Germinario et al. Herit Sci  (2017) 5:44 
DOI 10.1186/s40494-017-0156-z
RESEARCH ARTICLE
Trachyte weathering in the urban built 
environment related to air quality
Luigi Germinario1* , Siegfried Siegesmund2, Lara Maritan1, Klaus Simon2 and Claudio Mazzoli1
Abstract 
Decay of trachyte used as building stone in urban environment was investigated through the analysis of crusts and 
patinas found on trachyte of the Euganean Hills in the Renaissance city walls of Padua, northeastern Italy. Mineral-
ogical and microstructural characteristics of the alteration products, as well as major- and trace-element chemical 
composition, were determined by optical microscopy, SEM–EDS and X-ray mapping, XRPD, and LA-ICPMS. The results 
are discussed referring to environmental parameters, in particular concerning air quality and anthropic pollution 
sources. The influence of composition of the stone and other neighboring materials on specific weathering processes 
is also debated. The formation of crusts and patinas turns out to be mainly due to exogenous processes. Enrichment 
in heavy metals and carbonaceous matter derives from the deposition of particulate emitted during fuel combus-
tion by road vehicles, domestic heating and, secondarily, industrial activities. The particulate is typically cemented by 
calcite, mainly mobilized after dissolution from nearby mortar joints, or iron, released by leaching from iron-bearing 
minerals, reprecipitated according to pH fluctuations. Gypsum layers were rarely observed. Generally, composition of 
the weathering crusts and patinas of Euganean trachyte proves to be an informative marker for the relevant environ-
mental conditions and their evolution.
Keywords: Building stone decay, Air pollution, Weathering crust, Mortar dissolution, Leaching, Mineral mobilization, 
Euganean trachyte
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Introduction
Air quality is a key factor affecting stone weathering in 
urban environment, where concentration of stoneworks 
is generally large and, at the same time, human activities 
are intense and diverse. The latter change in time and 
space, and so does their contribution to pollution. Time 
variations in quantity and quality of pollutant emissions 
strongly depend on changes in fuel use [1].  SO2 emissions 
have represented a major concern until the 20th century, 
but considerably declined in Europe during the last dec-
ades, by one or two orders of magnitude in cities, deter-
mining a general improvement of air quality [2]; however, 
globally, increasing coal demand according to recent pro-
jections [3–5] and, for example, the latest changes in cli-
mate policies in the USA [6], may revert this tendency. 
Nowadays, the higher concentration of other pollutants, 
such as N oxides  (NOx), particulate matter (PM), and 
 O3, must be reassessed. Road transport, domestic heat-
ing, industry, and power plants are the main pollution 
sources in urban areas, but their relative importance has 
changed with time as well [7].
In the modern urban environment, a multi-pollutant 
scenario arises with a major incidence of airborne par-
ticulate, having high concentration of elemental C (soot) 
and volatile organic compounds (VOC), with fuel com-
bustion from road traffic as the main contributor [8, 9]. 
This carbonaceous matter exhibits high specific surface 
area and contains heavy metals and aluminum–sili-
con particles, which act as catalysts and adsorbents for 
organic compounds [10]. Pollutant interaction with stone 
preferentially occurs through short-range dry deposition. 
Overall, the well-known processes of crust formation are 
becoming less significant in favor of soiling, character-
ized by an increasing enrichment in organic C, i.e., ali-
phatic and polycyclic aromatic hydrocarbons [11–14]. In 
Open Access
*Correspondence:  luigi.germinario@gmail.com 
1 Department of Geosciences, University of Padova, Via Gradenigo 6, 
35131 Padua, Italy
Full list of author information is available at the end of the article
Page 2 of 17Germinario et al. Herit Sci  (2017) 5:44 
urban environment, dry deposition is more significant 
than wet deposition, but a notable danger is still repre-
sented by short drizzles, fog, and dew, which have higher 
pH, do not remove previous acid deposits, and provide 
sufficient moisture for their chemical activation [15–17].
Most studies on the interaction between building stone 
and urban environment have focused so far on weather-
ing of carbonate rocks, their dissolution, and formation 
of gypsum crusts [18]; other rock types have been investi-
gated more rarely.
Deterioration of trachyte has also received scarce atten-
tion in the literature, not only because of its generally 
good durability. In fact, its use is historically less com-
mon if compared to other volcanic rocks, i.e., tuff above 
all, andesite, and basalt. These rock types have been 
quarried in Europe, Latin America, Middle and Far East 
and so on, and employed by some of the most important 
ancient civilizations, like the Romans, Egyptians, Greeks, 
Incas, and Aztecs [19, 20]. Trachyte use has not been 
such widespread, with an exploitation mostly limited 
to Europe, namely Italy, Germany, Czech Republic, and 
France, as well as the Azores and Canary Islands.
Most studies on trachyte weathering have focused 
on coastal salt-aggressive environments, such as those 
of Venice and Naples in Italy, and the Azores islands. 
Several deterioration patterns have been observed, 
including scaling, powdering, exfoliation, blistering, dif-
ferential erosion, and efflorescence. They result to be 
mainly determined by cyclic processes of in-pore salt 
crystallization related to sea-salt supply. The phases 
involved are halite, gypsum, thenardite, and mirabilite 
and, in indoor environments, also trona and natron [21–
24]. Only Lazzarini et al. [23] have addressed in detail the 
on-site decay of trachyte of the Euganean Hills, subject of 
the present paper; in this regard, Germinario et al. [25], 
in a recent work, explored the link between the chang-
ing petrophysical and mechanical properties of that stone 
and its diverse durability and resistance to water-driven 
weathering.
Few studies have also focused on trachyte used in 
inland continental climates, as in Czech Republic [26] 
and Germany [27]. In particular, Graue et  al. [27] have 
examined weathering crusts of trachyte in industrial, 
urban and rural environments, showing how their thick-
ness, grain size, and enrichment in heavy metals and 
other exogenous components well correlate with differ-
ent degrees and sources of anthropogenic air pollution.
In this paper, the problem of trachyte decay in urban 
environment is tackled investigating the mineralogi-
cal, microstructural and chemical characteristics of 
weathering crusts and patinas detected on trachyte of 
the Euganean Hills used in the Renaissance city walls of 
Padua, in northern Italy. Trachyte alteration is discussed 
referring to environmental parameters, in particular 
concerning air quality and anthropic pollution sources, 
which are examined based on measured or modeled pol-
lution data and placed in a cause-effect relationship with 
the weathering products. The influence of composition 
of the stone and other neighboring materials on specific 
weathering processes is also debated.
The city walls of Padua
Padua has a composite wall system surrounding the his-
torical district gone through millennia of history and sev-
eral layouts and building phases, dated to the Roman age, 
the Middle Ages (12th–14th century), and, finally, the 
Renaissance.
The latest wall circuit, the best preserved today, was 
built roughly following the previous Medieval perimeter 
by the Republic of Venice Serenissima, an ancient state of 
northern Italy (697–1797). The supremacy of Serenissima 
in Padua began in 1405, but the works for new defensive 
walls started one century later, during and after the war 
with the League of Cambrai, an alliance formed in 1508 
by the major European powers attempting to hinder the 
expansionist goals of Venice. The difficulties encoun-
tered in defending Padua, the most important mainland 
city, and the ongoing technological military innovations 
forced Serenissima to plan the construction of a new 
fortification system. This started in 1513 and continued 
until half of the century, with the realization of walls 
with an 11 km perimeter, 19 bastions, 8 gates, and sev-
eral bridges, protected by moats, rivers, and channels 
(Fig. 1). What can be seen today is the result of the exten-
sive modifications and demolitions of several parts of the 
curtain walls and two gates occurred under urbanization 
pressure from the 19th century [28, 29].
The Renaissance wall system was built almost com-
pletely using bricks for the outer surfaces, with a core 
filled with rubble of bricks and stones consolidated with 
mortar. Trachyte was used not only as stone blocks in 
the core. It was employed for stringcourses, parapets, 
ashlars on angular ends of the bastions and other minor 
elements, as well as for building some of the gates (Porta 
Savonarola, Porta San Giovanni, Porta Santa Croce, and 
Porta Liviana-Pontecorvo).
A set of 22 trachyte samples was collected on four dif-
ferent segments of the Renaissance walls for analyzing 
their weathering crusts and patinas. Stringcourses on 
curtains and roundels as well as ashlars of an angled bas-
tion were sampled, their localization being indicated in 
Fig.  2. During sampling, spots with different exposure 
were chosen; in the case of stringcourses, samples from 
the upper, frontal and lower surface were collected. To 
our knowledge, no cleaning restoration intervention was 
ever carried out on the sampled stone elements.
Page 3 of 17Germinario et al. Herit Sci  (2017) 5:44 
Euganean trachyte
The trachyte used in the Renaissance walls was extracted 
in the quarry district of the Euganean Hills, a group of 
hills located near Padua formed by a sedimentary succes-
sion of limestones and marls of the upper Jurassic—lower 
Oligocene, a Paleogene volcanic and hypabyssal series, 
and Quaternary detrital deposits. Trachytes are ascrib-
able to a subvolcanic series dated to the lower Oligocene, 
and have acid to intermediate composition and moderate 
Na-alkaline affinity [30, 31].
From a petrographic point of view, Euganean trachyte 
is a holocrystalline to hypocrystalline rock with por-
phyritic texture and a mineralogical composition given 
mostly by feldspars (anorthoclase, plagioclase, and sani-
dine, in diverse combination), biotite and, occasionally, 
augite and kaersutite. The accessory minerals typically 
comprise quartz, cristobalite, Ti-magnetite, ilmenite, 
apatite, and zircon. Groundmass is composed by alkali-
feldspar microlites usually with a felty texture, or some-
times showing preferred orientations [32].
Fig. 1 The Renaissance city walls of Padua raised by the Republic of Venice Serenissima: a Porta Savonarola gate, with a wall segment; b Castel-
nuovo circular bastion with a water gate facing a channel; c Cornaro pentagonal bastion
Page 4 of 17Germinario et al. Herit Sci  (2017) 5:44 
The exploitation of Euganean trachyte started in Pre-
Protohistory, but became more intense from Roman 
times. This material has been extensively used as carv-
ing and building stone in northern and central Italy 
and nearby its borders. Querns, mortars, cippi, mile-
stones, steles, urns, tombstones, and sarcophagi com-
prise the most common artifacts crafted with trachyte 
all through the centuries. Euganean trachyte was widely 
used in the built environment too, as an instance for 
the admirable roads and other great infrastructure of 
the Roman age or the monumental architecture and 
construction from the Middle Ages and Renaissance. 
Indeed, with the rise of the Republic of Venice Serenis-
sima, stone construction was given a substantial boost, 
and trachyte was largely employed in public buildings, 
churches, monasteries, monumental gates, defen-
sive walls and private residences, as well as for paving 
squares and streets; the most striking examples can be 
admired in Padua and Venice ([32, 33] and references 
therein).
Experimental methods
The trachyte samples collected on the walls of Padua 
were analyzed in order to determine their mineralogical, 
microstructural and chemical characteristics, using the 
facilities of the Geoscience Center of Georg-August-Uni-
versität Göttingen.
Rock thin sections both parallel and perpendicular to 
the exposed surface were investigated with a polarized-
light microscope and a field-emission scanning electron 
microscope (FE-SEM) FEI Quanta 200 FEG equipped 
with a ZrO/W Schottky field-emission gun and detec-
tor for energy-dispersive X-ray spectroscopy (EDS). In 
addition to usual observations and phase identifications, 
carried out on gold-coated samples, the SEM was used 
for acquiring X-ray elemental maps of selected cross 
sections, operating at 20  kV acceleration voltage, and 
scanning a grid of 512 × 400 pixels with a dwell time of 
300 ms.
Powdery and incoherent samples were analyzed by 
X-ray powder diffraction (XRPD) with a Philips PW 1800 
Fig. 2 The present-day circuit of the Renaissance city walls of Padua (satellite image from ©2016 Google), with sampling areas indicated, and two 
examples of weathering crusts and patinas on Euganean trachyte used for a stringcourse and as filling material in the wall core
Page 5 of 17Germinario et al. Herit Sci  (2017) 5:44 
diffractometer equipped with Cu anode operating at 
45 kV and 30 mA, measuring with scan steps of 0.02°2θ 
in the range 3–70°2θ and an integration time of 4 s.
Furthermore, analyses by laser ablation inductively 
coupled plasma mass spectrometry (LA-ICPMS) were 
performed in order to determine major- and trace-ele-
ment composition of both the altered layers and fresh 
host rock. The latter, prepared as polished samples 
embedded in epoxy, was analyzed with a Thermo Scien-
tific Element 2 double-focusing magnetic-sector spec-
trometer coupled to a Resonetics Resolution 193 nm Ar-F 
excimer laser; data were acquired along 1.5  mm-long 
profiles and average compositions calculated. Instead, the 
crusts and patinas were analyzed as they are, given the 
difficulty in preparing polished sections due to their lim-
ited thickness. For these samples, a Perkin Elmer ELAN 
DRC II quadrupole spectrometer was used coupled to 
a Lambda Physik COMPex 110 193  nm Ar-F excimer 
laser. Data were acquired on profiles on the entire sample 
surface (centimetric in size) and average compositions 
calculated. Both lasers operated at 7  Hz repetition rate, 
3 J/cm2 fluence, 7 µm/s velocity, and using a spot size of 
120  µm. Element concentrations were calculated with 
Iolite v2.5 software package, by a script based on the fol-
lowing procedure: the LA-ICPMS signal is first smoothed 
by ratioing to an appropriate denominator isotope pre-
sent in the sample and standard (29Si); the element ratios 
are standardized with NIST 610 glass reference material; 
then, they are normalized to oxides sum to reach 100%, 
including all the elements [34].
Weathering analysis
Mineralogy and microstructure
Microscopic observations reveal that the thickness of the 
weathering crusts and patinas on the exposed surfaces is 
rather limited, often below few tens of micrometers, and 
only exceptionally may reach few hundreds of microm-
eters. Sometimes, powdery and incoherent deposits are 
also observed.
Almost all the samples have a high C content, respon-
sible for the black-greyish color of many crusts and pati-
nas. Subspherical carbonaceous particles may be isolated, 
grouped in small clusters (Fig.  3a), or form extensive 
layers, possibly displaying fractures and microcracks 
Fig. 3 SEM-BSE photomicrographs showing different features of the carbonaceous fraction (darker in the images) detected on the weathering 
crusts and patinas of Euganean trachyte and its microchemical composition by EDS measured on two different spots (signal from gold coating is 
also visible). a Cluster of subspherical carbonaceous particles. b Microcracked patina with crumbled fine-grained feldspars. c Carbonaceous mass 
with Fe oxides, carbonates, and quartz. d Aggregates of carbonaceous particles arranged along the edges and the internal fractures of a plagioclase 
phenocryst
Page 6 of 17Germinario et al. Herit Sci  (2017) 5:44 
(Fig.  3b). Soot represents a container for further accu-
mulation of pollutants, indeed it may be rich in heavy 
metals, especially Pb, or include exogenous quartz, alu-
minosilicate minerals, chlorides, Al oxides, etc.
The airborne carbonaceous pollutants are frequently 
trapped in crusts formed by microcrystalline calcite and, 
secondarily, dolomite (Fig. 4). The high concentration of 
these phases cannot be traced back to trachyte composi-
tion, since they are originally present in low or negligi-
ble amount. A high content of quartz is often detected as 
well.
The carbonaceous particles may be also associated with 
a matrix rich in Fe, present as oxides and hydroxides or in 
amorphous state, giving a general brown-reddish color, 
in possible combination with carbonates (Fig. 3c).
In the thinnest patinas, there are virtually no inter-
mediate alteration layers between the host rock and the 
carbonaceous components, the adhesion of which takes 
place directly on the feldspars constituting the substrate; 
their fine grain size and crumbled appearance, which cre-
ates a porous surface favoring C deposition, suggests for-
mer processes of granular disintegration. C accumulates 
mainly on the groundmass or fine-grained phenocrysts, 
taking advantage of intercrystalline spaces and higher 
porosity, whereas large phenocrysts are less affected 
(Fig. 3d).
Gypsum crusts are detected on a single sample, very 
close to a mortar splash by the joint of two trachyte 
blocks. Its collocation, on the lower side of a string-
course, was a shelter against direct rainfall and washing 
out. The microscopic investigation revealed a complex 
stratigraphy (Fig.  5). The superficial layer is composed 
of a network of acicular or tabular gypsum crystals with 
rosette-like intergrowths, which embeds carbonaceous 
particles, but in rather low concentration. The second 
underlying layer is composed of amorphous silica. The 
third layer is constituted mostly of calcite, directly crys-
tallized on the host rock. The presence of separate gyp-
sum and calcite levels suggests a slow-rate alteration 
process, started with the crystallization and growth of 
a carbonate layer and its later, partial reaction with S, 
mostly limited to its outermost part. The gypsum layer 
represents a rather compact domain, whereas the under-
lying host rock shows a high degree of fracturing.
The XRPD analyses of powdery and incoherent depos-
its sampled on trachyte confirm the occurrence of some 
of the mineral phases detected through the SEM obser-
vations and microanalyses. Quartz, calcite, and dolomite 
are the major components, while the other identified 
phases comprise minerals from the host rock, like feld-
spars and biotite, or from their alteration, such as illite 
and chlorite (Fig. 6).
Major‑ and trace‑element composition
The LA-ICPMS analyses of major elements (Table 1) sub-
stantially confirm the occurrence of two main alteration 
types, characterized by a high concentration of calcite 
and Fe. If the average composition of Euganean trachyte 
in Germinario et al. [32] is taken as reference, the calcite 
crusts and patinas show an increase of CaO by a factor 
from 7 up to 60, corresponding to a maximum concen-
tration of 86%. At the same time, a decrease in the con-
tent of  SiO2,  Al2O3,  Na2O, and  K2O is always evident, 
up to a maximum of 87, 93, 97, and 98%, respectively. A 
modest increase of MgO, associated with dolomite pres-
ence, is also noticeable. The different ratios between CaO 
Fig. 4 SEM–EDS X-ray maps of a calcite crust of Euganean trachyte prepared as epoxy-embedded cross section, with the exposed surface dis-
played on the top (field size: 523.6 × 406.6 µm)
Page 7 of 17Germinario et al. Herit Sci  (2017) 5:44 
and the feldspar-related elements reveal different degrees 
of alteration and homogeneity of the weathering layers, 
hence to what extent the silicate host rock has been oblit-
erated by newly formed phases. As pointed out before, 
enrichment in carbonates and Fe may be associated but, 
when the latter is predominant, a Fe increase by a factor 
up to 6.5 is recorded. Although a general surface sulfation 
is often evident, only in the gypsum crust a large increase 
in  SO3 is reported, by a factor of 2487, corresponding to a 
concentration of 25%, which almost completely hides the 
silicate composition of the host rock, in association with 
the high content of CaO.
Further indications are given by the concentration of 
trace elements (a selection is reported in Table  2, while 
the complete dataset is included in Additional file 1). In 
comparison to the host rock, a remarkable enrichment 
in heavy metals of the crusts/patinas is evident (Fig.  7), 
especially in V, Cr, Ni, Cu, Zn, As, Cd, Sn, Sb, Pb, and 
Bi. As an instance, Pb results to be increased by a fac-
tor of over 1700. The highest absolute concentrations are 
reported for Cu, Zn, and Pb, equal to 1009, 11,460, and 
25,800  ppm, respectively. No significant mobilization of 
heavy metals into the host rock is detected [35].
As also summarized in Fig.  8, when the host rock is 
shielded by thick, homogeneous and well-developed 
crusts, as those rich in calcite or gypsum, the near-sur-
face concentration of heavy metals is lower on average, 
i.e., the absorption of pollutants is more limited. Calcite 
and gypsum tend to form microcrystalline domains more 
compact than the underlying host rock, so that mecha-
nisms of dry and wet deposition of pollutants are hin-
dered. This is confirmed by a higher content of heavy 
metals on the stone surfaces exhibiting only a weak incip-
ient alteration, maybe only recently exposed (e.g., due to 
previous detachment of outer layers). On the other hand, 
non-uniform crusts, which do not entirely cover the 
host rock, represent an intermediate condition: storage 
of airborne carbonaceous particles and surface accumu-
lation of metallic pollutants are enhanced because of a 
relatively high porosity, given by a mix of disaggregated 
host rock and uneven, incomplete and scarcely adhering 
crystallization of newly formed phases. In this case, an 
Fig. 5 SEM–EDS X-ray maps of a gypsum crust of Euganean trachyte prepared as epoxy-embedded cross section, with the exposed surface 
displayed on the top (field size: 524.5 × 407.3 µm). Details of the gypsum crystals and the fractured host rock beneath the crust are showed in the 
SEM-BSE photomicrographs
Page 8 of 17Germinario et al. Herit Sci  (2017) 5:44 
enrichment in CaO,  Fe2O3, and heavy metals is clear, but 
the contribution of the silicate substrate to the chemical 
composition of the stone surface is still distinct.
Finally, the relationship between trachyte sampling 
point and sample composition suggests the following 
considerations: the samples collected on the frontal sides 
of stringcourses or ashlars feature a higher concentration 
of carbonates on average, thus indicating a major inci-
dence of calcite-rich alteration on vertical surfaces; the 
samples collected on the lower sides, including the gyp-
sum crusts, display lower concentrations of heavy metals; 
no specific alteration trends dependent on the sampling 
site were recognized.
Correlation with air quality
Environmental setting
In order to establish a correlation between trachyte alter-
ation and air quality, it is necessary to describe the envi-
ronmental setting the stone interacts with.
Padua is a city of about 200,000 people in the Veneto 
region, northeastern Italy, located in the Po Plain about 
20 km far from the Venetian Lagoon and 40 km from the 
coastline of the Adriatic Sea.
The climate is humid temperate (Köppen classifica-
tion: “Cfa”). It features hot summers, with record maxi-
mum temperatures usually exceeding 35 °C, and mild to 
cold winters, when minimum temperatures may easily 
drop below 0  °C. The most humid period in the year is 
between fall and winter, whereas late-spring and summer 
months are the driest. Rainfall is concentrated during 
fall and spring, while winter has the lowest precipitation. 
Spring is usually the windiest season (Table 3).
The pH value of rainfall is from 5.5 to 6 on average,1 
which is the conventional value of unpolluted rainwater, 
i.e., 5.6 [36].
Concerning air quality, the most significant pollu-
tion sources in Padua, besides road traffic and domes-
tic combustion, are the only two major industrial plants 
in the city area, namely a waste-to-energy incinerator 
and a steel plant, about 3 and 6 km far from downtown, 
respectively. Compared to the pollution measured in 
background areas, traffic zones present a concentration 
of  NOx increased by a factor of 1.5, whereas near indus-
trial plants the same increase in the concentration of  SO2 
is registered, as well as an enrichment in heavy metals in 
the PM fraction, by a factor up to over 2 (Table 4). Finally, 
1 No recent institutional data are available, so the value indicated has been 
assumed from alternative sources: dated measurements in Padua [16] and 
Venice (RIDEP network, 1988), as well as recent datasets from mountain 
localities in Veneto (CONECOFOR network and TESAF, Padua). For pro-
posing that pH value, lower accuracy of dated analyses, sampling location, 
and the general reduction of emissions during the last decades have been 
taken into account.
Fig. 6 XRPD spectrum of a powdery deposit on Euganean trachyte, showing a composition given mostly by quartz, calcite, and dolomite
Page 9 of 17Germinario et al. Herit Sci  (2017) 5:44 
the influence of the industrial area of Venice-Porto 
Marghera, one of the largest coastal industrial zones in 
Europe, located 30 km far from Padua, cannot be ruled 
out. In its area of over 20 km2, chemical, petrochemical 
and petroleum industries, refineries, thermal power sta-
tions, metallurgical industries, air separation and natural-
gas processing plants, incinerators, etc. are operational. 
The emissions comprise mainly  SO2,  NOx, CO, PM, and 
VOC [37–39], which are easily transported to Padua by 
winds having usually a NE direction.
Exogenous processes
The mineralogical and chemical identity of the alterations 
of Euganean trachyte can be related to air pollution, so 
that composition of the weathering crusts and patinas 
turns out to be a marker for the relevant environmental 
conditions and their evolution.
The enrichment in C and heavy metals can be traced 
back to the particulate deriving mostly from road traffic, 
emitted by diesel and gasoline-powered vehicles, and 
domestic combustion of woody biomass. These are the 
main sources of total suspended particulate (TSP) in 
Padua, according to the emission projections by ARPAV 
agency [40]2 summarized in Fig.  9. A further major 
2 INEMAR projections by ARPAV agency contain space- and time-based 
estimations of the yearly emissions in the atmosphere generated by several 
anthropic and natural activities that, given the complexity and amount of 
the possible sources, could not be all exactly calculated. The estimations 
are based on both real measured data and theoretical indicators, the latter 
inferred from statistical data and exploratory surveys concerning popula-
tion, territory, economy, development, etc. [40].
Table 1 Major-element chemical composition expressed as oxide weight percent of representative samples of Euganean 
trachyte from the Renaissance city walls of Padua determined by LA-ICPMS, on both surface (i.e., weathering crust or pat-
ina) and host rock (inner part)
The samples are divided by different types of alteration and sampling location as in Fig. 2 (SCR, Bastione Santa Croce; GAR, Torrione dell’Arena; CSN, Bastione 
Castelnuovo; FST, Torrione Venier)
a  Bulk-rock chemical composition determined by X-ray fluorescence and averaged among 86 fresh trachyte samples collected on the Euganean Hills in 40 different 
quarries and outcrops [32]
Sample SiO2 TiO2 Al2O3 Fe2O3 MnO MgO CaO Na2O K2O P2O5 SO3
Calcite-rich alteration
SCR-01
 Surface 8.57 0.02 1.14 0.58 0.04 1.49 85.85 0.17 0.12 0.69 0.38
 Host rock 63.69 0.12 18.09 0.76 0.01 0.14 4.40 6.18 4.56 0.04 0.45
GAR-03
 Surface 52.04 0.17 13.40 3.98 0.31 1.21 16.29 3.28 0.83 3.21 1.18
 Host rock 67.17 0.09 18.08 0.91 0.00 0.20 1.51 5.75 5.70 0.12 0.10
CSN-03
 Surface 55.10 0.40 11.59 3.51 0.09 1.51 15.60 3.00 0.97 1.42 2.93
 Host rock 65.78 0.11 18.31 2.04 0.01 0.35 1.03 5.82 5.63 0.04 0.06
SCR-05
 Surface 58.50 0.19 13.81 3.31 0.05 0.72 10.42 2.77 0.55 1.22 0.44
 Host rock 67.89 0.30 15.96 1.97 0.02 0.59 1.69 5.26 5.21 0.17 0.12
Iron-rich alteration
SCR-07
 Surface 40.97 0.39 14.27 21.19 0.15 1.22 5.22 1.96 0.57 7.47 0.82
 Host rock 68.09 0.15 17.23 1.34 0.02 0.40 1.21 5.32 5.64 0.10 0.08
Weak alteration
FST-07
 Surface 66.20 0.13 17.71 2.99 0.12 0.33 3.73 5.07 0.91 0.72 0.65
 Host rock 69.08 0.06 16.46 0.84 0.01 0.12 2.01 5.20 4.33 0.07 0.11
Gypsum-rich alteration
FST-05
 Surface 5.44 0.01 0.41 0.11 0.00 0.17 66.07 1.34 0.12 0.58 24.87
 Host rock 70.62 0.23 14.93 1.29 0.01 0.32 1.05 4.01 6.32 0.03 0.19
Average composition of Euganean  trachytea 66.02 0.66 16.77 3.26 0.06 0.66 1.42 5.04 5.35 0.21 0.01
Page 10 of 17Germinario et al. Herit Sci  (2017) 5:44 
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ac
e-
el
em
en
t c
he
m
ic
al
 c
om
po
si
ti
on
 e
xp
re
ss
ed
 a
s 
pp
m
 o
f r
ep
re
se
nt
at
iv
e 
sa
m
pl
es
 o
f E
ug
an
ea
n 
tr
ac
hy
te
 fr
om
 th
e 
Re
na
is
sa
nc
e 
ci
ty
 w
al
ls
 o
f P
ad
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 d
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er
-
m
in
ed
 b
y 
LA
-IC
PM
S,
 o
n 
bo
th
 s
ur
fa
ce
 (i
.e
., 
w
ea
th
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g 
cr
us
t o
r p
at
in
a)
 a
nd
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os
t r
oc
k 
(in
ne
r p
ar
t)
. O
nl
y 
a 
se
le
ct
io
n 
of
 th
e 
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al
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ed
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le
m
en
ts
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ho
w
ed
 (t
he
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om
-
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e 
da
ta
se
t i
s 
in
cl
ud
ed
 in
 A
dd
it
io
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l fi
le
 1
)
Th
e 
sa
m
pl
es
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re
 d
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id
ed
 b
y 
di
ffe
re
nt
 ty
pe
s 
of
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lte
ra
tio
n 
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d 
sa
m
pl
in
g 
lo
ca
tio
n 
as
 in
 F
ig
. 2
 (S
CR
, B
as
tio
ne
 S
an
ta
 C
ro
ce
; G
A
R,
 To
rr
io
ne
 d
el
l’A
re
na
; C
SN
, B
as
tio
ne
 C
as
te
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vo
; F
ST
, T
or
rio
ne
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r)
a  
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k-
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he
m
ic
al
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om
po
si
tio
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te
rm
in
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y 
X-
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flu
or
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er
ag
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ga
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ill
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in
 4
0 
di
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re
nt
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ua
rr
ie
s 
an
d 
ou
tc
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ps
 [3
2]
Sa
m
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Cr
Co
N
i
Cu
Zn
A
s
Cd
Sn
Sb
Σ 
RE
E
Pb
Bi
Ca
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 S
ur
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3.
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ea
k 
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ic
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al
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os
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k
10
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0
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0.
06
A
ve
ra
ge
 c
om
po
si
tio
n 
of
 E
ug
an
ea
n 
 tr
ac
hy
te
a
23
3
3
2
23
10
3
n/
a
n/
a
n/
a
n/
a
n/
a
15
n/
a
Page 11 of 17Germinario et al. Herit Sci  (2017) 5:44 
source of particulate is fuel-free industrial processes in 
the steel mill (“productive processes”); as indicated in 
Table 4, its emissions have a relatively high content of Pb, 
Ni, and As, so this can be directly related to the enrich-
ment in heavy metals detected on the weathering crusts. 
By comparison, TSP produced by the local incinerator 
(“waste treatment and disposal”) is almost negligible. If 
the contribution from the industrial area of Venice-Porto 
Marghera is also considered, a further supply of carbona-
ceous pollutants and heavy metals can be identified 
mainly from the power stations, refinery, petroleum 
industries, and the related employment of fuels and 
machines. Conditions of high air humidity and 
precipitation and strong wind are the most favorable for 
pollutant dispersion, so that summer can be considered 
the least dangerous season. Carbonaceous and metallic 
particles act as catalysts, so their accumulation enhance 
further stone alteration and crust growth [41].
Among other exogenous processes contributing to the 
weathering of Euganean trachyte, it is worth mentioning 
the possible reactions leading to the formation of the car-
bonate crusts. Considering the originally low concentra-
tion of calcite and dolomite in the host rock, the only 
plausible and consistent source for these phases is identi-
fied in lime and Mg-lime mortars used in the walls of 
Padua for joining trachyte blocks. Indeed, Ca carbonate 
Fig. 7 Time-resolved LA-ICPMS spectrum obtained from a Fe-rich crust of Euganean trachyte, by a combined profile and spot analysis: crust surface 
was first ablated along a line and eventually drilled through, until reaching the host rock
Fig. 8 Comparison of the major- and trace-element composition measured by LA-ICPMS on the weathering crusts and patinas of representative 
samples of Euganean trachyte. Sample names and compositions refer to Tables 1 and 2
Page 12 of 17Germinario et al. Herit Sci  (2017) 5:44 
may be dissolved from mortars by acid solutions and 
reprecipitate in basic ones; calcite is less stable, i.e., its 
dissolution is faster, when pH is lower than about 5–6: 
dissolution rate increases with increasing  H+ activity, in 
high-acidity regime, or  CO2 partial pressure, in low-acid-
ity regime [42–44]. As reported above, average pH of 
rainfall in Padua is around 5.5–6, just around the limit of 
calcite stability. This means that pH fluctuations3 to 
higher acidity may increase leachability of Ca carbonate 
from mortars; the resulting solution containing leached 
Ca(OH)2, thus an alkaline medium [36], continues its 
short-range path, and may easily reach trachyte elements 
(especially subvertical substrates), wetting their surface 
and penetrating into pores; finally, calcite reprecipitates, 
taking advantage of the alkaline pH. Carbonate recrystal-
lization episodes might be more common in summer-
time, whereas dissolution process possibly takes place 
more frequently during late fall and winter: in the cold 
season, atmosphere acidity is generally higher due to 
domestic heating and related emissions, and low temper-
atures increase calcite solubility [45]; higher humidity 
and precipitation represent other favorable factors, as 
well as the recurrence of misty days, with fog being more 
acid than rainfall, with pH even below 4 [13, 36].
The role of neighboring mortars acting as Ca source 
for trachyte weathering has been outlined by previous 
studies too [21, 22, 27]. It seems to be confirmed also 
3 pH fluctuations of an aqueous solution can occur due to leaching of 
stones/mortars or solubilization of acid particles previously dry-deposited 
on their surface. Fluctuations also depend on the current general air qual-
ity and other large-scale factors: for example, a short drizzle or the initial 
stage of a rainfall are more acid, since the highly-soluble anthropogenic pol-
lutants are first gathered; in a later stage, airborne alkaline agents reacting 
with slower kinetics and solubility—e.g.,  NH3 from agricultural fertilizers, 
soil particles, wind-transported Saharan dust, etc.—make water pH increase 
[15, 16].
by the formation of the gypsum crusts very close to a 
mortar joint, and the possible supply of quartz, sulfates, 
chlorides, etc. from the mortar aggregate. The layers of 
amorphous silica might develop from the dissolution of 
either the mortar or the rock-forming silicate minerals 
or glass-bearing domains in trachyte [46]. Quartz might 
be also derived by Saharan dust, long-range transported 
from Africa by Sirocco: when this wind rises to pass over 
the Alps further north than Padua, the desert particles, 
composed of silicates and carbonates, are scavenged by 
rainfall and may precipitate in the Po Plain [15, 16].
On the other hand, the gypsum crusts might be also 
connected to anthropogenic air pollutants, i.e., to  SO2 
oxidation and hydration and the well-known subsequent 
reaction of  H2SO4 with a Ca carbonate substrate, in this 
case formed on trachyte after mortar leaching. The high 
degree of fracturing of the underlying host rock suggests 
an initial penetration of Ca-rich solutions in the outer 
pores, then producing crystallization pressures during 
water evaporation up to rock failure. Gypsum possibly 
formed after subsequent Ca loading and growing out-
wards of the carbonate crystallization layer, on surfaces 
sheltered from direct rainfall and washing out. Concern-
ing  SO2 supply, the most important contribution is given 
by the emissions of the steel mill. Anyway, the overall 
concentration of  SO2 is rather low in Padua and not com-
parable to that typical of big urban and industrial centers 
[13], and presumably it was so even in the past. This—
other than the carbonate-poor composition of trachyte—
justifies the very limited extension of the gypsum crusts 
and their rare occurrence [47]. A hypothesis that can be 
completely discarded is the nucleation of gypsum directly 
from soot absorbing pollutants [48], given its low con-
centration and, on the other hand, the large extension of 
the gypsum crusts.
Table 3 Climatic parameters measured in Padua averaged from 2000 to 2015. Source: ARPAV
Climatic parameter Value Climatic parameter Value
Temperature (°C) Precipitation (mm)
Annual mean 14.5 Annual total 959
Annual mean min 10.7 Lowest annual total 561
Annual mean max 19.1 Highest annual total 1395
Lowest monthly mean and monthly mean min (month) 3.9/1.5 (January) Lowest monthly total (month) 58 (January)
Highest monthly mean and monthly mean max (month) 24.7/30.2 (July) Highest monthly total (month) 107 (November)
Relative humidity (%) Precipitation days
Annual mean 74 Annual total (≥ 1 mm) 84
Annual mean min 53
Annual mean max 91 Solar irradiance (MJ/m2)
Lowest monthly mean and monthly mean min (month) 65/43 (July) Annual total (Legnaro, 1994–2015) 5005
Highest monthly mean and monthly mean max (month) 84/94 (November) Wind direction
Annual mean NE
Page 13 of 17Germinario et al. Herit Sci  (2017) 5:44 
Ta
bl
e 
4 
Co
nc
en
tr
at
io
n 
of
 a
ir
 p
ol
lu
ta
nt
s 
m
ea
su
re
d 
in
 P
ad
ua
 in
 d
iff
er
en
t l
oc
at
io
ns
 a
nd
 e
xp
re
ss
ed
 a
s 
ho
ur
ly
 g
ra
nd
 m
ea
ns
, f
or
 g
as
eo
us
 p
ol
lu
ta
nt
s,
 a
nd
 d
ai
ly
 g
ra
nd
 
m
ea
ns
, f
or
  P
M
10
. S
ou
rc
e:
 A
RP
AV
Th
e 
re
co
rd
s 
co
m
pr
is
e 
th
e 
fo
llo
w
in
g 
pe
rio
ds
: f
or
 g
as
eo
us
 p
ol
lu
ta
nt
s, 
fr
om
 2
00
0 
to
 2
01
5 
(B
ac
kg
ro
un
d 
an
d 
Tr
affi
c 
st
at
io
ns
) a
nd
 fr
om
 2
00
1 
to
 2
01
5 
(In
du
st
ria
l I
I s
ta
tio
n)
; f
or
  P
M
10
, f
ro
m
 2
00
3 
to
 2
01
5 
(B
ac
kg
ro
un
d,
 T
ra
ffi
c 
an
d 
In
du
st
ria
l I
 s
ta
tio
ns
) a
nd
 fr
om
 2
00
8 
to
 2
01
5 
(In
du
st
ria
l I
I s
ta
tio
n)
In
du
st
ria
l I
: o
ne
 s
ta
tio
n 
m
on
ito
rin
g 
th
e 
em
is
si
on
s 
fr
om
 a
 lo
ca
l s
te
el
 m
ill
In
du
st
ria
l I
I: 
tw
o 
st
at
io
ns
 m
on
ito
rin
g 
th
e 
em
is
si
on
s 
fr
om
 a
 lo
ca
l w
as
te
-t
o-
en
er
gy
 in
ci
ne
ra
to
r
M
ea
su
re
m
en
t s
ta
tio
n
CO (m
g/
m
3 )
N
O
(µ
g/
m
3 )
N
O
2
(µ
g/
m
3 )
Σ 
 N
O
x
(µ
g/
m
3 )
SO
2
(µ
g/
m
3 )
O
3
(µ
g/
m
3 )
PM
10
(µ
g/
m
3 )
A
s
(n
g/
m
3 )
Cd (n
g/
m
3 )
N
i
(n
g/
m
3 )
Pb (n
g/
m
3 )
C 6
H
6
(µ
g/
m
3 )
C 2
0H
12
(n
g/
m
3 )
PM
10
 c
om
po
si
tio
n
Ba
ck
gr
ou
nd
 W
ho
le
 re
co
rd
0.
7
29
.9
42
.1
88
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2.
5
52
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43
.0
1.
4
0.
9
3.
4
17
.7
2.
1
1.
3
 L
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t 5
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 (2
01
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15
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0.
6
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Tr
affi
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 W
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0.
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53
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 (2
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In
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 W
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 L
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15
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 (2
01
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3
Page 14 of 17Germinario et al. Herit Sci  (2017) 5:44 
Finally, it is worth reminding that no evident effect 
of interaction between trachyte and sea salts carried 
by wind or rainwater was noticed. Indeed, the typical 
weathering products connected to coastal environment 
identified in previous studies [22, 23], in particular high 
concentrations of halite, were not found here. The scant 
chlorides detected have to be traced back to mortar com-
position instead, as stated above.
On the other hand, composition of the weathering 
products of Euganean trachyte can be compared to that 
detected in inland environment on Drachenfels trachyte 
studied by Graue et al. [27]. The main difference lies in a 
greater incidence of CaO enrichment and calcite recrys-
tallization on surface alteration of Euganean trachyte, 
whereas the framboidal crusts analyzed on Drachen-
fels trachyte in an urban and industrial setting generally 
are thicker (centimetric size), richer in well-developed 
gypsum crystals, and may show stronger sulfation and 
higher concentration of heavy metals. Nevertheless, if Pb 
concentration is the term for comparison, that analyzed 
in the crusts and patinas of Euganean trachyte is often 
close to the typical values measured in European cities, 
i.e., from few hundreds ppm up to 2000 ppm [27].
Stone leaching
Some features of the weathering crusts and patinas of 
Euganean trachyte can be explained by intrinsic fac-
tors, in particular the Fe-rich alterations. Microscopic 
examinations disclosed an enrichment in fine-grained Fe 
oxides and hydroxides and amorphous Fe in the proxim-
ity of biotite phenocrysts and, secondarily, magnetite and 
ilmenite crystals (Fig. 10). This suggests Fe mobilization 
from the minerals by leaching and migration to surface, 
forming brown-reddish alteration layers. Leaching might 
have also occurred at the expense of mafic xenoliths 
[23] or pervasive migration fronts of Fe oxides/hydrox-
ides, genetically linked to post-magmatic processes [32]. 
Leaching of biotite seems more likely, since solubility of 
Fig. 9 Estimated emissions of the major air pollutants in Padua during 2010 by several macro-groups of anthropic and natural activities, and com-
parison with emissions calculated for Venice in the same year, mainly deriving from the industrial area of Porto Marghera (INEMAR projections [40])
Page 15 of 17Germinario et al. Herit Sci  (2017) 5:44 
magnetite and ilmenite is lower.  Fe2+ release from the 
octahedral layers of biotite is strongly pH dependent: rate 
of dissolution linearly increases with decreasing pH, but 
the reaction is significant only for values lower than 4–5 
[49–51]. The environmental conditions leading to the 
formation of the Fe-rich crusts and patinas would be sim-
ilar to those described for the calcite crusts, involving pH 
fluctuations around the limit of the stability field even of 
biotite; in this case, however, its lower leachability if com-
pared to that of calcite requires a more acid environment 
for dissolution to get started. Finally, a minor contribu-
tion of PM to Fe enrichment of trachyte surfaces must be 
taken into account, however that is not the main source, 
as also confirmed by the absence of Fe compounds in the 
incoherent and powdery surface deposits of exogenous 
origin.
A leaching process of the host-rock has been supposed 
also with regard to dissolution of plagioclase and release 
of  Ca2+ cations, as an alternative or concurrent mecha-
nism of formation of the calcite crusts. In Euganean tra-
chyte, plagioclase represents one of the main mineral 
phases, it has a prevalent oligoclase–andesine compo-
sition with an average CaO content of 6% [32], so theo-
retically it is a possible source of Ca [52, 53]. However, 
the overall CaO content of the bulk rock is rather low 
on average (1.4%, see Table 1). Additionally, in acid solu-
tions, Ca leachability from plagioclase is rather low, espe-
cially taking calcite as a term of comparison or even Fe 
release from biotite [46, 54]. Leaching is also facilitated in 
fine-grained crystals, whereas plagioclases are among the 
coarsest phenocrysts in Euganean trachyte, even reach-
ing a centimetric size. Moreover, clay minerals, typically 
resulting from feldspar alteration, were detected only in 
minor amounts (their concentration in the host rock is 
also rather low or negligible). For all these reasons, plagi-
oclase cannot be considered the primary source of such a 
high concentration of carbonates in the crusts, although 
its contribution cannot be totally excluded.
Conclusions
The crusts and patinas of Euganean trachyte related to 
urban weathering have mostly limited thickness and 
extension. They are rich in heavy metals and carbona-
ceous matter, which promote further accumulation of 
pollutants, mainly derived from fuel use in road trans-
port and domestic combustion, and, secondarily, short- 
and medium-range industrial emissions. These products 
are typically embedded in matrixes rich in calcite or Fe 
(either as oxides/hydroxides or amorphous components). 
The crusts and patinas also include grains of quartz, 
dolomite, and other minor components, such as metallic 
and aluminum–silicon particles, chlorides, etc. The high 
concentration of carbonates cannot derive from host 
rock components; pH-controlled dissolution, mobiliza-
tion, and recrystallization of carbonates from nearby lime 
mortars used in joints seems the most plausible source 
of Ca. This process may also occur on seasonal basis, 
depending on pH fluctuations. A secondary and very 
limited source of Ca can be represented by dissolution of 
plagioclases. A more likely intrinsic process of alteration 
affects biotite and other Fe-bearing minerals, through 
pH-dependent leaching of Fe and its migration to surface. 
Other alteration forms recognized comprise powdery 
deposits and gypsum crusts, but they do not occur com-
monly. The latter possibly derive from the contribution of 
 SO2 pollutant, having a rather low concentration in the 
air though; the presence of sulfate impurities in mortar 
aggregate and their leaching can be alternatively invoked. 
Fig. 10 Thin-section photomicrographs of samples of Euganean trachyte with Fe-rich crusts, showing dispersion of fine-grained Fe oxides/hydrox-
ides or Fe in amorphous state around a biotite crystal (left) and two opaque minerals (i.e., magnetite or ilmenite) (right), apparently indicating 
near-surface mineral leaching
Page 16 of 17Germinario et al. Herit Sci  (2017) 5:44 
When present, thick, homogeneous and well-developed 
crusts, rich in either calcite or gypsum, partially shield 
the host rock from further pollutant absorption.
From this study, it arises that most of the alteration 
products of Euganean trachyte are due to exogenous pro-
cesses, whereas the stone itself does not have particular 
compositional features prone to trigger major danger-
ous mechanisms of decay. Generally, composition of 
the weathering crusts and patinas of Euganean trachyte 
proves to be an informative marker for the relevant envi-
ronmental conditions and their evolution, with a strict 
link with air pollution determined by different anthropic 
pollution sources.
Further studies are needed concerning trachyte-mortar 
interaction, in order to explore to what extent mortar 
affects stone surface alteration and in which microcli-
matic conditions, what is the mobilization potential of 
the leached components, and the influence of different 
mortar recipes.
Abbreviations
EDS: energy-dispersive X-ray spectroscopy; FE-SEM: field-emission scanning 
electron microscope; LA-ICPMS: laser ablation inductively coupled plasma 
mass spectrometry; PM: particulate matter; SEM: scanning electron micro-
scope; TSP: total suspended particulate; VOC: volatile organic compounds; 
XRPD: X-ray powder diffraction.
Authors’ contributions
This paper has been extracted from the Ph.D. thesis written by LG, after a 
research work supervised by CM and co-supervised by LM at the University of 
Padova. SS supervised the research activities carried out at the University of 
Göttingen. Finally, KS provided support for the LA-ICPMS analyses. All authors 
read and approved the final manuscript.
Author details
1 Department of Geosciences, University of Padova, Via Gradenigo 6, 
35131 Padua, Italy. 2 Geoscience Center, Georg-August-Universität Göttingen, 
Goldschmidtstrasse 3, 37077 Göttingen, Germany. 
Acknowledgements
The authors thank Kirsten Techmer and Klaus Wemmer (Uni. Göttingen) for 
their support during the SEM and XRPD analyses, respectively. The authors 
are very grateful to Hans Ruppert (Uni. Göttingen) for the helpful discussions 
on the results. The review and comments on an early draft of the manuscript 
by Giuseppe Cultrone (Uni. Granada) are also much appreciated. Thanks are 
due to Comune di Padova for kindly authorizing sampling on the city walls 
and to Comitato Mura di Padova, in particular Fabio Bordignon, for provid-
ing information on the building phases and past conservation interventions. 
Finally, ARPAV agency is acknowledged for providing the climatic and air qual-
ity data, and Dario Camuffo (CNR-ISAC, Padova) and Michela Rogora (CNR-ISE, 
Verbania) for further information on local environmental parameters.
Additional file
Additional file 1. Trace-element chemical composition expressed as 
ppm of representative samples of Euganean trachyte from the Renais-
sance city walls of Padua determined by LA-ICPMS, on both surface (i.e., 
weathering crust or patina) and host rock (inner part). The samples are 
divided by different types of alteration and sampling location as in Fig. 2 
(SCR, Bastione Santa Croce; GAR, Torrione dell’Arena; CSN, Bastione Castel-
nuovo; FST, Torrione Venier).
Competing interests
The authors declare that they have no competing interests.
Availability of data and materials
An extra database of chemical data is provided as supplementary on-line 
material (“Additional file 1”).
Consent for publication
Not applicable.
Ethics approval and consent to participate
Not applicable.
Funding
University of Padova (Research Project No. CPDA151883/15 of CM), DAAD 
(German Academic Exchange Service, Short-Term Research Grants 2016–
57214227 to LG), European Union (Erasmus + grant to LG).
Publisher’s Note
Springer Nature remains neutral with regard to jurisdictional claims in pub-
lished maps and institutional affiliations.
Received: 30 June 2017   Accepted: 13 September 2017
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