil-based paints from the early twentieth century.

Keywords: Ripolin, Enamel paints, Mass spectrometric techniques

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Introduction
Ready-mixed industrial and household paints were an 
invention of the late nineteenth-early twentieth century 
[17]. Significant advances in paint technology and experi-
mentation with different types of raw or heat-processed 

oils, resins and curing agents, provided commercial 
painters with products that had good hiding and level-
ling properties, consistency and brushability, provided 
adequate protection to the surface, dried fast, and came 
ready-mixed in an easy-to-use can [44]. Similarly, the for-
mulations of artists’ tube paints were expanded to include 
a variety of ingredients, with a drying oil (one rich in 
polyunsaturated triglycerides) or mixtures of oils as the 
main component, and additives such as wax, rosin or 

Open Access

*Correspondence:  mkokkori@artic.edu 
1 The Art Institute of Chicago, 111 S. Michigan Ave., Chicago, IL 60603, 
USA
Full list of author information is available at the end of the article

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Page 2 of 14Kokkori et al. Herit Sci  (2015) 3:30 

metal soaps. The tube paint was designed to dry through 
oxidative cross-linking of the oil binder upon exposure 
to air and in the presence of a catalyst, which could be 
one of the pigments themselves, in a process that could 
take months to achieve a dry-to-the-touch surface and 
decades to reach a fully cured status. The ability for the 
paint to retain brushstrokes was important, as well as 
its thixotropic properties. On the other hand, industrial 
and household oil-based enamel paints were applied in 
thin coatings and required to be dry to the touch in a few 
hours and cured within days. A brushless surface appear-
ance was desired in most cases. In this context the term 
“enamel” describes the glossy, porcelain-like finish of the 
dried paint:  a brushless surface appearance was desired 
in most cases.

Oil-based enamel paints soon became popular among 
avant-garde European painters: Pablo Picasso, Wass-
ily Kandinsky, Francis Picabia, and René Magritte are 
among those reported to have used such paints in their 
works, in particular those produced by Ripolin. Ripo-
lin paints were originally developed in the Netherlands 
in the early 1890s through the work of the chemist Carl 
Julius Ferdinand Riep [37], and from 1897 until the end of 
the Second World War Ripolin production took place on 
the premises of the famed fine artists’ materials manufac-
turer Lefranc, in Issy-les-Moulineaux, a suburb of Paris. 
Ripolin paints were high grade enamels that enjoyed 
enormous success in commercial applications as well as 
with the avant-garde artists of the time [8, 15, 24, 25, 39].

Confirming the presence of enamel paint such as Rip-
olin in early twentieth century artworks scientifically 
through binding medium analysis is challenging because, 
until the end of the Second World War, the most widely 
used house paints were oil-based and chemically simi-
lar to artists’ oil paints. In addition, artists often modi-
fied their paints through the mixing of colors, as well as 
the addition of mediums, thinners, driers, waxes etc. to 
customize their handling and optical properties. As a 
result, suppositions about the presence of house paints in 
artworks have typically been based on a combination of 
visual characteristics, anecdotal and historical references. 
However, a growing body of reference data on the com-
position of paints from this period may help to provide 
more informed interpretations and distinctions between 
the different types of paints.

While the pigments and extenders for a large part of 
Ripolin’s production, spanning the period 1890–1950, 
have been documented [19, 39], no in-depth charac-
terization of the organic fraction has been published to 
date. Because of a growing interest in the formulations of 
20th century oil paints [47], with the publication of sev-
eral isolated studies of oil-based enamels of the period [1, 
7, 16, 21, 45], the results of this systematic study of the 

composition of the most important French brand of the 
early 20th century and its correlation with data from con-
temporary Lefranc artists’ tube paint samples represent 
an important benchmark.

Chromatographic and mass spectrometric methods 
have been extensively applied for the characterization 
of binding media of Old Master paintings and, similarly, 
of acrylics and other synthetic media, but only few stud-
ies to date have focused on the technology of oil-based 
enamel paints from the first half of the 20th century. To 
fill this gap, and to provide a thorough characterization 
of 20th century oil-based enamel paints, several mass 
spectrometric techniques were used: pyrolysis gas chro-
matography mass spectrometry with thermally-assisted 
hydrolysis and methylation (Py–THM–GCMS), direct 
temperature-resolved mass spectrometry (DTMS) and 
electrospray ionization mass spectrometry (ESI–MS). 
While GCMS techniques are well established for deter-
mination of the molecular components of oils and res-
ins, direct MS techniques such as DTMS and ESI–MS 
provide complementary information on paint composi-
tion since they can indicate the chemical form of species 
such as fatty and terpene acids in the paint (i.e. free, ioni-
cally or covalently bonded), and allow characterization 
of higher molecular weight and polymeric fractions not 
amenable to Py–THM–GCMS analysis. The compara-
tive analysis of paint in different forms—liquid samples 
from cans, dried paint-outs, and color swatches in bro-
chures—provided further insights into drying and ageing 
processes in the media, as well as the adjustments made 
by paint manufacturers to their formulations for different 
purposes. The experimental work conducted here is also 
important to shed light on the relative merits of these dif-
ferent kinds of samples for historic paint analysis.

This paper presents results from the characterization of 
the binding media of an extensive reference collection of 
early 20th century house paints, primarily Ripolin, along 
with paint brochures and Lefranc artists’ tube paints 
assembled at the Art Institute of Chicago (AIC, Fig.  1). 
Two analytical case studies are presented to illustrate 
the challenges in discriminating industrial house paints 
and artists’ paints in practice: Kandinsky’s Leichtes 1930 
(69  ×  48  cm, AM-1974-16; Musée National d’Art Mod-
erne, MNAM, Centre Georges Pompidou) and Picasso’s 
Pêcheur assis à la casquette, 1946 (106.5  ×  82.5  cm, 
Musée Picasso Antibes, MPA 1946.1.20).

Experimental
Samples
The oil-based enamel paints, all made by Ripolin except 
one ultramarine blue paint made by Bengaline, another 
French firm; and Lefranc tube paints were applied to 
microscope slides using a fixed-thickness applicator 



Page 3 of 14Kokkori et al. Herit Sci  (2015) 3:30 

to achieve a uniform film of approximately 100–200 
microns. For this investigation paint samples were taken 
from films which had been stored at ambient temperature 
in a variety of light conditions (dark storage and ambi-
ent indoor light) for approximately 6  years. Additional 
liquid and dried paint samples were taken directly from 
paint cans for analysis: when well-sealed, some cans have 
preserved their content in the liquid phase for almost a 
century. The examined samples cover a broad range of 
colors and dates of manufacture. 20 Ripolin paint sample 
cards (“brochures”, each containing 20–86 swatches of 
paint), which represent the entire color range produced 
by the company in France and roughly cover the period 
1897–1950, have been gathered and analysed as reported 
in an earlier study [19]; several examples are discussed 
here for comparison with the samples from cans. In total, 
31 samples of historic reference paints were analyzed for 
this study. The paint sample from Kandinsky’s Leichtes 
1930 (sample #1, light blue paint from drip at edge), was 
provided by the MNAM, Centre Georges Pompidou, 
Paris [32], and the sample from Picasso’s Pêcheur assis à 
la casquette, 1946 (sample #5 from the back: drip of gray/
white under “Antibes” in the artist’s writing) by the Musée 
Picasso, Antibes [7, 39]. The cold-pressed linseed oil used 
as a reference in the ESI–MS measurements was pre-
pared by Leslie Carlyle as part of the HART (Historically 
Accurate Reconstructions Techniques) project [5]; linseed 
stand oil was Winsor and Newton, collection of AIC.

Py–THM–GCMS
Py–THM–GCMS analyses were performed at AIC. Sam-
ples of c. 20–50 μg were placed in stainless steel sample 
cups (Frontier Disposable Eco-Cup LF) and 2–4 μL of tri-
methylphenylammonium hydroxide (25  % in methanol), 
depending on the sample size, were added; after 1 min the 
cup was loaded into the Frontier PY-2020iD pyrolyzer. A 
Varian 3800 gas chromatograph was used, coupled with a 
2200 ion trap mass spectrometer operated in EI positive 

mode (70 eV; scan range m/z 35–650). He carrier gas was 
used in constant flow mode (1.0  mL/min) with a 50:1 
split. The pyrolyzer temperature was 600  °C, GC inlet 
280  °C. The GC oven temperature was programed from 
50 °C with a 2 min hold, increased at 5 °C min−1 to 260 °C, 
3 min hold, and then at 20 °C min−1 to 300 °C, final hold 
5.9 min; total run time 54.9 min. The Varian MS data sys-
tem was used for data acquisition and processing.

DTMS
For DTMS analysis, an aliquot of sample is homogenized 
in ethanol, which is subsequently applied to a Platinum/
Rhodium filament probe (Pt/Rh 9:1, diam.100 microns) 
and inserted in the ionization chamber of the JEOL 
SX102-102A 4-sector mass spectrometer for in-source 
analysis. Temperature was ramped after a 10  s waiting 
time from room temperature to approximately 800  °C at 
a rate of 8 °C per second. Spectra were generated at 16 eV 
electron ionisation over a mass range up to 1,000 Dalton 
at a cycle time of 1 s and accelerating voltage of 8 kV [3]. 
A MP-7000 data system was used for data processing.

ESI–MS
ESI–MS was performed on a Thermo nano-ESI LTQ 
FTMS for positive ion analysis at AMOLF (Amsterdam) 
and a Thermo Finnigan LcQ DUO MS for negative ion 
analysis at the University of Lisbon. The ethanol extracts 
were analyses as ammoniated solutions of paint samples 
as described in earlier studies [53]. Aliquots of the paints 
were taken up in chloroform-ethanol (7:3) and centri-
fuged at 20,000  rpm to remove particulate matter. The 
solutions were diluted and ammonium acetate was added 
to a final concentration of 10 mmol.

Results and discussion
Py–THM–GCMS: samples from cans and paint brochures
Py–THM–GCMS analysis of paint samples from the cans 
and brochures indicated the presence of drying oil, in 

Fig. 1 Ripolin and other oil-based enamel paints in the Art Institute of Chicago’s reference collection.



Page 4 of 14Kokkori et al. Herit Sci  (2015) 3:30 

most cases combined with diterpene (Pinaceae) resin, as 
summarised in Table  1; representative examples of data 
for Ripolin Blanc d’ Ivoire and Noir d’ Ivoire are shown in 
Fig. 2. This is in general agreement with technical litera-
ture on oleoresinous paints and specific historical refer-
ences where Ripolin paint is often described as a lacquer 
containing linseed oil, resinous materials, some solvent 
and pigments [26] or as a ‘peinture vernissée’ containing 
hard or soft resins [38, 46].

The typical compounds indicating a drying oil are fatty 
acids and dicarboxylic acids deriving from the triacylglyc-
erols of the oil binder [33]. The ratio of palmitic to stearic 
acid (P/S, based on peak areas in the total ion chroma-
togram) ranges from 0.87 to 1.9 for the samples tested; 
while most of these values fall within the range typical 
for linseed oil (c. 1–2), the lower values may be attribut-
able to the presence of additives such as stearates. Metal 
stearates have been used in the paint industry to help 
suspend pigments in oil to prevent separation, to reduce 
the amount of oil needed to wet the pigment, and/or to 
increase the body of the paint by forming a gel with the 
oil thereby requiring less pigment [18].

The presence of drying oil was indicated in particular 
by high levels of dicarboxylic acids. These are relatively 
stable end-products formed upon oxidation and scis-
sion of unsaturated fatty acids and are encountered in 
relatively high amounts in aged oil paint systems. It is 
thought that the ratio of the diacids suberic acid (Su, 
C8) to azelaic acid (Az, C9) gives an indication whether 
the oil has been prepolymerized by heat treatment [34, 
50], since isomerization of the original double bond sys-
tems during heating leads to the formation of elevated 
amounts of diacids other than azelaic acid. Su/Az ratios 
of 0.4–0.5 have been proposed as an indication of heat-
processing of the drying oils, although the value will vary 
according to the exact nature and extent of prepolym-
erization and other factors. Bodied oils such as stand oil 
have higher viscosity and were used in oil enamel paints 
to improve application and performance characteristics 
[9, 36]. In the dried paint samples from cans examined, 
the generally high Su/Az ratios of 0.36–0.59 suggest that 
the oil medium has undergone heat-bodying. In com-
parison to the dried paint samples, the liquid samples 
analysed did not exhibit detectable levels of diacids and 
correspondingly higher levels of monounsaturated (oleic) 
and polyunsaturated acids (linoleic, linolenic and iso-
mers) were found; this is consistent with bulk paint that 
has been aged in a closed container and not exposed to 
oxidation.

Ricinoleic acid was detected in two samples, both 
red paints (Ripolin rouge de Chine HP016 and HP030). 
These paints also showed unidentified components with 
an anthraquinone structure suggestive of an organic 

pigment (positively identified as PR83, alizarin red, with 
Raman spectroscopy) [19, 39]. Ricinoleic acid, a mono-
unsaturated hydroxy C18 fatty acid, is a characteristic 
bio-marker for castor oil. This oil is considered a slow- 
or non-drying oil as it is composed of as much as 95  % 
ricinoleic acid, with only a few percent each of oleic and 
linoleic acids [43]. Surprisingly, it was considered a suit-
able painting medium by Doerner [13], although viscous 
and remaining wet for a long time; other authors recom-
mended that it be mixed with better drying oils such as 
linseed [29]. It is not clear at this time whether the pres-
ence of castor oil is related to the specific formulation of 
the Ripolin red color or to the manufactory of a specific 
batch of paint at a certain point in time. For example, 
Dredge [15] in a study of Ripolin paints used by Sidney 
Nolan in the context of Australian house paint produc-
tion mentions castor oil as a cheap alternative to linseed 
oil when imports to Australia from India ceased because 
of World War II. Erucic acid (a monounsaturated C22 
fatty acid) was detected at low levels in Ripolin samples 
HP087 (gris perle foncé), HP013 (bleu outremer), and 
HP089 (bleu turquoise). This compound is characteristic 
of Brassicaceae oils such as rapeseed [14], and has been 
observed in oil-based paints used by other 20th century 
artists such as Lucio Fontana [21, 55]. It may indicate the 
presence of this type of oil in the paint formulation as an 
additive or adulterant.

Although traditional household paints were based on 
linseed oil alone soon it became common to use oils in 
admixture to obtain optimum results. For example, the 
use of tung oil in various combinations with linseed oil 
was recommended [2, 22] as well as the use of other dry-
ing or semi-drying oils such as perilla, oiticica, soybean, 
fish and dehydrated castor oil [11]. However, the identifi-
cation of these or other types of drying or semi-drying oil 
recommended in the technical literature was not possible 
because of the lack of specific chemical markers for these 
materials.

The main resin components identified in the refer-
ence enamel paints were abietic acid and its oxidation 
products including dehydroabietic acid (DHA), 7-oxo-
dehydroabietic acid (7-oxo-DHA), and 15-hydroxy-7-oxo-
dehydroabietic acid (15-OH-7-oxo-DHA), indicative of 
diterpenoid (Pinaceae) resin, most probably pine resin. As 
with the fatty acids, greater proportions of the unoxidised 
or less oxidized species, abietic acid and DHA, were found 
in the liquid paint samples, consistent with a scarce sup-
ply of oxygen in the bulk samples in sealed historic cans. 
Pinaceae resins have been known and utilised through 
the ages as adhesives, coatings, etc. The resins are exuded 
from trees as balsams, which are rather viscous solutions 
of diterpenoid components in mono- and sesquiterpenes. 
Evaporation of the volatile monoterpene fraction results 



Page 5 of 14Kokkori et al. Herit Sci  (2015) 3:30 

in colophony (rosin), in the case of pine [41]. Pine coloph-
ony was used extensively in the paint industry and is still 
a commonly used raw material for industrial purposes; its 
properties and durability are often improved by chemical 

modifications such as esterification with glycerol [30]. 
Natural resins were used in the paint industry to improve 
the rheology of paints and to produce quick-drying, high 
performance enamels [10, 20].

Table 1 Summary of Py–THM–GCMS data from reference paint samples and case studies of Kandinsky and Picasso paint-
ings

n.d. = not determined: levels too low for accurate measurement.
a The numbers are Ripolin and Lefranc product numbers.
b All paint cans are Ripolin brand except one Bengaline sample, HP019 Bleu Outremer.

Sample Paint colora Description P/S Su/Az Pinaceae Additional components

Paint from cansb

 HP002 Blanc de Neige 1 Dry film 1.2 0.54 –

 HP008 Blanc d’Ivoire 53 Dry residue 1.9 0.40 Trace

 HP010 Gris Perle Foncé 10 Dry film 1.3 0.50 –

 HP087 Gris Perle Foncé 10 Dry film 1.1 0.38 x Erucic acid

Liquid 0.94 n.d. x Erucic acid; sesquiterpenes

 HP088 Gris Pierre Clair 76 Dry film 1.1 0.36 xx Trace sesquiterpenes

 HP013 Bleu Outremer 13 Dry residue 0.87 0.54 xx

Liquid 0.99 n.d. xx Erucic acid; sesquiterpenes

 HP019 Bengaline Bleu Outremer Dry film 0.99 0.40 xxx

 HP089 Bleu Turquoise Moyen 69 Dry film 1.1 0.56 xx Erucic acid; trace sesquiterpenes

 HP060 Noire d’Ivoire 5 Dry film 1.2 0.58 xxx Sesquiterpenes

 HP064 Noir d’Ivoire 5 Dry medium 1.1 0.47 xx

Liquid 1.1 n.d. xx Sesquiterpenes

 HP093 Noir d’Ivoire 5 Dry film 1.0 0.51 xx

 HP016 Rouge de Chine 16 Dry film 0.91 0.58 xx Ricinoleic acid; anthraquinone?

 HP030 Rouge de Chine 16 Dry film 0.91 0.59 xx Ricinoleic acid; anthraquinone?

 HP029 Vert Romain Moyen 73 Dry film 1.0 0.53 xx

 HP092 Vert Irlandais Clair 29 Dry film 1.0 0.41 xx Sesquiterpenes

Ripolin brochures

 B1 Blanc de Neige 1 Color swatch 1.4 0.42 x

 B1 Gris Perle Foncé 10 Color swatch 1.3 0.52 xx

 B1 Bleu Outremer 13 Color swatch 1.1 0.36 xxx

 B1 Noir d’Ivoire 5 Color swatch 1.0 0.32 xx

Lefranc tube paints

 2009.32 Blanc de Zinc Dry film 1.7 0.14 – Erucic acid

 2007.48 Blanc de Zinc Dry film 1.7 0.14 –

 2009.49 Blanc de Zinc Dry film 1.1 0.16 – Erucic acid

 2009.70 Blanc de Zinc Dry film 1.6 0.13 –

 2009.68 Blanc d’Argent Dry film 3.9 0.12 –

 2007.15 Outremer 2 Dry film 1.0 0.38 Trace

 2009.66 Outremer N1 Dry film 2.7 0.43 –

 2009.39 Bleu Mineral Dry film 1.1 0.23 – Erucic acid

 2007.31 Black (unlabeled) Dry film 0.79 0.16 –

 2007.61 Noir d’Ivoire Dry film 3.2 0.20 –

 2007.58 Laque Carminée Fixe Dry film 1.5 0.30 Trace Trace ricinoleic acid

 2007.04 Orange (unlabeled) Dry film 2.6 0.17 – Beeswax

Samples from paintings

 Kandinsky Light blue Paint 1.6 0.39 xxx

 Picasso White Paint 1.4 0.19 Trace



Page 6 of 14Kokkori et al. Herit Sci  (2015) 3:30 

Sesquiterpene hydrocarbons were identified in liq-
uid and certain dried samples. These are rather volatile 
compounds expected to disappear in the aged samples, 
probably by evaporation or polymerization; their pres-
ence in the Ripolin paint samples can be associated with 
the relatively young age (equal or less than 100 years old) 
of the examined samples that have had little exposure to 
air. The sesquiterpenes may be associated with the added 
Pinaceae resins but could also indicate the addition of 
turpentine to the paint, which was recommended on the 
labels on Ripolin cans to dilute the paints.

The amount of Pinaceae resin detected in the samples 
was found to vary according to the color: white and light-
colored paint samples contained less resin than the dark 
colors (see Fig.  2). In the first decades of the twentieth 
century, high gloss enamel paints reportedly comprised 
drying oils mixed with a semi-fossil resin such as Congo 
copal and/or a soft resin such as colophony (pine rosin) 
and good quality opaque pigments; though colophony 
was regarded as a poor and unstable paint ingredient, it 
was extensively used in enamel paint manufacture (Mat-
tiello, 228) in mixtures with drying oils and lime or zinc 
white or glycerol [40]. Because of the perceived ten-
dency of resins to discolor, technical manuals instructed 

commercial painters to make white and light-colored 
house paints using raw linseed oil and/or stand oil with 
very small quantities of resins, if any, whereas the addi-
tion of resins in large quantities was strongly recom-
mended for darker colored enamel paints. (Mattiello, 
199–206) This is in agreement with the findings on the 
Ripolin paints tested.

The detection of Pinaceae resin in Ripolin paints is 
perhaps surprising, as critical reading of period tech-
nical literature seems to imply that oil-based enamels 
including resins in their formulations were considered 
of lower quality, and Ripolin cans, on the contrary, were 
among the first and highest quality enamel paints avail-
able in the French market [39]. Historically, the highest 
quality enamels consisted of only stand oil as vehicle. It is 
important to note that in the sample set studied, the only 
non-Ripolin sample analysed, Bengaline bleu outremer 
(HP019), was the one for which the highest levels of resin 
diterpenes were detected.

Analysis of four paint samples from a Ripolin brochure 
(B1, c. 1930–1946) [19, 39] revealed a composition of 
drying oil and Pinaceae resin similar to the correspond-
ing colors from paint cans, although the levels of resin 
were higher in three cases (Blanc de Neige, Gris Perle 
Foncé and Bleu Outremer; the Noir d’Ivoire paint swatch 
showed similar levels of resin to the sample from the 
can). This finding suggests that the formulation of the 
paint may have been modified to achieve faster-drying 
samples for the brochures. Thus, while previous studies 
have shown the inorganic composition of paint swatches 
in Ripolin brochures to be highly consistent with the 
commercial paint in the cans [19, 35], the organic com-
position of the swatches must be interpreted with cau-
tion and may not give an accurate reflection of the actual 
formulation of the commercial products.

As mentioned above, historical literature indicated 
that copal was a common ingredient in enamel paints. 
Evidence for the use of copal in Ripolin paints of British 
production was reported in a study of Dredge et  al., as 
well as in a French promotional video produced by the 
Ripolin company at an unknown date before 1950 (Fig. 3) 
Compounds characteristic for copal were not detected in 
the current study, however. The detection of this semi-
fossil resin can be challenging because of the rapid degra-
dation of its characteristic diterpenes upon heating of the 
oil-resin mixture and subsequent ageing. For this reason 
the detection of intact copal diterpenes in oil-resin paints 
by Dredge et  al. is unusual. The industrial literature sur-
veyed [24, 25] in fact recommended the heating of copal/
oil mixtures in the presence of oxygen (a practice which 
may be responsible for the fire in the Ripolin factory in 
1904) [28]. In earlier studies using Py–GCMS, pyroly-
sis products of the polymeric phase of copal have been 

Fig. 2 Py–THM–GCMS data for a Ripolin Blanc d’Ivoire 53, HP008; 
b Ripolin Noir d’Ivoire 5, HP064; c Lefranc Noir d’Ivoire, 2007.61. P 
palmitic, S stearic, Su suberic, Az azelaic, Se sebacic acid, 7oxoDHA 
7-oxo-dehydroabietic acid, 15OH7oxoDHA 15-hydroxy-7-oxo-DHA (all 
compounds detected as methyl derivatives).



Page 7 of 14Kokkori et al. Herit Sci  (2015) 3:30 

identified as chemical markers for the aged resin, but 
these too may not be detectable depending on the exact 
heat/oxidizing treatment and ageing conditions [48–50, 
52, 54]. Further research is needed on this aspect of the 
paint composition, to provide a better understanding 
of detection limits using current analytical methods for 
copal that has been subjected to industrial processing, 
and to investigate whether additional chemical markers, 
such as reaction products of oil and resin components, 
may be detectable by (GC)MS methods.

Py–THM–GCMS: tube paints
Analysis of Lefranc tube paint samples showed the char-
acteristic components for drying oil, as discussed above; 
a representative example of data for Noir d’ Ivoire is 
shown in Fig. 2c. P/S ratios were in a broader range than 
for the samples from cans, from 0.79 to 3.9. Several of 
these values are higher than it is typical for linseed oil, 
suggesting that other oils are present in the tube paints; 
however, because of the wide range of possible oils availa-
ble to manufacturers at the time it is not possible to make 
an identification using this parameter alone [42]. As with 
the Ripolin paints, the lower values may be attributed to 
the presence of additives such as metal stearates. Trace 
levels of ricinoleic acid were detected in one Lefranc tube 
paint, a Laque Carminée Fixe (2007.58), indicating a cas-
tor oil component. Several tube paints (blanc de zinc 
2009.32, blanc de zinc 2009.49, and bleu mineral 2009.39) 
showed trace quantities of erucic acid, suggestive of a 

Brassicaceae oil such as rapeseed. The Su/Az ratios for 
the tube paints on the whole are lower than those found 
for the samples from cans: 0.12–0.43. While a few of the 
higher values might indicate the use of heat-bodied oil, 
in most cases the results suggest oil with little or no heat-
bodying. No evidence was found for the addition of natu-
ral resins to the paint formulations, with the exception of 
two samples (ultramarine no 2 clair 2007.15 and Laque 
carminée fixe 2007.58) in which traces of Pinaceae resin 
were detected. Evidence for the presence of beeswax 
(hydrocarbons and C20-24 fatty acids) was found in an 
orange paint (2007.04).

Case studies
The new information on the organic fraction of refer-
ence Ripolin and tube paints from the first half of the 
20th century can be used to deepen our understanding 
of data obtained from specific case studies of paintings. 
In this work, we analyzed with Py–THM–GCMS sam-
ples from two paintings showing visual characteristics of 
enamel paints, by Kandinsky and Picasso, artists who are 
documented to have used these materials. Kandinsky’s 
Leichtes, 1930 has been listed in the Pompidou catalogs 
primarily as “oil”, with occasional “oil and enamel” media 
identifications. Recent research identified a high amount 
of zinc white with little Prussian blue, trace amounts of 
barium sulfate and small quantities of lead and possibly 
cobalt driers in the paint sample of the light blue back-
ground paint [32]. Given the similarity of the molecular, 

Fig. 3 Stills from an undated promotional film produced by Ripolin, showing suppliers of resins and manufacturing processes.



Page 8 of 14Kokkori et al. Herit Sci  (2015) 3:30 

elemental and morphological fingerprint of the inorganic 
fraction in the Kandinsky sample with the formulation of 
the Bleu Azur Foncé paint of a Ripolin brochure predating 
1946, that previous study argued for the use of Ripolin by 
Kandinsky in select areas of the painting [32] Py–THM–
GCMS of the same sample, carried out for this project, 
strengthens this hypothesis, with fatty acid ratios of P/S 
1.6 and Su/Az 0.39, consistent with heat-bodied linseed 
oil and similar to the values for paint cans determined in 
this work (see Fig. 4a). High levels of Pinaceae resin were 
also identified: these results in combination with the pub-
lished analytical evidence on the inorganic fraction and 
the existing visual and documentary evidence support 
interpretation of the artist’s use of oil-based enamel paint 
in Leichtes [32].

A sample of whitish paint from a drip at the back of 
Picasso’s Pêcheur assis à la casquette, 1946 was previ-
ously analyzed with FTIR spectroscopy and found to 
contain mostly zinc oxide white, a drying oil and metal 
soaps. While the FTIR data matched well with reference 
samples of Ripolin white paint (such as HP002, Ripolin 
Blanc de neige) further analysis with Py–THM–GCMS 
conducted for this study demonstrated values of P/S 1.4 
and Su/Az 0.19, suggesting linseed oil with no heat-bod-
ying; coupled with only trace levels of Pinaceae (Fig. 4b). 
Pentachlorophenol was also detected in the sample (as 

its methyl ether): this compound was widely used in the 
early 20th century as a preservative for wood and other 
materials [6], and it may therefore be associated with the 
plywood support for this painting, or possibly with the 
formulation of the paint itself. While the low levels of 
Pinaceae resin are consistent with results from reference 
house paints in light colors presented in this work, the 
apparent absence of heat-bodying is not consistent with 
data for Ripolin paints and this result remains ambigu-
ous. Because several types of white oil-based enamel 
paints have been documented for Picasso in the collec-
tion of the Antibes Museum, it is possible that the paint 
in 1946.1.20 may represent another brand with inorganic 
fraction very similar to white Ripolin paints, but differ-
ences in the formulation of the medium [7].

These examples are useful to illustrate the advantages 
and limitations of the analytical approach. They also 
underscore how the positive identification of oil-based 
enamel paints, and especially of specific brands, can 
be challenging given the compositional similarities of 
enamel and artists’ oil paints of the time, as well as the 
possibility of artist’s manipulation of the original formu-
lations. A reliable hypothesis on the specific type of paint 
used can therefore only be put forth on the basis of the 
results of multiple types of analysis, taking into account 
both the organic and inorganic components.

DTMS and ESI–MS
As discussed in the introduction, DTMS and ESI–MS 
provide information on the paint medium composition 
complementary to that obtained with Py–THM–GCMS. 
For DTMS, no sample derivatization is required, and dif-
ferentiation is achieved between organic fractions in the 
paints: low molecular weight (volatile) species are evap-
orated and detected early in the analytical temperature 
program, whereas cross-linked or macromolecular com-
ponents are pyrolysed and analyzed later in the program. 
DTMS is a rapid analytical technique, with a typical cycle 
time of 5 min. ESI–MS is also valuable for the analysis of 
higher molecular weight species—triglycerides in par-
ticular—that are not observed using Py–THM–GCMS, 
since the latter technique involves hydrolysis of the glyc-
erides to produce methylated derivatives of the compo-
nent fatty acids.

DTMS analysis of samples from cans, paint brochures 
and tube paints corroborated the Py–THM–GCMS data 
with respect to the more volatile species: fatty acids were 
detected in ratios characteristic of drying oils (character-
istic ions were m/z 256 for palmitic and 284 for stearic 
acid, with electron ionization fragment ions of saturated 
fatty acids at m/z 60, 73, 129, 185, 213 and 241) and oxi-
dized diterpenes (ions at m/z 239, 253, 271, 299, 315 and 
330; see [51] characteristic of a Pinaceae resin such as 

Fig. 4 Py–THM–GCMS data for a a blue paint sample from Leichtes, 
W. Kandinsky, 1930, Centre Georges Pompidou, AM-1974-16; b a 
gray/white paint sample from Pêcheur Assis à la Casquette, P. Picasso, 
1946, Musée Picasso, Antibes, 1946.1.20. P palmitic, S stearic, Su 
suberic, Az azelaic acid, 7oxoDHA 7-oxo-dehydroabietic acid, 
15OH7oxoDHA 15-hydroxy-7-oxo-DHA, PCP pentachlorophenol (all 
compounds detected as methyl derivatives).



Page 9 of 14Kokkori et al. Herit Sci  (2015) 3:30 

pine resin in some of the paints from cans and brochures. 
In addition to fatty acids, glycerides (acylglycerols) were 
found preserved in about 20  % of the cases analysed 
(diagnostic peaks including m/z 550, 574–578 and 602–
606 indicative of diacylglyceryl ions with C16:0, C18:0, 
C18:1 and C18:2 fatty acids).

Examination of DTMS data for the Ripolin paints 
from cans provided clues to the chemical form of the 
resin component in the paint, as illustrated in Fig.  5 for 
HP008 (blanc d’ ivoire) and HP013 (bleu outremer). The 
two upper profiles show the total ion current (TIC) for 
HP008 (a) and the corresponding selected ion current for 
m/z 253, characteristic for oxidized Pinaceae diterpenes. 
The 253 ion is most prominent in the later region of the 
temperature program corresponding to pyrolysed poly-
meric material, around scans 60–75, suggesting that the 
resin is present in a bound/cross-linked form as a con-
sequence of the heat processing used in the preparation 
of the oil-resin medium. These results are compared with 
the TIC for HP013 (d) and the selected ion current for 
m/z 253 for the same sample (e). In trace (e) the 253 ion 
appears in a broader profile, from scans 20–75, indicat-
ing that some of the resin in this paint is present mixed 
but not chemically combined with the medium, and 
thus evaporates early in the temperature program. This 
unbound resin component is present in addition to the 
cross-linked resin that is released later in the run.

ESI–MS analysis of Ripolin paint samples from cans 
provided additional indications of the chemical reac-
tions undergone during heat-bodying of the paint 
medium. Figure 6 shows the positive ion mass spectrum 
of HP087 (gris perle foncé) measured over the range 
m/z 350–2,000, with an insert showing the distribu-
tion of the ammoniated triglycerides (triacylglycerides, 
TAGs) in the paint medium. The most prominent mass 
peaks observed correspond to TAGs ranging from m/z 
894–898. Table  2 lists the TAG mass peaks with their 
fatty acyl moiety distribution indicated as Ln (linolenic, 
18:3), L (linoleic, 18:2), O (oleic, 18:1), S (stearic, C18:0) 
and P (palmitic, C16:0); the unsaturated fatty acids may 
also be present in TAGs as isomers with respect to the 
position and configuration of the double bonds, which 
cannot be determined from the ESI–MS data. A further 
study of the positional distribution of double bonds in 
the glyceride fatty acids and their extent of isomerization 
could be valuable to characterize oils according to the 
heat pretreatments they have been subjected to. Peaks 
above m/z 900 suggest adducts formed during processing 
of the oil medium involving heating. Peaks around m/z 
1,750 are interpreted as two covalently-linked TAGs. A 
check over a larger mass range up to m/z 4,000 revealed 
some small intensity peaks, pointing to larger adducts, 
but it should be kept in mind that ion formation in ESI 

is strongly dependent on the polarity of the compounds, 
which diminishes when TAGs are covalently bound into 
larger complexes. Some adducts of fatty acid moieties 
with TAGs have been identified in frying oils [12] but a 
characterization of mass peaks observed in the ESI–MS 
data using tandem mass spectrometry (ESI–MSMS) is 
not straightforward, and further research is necessary for 
a more definitive identification of these higher mass spe-
cies. Research has shown that heating periods of weeks 
for the preparation of stand oil were not unusual in the 
late 19th and early 20th century [4], and in general the 
process of heating with exclusion of oxygen will lead 
to complex reactions including free radical formation, 
cross-linking from radical quenching, Diels–Alder reac-
tions, and isomerization (cis–trans and positional) of 
double bonds [23, 31]. Isomerization has been found to 
occur even at relatively low temperatures [53]. 

In Fig.  7, relative intensities of the TAG mass peaks 
in ESI spectra for liquid Ripolin medium samples from 
HP013 (bleu outremer), HP064 (noir d’ivoire) and HP087 
(gris perle foncé) are plotted alongside reference data for 
cold pressed linseed oil and linseed stand oil. The TAGs 
are plotted in order of increasing saturation (see Table 2). 
The distribution of the TAGs in stand oil as compared to 
cold pressed linseed oil can be interpreted in terms of a 
loss of the more unsaturated TAGs as a result of the pre-
polymerization treatment. The TAG profiles for the Ripo-
lin media match the profile of stand oil quite closely, and 
although the greater age of the Ripolin samples must be 
borne in mind, for these bulk paints aged in a closed con-
tainer with limited oxygen exposure the initial pretreat-
ment is likely to have had the most significant influence 
on the TAG composition. This finding thus reinforces 
the interpretation that in Ripolin formulations the oil has 
undergone prepolymerization leading to a diminished 
concentration of the most unsaturated TAGs.

Negative ion ESI mass spectra obtained from the same 
Ripolin paint media and stand oil reference sample show 
fatty acids as [M–H]− ions at m/z 255 (C16:0), 283 (18:0), 
281 (18:1), 279 (18:2) and 277 (18:3). The relative inten-
sities of these species are plotted in Fig.  7. Although the 
overall TAG distribution in the Ripolin samples shows 
clear similarities to that of the reference stand oil, as seen 
in the positive ion data in Fig.  8, analysis of the compo-
nent fatty acids highlights differences that are not evident 
from analysis of the intact TAGs. In particular, greater 
intensities for the 18:1 and 18:3 fatty acids (the latter 
including linolenic acid, along with its positional and 
configurational isomers) are observed in Ripolin samples 
as compared to the stand oil. This could be explained, for 
example, by a small addition of drying oil at a late stage 
in the production process, after heat-bodying has taken 
place. In the overall TAG (positive ion) data such an 



Page 10 of 14Kokkori et al. Herit Sci  (2015) 3:30 

Fig. 5 DTMS data for Ripolin samples Blanc d’Ivoire 53, HP008 (a–c), and Bleu Outremer 13, HP013 (d–f). The total ion current (TIC) and selected ion 
current for m/z 253 are shown for each sample along with a summed mass spectrum for the region indicated; see text for discussion.



Page 11 of 14Kokkori et al. Herit Sci  (2015) 3:30 

addition would be masked by the large relative amount of 
stand oil in the medium.a

The oxidation of unsaturated fatty acids has also been 
shown to be reduced when ageing occurs in the presence 
of colophony resin [27], which could be an additional fac-
tor in the greater levels of 18:3 and 18:1 acids observed in 
the Ripolin samples.

In this first study of Ripolin paints with DTMS and 
ESI–MS, the mass spectrometric approaches clearly 
show promise for the elucidation of cross-linking and 

polymerisation mechanisms brought about by industrial 
processing of oils and resins, as well as by subsequent 
modification, drying and ageing of the paints, and fur-
ther research using these techniques may be helpful to 
develop diagnostic strategies and indicate novel marker 
compounds for the characterization of oil media.

Conclusion
The analysis of the organic fraction of early 20th century 
oil paints, and the characterization of oil paints in works 
of art, poses significant challenges due to the variability 
and complexity of the paint formulations as well as modi-
fications executed by artists. Twentieth century artists 
experimented with a range of materials including manu-
factured artists’ paints and also modified/reformulated 
materials such as mixtures of oils, driers, industrial and 
house paints.

In this study, Py–THM–GCMS demonstrated that the 
organic fraction of the house paints tested (primarily 
French oil-based Ripolin enamels) is composed of heat-
bodied linseed oil in admixture with Pinaceae resin, with 
evidence for the addition of castor and rapeseed oil found 
in a few samples. The identification of other types of dry-
ing oils such as soybean, perilla or fish oil recommended 
for industrial oil-based paints in technical literature is 
challenging because of similarities in their fatty acid com-
position. As a comparison, the results from the tube oil 
paints suggested the use of more than one type of drying 
or semi-drying oil, as indicated by the more divergent P/S 
ratios and for the most part they seem to have undergone 

Fig. 6 ESI–MS positive ion data for Ripolin sample Gris Perle Foncé 10, HP087, with inset showing expanded region corresponding to ammoniated 
triglycerides as listed in Table 2.

Table 2 Nominal masses of  triglyceride (TAG) ammo-
nia adduct ions detected by  ESI–MS, with  their fatty acid 
composition [P  =  palmitic, S  =  stearic, O  =  oleic (or iso-
mer), L  =  linoleic (or isomer), Ln  =  linolenic (or isomer)] 
and numbers of double bonds in the fatty acyl moieties

Nominal mass Double bonds TAG

868 6 PLnLn

870 5 PLLn

872 4 POLn PLL

874 3 POL PSLn

890 9 LnLnLn

892 8 LnLnL

894 7 LnLnO LnLL

896 6 OLLn LLL SLnLn

898 5 OOLn OLL SLLn

900 4 SOLn OOL SLL

902 3 SSLn OOO SOL



Page 12 of 14Kokkori et al. Herit Sci  (2015) 3:30 

little or no heat-bodying. Trace levels of Pinaceae resin 
were found only in a few tube paints, and beeswax was 
detected in one example. DTMS and ESI–MS data com-
plemented the Py–THM–GCMS analyses, providing 
indications of the cross-linking and prepolymerization 
reactions occurring during processing of the oils, and 
as a result of reaction between the oil and resin compo-
nents of the paints. Further research on a broader range 
of reference materials should help in the development of 
refined strategies for characterizing oil-based paints from 
the early 20th century.

The results of this study indicate that complementary 
information can be obtained from the study of liquid 

paint from cans and dried paint-outs, while the media of 
painted brochures may differ from the original formula-
tion as those were designed for expediency of drying and 
aesthetics. The results also elucidate how formulations 
and processing technology influence the physical and 
drying properties of oil-based enamel paints, in compari-
son with contemporary artists’ oil tube paints.

Endnote
aAdditions of a few percent of linseed oil to a stand oil 

medium are still used in the artists’ oil paint industry to 
obtain a fast-drying surface film with enamel-like prop-
erties; Langridge Artist Colors, Factory 23, 155 Hyde 

Fig. 7 Bar graph of the relative intensities of ions corresponding to triglycerides in positive ion ESI–MS spectra of Ripolin samples HP013, HP064 
and HP087, compared with reference linseed oil samples; nominal masses correspond to Table 2.

Fig. 8 Bar graph of the relative intensities of ions corresponding to fatty acids in negative ion ESI–MS Ripolin samples HP013, HP064 and HP087, 
compared with reference linseed stand oil.



Page 13 of 14Kokkori et al. Herit Sci  (2015) 3:30 

Street, Yarraville, Vic. http://www.langridgecolours.com) 
September 2014, personal communication.

Authors’ contributions
MK analysed data and drafted the manuscript; KS interpreted the GCMS data 
and edited the manuscript; JB conducted DTMS and ESI–MS analysis; MV 
conducted GCMS analysis; FC supervised the project. All authors read and 
approved the final manuscript.

Author details
1 The Art Institute of Chicago, 111 S. Michigan Ave., Chicago, IL 60603, USA. 
2 JAAP Enterprise for Art Scientific Studies, Amsterdam, The Netherlands. 
3 IRPA-KIK Royal Institute for Cultural Heritage, Brussels, Belgium. 

Acknowledgements
National Science Foundation, Division of Materials Research, DMR 1241609 the 
Grainger Foundation, the Stockman Family Foundation, and the Mellon Foun-
dation. Veronique Sorano-Stedman Brigitte Léal, Sylvie Lepigeon, Géraldine 
Guillaume-Chavannes and Ingrid Novion at the Pompidou are also gratefully 
acknowledged, as well as Jean-Louis Andral at the Musée Picasso, Antibes, for 
supporting analysis of the samples form works in their collections; Jerre van 
der Horst (AMOLF, Amsterdam NL) for assistance with DTMS; Mark Duursma 
(AMOLF, Amsterdam NL) and Pedro Alves (University of Lisbon, Lisbon, P) for 
assistance with ESI–MS.

Compliance with ethical guidelines

Competing interests
The authors declare that they have no competing interests.

Received: 2 April 2015   Accepted: 24 July 2015

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	Synergistic use of Py–THM–GCMS, DTMS, and ESI–MS for the characterization of the organic fraction of modern enamel paints
	Abstract 
	Introduction: 
	Results: 
	Conclusions: 

	Introduction
	Experimental
	Samples
	Py–THM–GCMS
	DTMS
	ESI–MS

	Results and discussion
	Py–THM–GCMS: samples from cans and paint brochures
	Py–THM–GCMS: tube paints

	Case studies
	DTMS and ESI–MS

	Conclusion
	Endnote
	Authors’ contributions
	Received: 2 April 2015   Accepted: 24 July 2015References