318 research outputs found
Improved determination of the 1(0)-0(0) rotational frequency of NH3D+ from the high resolution spectrum of the v4 infrared band
The high resolution spectrum of the v4 band of NH3D+ has been measured by
difference frequency IR laser spectroscopy in a multipass hollow cathode
discharge cell. From the set of molecular constants obtained from the analysis
of the spectrum, a value of 262817(6) MHz (3sigma) has been derived for the
frequency of the 1(0)-0(0) rotational transition. This value supports the
assignment to NH3D+ of lines at 262816.7 MHz recorded in radio astronomy
observations in Orion-IRc2 and the cold prestellar core B1-bS.Comment: Accepted for publication in the Astrophysical Journal Letters 04 June
201
A Rational Expectations Model for Simulation and Policy Evaluation of the Spanish Economy
This paper describes a Rational Expectations Model of the Spanish economy, REMS, which is in the tradition of small open economy dynamic general equilibrium models, with a strongly microfounded system of equations. The model is built on standard elements, but incorporates some distinctive features to provide an accurate description of the Spanish economy. We contribute to the existing models of the Spanish economy by adding search and matching rigidities to a small open economy framework. Our model also incorporates habits in consumption and rule-of-thumb households. As Spain is a member of EMU, we model the interaction between a small open economy and monetary policy in a monetary union. The model is primarily constructed to serve as a simulation tool at the Spanish Ministry of Economic Affairs and Finance. As such, it provides a great deal of information regarding the transmission of policy shocks to economic outcomes. The paper describes the structure of the model in detail, as well as the estimation and calibration technique and some examples of simulations.general equilibrium, rigidities, policy simulations
The REMSDB Macroeconomic Database of The Spanish Economy
This paper presents a new macroeconomic database for the Spanish economy, REMSDB. The construction of this database has been oriented to conducting medium-term simulations for policy evaluation with the REMS model, a large Rational Expectations macroeconomic Model for Spain. The paper provides a detailed description of the data and documents its main statistical properties. The database is thought to be of major interest to related applications,whether strictly associated with the REMS model or, rather, with empirical macroeconomic studies.Spanish Data, Growth Data, Business Cycle Data, REMS
Culture and World Vision: The Cognitive Mythical Mode
Abstract Culture is the system of knowledge, from whose meanings the human being screened and selected their understanding of Reality in the broad sense, and interprets and regulates the facts and data of social behavior. In this sense, culture is a program for social action and acting in humans during the process of socialization and social interaction. The meanings of each culture are the cumulative product of collective and individual thinking, in ecological economic, social and political specific situations, so are the expression of each particular cultural historical conjuncture. Moreover, the universal cognitive structure for the apprehension of cultural reality is the World Vision (WV). Due to its importance and significance as substratum of religious and political belief systems, we will gird our study to mythical cognitive mode or mythical WV. Keywords: beliefs, culture, modal logic, myth, mythical dimension, mythopoiesis, world vision Cite This Article: J. Nescolarde-Selva, and J.L. Usó-Doménech, "Culture and World Vision: The Cognitive Mythical Mod
Using radio astronomical receivers for molecular spectroscopic characterization in astrochemical laboratory simulations: A proof of concept
We present a proof of concept on the coupling of radio astronomical receivers
and spectrometers with chemical reactorsand the performances of the resulting
setup for spectroscopy and chemical simulations in laboratory astrophysics.
Several experiments including cold plasma generation and UV photochemistry were
performed in a 40\,cm long gas cell placed in the beam path of the Aries 40\,m
radio telescope receivers operating in the 41-49 GHz frequency range interfaced
with fast Fourier transform spectrometers providing 2 GHz bandwidth and 38 kHz
resolution.
The impedance matching of the cell windows has been studied using different
materials. The choice of the material and its thickness was critical to obtain
a sensitivity identical to that of standard radio astronomical observations.
Spectroscopic signals arising from very low partial pressures of CH3OH,
CH3CH2OH, HCOOH, OCS,CS, SO2 (<1E-03 mbar) were detected in a few seconds. Fast
data acquisition was achieved allowing for kinetic measurements in
fragmentation experiments using electron impact or UV irradiation. Time
evolution of chemical reactions involving OCS, O2 and CS2 was also observed
demonstrating that reactive species, such as CS, can be maintained with high
abundance in the gas phase during these experiments.Comment: Accepted for publication in Astronomy and Astrophysics in September
21, 2017. 16 pages, 18 figure
Another beauty of analytical chemistry: chemical analysis of inorganic pigments of art and archaeological objects
[EN] This lecture text shows what fascinating tasks analytical chemists face in Art Conservation and Archaeology, and it is hoped that students reading it will realize that passions for science, arts or history are by no means mutually exclusive. This study describes the main analytical techniques used since the eighteenth century, and in particular, the instrumental techniques developed throughout the last century for analyzing pigments and inorganic materials, in general, which are found in cultural artefacts, such as artworks and archaeological remains. The lecture starts with a historical review on the use of analytical methods for the analysis of pigments from archaeological and art objects. Three different periods can be distinguished in the history of the application of the Analytical Chemistry in Archaeometrical and Art Conservation studies: (a) the "Formation'' period (eighteenth century1930), (b) the "Maturing'' period (1930-1970), and (c) the "Expansion'' period (1970-nowadays). A classification of analytical methods specifically established in the fields of Archaeometry and Conservation Science is also provided. After this, some sections are devoted to the description of a number of analytical techniques, which are most commonly used in routine analysis of pigments from cultural heritage. Each instrumental section gives the fundamentals of the instrumental technique, together with relevant analytical data and examples of applications.Financial support is gratefully acknowledged from Spanish ‘‘I+D+I MINECO’’ projects CTQ2011-28079-CO3-01 and CTQ2014-53736-C3-1-P supported by ERDEF funds.Domenech Carbo, MT.; Osete Cortina, L. (2016). Another beauty of analytical chemistry: chemical analysis of inorganic pigments of art and archaeological objects. ChemTexts. 2:1-50. https://doi.org/10.1007/s40828-016-0033-5S1502Wilks H (ed) (1987) Science for conservators: a conservation science teaching series. The Conservation Unit Museums and Galleries Commission, LondonSan Andrés Moya M, Viña Ferrer S (2004) Fundamentos de química y física para la conservación y restauración. Síntesis, MadridDoménech-Carbó MT (2013) Principios físico-químicos de los materiales integrantes de los bienes culturales, Universitat Politècnica de ValènciaMills JS, White R (1987) The organic chemistry of museum objects. Butterworths, London, pp 141–159Matteini M, Moles A (1991) La Quimica nel Restauro. I materiali dell’arte pittorica. Nardini, FirenzeGomez MA (1998) La Restauración. Examen científico aplicado a la conservación de obras de arte. Cátedra, MadridTaft WS Jr, Mayer JW (2000) The science of paintings. Springer, New YorkAllen RO (ed) (1989) Archaeological chemistry IV; Advances in chemistry. American Chemical Society, Washington, DCAitken MJ (1990) Science-based dating in archaeology. Longman Archaeology Series, New YorkCiliberto E, Spoto G (eds) (2000) Modern analytical methods in art and archaeology. Wiley, New YorkMatteini M, Moles A (1986) Sciencia e Restauro. Metodi di Indagine, 2nd edn. Nardini, FirenzeOdegaard N, Carroll S, Zimmt W (2000) Material characterization tests for objects of art and archaeology. Archetype Publications, LondonDerrick MR, Stulik DC, Landry MJ (1999) Infrared spectroscopy in conservation science. Getty Conservation Institute, Los AngelesDoménech-Carbó A, Doménech-Carbó MT, Costa V (2009) Electrochemical methods in archaeometry, conservation and restoration. In: Scholz F (ed) Series: Monographs in electrochemistry. Springer, BerlinEdwards HGM, Chalmers JM (eds) (2005) Raman spectroscopy in archaeology and art history. The Royal Society of Chemistry, CambridgeLahanier C (1991) Scientific methods applied to the study of art objects. Mikrochim Acta II:245–254Bitossi G, Giorgi R, Salvadori BM, Dei L (2005) Spectroscopic techniques in cultural heritage conservation: a survey. Appl Spectrosc Rev 40:187–228Odlyha M (2000) Special feature: preservation of cultural heritage. The application of thermal analysis and other advanced analytical techniques to cultural objects. Thermochim Acta 365Feature Special (2003) Archaeometry. Meas Sci Technol 14:1487–1630Aitken MJ (1961) Physics and archaeology. Interscience, New YorkOlin JS (ed) (1982) Future directions in archaeometry. A round table. Smithsonian Institution Press, Washington, DCTownsend JH (2006) What is conservation science? Macromol Symp 238:1–10Nadolny J (2003) The first century of published scientific analyses of the materials of historical painting and polychromy, circa 1780–1880. Rev Conserv 4:39–51Montero Ruiz I, Garcia Heras M, López-Romero E (2007) Arqueometría: cambios y tendencias actuales. Trabajos de Prehistoria 64:23–40Fernandes Vieira G, Sias Coelho LJ (2011) Arqueometría: Mirada histórica de una ciencia en desarrollo. Revista CPC 13:107–133Rees-Jones SG (1990) Early experiments in pigment analysis. Stud Conserv 35:93–101Allen RO (1989) The role of the chemists in archaeological studies. In: Allen RO (ed) Archaeological chemistry IV. Advances in chemistry. American Chemical Society, Washington DC, pp 1–17Plesters J (1956) Cross-sections and chemical analysis of paint samples. Stud Conserv 2:110–157 and references thereinGilberg M (1987) Friedrich Rathgen: the father of modern archaeological conservation. J Am Inst Conserv 26:105–120Olin JS, Salmon ME, Olin CH (1969) Investigations of historical objects utilizing spectroscopy and other optical methods. Appl Optics 8:29–39Feller RL (1954) Dammar and mastic infrared analysis. Science 120:1069–1070Hall ET (1963) Methods of analysis (physical and microchemical) applied to paintings and antiquities. In: Thomson G (ed) Recent advances in conservation. Butterworths, London, pp 29–32Feigl F, Anger V (1972) Spot tests in inorganic analysis, 6th English edition, translated by Oesper RE. Elsevier, AmsterdamLocke DC, Riley OH (1970) Chemical analysis of paint samples using the Weisz ring oven technique. Stud Conserv 15:94–101Mairinger F, Schreiner M (1986) Analysis of supports, grounds and pigments. In: van Schoute R, Verougstracte-Marcq H (eds) PACT 13, Xth Anniversary Meeting of PACT Group. Louvain-la Neuve, pp 171–183 (and references therein)Vandenabeele P, Edwards HGM (2005) Overview: Raman spectrometry of artefacts. In: Edwards HGM, Chalmers JM (eds) Raman spectroscopy in archaeology and art history. The Royal Society of Chemistry, Cambridge, pp 169–178Tykot RH (2004) Scientific methods and applications to archaeological provenance studies. In: Proceedings of the International School of Physics “Enrico Fermi”. IOS Press, Amsterdam, pp 407–432Doménech-Carbó A, Doménech-Carbó MT, Valle-Algarra FM, Domine ME, Osete-Cortina L (2013) On the dehydroindigo contribution to Maya Blue. J Mat Sci 48:7171–7183Lovric M, Scholz F (1997) A model for the propagation of a redox reaction through microcrystals. J Solid State Electrochem 1:108–113Fitzgerald AG, Storey BE, Fabian D (1993) Quantitative microbeam analysis. Scottish Universities Sumer School in Physics and Institute of Physics Publishing, BristolDoménech-Carbó A (2015) Dating: an analytical task. ChemTexts 1:5Mairinger F, Schreiner M (1982) New methods of chemical analysis-a tool for the conservator. Science and Technology in the service of conservation, IIC, London, pp 5–13Malissa H, Benedetti-Pichler AA (1958) Anorganische qualitative Mikroanalyse. Springer, New YorkTertian R, Claisse F (1982) Principles of quantitative X-ray fluorescence analysis. Heyden, LondonMantler M, Schreiner M (2000) X-ray fluorescence spectrometry in art and archaeology. X-Ray Spectrom 29:3–17Scholz F (2015) Voltammetric techniques of analysis: the essentials. ChemTexts 1:17Inzelt G (2014) Crossing the bridge between thermodynamics and electrochemistry. From the potential of the cell reaction to the electrode potential. ChemTexts 1:2Milchev A (2016) Nucleation phenomena in electrochemical systems: thermodynamic concepts. ChemTexts 2:2Milchev A (2016) Nucleation phenomena in electrochemical systems: kinetic models. ChemTexts 2:4Seeber R, Zanardi C, Inzelt G (2015) Links between electrochemical thermodynamics and kinetics. ChemTexts 1:18Feist M (2015) Thermal analysis: basics, applications, and benefit. ChemTexts 1:8Stoiber RE, Morse SA (1994) Crystal identification with the polarizing microscope. Springer, BerlinGoldstein JI, Newbury DE, Echlin P, Joy DC, Lyman CE, Echlin P, Lifshin E, Sawyer L, Michael JR (2003) Scanning electron microscopy and X-ray microanalysis. Plenum Press, New YorkDoménech-Carbó A, Doménech-Carbó MT, Más-Barberá X (2007) Identification of lead pigments in nanosamples from ancient paintings and polychromed sculptures using voltammetry of nanoparticles/atomic force microscopy. Talanta 71:1569–1579Reedy TJ, Reedy ChL (1988) Statistical analysis in art conservation research. The Getty Conservation Institute, Los AngelesEastaugh N, Walsh V, Chaplin T, Siddall R (2004) Pigment compendium, optical microscopy of historical pigments. Elsevier, OxfordFeller RL, Bayard M (1986) Terminology and procedures used in the systematic examination of pigment particles with polarizing microscope. In: Feller RL (ed) Artists’ pigment. A handbook of their history and characteristics, vol 1. National Gallery of Art, Washington, pp 285–298Feller RL (ed) (1986) Artists’ pigment. A handbook of their history and characteristics, vol 1. National Gallery of Art, WashingtonRoy A (ed) (1993) Artists’ pigments. A handbook of their history and characteristics, vol 2. National Gallery of Art, WashingtonFitzHugh EW (ed) (1997) Artists’ pigments. A handbook of their history and characteristics, vol 3. National Gallery of Art, WashingtonBerrie BH (ed) (2007) Artists’ pigment. A handbook of their history and characteristics, vol 4. National Gallery of Art, WashingtonHaynes WN (ed) (2015) CRC handbook for physics and chemistry, 96th edn. Taylor and Francis Group, UKFiedler I, Bayard MA (1986) Cadmium yellows, oranges and reds. In: Feller RL (ed) Artists’ pigment. A handbook of their history and characteristics, vol 1. National Gallery of Art, Washington, pp 65–108Domenech-Carbó MT, de Agredos Vazquez, Pascual ML, Osete-Cortina L, Domenech A, Guasch-Ferré N, Manzanilla LR, Vidal C (2012) Characterization of Pre-hispanic cosmetics found in a burial of the ancient city of Teotihuacan (Mexico). J Archaeol Sci 39:1043–1062Mühlethaler B, Thissen J (1993) Smalt. In: Roy A (ed) Artists’ pigments. A handbook of their history and characteristics, vol 2. National Gallery of Art, Washington, pp 113–130Musumarra G, Fichera M (1998) Chemometrics and cultural heritage. Chemometr Intell Lab Syst 44:363–372Hochleitner B, Schreiner M, Drakopoulos M, Snigireva I, Snigirev A (2005) Analysis of paint layers by light microscopy, scanning electron microscopy and synchrotron induced X-ray micro-diffraction. In: Van Grieken R, Janssens K (eds) Cultural heritage conservation and environment impact assessment by non-destructive testing and micro-analysis. AA Balkema Publishers, London, pp 171–182Švarcová S, Kočí E, Bezdička P, Hradil D, Hradilová J (2010) Evaluation of laboratory powder X-ray micro-diffraction for applications in the fields of cultural heritage and forensic science. Anal Bioanal Chem 398:1061–1076Van de Voorde L, Vekemans B, Verhaeven E, Tack P, DeWolf R, Garrevoet J, Vandenabeele P, Vincze L (2015) Analytical characterization of a new mobile X-ray fluorescence and X-ray diffraction instrument combined with a pigment identification case study. Spectrochim Acta B 110:14–19Hochleitner B, Desnica V, Mantler M, Schreiner M (2003) Historical pigments: a collection analyzed with X-ray diffraction analysis and X-ray fluorescence analysis in order to create a database. Spectrochim Acta B 58:641–649Middleton PS, Ospitali F, Di Lonardo F (2005) Case study: painters and decorators: Raman spectroscopic studies of five Romano-British villas and the Domus Coiedii at Suasa, Italy. In: Edwards HGM, Chalmers JM (eds) Raman spectroscopy in archaeology and art history. The Royal Society of Chemistry, Cambridge, pp 97–120Helwig K (1993) Iron oxide pigments: natural and synthetic. In: Roy A (ed) Artists’ pigments. A handbook of their history and characteristics, vol 2. National Gallery of Art, Washington, pp 39–95Silva CE, Silva LP, Edwards HGM, de Oliveira LFC (2006) Diffuse reflection FTIR spectral database of dyes and pigments. Anal Bioanal Chem 386:2183–2191Hummel DO (ed) (1985) Atlas of polymer and plastic analysis, vol 1, Polymers, structures and spectra. Hanser VCH, Münichhttp://www.irug.org (consulted: 1 Feb 2016)http://www.ehu.es/udps/database/database.html (consulted: 1 Feb 2016)Burgio L, Clark RJH (2001) Library of FT-Raman spectra of pigments, minerals, pigment media and varnishes, and supplement to existing library of Raman spectra of pigments with visible excitation. Spectrochim Acta A 57:1491–1521http://www.chem.ucl.ac.uk/resources/raman/speclib.html (consulted: 1 Feb 2016)Madariaga JM, Bersani D (2012) Special feature: Raman spectroscopy in art and archaeology. J Raman Spectrosc 43(11):1523–1844http://minerals.gps.caltech.edu/ (consulted: 1 Feb 2016)http://www.rruff.info (consulted: 1 Feb 2016)Frost RL, Martens WN, Rintoul L, Mahmutagic E, Kloprogge JT (2002) J Raman Spectrosc 33:252–259Smith D (2005) Overwiew: jewellery and precious stones. In: Edwards HGM, Chalmers JM (eds) Raman spectroscopy in archaeology and art history. The Royal Society of Chemistry, Cambridge, pp 335–378Weiner S, Bar-Yosef O (1990) States of preservation of bones from prehistoric sites in the Near East: a survey. J Archaeol Sci 17:187–196Chu V, Regev L, Weiner S, Boaretto E (2008) Differentiating between anthropogenic calcite in plaster, ash and natural calcite using infrared spectroscopy: implications in archaeology. J Archaeol Sci 35:905–911Beniash E, Aizenberg J, Addadi L, Weiner S (1997) Amorphous calcium carbonate transforms into calcite during sea-urchin larval spicule growth. Proc R Soc Lond Ser B 264:461–465Regev L, Poduska KM, Addadi L, Weiner S, Boaretto E (2010) Distinguishing between calcites formed by different mechanisms using infrared spectrometry: archaeological applications. J Archaeol Sci 37:3022–3029Farmer C (ed) (1974) The infrared spectra of mineral, Monograph 4. Mineralogical Society, LondonMadejová J, Kečkéš J, Pálková H, Komadel P (2002) Identification of components in smectite/kaolinite mixtures. Clay Miner 37:377–388Šucha V, Środoń J, Clauer N, Elsass F, Eberl DD, Kraus I, Madejová J (2001) Weathering of smectite and illite–smectite under temperate climatic conditions. Clay Miner 36:403–419Doménech-Carbó A, Doménech-Carbó MT, López-López F, Valle-Algarra FM, Osete-Cortina L, Arcos-Von Haartman E (2013) Electrochemical characterization of egyptian blue pigment in wall paintings using the voltammetry of microparticles methodology. Electroanalysis 25:2621–2630Doménech-Carbó MT, Edwards HGM, Doménech-Carbó A, del Hoyo-Meléndez JM, de la Cruz-Cañizares J (2012) An authentication case study: Antonio Palomino vs. Vicente Guillo paintings in the vaulted ceiling of the Sant Joan del Mercat church (Valencia, Spain). J Raman Spectrosc 43:1250–1259Lovric M, Scholz F (1999) A model for the coupled transport of ions and electrons in redox conductive microcrystals. J Solid State Electrochem 3:172–175Oldham KB (1998) Voltammetry at a three phase junction. J Solid State Electrochem 2:367–377Doménech A, Doménech-Carbó MT, Gimeno-Adelantado JV, Bosch-Reig F, Saurí-Peris MC, Sánchez-Ramos S (2001) Electrochemical identification of iron oxide pigments (earths) from pictorial microsamples attached to graphite/polyester composite electrodes. Analyst 126:1764–1772Doménech A, Doménech-Carbó MT, Moya-Moreno MCM, Gimeno-Adelantado JV, Bosch-Reig F (2000) Identification of inorganic pigments from paintings and polychromed sculptures immobilized into polymer film electrodes by stripping differential pulse voltammetry. Anal Chim Acta 407:275–289Doménech-Carbó A, Doménech-Carbó MT, Valle-Algarra FM, Gimeno-Adelantado JV, Osete-Cortina L, Bosch-Reig F (2016) On-line database of voltammetric data of immobilized particles for identifying pigments and minerals in archaeometry, conservation and restoration (ELCHER database). Anal Chim Acta 927:1–12http://www.elcher.info (consulted: 1 July 2016)Scholz F, Doménech-Carbó A (2010) Special feature: electrochemistry for conservation science. J Solid State Electrochem 14Domenech-Carbó A, Domenech-Carbó MT, Edwards HGM (2007) Identification of earth pigment by hierarchical cluster applied to solid state voltammetry. Application to a severely damaged frescoes. Electroanalysis 19:1890–1900Domenech-Carbó A, Domenech-Carbó MT, Vázquez de Agredos-Pascual ML (2006) Dehydroindigo: a new piece into the Maya Blue puzzle from the voltammetry of microparticles approach. J Phys Chem B 110:6027–6039Doménech-Carbó A, Doménech-Carbó MT, Vázquez de Agredos-Pascual ML (2007) Chemometric study of Maya Blue from the voltammetry of microparticles approach. Anal Chem 79:2812–2821Doménech-Carbó A, Doménech-Carbó MT, Vázquez de Agredos-Pascual ML (2011) From Maya Blue to ‘Maya Yellow’: a connection between ancient nanostructured materials from the voltammetry of microparticles. Angew Chem Int Edit 50:5741–5744Doménech-Carbó A, Doménech-Carbó MT, Vidal-Lorenzo C, Vázquez de Agredos-Pascual ML (2012) Insights into the Maya Blue Technology: greenish pellets from the ancient city of La Blanca. Angew Chem Int Ed 51:700–703Doménech-Carbó A, Doménech-Carbó MT, Osete-Cortina L, Montoya N (2012) Application of solid-state electrochemistry techniques to polyfunctional organic-inorganic hybrid materials: the Maya Blue problem. Micropor Mesopor Mater 166:123–130Doménech-Carbó MT, Osete-Cortina L, Doménech-Carbó A, Vázquez de Agredos-Pascual ML, Vidal-Lorenzo C (2014) Identification of indigoid compounds present in archaeological Maya blue by pyrolysis-silylation-gas chromatography–mass spectrometry. J Anal Appl Pyrol 105:355–36
First detection of the pre-biotic molecule glycolonitrile (HOCH2CN) in the interstellar medium
Theories of a pre-RNA world suggest that glycolonitrile (HOCHCN) is a key
species in the process of ribonucleotide assembly, which is considered as a
molecular precursor of nucleic acids. In this Letter, we report the first
detection of this pre-biotic molecule in the interstellar medium (ISM) by using
ALMA data obtained at frequencies between 86.5GHz and 266.5GHz toward
the Solar-type protostar IRAS16293-2422 B. A total of 15 unblended transitions
of HOCHCN were identified. Our analysis indicates the presence of a cold
(T=248K) and a warm (T=15838K)
component meaning that this molecule is present in both the inner hot corino
and the outer cold envelope of IRAS16293 B. The relative abundance with respect
to H is (6.50.6)10 and
(62)10 for the warm and cold components
respectively. Our chemical modelling seems to underproduce the observed
abundance for both the warm and cold component under various values of the
cosmic-ray ionisation rate (). Key gas phase routes for the formation of
this molecule might be missing in our chemical network.Comment: 5 pages, 4 figures, 2 tables, accepted in Monthly Notices of the
Royal Astronomical Society Letter
FIB-FESEM and EMPA results on Antoninianus silver coins for manufacturing and corrosion processes
[EN] A set of ancient Antoninianus silver coins, dating back between 249 and 274¿A.D. and minted in Rome, Galliae, Orient and Ticinum, have been characterized. We use, for the first time, a combination of nano-invasive (focused ion beam-field emission scanning electron microscopy-X-ray microanalysis (FIB-FESEM-EDX), voltammetry of microparticles (VIMP)) and destructive techniques (scanning electron microscopy (SEM-EDX) and electron microprobe analysis (EMPA)) along with non-invasive, i.e., micro-Raman spectroscopy. The results revealed that, contrary to the extended belief, a complex Ag-Cu-Pb-Sn alloy was used. The use of alloys was common in the flourishing years of the Roman Empire. In the prosperous periods, Romans produced Ag-Cu alloys with relatively high silver content for the manufacture of both the external layers and inner nucleus of coins. This study also revealed that, although surface silvering processes were applied in different periods of crisis under the reign of Antoninii, even during crisis, Romans produced Antoninianus of high quality. Moreover, a first attempt to improve the silvering procedure using Hg-Ag amalgam has been identified.Financial support was provided by Sapienza University of Rome (Ateneo funding, 2014 15) and Spanish
projects CTQ2014-53736-C3-1-P and CTQ2014-53736-C3-2-P, which are supported with Ministerio de
Economía, Industria y Competitividad (MINECO) and Fondo Europeo de Desarrollo Regional (ERDF) funds, as
well as project CTQ2017-85317-C2-1-P supported with funds from, MINECO, ERDF and Agencia Estatal de
Investigación (AEI). PhD grants of the Department of Earth Sciences, Sapienza University of Rome, are gratefully
acknowledgedDomenech Carbo, MT.; Di Turo, F.; Montoya, N.; Catalli, F.; Doménech Carbó, A.; De Vito, C. (2018). FIB-FESEM and EMPA results on Antoninianus silver coins for manufacturing and corrosion processes. Scientific Reports. 8. https://doi.org/10.1038/s41598-018-28990-xS8Doménech-Carbó, A., del Hoyo-Meléndez, J. M., Doménech-Carbó, M. T. & Piquero-Cilla, J. Electrochemical analysis of the first Polish coins using voltammetry of immobilized particles. Microchem. J. 130, 47–55 (2017).Di Turo, F. et al. Archaeometric analysis of Roman bronze coins from the Magna Mater temple using solid-state voltammetry and electrochemical impedance spectroscopy. Anal. Chim. Acta 955, 36–47 (2017).Doménech-Carbó, A., Doménech-Carbó, M. T. & Peiró-Ronda, M. A. Dating Archeological Lead Artifacts from Measurement of the Corrosion Content Using the Voltammetry of Microparticles. Anal. Chem. 83, 5639–5644 (2011).Giumlia-Mair, A. et al. Surface characterisation techniques in the study and conservation of art and archaeological artefacts: a review. Materials Technology 25(5), 245–261 (2010).Robbiola, L. & Portier, R. A global approach to the authentication of ancient bronzes based on the characterization of the alloy–patina–environment system. Journal of Cultural Heritage 7, 1–12 (2006).Campbell, W. Greek and Roman plated coins, Numismatics Notes and Monographs 57, American Numismatic Society, New York (1933).Kallithrakas-Kontos, N., Katsanos, A. A. & Touratsoglou, J. Trace element analysis of Alexander the Great’s silver tetradrachms minted in Macedonia, Nuclear Instruments and Methods in Physics. Research B 171, 342–349 (2000).Catalli, F. Numismatica greca e romana. (Libreria dello Stato, 2003).Cope, L. H. The Metallurgical development of the Roman Imperial Coinage during the first five centuries. (Liverpool, 1974).Scriptores Historiae Augustae. Historia Augusta. (The Perfect Library, 2014).Vlachou-Mogire, C., Stern, B. & McDonnell, J. G. The application of LA-ICP-MS in the examination of the thin plating layers found in late Roman coins. Nucl. Instruments Methods Phys. Res. Sect. B Beam Interact. with Mater. Atoms 265, 558–568 (2007).Keturakis, C. J. et al. Analysis of corrosion layers in ancient Roman silver coins with high resolution surface spectroscopic techniques. Appl. Surf. Sci. 376, 241–251 (2016).Ingo, G. M. et al. Roman sophisticated surface modification methods to manufacture silver counterfeited coins. Appl. Surf. Sci. 1–11, https://doi.org/10.1016/j.apsusc.2017.01.101 (2017).La Niece, S. In: La Niece S. & Craddock, P. (Eds), Metal, Plating and Platination, Butterworth–Heinemann, London, 1993, p. 201.Anheuser, K. & France, P. Silver plating technology of the late 3rd century Roman coinage. Historical Metallurgy 36(1), 17–23 (2002).Anheuser, K. & Northover, P. Silver plating on Roman and Celtic coins from Britain– A technical study. The British Numismatic Journal 64, 22–32 (1994).Anheuser, K. Where is all the amalgam silvering? Materials Issues1996 in Art and Archaeology - V proceedings, Boston.Beck, L. et al. In NIM 269, 2011 and in Counterfeit coinage of the Holy Roman Empire in the 16th century: silvering process and archaeometallurgical replications, Archaeometallurgy in Europe III.Deraisme, A., Beck, L., Pilon, F. & Barrandon, J. N. A study of the silvering process of the Gallo-Roman coins forged during the third century AD. Archaeometry 48, 469–480 (2006).Giumlia-Mair, A. On surface analysis and archaeometallurgy. Nucl. Instruments Methods Phys. Res. Sect. B Beam Interact. with Mater. Atoms 239, 35–43 (2005).Tate, J. Some problems in analysing museum material by nondestructive surface sensitive techniques. Nuclear Inst. and Methods in Physics Research, B, 14 (1), pp. 20–23 (1986).Beck, L., Bosonnet, S., Réveillon, S., Eliot, D. & Pilon, F. Silver surface enrichment of silver-copper alloys: A limitation for the analysis of ancient silver coins by surface techniques. Nucl. Instruments Methods Phys. Res. Sect. B Beam Interact. with Mater. Atoms 226, 153–162 (2004).Pardini, L. et al. X-ray fluorescence and laser-induced breakdown spectroscopy analysis of Roman silver denarii. Spectrochim. Acta - Part B At. Spectrosc. 74–75, 156–161 (2012).Klockenkämper, R., Bubert, H. & Hasler, K. Detection of near-surface silver enrichment on Roman imperial silver coins by x-ray spectral analysis. Archaeometry 41, 311–320 (1999).Ponting, M., Evans, J. A. & Pashley, V. Fingerprinting of roman mints using laser-amblation MC-ICP-MS lead isotope analysis.Del Hoyo-Meléndez, J. M. et al. Micro-XRF analysis of silver coins from medieval Poland. Nucl. Instruments Methods Phys. Res. Sect. B Beam Interact. with Mater. Atoms 349, 6–16 (2015).Cesare Brandi. Il restauro. Teoria e pratica (1939–1986). (Editori Riuniti, 2009).Barberio, M., Veltri, S., Scisciò, M. & Antici, P. Laser-Accelerated Proton Beams as Diagnostics for Cultural Heritage. Sci. Rep. 7, 40415 (2017).Linke, R., Sehreiner, M., Demortier, G., Alram, M. & Winter, H. Non-Destructive Microanalysis of Cultural Heritage Materials. Comprehensive Analytical Chemistry 42, (Elsevier, 2004).Łojewska, J. et al. Recognizing ancient papyri by a combination of spectroscopic, diffractional and chromatographic analytical tools. Sci. Rep. 7, 46236 (2017).Meulebroeck, W., Wouters, H., Nys, K. & Thienpont, H. Authenticity screening of stained glass windows using optical spectroscopy. Nat. Sci. Reports 6 37726, 1–10 (2016).Martina, I., Wiesinger, R. & Schreiner, M. Micro-Raman Characterisation of Silver Corrosion Products: Instrumental Set Up and Reference. e-Preservation. Sci. Rep 9, 1–8 (2012).Rizzo, F. et al. Non-destructive determination of the silver content in Roman coins (nummi), dated to 308–311 A. D., by the combined use of PIXE-alpha, XRF and DPAA techniques. Microchem. J. 97, 286–290 (2011).Carl, M. & Young, M. L. Complementary analytical methods for analysis of Ag-plated cultural heritage objects. Microchem. J. 126, 307–315 (2016).Cepriá, G., Abadías, O., Pérez-Arantegui, J. & Castillo, J. R. Electrochemical Behavior of Silver-Copper Alloys in Voltammetry of Microparticles: A Simple Method for Screening Purposes. Electroanalysis 13, 477–483 (2001).Capelo, S., Homem, P. M., Cavalheiro, J. & Fonseca, I. T. E. Linear sweep voltammetry: a cheap and powerful technique for the identification of the silver tarnish layer constituents. J. Solid State Electrochem. 17, 223–234 (2013).Doménech-Carbó, A. et al. Detection of archaeological forgeries of Iberian lead plates using nanoelectrochemical techniques. The lot of fake plates from Bugarra (Spain). Forensic Sci. Int. 247, 79–88 (2015).Doménech-Carbó, A., Doménech-Carbó, M. T. & Peiró-Ronda, M. A. ‘One-Touch’ Voltammetry of Microparticles for the Identification of Corrosion Products in Archaeological Lead. Electroanalysis 23, 1391–1400 (2011).Doménech-Carbó, A., Doménech-Carbó, M. T., Montagna, E., Álvarez-Romero, C. & Lee, Y. Electrochemical discrimination of mints: The last Chinese emperors Kuang Hsü and Hsüan T’ung monetary unification. Talanta1 69, 50–56 (2017).Ager, F. J. et al. Combining XRF and GRT for the analysis of ancient silver coins. Microchem. J. 126, 149–154 (2016).Fawcett, T., Blanton, J., Blanton, T., Arias, L. & Suscavage, T. Non-destructive evaluation of Roman coin patinas from the 3rd and 4th century. Powder Diffraction, 1–10.Salvemini, F. et al. Neutron tomographic analysis: Material characterization of silver and electrum coins from the 6th and 5th centuries B.C. Mater. Charact. 118, 175–185 (2016).Ashkenazi, D., Gitler, H., Stern, A. & Tal, O. Metallurgical investigation on fourth century BCE silver jewellery of two hoards from Samaria. Sci. Rep. 7, 40659 (2017).Romano, F. P., Garraffo, S., Pappalardo, L. & Rizzo, F. In situ investigation of the surface silvering of late Roman coins by combined use of high energy broad-beam and low energy micro-beam X-ray fluorescence techniques. Spectrochim. Acta - Part B At. Spectrosc. 73, 13–19 (2012).Ingo, G. M. et al. Ancient Mercury-Based Plating Methods: Combined Use of Surface Analytical Techniques for the Study of Manufacturing Process and Degradation Phenomena. Accounts of Chemical Research 46(11), 2365–2375.Pouchou, J. L. & Pichoir, F.¨PAP¨ (ϕ–ρ–Z) procedure for improved quantitative microanalysis, in: Armstrong, J. T. (Ed.), Microbeam Analysis, San Francisco Press, San Francisco, pp. 104–106 (1985)
Spectrally-resolved UV photodesorption of CH4 in pure and layered ices
Context. Methane is among the main components of the ice mantles of
insterstellar dust grains, where it is at the start of a rich solid-phase
chemical network. Quantification of the photon-induced desorption yield of
these frozen molecules and understanding of the underlying processes is
necessary to accurately model the observations and the chemical evolution of
various regions of the interstellar medium. Aims. This study aims at
experimentally determining absolute photodesorption yields for the CH4 molecule
as a function of photon energy. The influence of the ice composition is also
investigated. By studying the methane desorption from layered CH4:CO ice,
indirect desorption processes triggered by the excitation of the CO molecules
is monitored and quantified. Methods. Tunable monochromatic VUV light from the
DESIRS beamline of the SOLEIL synchrotron is used in the 7 - 13.6 eV (177 - 91
nm) range to irradiate pure CH4 or layers of CH4 deposited on top of CO ice
samples. The release of species in the gas phase is monitored by quadrupole
mass spectrometry and absolute photodesorption yields of intact CH4 are
deduced. Results. CH4 photodesorbs for photon energies higher than ~9.1 eV
(~136 nm). The photodesorption spectrum follows the absorption spectrum of CH4,
which confirms a desorption mechanism mediated by electronic transitions in the
ice. When it is deposited on top of CO, CH4 desorbs between 8 and 9 eV with a
pattern characteristic of CO absorption, indicating desorption induced by
energy transfer from CO molecules. Conclusions. The photodesorption of CH4 from
the pure ice in various interstellar environments is around 2.0 x 10^-3
molecules per incident photon. Results on CO-induced indirect desorption of CH4
provide useful insights for the generalization of this process to other
molecules co-existing with CO in ice mantles
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