Because of their vivid colors, ranging from yellow to red, arsenic sulfides were used as pigments since ancient times [1, 2]. Natural arsenic sulfide pigments differ for their As:S ratios, and include realgar (α-AsS), pararealgar (β-AsS), and orpiment (As2S3). Realgar, a widely used orange/red pigment, occurs in low-temperature hydrothermal deposits [35]. Pararealgar is the light-induced degradation yellow form of realgar and alacranite [6, 7]. Mixtures of pararealgar and/or realgar have been systematically observed in many studies [810]. Orpiment was widely used as a yellow colorant besides yellow ochre since ancient times [11]. Another arsenic sulfide, alacranite (As8S9) [12] is a rather uncommon red mineral showing a complicated crystallographic structure where clusters of As4S4 (realgar-type) and As4S5 coexist in an ordered cagelike structure [3]. Although rare in nature, alacranite has been documented in works of art as a possible artificial product deriving from the arsenolite smelting [1315]. The production of artificial orpiment in Western Europe was first mentioned by Johannes Alcherius in his recipe collection (1380–1420) [16], but the very first description of this synthetic pigment was made by Cennino Cennini in his treatise [17]. According to these and later sources artificial orpiment was initially obtained by sublimation, using the dry-process method [15]. The wet-process method, which produces a yellow precipitate, was introduced at the end of the nineteenth century [2 and references therein, 18].

Characterizing arsenic sulfide pigments and accurately distinguishing between natural and synthetic origin is a challenging chemical and crystallographic problem which requires a multi-analytical approach. Techniques such as polarized light microscopy (PLM), micro-Raman spectroscopy (RM), X-Ray Fluorescence spectrometry, X-Ray Diffraction (XRD), Scanning Electron Microscopy with Energy Dispersive microanalysis (SEM-EDS) [15] are best suited to this task: some of them allow non-invasive analysis while others require microsampling. An in-depth study carried out on natural and artificial orpiment, the latter obtained through both wet- and dry-process, pointed out how only the results from the combination of several techniques allowed to identify the actual nature of the pigment [2, 14]. In particular, the presence of spherules of arsenic sulfide glass or alacranite solid solution series (As8S8)–(As8S9) was shown to be conclusive evidence for an artificial origin for orpiment [14].

In this work we investigated green and yellow pigments in Japanese woodblock prints dating to the late Edo (1615–1868) and early Meiji period (1868–1912). A collection of 30 dated prints ranging from 1864 to 1887 (Table 1) was assembled by one of the authors with the purpose of examining the chronology of the introduction of synthetic organic dyes in Japan (a paper on this topic is forthcoming). In the course of this study we initially surveyed the prints in all colored areas with X-ray Fluorescence Spectroscopy. The discovery of arsenic in the yellow and green areas, usually interpreted as a sign of the use of the pigment orpiment (As2S3) was rather interesting. Yellow pigments traditionally used in Japan for painting include orpiment, yellow earth, gamboge, and berberin [19, 20]. A recent study by Yamato [21] on Japanese prints dating to 1811–29 and 1836–91 similarly noted a widespread use of arsenic containing pigments for yellow and green areas, with turmeric often present in the yellow area.

Table 1 List of the prints analyzed in this research, complete of dates, authors, and titles

For woodblock prints, a commercial form of art, the use of cheaper pigments is generally expected, making the use of natural orpiment, usually an expensive pigment, quite unlikely. In her study, Yamato used the appearance of the pigment under optical microscopy observation to distinguish between synthetic and natural arsenic sulfides. In this study, we offer a fully multianalytical classification based on optical microscopy, Raman microscopy, and Scanning Electron microscopy with Energy Dispersive Spectrometry.



30 Japanese prints dated from 1864 to 1887 were selected for the analyses. A complete list of the prints alongside with their titles and authors is reported in Table 1.

A multi-technique approach, which includes micro-X-ray fluorescence, micro-Raman spectroscopy and Scanning Electron Microscopy equipped with Energy Dispersive Spectrometry, was followed in this study. The use of X-ray Diffraction was ruled out because of the small dimensions of the pigment particles and the low pigment coverage, which would have resulted in unacceptably large samples.


Micro X-ray fluorescence (micro-XRF) measurements were acquired with a Bruker ARTAX 400 instrument using unfiltered Rh radiation at 50 kV, 700 μA. Spectra were acquired with a 1 mm collimator for 120 s live-time accumulations.

Micro-Raman spectroscopy

Micro-Raman spectra were acquired with using a Bruker Senterra™ dispersive Raman microscope system, operating at 785 nm. Raman spectra were acquired directly from the prints using an Olympus LMPlanFL 50× long working distance objective, at a spectral resolution of 3–5 cm−1 and 30 s integration time. To avoid degradation or heat induced physical changes, the power at the laser injection port was limited to 1 mW. Integration times of 30 s were employed and three accumulations were averaged for each spectrum to obtain an adequate signal-to-noise ratio. Spectra were acquired and processed using the Opus 7.0 Raman software.


Pigment coated paper fiber samples for SEM-EDS analysis were mounted on aluminum stubs using a carbon adhesive tab and coated with a 10 nm carbon layer. SEM analyses (backscattered electron images and point analyses) were performed with a FE-SEM Zeiss Σigma HD, equipped with an Oxford Instrument X-MaxN 80 SDD detector. EDS microanalyses were run at 20 kV acceleration voltage and a working distance of 8.5 mm. Data were acquired and processed using the AZtec software system, v. 2.2 SP2 (Oxford Instruments).

Results and discussion

The majority of data was initially acquired by using non-destructive techniques, and for all the prints the same analytical approach was followed: XRF was systematically run on all the colored portions of each print, then, according to the elemental composition Raman measurements were acquired on selected areas. Finally, selective sampling was carried out to proceed with SEM-EDS analyses.


XRF data for green and yellow areas show the presence of arsenic and sulfur with other minor elements, notably iron, due to the paper matrix. The iron concentration seems higher in the green areas, possibly reflecting the use of Prussian blue mixed with the yellow to obtain the green shade.

Micro-Raman spectroscopy

Raman measurements were collected on both green (Fig. 1) and yellow (Fig. 2) areas from all the prints. Spectra resulting from the arsenic containing green- and yellow-colored areas display the same characteristic features across the range of prints examined: a broad band at 329–340 cm−1, with a shoulder at 365 cm−1 (Figs. 1, 2) as well as small bands at 230 and 471 cm−1. Only spectra collected from green areas exhibit an additional band at 2154 cm−1 (Fig. 1), which is the diagnostic band of Prussian blue. The band at 471 cm−1 was detected in all the prints, with variable intensity: this band and the associated bands at 150 and 217 cm−1 are characteristic of sulfur. The broad peak at 329–340 cm−1 and that at 230 cm−1 find a good match with alacranite [22]. No matches with natural orpiment were found [23, 24].

Fig. 1
figure 1

Raman Spectra of selected green colored areas. A Print 5, B Print 11, C Print 27

Fig. 2
figure 2

Raman Spectra obtained from selected yellow colored areas. A Print 3, B Print 4, C Print 19, D Print 7

The strong characteristic peaks at 329 and 340 cm−1 may be attributed to the monomer units in the alacranite structure, forming the shoulder at 360 cm−1. The insert in Fig. 1 shows also the characteristic peaks at about 349 and 355 cm−1, which may be assigned to the deformation and cage breath of the monomer As4S4 [22].


Backscattered electron images of some fibers taken from the yellow colored areas, display variously shaped and sized particles, scattered on single fibers (Fig. 3). Some particles show an irregular, elongated shape with sharp edges and sizes up to 13 μm (Fig. 3a). Rare particles are very small spheres (Fig. 3b), up to 8 μm in size, perfectly round and smooth. Semi-quantitative EDS microanalyses have been performed on both these particle typologies, and all showed similar compositions, with an average sulfur content of 53.8 ± 3.9 wt% and arsenic of 45.2 ± 3.8 wt%. This composition is consistent with that of arsenic sulfide pigments, with sulfur unusually exceeding the arsenic concentration. Similar compositions have been detected also in the arsenic sulfide pigments used to decorate the Japanese tower in Laeken, Belgium [13]. These results are not consistent with the use of a natural arsenic sulfide (e.g., orpiment), as none of the observed particles did exhibit the foliated structure of natural orpiment and the chemical compositions are non-stoichiometric. It is worth to note that every arsenic sulfide particle is characterized by the presence of copper as minor component. No As2O3 particles have been observed on the selected fibers.

Fig. 3
figure 3

Back-scattered Electron image of a yellow colored fiber from Print 2, Kunichika, The actor Kawarazaki Gonjûrô, from the series Shindô Suikoden. a prismatic particle of arsenic sulfide; b spherical arsenic sulfides


In all the prints from late Edo to Meiji period analyzed in this study, the systematic presence of arsenic and sulfur for the yellow and green colors indicates the use of arsenic sulfide-based pigments. This is consistent with results obtained by Yamato [21].

Micro-Raman spectroscopy showed the presence of alacranite and sulfur in the yellows, with additional Prussian blue added to obtain the green shades. The mixture of arsenic sulfide and Prussian blue explain the higher iron concentration detected by XRF in the green pigments. The broadening of the alacranite bands in the range between 329 and 340 cm−1, indicative of the presence of amorphous arsenic sulfide glass is consistent with the use of synthetic arsenic sulfides as shown by Vermeulen et al. [13]. Likewise, the presence of free sulfur has been interpreted by Vermeulen et al. [13] as due to the dry-process method used to synthesize the pigment. SEM-EDS analyses further strengthen this hypothesis, since the presence of alacranite spherules (Fig. 3b), with non-stoichiometric ratio between arsenic and sulfur, is indicated in literature as the evidence for synthetic arsenic sulfides produced by dry-process rather than a wet-process method [2, 14, 15]. Interestingly, the analyses of the Aizu synthetic arsenic sulfide pigment carried out by Takamatsu in 1878 also show excess free sulfur [25].

The production of arsenic sulfides by sublimation from burning arsenolite and sulfur, dates back to the fourteenth century in Western Europe, but no sources have been found about their production in East Asia. The only reference known, that of Takamatsu in 1878 [25], refers to a possible production of artificial orpiment in Japan in about 1846, by burning arsenical stones with sulfur, in Aizu (in the present Fukushima prefecture). The very low concentration of copper may be explained by the exploitation of arsenic ores related to copper mining, largely attested in Japan [2628].


The evidence presented in this study demonstrates that synthetic arsenic sulfide pigments were most likely manufactured in Japan in the late Edo period and in the early Meiji period. We show conclusively that this pigment was commonly used in woodblock printing, probably due to its low cost and easy availability. Takamatsu [25] reports “large scale” manufacture of orpiment in the Aizu region in northern Japan, and mentions the use of the pigment for tinting varnishes and painting book covers. No mention is made however of its use for woodblock prints. Takamatsu reports also that manufacture of synthetic orpiment would have started after 1846: while it is tempting to correlate this report with the finding of realgar (likely available and mined in the prefecture of Gunma) in several Edo period prints in the collection of the Metropolitan Museum of Art (results unpublished), a full study of arsenic pigments in Edo period woodblock prints will need to be carried before giving excessive weight to this date.

Finally, Takamatsu’s article also allows us to compare the price of artificial orpiment with that of gamboge, an imported and expensive yellow pigment also traditionally used on woodblock prints. The price of synthetic orpiment is quoted as 42 sen per 1 kin, while that of gamboge is 1.35 yen per 1 kin. At 100 sen to the yen, synthetic orpiment is less than one third the price of gamboge, making it a very attractive pigment for the woodblock printing trade.