

Collections care scenario appraisal for painting canvases at Museu Nacional d'Art de Catalunya, Barcelona, Spain


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Original research paper

Collections care scenario appraisal for
painting canvases at Museu Nacional d’Art de
Catalunya, Barcelona, Spain
Marta Oriola1, Gema Campo1, Cristina Ruiz-Recasens1, Núria Pedragosa2,
Matija Strlič3

1Faculty of Fine Arts, Conservation Section, University of Barcelona, Barcelona, Spain, 2Conservation
Department, Museu Nacional d’Art de Catalunya, Barcelona, Spain, 3Institute for Sustainable Heritage,
University College London, London, UK

We surveyed the canvas of 31 paintings from the collection of the Museu Nacional d’Art de Catalunya,
Barcelona, Spain, using non-destructive near infrared spectroscopy (NIR) in order to determine the pH
and degree of polymerisation (DP) of the canvas supports. The data showed that the canvases, all from
1890 to 1910, are acidic (average pH 5.1 ± 0.4) and fairly degraded (DP 710 ± 260). Using the dose-
response function for cellulosic materials with pH, DP, T, and relative humidity (RH) as inputs, the rate of
degradation can be calculated, as well as the period of time until the point when the canvases become so
fragile that their handling could lead to mechanical damage and thus risk the integrity of paint layers. On
the basis of the survey data, we calculated isochrone plots as well as demographic curves for the
collection. Using these, we explored a number of conservation management scenarios and compared
them with the expected rate of degradation under current average environmental conditions (21 °C, 58%
RH). At these conditions, it is predicted that the average canvas will become fragile and might require
interventive treatment in ca. 140 years. However, if the storage temperature is decreased, or if the
canvases are deacidified, the period of time until treatment becomes necessary can be considerably
increased. As a separate case study we also present a survey of the canvas of The Woman in Hat and Fur
Collar (Marie-Thérèse Walter) by Pablo Picasso. The pH and DP of this canvas was determined in 15
sampling points, the averages being pH 5.6 ± 0.2 and DP 1700 ± 320, which allowed us to calculate the
isochrone plot for this canvas.

Keywords: NIR spectrometry, pH, DP, Canvas degradation, Lifetime prediction, Paintings

Introduction
In a traditional easel painting, the canvas support is
made of plant-derived cellulosic fibres. In a recent
survey of a large sample set of ca. 200 historic can-
vases, the majority was found to have pH of 4.5–6.0,
i.e. less than neutral (Oriola et al., 2011). Acidity in
the environment of a cellulose macromolecule is well
known to catalyse its hydrolytic breakdown, thus
decreasing its degree of polymerisation (DP, the
number of monomers in a macromolecule) (Zou
et al., 1996; Strlič & Kolar, 2005). Fibres with a

lower DP are known to have lower mechanical resist-
ance thus reducing the fitness of the textile to be
used (Zou et al., 1996).
Painting canvases with a DP of ca. 600 can be con-

sidered to be at the upper boundary of the ‘very fragile’
condition category (Oriola et al., 2011). In the survey
of 35 degraded canvas samples carried out by 17 inter-
nationally renowned paintings conservators, it was
established (with a remarkable level of agreement)
that such canvases are fragile to the point where they
‘cannot be stretched without reinforcement’ and
‘excessive stress is not advisable’. Such canvases
could be considered to be at high risk of tearing and
similar mechanical damage during handling (reloca-
tion of a painting, transportation to exhibitions,
etc.), thus requiring resource-intensive interventive
treatment.

Correspondence to: Marta Oriola, Facultat de Belles Arts, C/ Pau Gargallo 4,
08028 Barcelona, Spain. Email: martaoriola@ub.edu; Matija Strlič, Institute
for Sustainable Heritage, University College London, Central House, 14
Upper Woburn Place, London WC1H 0NN, UK. Email: m.strlic@ucl.ac.uk

© The International Institute for Conservation of Historic and Artistic Works 2015
MORE OpenChoice articles are open access and distributed under the terms of the Creative Commons Attribution License 3.0
DOI 10.1179/0039363015Z.000000000224 Studies in Conservation 2015 VOL. 60 SUPPLEMENT 1 S193

mailto:martaoriola@ub.edu
mailto:martaoriola@ub.edu
mailto:m.strlic@ucl.ac.uk
mailto:m.strlic@ucl.ac.uk
mailto:m.strlic@ucl.ac.uk
mailto:m.strlic@ucl.ac.uk


The time until fitness for use is lost (useful lifetime)
of a canvas can be managed either by controlling
environmental conditions or by alteration of the chemi-
cal properties of a canvas. The addition of a deacidifi-
cation agent counteracts the acidity of a canvas and
delays its chemical degradation (Poggi et al., 2013)
and therefore its fragility (Seves et al., 2000). This is
not a frequently used procedure, although a reassess-
ment of its conservation cost–benefit might be timely.
Environmental management of paintings collec-

tions, on the other hand, is (understandably so)
geared towards conservation of the paint layer. Here,
particularly for mixed (canvas and panel) and
framed collections, the concerns lie elsewhere:
adhesion of paint, gilding, and gesso layers, as well
as mechanical stability of wooden parts, are
managed by suitably controlling fluctuations of rela-
tive humidity (RH) (PAS198, 2012), whereas the
chemical stability of canvases is seen as a secondary
concern. However, both fluctuations and long-term
averages of environmental parameters can be
managed so that preservation is optimised.
The time until the fitness of a canvas to support the

paint layer is reduced to a state when the risk of mech-
anical damage is unacceptable (Strlič et al., 2013), is
determined by the rate of its degradation. There is
ample evidence in the literature that the degradation
rate of cellulosic materials is affected by temperature
(T) and RH (Sebera, 1994). A recent Collections
Demography project re-examined the available exper-
imental evidence and quantitatively demonstrated
how the rate of degradation of cellulosic materials is
affected by material acidity (Strlič et al., 2015). A
dose-response function describing this dependence
was calculated and a new isoperm for cellulosic
materials was presented.
Ontheotherhand,itcan beassumedthatphotodegra-

dation is negligible in the majority of cases, since in easel
paintings the canvas is usually protected from light.
Additionally, in post-industrial environments the degra-
dative effects of outdoor pollutants (NO2 and SO2) and
even of indoor pollutants (acetic acid) can be assumed
to be of minor importance in comparison with T, RH,
and inherent acidity (Menart et al., 2014).
Using the knowledge of degradation of cellulosic

materials available in the literature, it should therefore
be possible to predict the distribution of rates of degra-
dation of canvases in a collection, as long as we know
the distribution of pH and DP. This data can be col-
lected using near infrared spectroscopy (NIR), a
non-destructive analytical tool that can easily be
used in a non-laboratory environment as it requires
no sample preparation and no sampling (Oriola
et al., 2011).
NIR spectroscopy was first used to survey a collec-

tion of painting canvases non-destructively in the

Teatre-Museu Dalí in Figueres, Spain (Oriola et al.,
2014). The DP and acidity of 12 canvases were deter-
mined using this technique, based on the same prin-
ciple as previously used for historic paper (Trafela
et al., 2007), historic textiles (Richardson et al.,
2008), photographs (Fenech et al., 2013), and other
types of collections. The principle is based on
multivariate analysis of spectral data and method
calibration based on a set of known and well-
characterised physical samples. However, an
important limitation of this method is that it can
only be used for objects that are as similar to the
calibration set as possible.

In this work, the developed NIR method has been
applied to a collection of canvas paintings from the
Museu Nacional d’Art de Catalunya, Barcelona,
Spain. The obtained survey data (pH and DP
values) was analysed using the Collections
Demography dose-response function for cellulosic
materials to provide evidence-based advice for conser-
vation management of painting canvases.

Methodology
Collection survey
Using the previously developed methodology based on
NIR spectroscopy of painting canvases (Oriola et al.,
2011, 2014), pH and DP were determined for 31
canvas paintings by Catalan painters, from 1890 to
1910, at the Museu Nacional d’Art de Catalunya,
Barcelona, Spain (MNAC) (Supplementary material 1).
A painting by Pablo Picasso from 1937 was also
analysed using this technique. From the material
point of view, the canvases from this collection are
contemporary with the ca. 200 canvas samples used
for method calibration, the pH of which was deter-
mined using a cold-extraction method, while DP was
measured using viscometry (Oriola et al., 2011). The
majority of these calibration samples were from the
nineteenth to the twenty-first century and from
Catalonia, therefore of a very similar provenance to
the canvases used in the survey. Consequently, the
NIR spectroscopic method is likely going to give
reliable data.

Since the surveyed paintings were selected on the
basis of age, provenance, absence of any previous con-
servation treatments, and availability, the survey
cannot be considered to be random, and thus represen-
tative of the larger collection. However, the selection
restrictions were necessary in order to obtain collec-
tion data to be used to develop conservation guidance:
a diverse collection of differently degraded and
untreated real historic canvases.

NIR measurements
The NIR method for determination of pH and DP of
historic canvases as developed in previous research

Oriola et al. Collections care scenario appraisal for painting canvases

Studies in Conservation 2015 VOL. 60 SUPPLEMENT 1S194


(Oriola et al., 2014) was used in the survey (errors of
prediction being ±0.4 for pH and ±270 for DP deter-
mination). The spectra (100 averaged spectra per
measurement spot) were taken at the back of a paint-
ing using a LabSpec 5000 NIR spectrometer equipped
with fibre optics and a custom-made attachment for
spectral collection in the 45°/45° geometry. The diam-
eter of the measured spot was ca. 2 mm. Multivariate
analysis of data (partial least squares regression) and
prediction of pH and DP was carried out using
Grams software (Thermo Scientific). Values of pH
were obtained for all canvases, while DP for three can-
vases (Cat. nos. 004.660, 004.631, 011.382) was not,
due to failed statistical tests (Mahalanobis distance
>3) indicating low reliability of these predictions.
Several measurements were made per canvas, typically
up to 7, and the average is reported.
Using the canvas identification algorithm based on

linear discriminant analysis of NIR spectra (Oriola
et al., 2014), bast, cotton, and jute fibres were ident-
ified, however, out of the 31 surveyed paintings, only
3 were made of jute and 3 were made of cotton
fibres, the rest were all made of bast fibres.

Isoperm and isochrone calculations
The Collections Demography dose-response function
for degradation of cellulosic materials was used
(Strlič et al., 2015) to calculate isoperms – lines con-
necting pairs of T and RH values at which the rate
of degradation or permanence of a material is equal
(Sebera, 1994). However, since the Collections
Demography function reflects not only T and water
content (which depends on RH), but also pH of the
material, isoperms based on this function need to
reflect the pH of actual canvases.
Namely, as is well known, a reference permanence is

needed in the calculation of isoperms. In Sebera’s
work, this was calculated for 20 °C and 50% RH,
but we need to note that his data were developed for
acidic paper though of course at the time, this was

not considered as an input in the calculations, as a suit-
able dose-response function did not exist at that point.
In this work, however, we calculated isoperms for the
actual MNAC collection, so it made sense to take the
reference permanence as that of an average canvas, i.e.
pH 5.1, 20 °C, and 50% RH.
Using the threshold DP at which the risk of mechan-

ical damage to canvas is considered to be substantial
(loss of fitness for use), isochrones can be calculated.
These combine pairs of T and RH with equal expected
time until loss of fitness for use. In addition to depen-
dence on pH, isochrones also depend on the starting
DP, which is why two isochrone plots have been calcu-
lated, for the average DP and pH as determined in the
MNAC survey, and for the same DP and pH 8, repre-
senting the stability of hypothetically deacidified
canvas. All data analysis was carried out using
Origin Pro 9.0.

Results
Museu Nacional d’Art de Catalunya survey
The survey revealed that the paintings from MNAC,
all of which were from 1890 to 1910 on canvas
which has not undergone any interventive treatments
as yet, are appreciably degraded, considering that the
starting DP of new linen canvas was measured to be
as high as 6600 (Oriola et al., 2012). In contrast, the
average pH of the surveyed canvases was 5.1 ± 0.4
and the average DP was 710 ± 260 (Fig. 1). The fre-
quency plots also show distributions of pH and DP
peaking around average values tailing off towards
lower pH and higher DP.
It might be of interest to speculate why the values

are so low: namely, if the value of DP of canvas at
the point of production was a multiple of 1000, then
the average DP of 710 must be a reflection of extensive
degradation the canvases have already undergone.
Similarly, given the low pH value and again consider-
ing that fresh linen has a neutral pH, acidification

Figure 1 Frequency plots for pH (n = 31) and DP (n = 28) distribution for the surveyed paintings from the MNAC collection.

Oriola et al. Collections care scenario appraisal for painting canvases

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must have taken place either by (i) absorption of acidic
atmospheric pollutants, (ii) through penetration of oils
or varnishes from the front of a painting into the
canvas and their oxidation which yields acidic pro-
ducts such as carboxylic acids, (iii) oxidative degra-
dation of the cellulosic fibres themselves, or (iv) use
of products such as acidified (hardened) animal glues
or similar. In either case, the paintings have survived
the period of Catalan industrialisation, whereas in
post-industrial environments there is now a relatively
much cleaner environment in comparison with the
recent past (Brimblecombe & Grossi, 2009). It is there-
fore safe to assume that environmental pollution is not
going to represent a major source of acidification in
the near future. Local staining and discolouration
does not seem to result in significantly higher local
acidity either (Oriola et al., 2014), which would
mean that future acidification is likely going to be a
consequence of natural degradation processes inherent
to canvas.
It is of interest to compare MNAC averages with the

data obtained from the survey of 12 Dalí paintings
from Teatre-Museu Dalí, Figueres, Spain (Oriola
et al., 2014). The pH averages for the Dalí paintings
were 5.6 ± 0.4, which indicates less acidification
which translates into less degradation as well (DP
960 ± 350). The differences between the two survey
data could result from different starting acidity of the
materials used or different environmental histories of
the collections. Additionally, the surveyed Dalí can-
vases are all younger (1924–1968) than the surveyed
MNAC canvases (1890–1910), which should result in
more degradation of the latter.
The survey data itself, while of significance, does not

allow for any conclusions on what the optimal conser-
vation management strategies could be. To do this, we
need to predict how different environmental con-
ditions or conservation treatments will affect canvas
degradation in the future, and compare the outcomes.

Isoperm
The isoperm plot for the MNAC collection, calculated
using the Collections Demography dose-response func-
tion for cellulosic materials (Strlič et al., 2015), rep-
resents a plot of lines connecting points of equal
permanence, defined as the ratio of the rate of degra-
dation at a given combination of T, RH, and canvas
pH, vs. the rate of degradation at 20 °C, 50% RH,
and pH 5.1. This value of pH represents the average
pH of canvases in the collection, while the values of
T and RH represent typical values for exhibition
spaces, as adopted by Sebera (Sebera, 1994).
The isoperm plot allows us to estimate environ-

mental conditions at which the permanence of an
average canvas will be higher or lower than at 20 °C,
50% RH, where the permanence is arbitrarily set as

1 (Fig. 2). Thus, the isoperm is useful to compare
the suitability of various display or storage environ-
ments in relation to canvas degradation, but does
not allow us to assess the following:

– The effect of environmental fluctuations, affecting
material contraction/expansion and the associated
crack formation/growth, or adhesion of layered
structures
– The expected time until the MNAC canvases will
become ‘very fragile’

The former would need to be assessed using a
dose-response function describing crack growth and
delamination of paint layers as a function of RH or
temperature fluctuations, which is not the purpose of
this work. The latter, however, requires us to introduce
the concept of threshold DP, i.e. DP at which canvases
become unfit for manual handling, i.e. they become
‘very fragile’.

Canvas isochrones
In our previous work (Oriola et al., 2011), we have
shown that the category of canvases classified as
‘very fragile’ represents canvases with DP < 600,
which could thus be taken as a suitable threshold DP
for this category. This is a conservative threshold
value, as it represents the upper limit of the ‘very
fragile’ category: if a canvas was assessed as a border-
line ‘very fragile’ canvas, at least half of the assessors
actually thought it did not belong to the most fragile
category.

A less conservative threshold would reflect a higher
level of agreement between assessors. At DP 400,
80–100% of conservators-assessors agreed that the
canvas should be categorised in the unfit category.
Given that it has been shown that at DP 250 cellulosic
fibres lose all mechanical properties (Shroff &
Stannett, 1985), DP 400 represents the median DP of

Figure 2 The isoperm plot for MNAC canvases, taking the
average pH of the 31 surveyed canvases (and 20 °C/50% RH)
as the reference permanence conditions.

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the ‘very fragile’ category, and thus a more suitable
fitness threshold than its upper limit. We therefore
propose DP 400 as the threshold DP in the calcu-
lations of useful lifetime of painting canvases.
With this threshold, and using the Collections

Demography dose-response function, it is now poss-
ible to calculate isochrones, i.e. contour diagrams
linking points of equal expected remaining lifetime
for painting canvases in the collection of MNAC
(Fig. 3). We have taken the average pH (5.1) and
average DP (710) of the 31 surveyed canvases as the
starting point in these calculations, and DP 400 as
the endpoint.
The isochrone plot in Fig. 3 (left) shows that at

Sebera’s reference environmental conditions of 20 °C
and 50% RH, the average MNAC canvas will
become ‘very fragile’ in ∼220 years. Given that the
average environmental conditions in MNAC galleries
are 21 °C and 58% RH, this period of time is
reduced to ∼140 years. This is a reasonable prediction,
if we take into account that the similar canvases at the
Teatre-Museu Dalí were in average 40 years younger
and had an average DP higher by ∼290 – here we
need to note that the Dalí canvases are less acidic
and that the ageing curve is an exponential one, i.e.
it levels off at longer ageing times.
Whether or not the average expected time until loss

of fitness is a concern is a matter for discussion and
needs to take into account the frequency of use of
these canvases (e.g. travel to exhibitions) and their
value other than utility, such as rarity, artistic, or his-
torical value. In a recent assessment of a suitable long-
term planning horizon for collections of objects of no
ascribed exceptional value (Dillon et al., 2013), the
horizon of 500 years for preventive conservation man-
agement was considered suitable, on the basis of a
questionnaire distributed among visitors to a number
of large archives and libraries in the UK and the

USA. Compared to this planning horizon, a lower
storage temperature of ca. 15 °C would be suitable,
while maintaining the same RH of 50%.
(Interestingly, the mean annual temperature in
Barcelona is 15 °C (Wikipedia, 2014) which indicates
that a passive but humidity-controlled storage environ-
ment would suffice.)
On the other hand, cooling of a collection year-

round is a very resource-intensive option. In Fig. 3
(right), the isochrone plot is shown for the same collec-
tion, yet assuming that it has been deacidified, i.e. the
pH of the canvas has been increased to 8. It is clear
that by using this conservation intervention, it is poss-
ible to increase the period of time until loss of fitness
considerably, to ∼1100 years.
From the resource point of view, the cost–benefit

analysis clearly shows that deacidification is preferable
to cooling. However, ethical considerations also need
to be taken into account. Deacidification would lead
to loss of material integrity of the canvas (i.e. change
of its chemical composition due to deacidification)
and this needs to be weighed against the delayed risk
of loss of integrity of the painted layer.

Demography of the Museu Nacional d’Art de
Catalunya collection
With the data for the surveyed paintings at hand, it is
now also possible to calculate the time needed for each
individual object in this collection to degrade until it
becomes ‘very fragile’, since we have access to the
average pH and DP data for each object. Currently,
four canvases have already reached this stage, i.e.
15% of the collection.
The resulting frequency plot, showing the predicted

‘survival’ rate binned into intervals of 50 years, shows
a steadily decreasing curve, reflecting the spread of pH
and DP values of canvases in the collection. The
demographic plot is monotonic, which is a

Figure 3 Isochrone plots for the average MNAC painting canvas (starting pH 5.1 and DP 710) at various environmental
conditions (left), and assuming the pH of these canvases is increased to 8 by deacidification (right).

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consequence of the narrow Gaussian distribution of
pH values. This is in contrast with the demographic
plot for library collections, which is usually double-
bell shaped, reflecting the ageing of two populations
of paper: acidic and alkaline.
The demographic plots (Fig. 4) can be used to

evaluate the effect of different conservation manage-
ment scenarios. These show how storage at a lower
temperature or deacidification would affect the degra-
dation of canvases: by storage in a passive (yet humid-
ity controlled) environment at an average annual
temperature of 15 °C, about 40% would survive 500
years without reaching the ‘very fragile’ state. On the
other hand, by deacidification (increase of pH to 8)
and storage at current environmental conditions, this
number would increase to 60%.

The Woman in Hat and Fur Collar (Marie-Thérèse
Walter)
In 1937, Pablo Picasso painted the exceptional canvas
The Woman in Hat and Fur Collar (Marie-Thérèse
Walter), in the collection of MNAC (Doñate &
Llorens, 2007). As a separate case study, we measured
the pH and DP of this canvas at 15 points, with the
averages being pH 5.6 ± 0.2 and DP 1700 ± 320.
Picasso painted it on a commercially primed plain
weave canvas, of which one of the threads is cotton
and the other one is a bast fibre (possibly linen).
The canvas of this painting is evidently in a good

state, and would have been classified as ‘good con-
dition’ in the survey referred to above (Oriola
et al., 2011). As an example of a canvas in a ‘good
condition’, it is of interest how quickly it will
degrade in the future at various environmental
conditions.
In Fig. 5, we present the isochrone plot for the

canvas, showing that at the current average annual
environmental conditions in MNAC galleries of

21 °C and 58% RH, it will take approximately 330
years for the canvas to degrade to the ‘very fragile’
state, while at Sebera’s reference conditions (20 °C,
50% RH), this period would be ca. 500 years.

Conclusions
A survey of a limited number of canvases around the
year 1900 (±10 years) was performed at the Museu
Nacional d’Art de Catalunya. The selection of can-
vases (31) was such that they were all of natural
origin (bast, jute, or cotton) and showed no evidence
of previous conservation treatments. Using a near
infrared spectrometric method based on multivariate
data analysis, the degree of polymerisation and pH
of these canvases was determined non-destructively
and the data were analysed in a way that enabled
informed conservation decision making. As a particu-
lar case study, we also surveyed Picasso’s The Woman
in Hat and Fur Collar (Marie-Thérèse Walter), from
1937.

The average pH of the surveyed canvases was deter-
mined to be 5.1 ± 0.4 and the average DP was 710 ±
260. These are low compared with new canvas,
however, the period of time before they become
fragile to the point where their handling becomes a
risk to their mechanical integrity (loss of fitness) can
still be managed using different conservation strat-
egies. At the actual environmental conditions at the
museum, the average canvas will become ‘very
fragile’ in ca. 140 years.

On the basis of the survey data, we developed iso-
chrones (plots linking points of equal time until loss
of fitness) and demographic plots to explore the
benefits, and costs, of different storage and display cli-
mates, and of canvas deacidification.

The paper examines the stability of canvas as the
carrier of paint layers and therefore looks at long-
term average environmental conditions. In order to
computationally examine the stability of paint layers

Figure 4 Demographic curve for the surveyed collection of
MNAC paintings at the actual environmental conditions
(21 °C, 58% RH) as well as three hypothetic scenarios.

Figure 5 Isochrone plot calculated on the basis of the data
measured for The Woman in Hat ….

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themselves as well, a suitable dose-response function
yet needs to be developed.

Acknowledgements
This work has been possible thanks to financial
support from the University of Barcelona and from
Cost Action D42 (EU). Access to the paintings was
made possible thanks to Mireia Mestre, Head of the
Conservation Department of the Museu Nacional
d’Art de Catalunya (Barcelona).

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Supplementary material 1 

List of the 31 painting canvases from Museu Nacional d’Art de Catalunya, Barcelona, 
Spain (MNAC) used in the research. 

Cat. No. Author, Title, date 

004.038 Ramon Casas, Estudi, circa 1899 

004.040 Ramon Casas, Le Sacré Coeur, Montmartre, 1891 

004.033 Ramon Casas, Pati de l'antiga presó de Barcelona, 1894 

069.042 Ramon Casas, Dona en un interior, 1890 

011.382 Ramon Casas, Estudi del natural per al retrat del rei Alfons XIII, 1904 

010.901 Ramon Casas, Plen air, 1890-1891 

069.023 Francesc Gimeno, Llegint el diari, 1886 

113.503 Juli González, Dona rentant-se, 1912-1913 

004.005 Joan Llimona, La novícia, 1898 

004.006 Joan Llimona, Pasturant, 1901 

004.630 Joaquim Mir, Paisatge (Maspujols. Camp de Tarragona), 1907-1910 

004.631 Joaquim Mir, Paisatge, 1907-1910 

042.090 Joaquim Mir, Hort amb casa de pagès 

065.291 Mela Mutermilch, Retrat de J. Dalmau, 1911 

010.921 Isidre Nonell, Gitana jove, 1903 

065.620 Isidre Nonell, Gracieta, 1907 

010.926 Isidre Nonell, La Pilar, 1907 

004.660 Isidre Nonell, Júlia, 1908 

065.623 Isidre Nonell, Lassitud, 1910 

214.090 Pablo Picasso, Dona amb barret i coll de pell (Marie-Thérèse Walter), 1937 

004.093 Marià Pidelaserra, Un dia d'hivern en el jardí del Luxemburg, 1900 

043.719 Marià Pidelaserra, Vall de Querol, 1897 

004.003 Santigo Rusiñol, La riallera, 1894 

040.095 Santigo Rusiñol, Jardí de Montmartre, 1890-1891 


045.267 Santigo Rusiñol, Entrada al parc del Moulin de la Galette, 1891 

063.980 Santigo Rusiñol, Retrat de nen, 1893-1895 

004.048 Santigo Rusiñol, "La Butte", 1892 

039.143 Joaquim Sunyer, Gitanes, 1906 

039.144 Joaquim Sunyer, Gitanes, 1907 

010.588 Joaquim Vayreda, Nens jugant (estudi), 1889 

010.593 Joaquim Vayreda, Camp de fajol (apunt), 1892 

010.589 Joaquim Vayreda, La roureda, 1892 

 
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