Abstract
Designing museum exhibitions is a hot topic for architects, designers, museologists, and scholars since museography represents a powerful tool for valorizing collections, promoting education, communicating cultural values, and ensuring suitable conservation conditions for the exhibited specimens. This is especially true for museums displaying authentic objects which are conveyors of scientific, cultural, social, and ethical values. In particular, natural history and science museums often compete with the leisure industry, and thus their museographic solutions have to meet more and more demanding requirements to increase visitor engagement. This paper describes the museographic concepts beneath the Italian Museum of Planetary Sciences in Prato (Italy, hereinafter MISP). MISP is the only museum in Italy entirely devoted to illustrating planetary sciences and displays important collections of extraterrestrial materials (meteorites, tektites, and impactites). The exhibition layout, characterized by a continuous wall belt design, recalls the outer space while providing non-invasive visual means to improve visitors’ emotional engagement with the displayed specimens. MISP museographic strategies also outline the importance of spatial designs and transpositions focusing on the illustration of the exhibited collections, thus going against some current museographic practices emphasizing, for example, the use of augmented reality and digital stimuli.
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1 Introduction
In their handbook on the critical concepts in museology edited for the International Council of Museums (ICOM) Committee for Museology (ICOFOM), Desvallées and Mairesse (2010) defined the term «museography» as the practical aspects of museology, i.e., all the practical activities regarding the planning and fitting out of the museum premises, conservation, restoration, security, and exhibition. As recalled by Almeida (2022), the term was first used in Museographia, a treatise edited by Kaspar Friedrich Jencquel (better known as Caspar Friedrich Nickel) in 1727 (Jencquel 1727). In this regard, Giovannini (2007) pointed out that Neickel’s work represented a guide to organizing museums, collections, and libraries on aesthetic and educational criteria. Even if a comprehensive reconstruction of the history of museography is out of scope here, it is interesting to note, quoting Jamin (2017), that the modern use of the term was introduced during the meeting of the Office International des Musées (OIM) held in Madrid in 1934 and in 1977 was inserted into ICOM and ICOFOM (Soares 2021). However, Desvallés and Mairesse (2010) noted that the term museography covers diverse meanings in today's museum studies. For instance, it is seldom used in the English-speaking world since the expression «museum practices» is usually preferred to indicate all the practical activities commonly carried out in museums. «Applied museology» is utilized in Central and Eastern Europe to describe the practical applications resulting from procedures developed in museological studies. Finally, «museography» is regularly employed in French-speaking countries to define the techniques of exhibitions. Therefore, the term refers to not only the contents of an exhibition and the links between the exhibit areas and the rest of the museum spaces but also to the management of the collections, i.e., the preservation and valorization of the displayed objects through the creation of a scenario, and the usage of visualization methods and communication strategies to deliver various messages to visitors in the most effective way.
Contemporary museographical discourse highlights diverse trends, such as the rising of a social museography concerning, as pointed out by Sospedra-Roca et al. (2022), the use of tangible and intangible resources for sustainable development and the valorization of historical heritage (e.g., archeological heritage) through the participation of social agents, lay public and scholarly communities. In this framework, it is interesting to note the interdisciplinary and didactic approaches that link natural sciences and historical disciplines, even in non-scientific museum environments (e.g., Georgopoulou et al. 2021, 2022).
Regarding natural history museums, it is noteworthy that dioramas are utilized as tridimensional museographic transpositions. Based on the seminal work of Clement (2000), Moormann and Bélanger (2019) considered dioramas as model-based learning tools useful to illustrate animal behaviors (e.g., the animal adaptation to darkness, Mortensen 2012), ecosystems, biodiversity, and the relationships between the human being and the natural world (e.g., Reiss 2015; Marandino et al. 2015, 2019; Colombo et al. 2023). On this subject, Montanari (2022) argued that dioramas, together with other twentieth-century display systems still visible in natural history museums such as evolutionary trees (e.g., Torrens and Barahona 2012), should be considered a museographic heritage representing the development of the modern exhibition design culture. According to Montanari (2022), these transpositions are worth preserving and valorizing in contemporary museum settings as educational tools.
Van Geert (2019) pointed out that the museographic approaches used to display natural history collections over the centuries can be regarded as tools to display the meanings they covered. For instance, transpositions underlining the role of local history and culture can justify the financial efforts made by the residents for the conservation and valorization of the displayed specimens. In this case, the museographic solutions convey the meaning of natural objects as links with the territory and its population, emphasizing, for example, the figure of local scholars and amateurs who collected, preserved, and bequeathed them to the community. Therefore, museography is pivotal in improving public engagement in natural history museums, especially for those institutions preserving geo-mineralogical collections. In this regard, in their literature review on geoscience communication, Rodrigues et al. (2023) argued that the establishment of an informed commitment between science and society is mandatory to promote geoheritage and geodiversity awareness.
As suggested by Bueno and Marandino (2017), museographic solutions represent effective scientific and educational tools to outline the theoretical and practical implications of the exhibited objects from a praxeological perspective. Bruno and Marandino’s study (2017) supported the hypothesis that museography plays a pivotal role in displaying geo-mineralogical specimens, since museographic transpositions help in illustrating to the general public the purposes of their collecting (e.g., scientific value, aesthetic relevance) and usage (e.g., symbols of social status, scholarly tools, and educational instruments) (De Wever and Guiraud 2018; Hearth and Robbins 2022). Therefore, as pointed out by Macdonald (1998), museography is more than just putting science on display because it produces formal and informal knowledge through traditional transpositions (e.g., display cases, educational panels, graphic design, placement and ordering of the exhibited specimens) and the use of digital technologies as virtual reality and immersive experiences (e.g., Sinitò et al. 2020; Hincapie et al. 2023) to develop an experimental approach design that, as outlined by Parades (2021), uses both forms of art and science (i.e., experimental and object data) to improve museum exhibitions and communicative outreach.
Considering all this evidence, it seems that museographic practices are crucial when exhibiting meteorite collections. In this regard, Golia (2015) rightly remarked that people usually see meteorites for the first time in museums, typically displayed as an extension of mineralogical exhibitions. The author (Golia 2015) recalled her first encounter with meteorites at the National Museum of Prague, where iron meteorite specimens, shining like mirrors and mounted on red velvet, were hanging from the walls. Golia (2015) underlined the strange excitement she felt was induced by the museographic strategies chosen to exhibit each specimen. Golia’s study (2015) thus showed the importance of museography in improving visitors’ engagement with the meteorite specimens on display.
Meteorites, i.e., fragments of asteroids and planetary bodies originating in outer space and falling to Earth (e.g., Grady et al. 2014), have always captivated human imagination and have been investigated and collected since ancient times (e.g., Burke 1991; Marvin 2006; Gounelle 2006; Trevisani 2011; Gounelle and Zolensky 2014; Franza and Pratesi 2020; Franza et al. 2021a). Most of the natural history museums worldwide have a section dedicated to displaying meteorite collections (e.g., Folco and Rastelli 2002; Folco et al. 2002; Herd 2002; Muñoz-Espadas et al. 2002; Perchiazzi et al. 2004; Bevan 2006; Caillet Komorowski 2006; Clarke et al. 2006; Ebel 2006; Greshake 2006; Ivanova and Nazarov 2006; Russell and Grady 2006; Pratesi 2012, Koeberl et al. 2018) since meteorites represent a unique scientific heritage (Franza and Pratesi 2021) needed to be correctly preserved and valorized (McCubbin et al. 2019). Furthermore, as suggested by Dorfman (2015), meteorite collections are tangible heritage conveying intangible meanings. In this regard, Wilson (2018) pointed out that the transposition of planetary sciences in museum exhibits shows natural heritage as a means of moral and social witnessing. As an illustration of this, Wilson (2018) focused on temporary and permanent exhibitions displaying meteorites (e.g., ‘The Evolving Universe’ in The Arthur Ross Hall of Meteorites at the American Natural History Museum in New York and ‘Kosmos & Sonnensystem’ in the Museum für Naturkunde in Berlin), which helped visitors to understand not only the processes forming the Solar System but also how the human being has interacted with it through the recovery, study, and interpretation of extraterrestrial materials. The museographic strategies employed in these exhibitions –including the virtual ones, as recalled by Madiedo (2012, 2013), play a pivotal role in illustrating the historical, scientific, and social meanings carried by meteorites to a wide range of age groups through the designs of both the display areas and the educational panels (Hutson et al. 2006; Carpino 2015; Corrigan et al. 2018). On this subject, Cerceau and Michard (2006) outlined that investigating the museographic approaches used in meteorite exhibitions highlights both the advances in meteorite knowledge and the communication strategies adopted by scientists and museologists to foster public education in meteoritics.
While diverse studies (as detailed above) have been published on meteorite museum collections, there is little available literature (e.g., Pinto et al. 2020) on the role of museography in museums entirely devoted to the illustration of planetary sciences and the exhibition of meteorites. The purpose of this work is, therefore, to explore the relationships between museography and museums exhibiting mainly meteorites by discussing the design of the Museo Italiano di Scienze Planetarie (hereinafter, MISP) in Prato, which represents the only Italian museum institution entirely devoted to the exhibition of meteorites. In this regard, it is important to note that the rest of the meteorite collections in Italy are preserved in natural history museums (e.g., Folco and Rastelli 2000; Folco et al. 2002; Perchiazzi et al. 2004; Pratesi 2012) and therefore are parts of more complex collection systems. In these contexts, museography is generally used to illustrate the various aspects of natural sciences and their history. The museographic strategies and transpositions employed at MISP are specially designed to make planetary sciences and the exhibited meteorite collection intelligible to diverse audiences. In the following pages, the history of MISP is reviewed, and its museographic setting is presented to the scholarly community for the first time.
2 Case study
The MISP project started in the 2000s when the Province of Prato and the Pro Verbo Foundation committed to increasing citizens' scientific literacy and culture. The first goal achieved was the establishment of the Prato Ricerche Foundation—Institute for Environmental Research and Hazard Mitigation- to promote and coordinate scientific activities in the province. Later, the Prato Ricerche Foundation and the Province of Prato entered a contract to found and manage a museum devoted to illustrating planetary sciences and exhibiting meteorite collections. MISP was opened to the public on 19 March 2005.
MISP is situated on the ground floor of the former firehouse in Prato, which was established at the end of the 1950s and located on Galcianese Street, within the parking zone of the fire trucks. The area covered ca. 440 sqm and was originally divided into six garages by walls and pillars made of reinforced concrete (Fig. 1).
The MISP museographic project was realized by the architect Piero Roberto Papi between 2001 and 2002. From an architectural perspective, the project highlighted two contingency factors: (i) the physical constraints given by the load-bearing structure consisting of very rigid structural elements, regularly spaced to form the six garages for the fire department vehicles; (ii) the need for the architectural design to reproduce the curved perception of space. To resolve these challenges, MISP was designed as a belt characterized by convex and concave geometries defining a curved and ergonomic exhibition path (Fig. 2). In this regard, it is worth mentioning that the path shape is wholly curvilinear, including the display cases. The only exception is a corner space bordering the museum entrance, where the ticket office and bookshop are located.
The display cases run along the whole belt perimeter. The walls are made with ALUCOBOND® cladding sheets, which is a composite panel consisting of two aluminum sheets, one of which is finished and pre-painted by heat, with interposed high-density thermoplastic material bonded by a continuous manufacturing process that allows the sheets to be cut and bent while maintaining flatness. All the cladding is connected to the primary(vertical) and secondary (horizontal) structures without any rivets or nuts being visible from the visitor’s side. On the top of the primary vertical structure are fireproof wooden slats, calendered according to the curvature of the display walls to avoid differences in flatness (Fig. 3). All the wooden processing is realized in medium-density fiberboard.
The flooring is realized using first-rate absolute black stoneware floor tiles (60 × 60 cm), which is a hard, compact, and polishable material that simulates decorative rocks with a phanerocrystalline texture. Showcases are plugged with curved laminated extra-clear glass sheets (thickness 16 mm), mounted flush polished, without structural posts, and with transparent silicone sealing (Fig. 4). Five different dimmable systems consisting of luminaires connected in series to terminal controllers are placed within the display cases.
All the didactic panels in the display cases are realized with FOREX® to adapt their designs to curvilinear structures. In all panels, a fictional character, designed by Cristina Andreani, illustrates the key concepts of meteoritics and planetary sciences to children.
Along the exhibition path are present 17 touchscreens with short footage (150 videos), images (more than 250), informative text (ca. 190 pages in total), and interviews with planetary scientists (ca. 70 videos) about the Universe, the Solar System (i.e., the Sun, planets and their satellites, asteroids, comets), meteorites (i.e., chondrite and differentiated meteorites, history of Italian meteorites for a total of more than 240 text pages, 70 interviews, and 60 videos) impacts and impactites, impact craters found on Earth (ca. 200 text pages, 200 images, 100 short videos for both the topics), and minerals (ca. 40 text pages, eight interviews, and 18 videos). The multimedia stations are placed in different areas of the exhibition path. For instance, ten workstations are located at the beginning of the exhibition rooms and are entirely devoted to the illustration of the Universe and the Solar System (Fig. 5), while those relative to meteoritics in general and the history of Italian meteorites, in particular, are placed in the main hall, where the meteorite collection is on display, next to the exhibited specimens (e.g., chondrite meteorites on the right, differentiated meteorites on the left, and impactites at the end of the main hall on the left side) (Fig. 6). The contents of the short videos about the Universe, the Solar System, and meteoritics have been requested from NASA, ESA, and STSCI (Space Telescope Science Institute, Baltimore), which authorized their unrestricted use. The multimedia station about terrestrial minerals and mineralogy is in the last exhibition room (Fig. 7).
Besides the multimedia stations described above, interactive museographic devices create immersive experiences. At the entrance of the museum halls on the right side, there is the Quadrisphere room, a multimedia installation (ca. 6 × 2.50 × 2.50 m). Here, visitors can watch a short video (lasting ca. 4 min) on a compelling play of mirrors that tells the origin of a meteorite, its impact on the Earth, and the birth of life on our planet.
The MISP exhibition path is divided into five thematic areas, illustrated on a panel at the museum entrance. The panel also shows the curvilinear architectural design characterizing the entire exhibition (Fig. 8).
The first thematic area concerns the Universe and the Solar System. It is located at the entrance of the museum halls and consists of the ten multimedia stations described above. Subsequently, there is the main hall, where meteorite specimens are displayed to illustrate chondrite meteorites, differentiated meteorites, and impact processes. The last oval-shaped room displays terrestrial minerals, including samples from Tuscany.
The exhibition path is circular since its perimeter forms a continuous wall (the belt mentioned above) running from one side of the entrance and returning to it from the other after crossing the entire exhibition area. It is about 316 cm high with 140 cm high glass openings, representing the showcase's frontal side. The meteorites are displayed in interior containers ranging from 30 to 85 cm. The specimens can be viewed through curved glass panels (up to 6 m long) laid in place without structural mullions. This design emphasizes the shape of the exhibition path while ensuring that the display cases cannot be opened from the visitor's side. The tabletop is about 66 cm from the ground, thus providing a view of the displayed samples even by children and people with disabilities. The removal and maintenance of the meteorite specimens is allowed only from the back of the display cases. This design results in a “service belt" that runs parallel to the display area and is reserved for MISP staff.
Six circular showcases are placed along the exhibition path. The so-called “islands” are individually illuminated and include one pedestal without a glass cover. All of them display particularly relevant samples from a scientific and aesthetic perspective.
Concerning the museum lighting, the MISP entrance is partially illuminated with natural light from the glass front door. The remaining areas are fully illuminated with artificial light placed within the false ceiling and the showcases. Spotlights next to the display cases draw the visitors’ attention to specific meteorite specimens. A brighter light source is then present in the showcases to avoid reflections on the curved glass. The latter is placed backward from the showcase ceiling to cast as little light as possible on the visitors and thus eliminate possible mirroring effects.
3 Discussion
As mentioned in the literature review, museography is pivotal in conveying tangible and intangible meanings relative to the objects displayed in science and natural history museums, especially when geo-mineralogical specimens are exhibited. Regarding meteorite collections, Dorfman (2015) and Wilson (2018) highlighted how museographic transpositions and strategies are fundamental in conveying the diverse scientific, historical, cultural, and social meanings of these museum collections to scholars and the general public.
Even if meteorite collections can be found in several Italian natural history museums, MISP is the only scientific institution in Italy founded to illustrate planetary sciences and display extraterrestrial materials; therefore, its museography and design were studied to communicate concepts relative to meteoritics while promoting citizen science ideas (e.g., national meteorite recovery campaigns) and scientific literacy. On this subject, following Önal and Önal (2021), it is worth mentioning that astronomy and sciences related to this field of knowledge, such as planetary sciences and meteoritics, create a positive attitude toward learning science and promote its learning by gathering students’ attention.
MISP museographic project thus represents a design strategy that, starting from the illustration of the Universe, comes to the display of meteorites whose recovery and study made possible the knowledge of the Solar System (Grady et al. 2014) and via impact rocks and tektites leads the visitors back to the Earth in the last exhibition room where minerals, representing the extraordinary geodiversity of our planet, are on display. The elements that are on the MISP exhibition path (the so-called “islands”) thus present the specimens on display as linking elements (Morrissey 2002) to attract visitors’ attention for effective communication. For instance, in the main hall, on a pedestal without barriers, there is a specimen of the Nantan meteorite (Figs. 9 and 10).
According to the chronicles, the fall might have been observed in China in 1516, but the fragments were recovered only in 1958. Nantan has been classified as an iron meteorite belonging to the main group (MG) of the IAB complex (Caporali et al. 2018). The Nantan meteorite specimen kept at MISP represents the largest meteorite preserved in Italy and can be touched freely by visitors. In this regard, MacDonald (2007) highlighted how museums (except for science centers and children’s museums) commonly represent “no touch” environments since the opportunity for the visitor to touch the exhibited objects is very restricted and usually limited to interactive spaces. This object-based interaction has an essential role in enriching the learning experience for both disabled and non-disabled visitors while simultaneously opening imaginative, speculative, and emotional ways of knowing meteorites (e.g., Classen 2008; Chatterjee 2008; Candlin 2008; Pye 2016; Nicolaisen and Achiam 2020). In this regard, Carpino and Morelli (2024) highlighted, quoting Tokar (2004) and Ciaccheri (2022), how the possibility of touching meteorites was conceived following the Universal Design Learning (UDL) model, i.e., a transitional framework between learning sciences and education design to create exhibit spaces and museum programs usable by and effective for as many learners as possible (Rappolt‐Schlichtmann and Daley 2013).
As shown in Figs. 9 and 11, the MISP exhibit areas are designed as a continuous curvilinear path, recalling the perception the human being has of outer space. On this subject, Vartanian et al. (2019) stated that curvilinear contours in interior architectural spaces are usually preferred since visitors are more likely to enter curvilinear than rectilinear spaces. This assumption is supported by the last research in cognitive neurosciences and neuro-architecture, where curvilinear spaces, as pointed out by Wang et al. (2022) in their literature review, are perceived to be more aesthetically beautiful than rectilinear ones since the vision of curvilinear contours activates the lingual and the calcarine gyrus in the visual cortex more than images of rectilinear interiors. Based on the above, all the perimeter walls and showcases (including the so-called “islands”) are curvilinear, a design choice that helps to induce positive emotional states in visitors, as shown by Bower et al. (2019) in their systematic review.
The materials used in the exhibition path reflect the purpose for which MISP was established: to illustrate planetary sciences and meteoritics. The light gray-green ALUCOBOND® horizontal bands traversing the entire perimeter walls recall the sidereal space and the interior of a spaceship, while the floor and the ceiling remind us of the absolute black of the outer space and the petrographic texture of the chondrite meteorites. The wooden slats on the top of the vertical elements represent the organic matter on the Earth, and their combination with the ALUCOBOND® bands resemble the alberese and green serpentinite (Verde di Prato) rock cladding employed in alternative rows in Prato’s medieval architecture (e.g., Fratini et al. 2022; Carmignano and Brandao 2023).
The connections between the materials used in the museographic design, the Earth planet, and the local territory continue in the last museum room, where the mineralogical collection is displayed (Fig. 12).
Here, outstanding worldwide specimens (Fig. 13) are exhibited together with samples from Tuscany mineralogical outcrops or closed mines (Fig. 14). The latter represents evidence of the local mining sites and their history (e.g., Tanelli et al. 2001).
Furthermore, the MISP mineralogical collection comprises a fluorescent mineral display (Fig. 12, top right). The fluorescence phenomenon is observable thanks to the specimens’ exposure to ultraviolet (UV) lamps set in the display case that can be turned on and off by a push button. As underlined by Lustrino (2021), displaying fluorescent minerals is an effective educational tool to increase learning engagement in diverse audiences (e.g., curiosity-driven visitors, Rounds 2004) about complex science topics such as electromagnetic radiation, radioactivity and the origin of colors.
Museographic solutions, such as explanatory panels and multimedia installations, are integrated along the museum path to provide a logical reading guide for visitors to assimilate meteoritics and planetary sciences knowledge (Pasquaré Mariotto and Venturini 2017). The touchscreens and the digital installations –e.g., the devices at the beginning of the exhibition illustrating the Solar System (Fig. 15) and the quadrisphere (Fig. 16) – thus encourage free-choice environmental learning, foster curiosity, and improve self-education while enhancing STEM learning (e.g., Falk 2005; Russo and Sisto 2023).
It is then interesting to note the presence of satellite museographic solutions, i.e., tools that can project information in different communication spaces such as audiovisual, smartphones, and apps (Sospedra-Roca et al. 2022), such as QR codes (e.g., Pérez-Sanagustín et al. 2016) to distinguish meteorites from terrestrial rocks. In this case, diverse specimens are placed on pedestals at the same levels so as not to influence the visitor’s decision-making ability. After commenting on the nature of a specific specimen, visitors can check their responses by scanning the QR codes placed on each pedestal using their phone’s built-in cameras. QR code contents deal with the specimens' origin and main features. These tools improve interactive edutainment (e.g., Komarac et al. 2020) while enabling rapid user information processes and decision outcomes without diverting the visitors’ attention from the displayed specimens [Fig. 17].
However, interactive museography is mixed with traditional transpositions along the MISP exhibition path. In the main hall and the room devoted to the illustration of impact rocks, dioramas display cold and hot deserts where meteorites can be found, as well as the Martian and lunar environments (e.g., Pratesi et al. 2005; Aboulahris et al. 2019; Fan et al. 2022) [Fig. 18].
The academic literature on lighting design in museum contexts, as Balocco and Volante (2018) outlined, showed that the identification of the best lighting solutions was strictly linked to the improvement of visitors’ understanding, perception, vision, and emotions concerning the displayed objects, also based on cognitive mechanisms. The MISP lighting design, whether natural or artificial, thus represents a spatial variable for conveying messages and stimulating visitors’ emotional responses along the exhibition path (e.g., Jeong and Lee 2006; Zhisheng and Nagai 2020; Gharib and Shohdy 2023; Graser 2023). Besides the MISP entrance, illuminated by the daylight filtering through the front door windows, artificial light is set up within the continuous wall and the false ceiling. The overall effect is a restful, diffused light throughout the rooms inducing an emotional experience of calm in visitors (Duan 2022). The use of artificial light sources as lightning solutions is motivated as follows: (i) the simulation of a "non-light" typical of sidereal space; (ii) the possibility to focus on specimens exhibited both in the display cases and on the pedestals (e.g., the Nantan meteorite); (iii) the creation of an immersive atmosphere that, as Forrest (2013) pointed out in his literature review, acts a route to an affective, cognitive, and behavioral response in visitors.
The results of the present study suggest how museography plays a crucial role in natural history museum exhibitions. The case study presented here shows that the materials, techniques, and museographic solutions adopted at MISP are specifically designed to valorize the displayed collections within a narrative environment where spaces and specimens are part of a storytelling process, whose experience continues after the museum visit ends (Hanks Hourston et al. 2012, Dal Falco and Vassos 2017). The information learned about meteoritics and the history of the meteorites found in Italy over the centuries motivates visitors to be active in their recovery, joining citizen science projects in which they can participate in field campaigns and report the findings of potential meteorite specimens (e.g., Blake et al. 2018, Zanda et al. 2023). In this regard, MISP is actively involved in the PRISMA (Prima Rete Italiana per la Sorveglianza sistematica di Meteore e Atmosfera) all-sky camera network (Gardiol et al. 2016, 2019), a project managed by the Italian Institute of Astrophysics (INAF) in collaboration with the FRIPON project (Fireball Recovery and InterPlanetary Observation Network) (Colas et al. 2020). As Gardiol et al. (2021a) outlined, since the start of the project, PRISMA has experienced increasing participation of amateur astronomers and non-expert citizens reporting visual fireball observations and possible meteorite finds. The latter led to the recovery of the Cavezzo meteorite (Gardiol et al. 2021b; Pratesi et al. 2021), which is now kept at MISP. In collaboration with MISP, PRISMA organizes meteorite search campaigns and free training courses to teach citizens about meteorite identification. Furthermore, MISP is open to receiving samples of possible meteorites and performing scientific analyses, in collaboration with the Earth Sciences Department of the University of Firenze, to investigate their potential extraterrestrial origin (Franza et al. 2021b).
Finally, the findings of the present study highlighted how museographic solutions designed to valorize the specimens also play a crucial role in correctly preserving them. At MISP, the conservation practices of the displayed and stored meteorites comply with the Advanced Curation policies for extraterrestrial materials illustrated in McCubbin et al. (2019). Furthermore, most of the MISP meteorite collection has been cataloged using the national standard BNPL (Casto et al. 2007; Franza et al. 2022), issued by the Central Institute for Catalog and Documentation (ICCD), part of the Italian Ministry of Culture (MiC). The catalog records are accessible in open access on the Catalogo Generale dei Beni Culturali database (https://catalogo.beniculturali.it), managed by MiC, which represents the official repository for cataloging the entire Italian cultural heritage (Veninata 2020). To date, 66,398 samples relative to the natural heritage have been cataloged (data accessed on 28 April 2024). Among them, 43,646 are geo-mineralogical specimens (i.e., 41,932 minerals, 621 rocks, 1093 meteorites). The meteorite specimens preserved at MISP and present in the database are 376. Since 2002, the entire MISP meteorite collection has been accessible online on the museum’s official website. The inventory shows data regarding the weight and typology of the collected specimens (i.e., sample, complete individual, part slice, polished slice, sawn fragment, partially sawn fragment, thin or thick section), together with information about the meteorite classification, type, year, and place of recovery (Morelli et al. 2023).
4 Conclusions
This work has discussed the museographic solutions adopted at MISP, the only museum in Italy established to exhibit extraterrestrial materials and illustrate planetary sciences. The investigation outlined the following significant results: the design of the exhibition path, the use of the space, the presence of distinctive museographic transpositions, the materials, and the lighting design. Together, these findings highlight the central role of museography in valorizing the displayed specimens. Museographic strategies and transpositions should be representative of object-oriented analysis and design to enhance naturalistic museum collections properly. The findings of this research suggest how MISP museographic solutions contribute to sharing valuable information about the exhibited meteorites, which represent a unique scientific and cultural heritage in the Italian scenario.
Data availability
We do not analyse or generate any datasets, because our work proceeds within a theoretical approach.
References
Aboulahris M, Chennaoui Aoudjehane H, Rochette P, Gattacceca J, Jull AT, Laridhi Ouazaa N, Folco L, Buhl S (2019) Characteristics of the Sahara as a meteorite recovery surface. Meteorit Planet 54:2908–2928
Almeida MM (2022) Museography. In: Quinteiro S, Marques MJ (eds) Working definitions in literature and tourism. A research guide. CIAC, Faro, pp 103–104
Balocco C, Volante G (2018) Lighting design for energy sustainability, information, and perception. A museum environment as a case study. Sustainability 10:1671
Bevan AWR (2006) The Western Australian Museum meteorite collection. In: McCall GJH, Bowden AJ, Howart RJ (eds) The history of meteoritics and key meteorite collections: fireballs, falls and finds, vol 256. Geological Society, Special Publications, London, pp 305–323
Blake M, McKee J, Statom R, Qiu C, Menapace F (2018) Evaluating strategies to collect micrometeorites from rainwater for citizen scientists. J Astron Earth Sci E 5:151–160
Bower I, Tucker R, Enticott PG (2019) Impact of built environment design on emotion measured via neurophysiological correlates and subjective indicators: a systematic review. J Environ Psychol 66:101344
Bueno J, Marandino M (2017) The notion of praxeology as a tool to analyze educational process in science museums. In: Hahl K, Juuti K, Lampiselkä J, Uitto A, Lavonen J (eds) Cognitive and affective aspects in science education research. Springer, Cham, pp 339–355
Burke JG (1991) Cosmic debris: meteorites in history. University of California Press, Berkeley
Caillet Komorowski CL (2006) The meteorite collection of the National Museum of Natural History in Paris, France. In: McCall GJH, Bowden AJ, Howart RJ (eds) The history of meteoritics and key meteorite collections: fireballs, falls and finds, vol 256. Geological Society, Special Publications, London, pp 163–204
Candlin F (2008) Touch, and the limits of the rational museum or can matter think? Senses Soc 3:277–292
Caporali S, Pratesi G, Kabra S, Grazzi F (2018) Type I and type II residual stress in iron meteorites determined by neutron diffraction measurements. Planet Space Sci 153:72–78
Carmignano ORDR, Brandao PRG (2023) Employment of serpentinite rock in architecture. Mater Sci Eng 7:79–81
Carpino S (2015) Meteoritica: una sperimentazione integrata per una diversa modalità di promozione e diffusione della cultura scientifica. Museologia Scientifica 9:111–112
Carpino S, Morelli M (2024) La particolarità come estensione. Il museo per te, per me, per tutti. Museologia Scientifica Memorie 23:237–239
Casto L, Celi M, Ferrante F, Francescangeli R, Pesce GB, Pezzotta F, Pizzo M, Pratesi G, Scandurra P, Zorzin R (2007) Scheda BNPL. Beni Naturalistici – Planetologia. Istituto Centrale per il Catalogo e la Documentazione, Roma.
Cerceau FR, Michard JG (2006) A way to stress developments in astronomy: displaying a collection of meteorites. Adv Space Res 38(10):2247–2252
Chatterjee F (2008) Touch in museums. Policy and practice in object handling. Routledge, London
Ciaccheri MC (2022) Moltiplicare le opportunità. In: Ciaccheri MC, Fornasari F, Il museo per tutti. Buone pratiche di accessibilità, Edizioni La Meridiana, Molfetta, pp. 99–102.
Clarke RS Jr, Plotkin H, McCoy TJ (2006) Meteorites and the Smithsonian Institution Geological Society. In: McCall GJH, Bowden AJ, Howart RJ (eds) The History of meteoritics and key meteorite collections: fireballs, falls and finds, vol 256. Geological Society, Special Publications, London, pp 237–265
Classen C (2008) The book of touch. Routledge, London
Clement J (2000) Model based learning as a key research area for science education. Int J Sci Educ 22(9):1041–1053
Colas F, Zanda B, Bouley S, Jeanne S, Malgoyre A, Birlan M, Dardon A (2020) FRIPON: a worldwide network to track incoming meteoroids. Astron Astrophys 644:A53
Colombo PD Jr, Marandino M, Scalfi G (2023) Biodiversity and Science, Technology, Society and Environment (STSE): visitor perceptions at a Science and Natural History Museum. Int J Res Educ Sci 9:753–773
Corrigan CM, McCoy T, Hoskin CJ, Lunning N (2018) The U.S. National Meteorite Collection: bringing the Solar System to the Nation. In: Proceedings of AGU Fall Meeting, Washington D.C., USA, 10–14 December 2018, abstract #ED23E-0950.
Dal Falco F, Vassos S (2017) Museum experience design: a modern storytelling methodology. Des J 20(sup1):S3975–S3983
De Wever P, Guirard M (2018) Geoheritage and museums. In: Reynard E, Brilha J (eds) Geoheritage. Elsevier, Amsterdam, pp 129–145
Desvallées A, Mairesse F (2010) Key concepts of museology. Armand Colin/ICOM, Paris
Dorfman E (2015) Intangible natural heritage new perspectives on natural objects. Routledge, New York
Duan H (2022) Application and expression of artificial light source design in exhibition space. Highlights Art Des 1:48–51
Ebel DS (2006) History of the American Museum of Natural History meteorite collection. In: McCall GJH, Bowden AJ, Howart RJ (eds) The History of meteoritics and key meteorite collections: fireballs, falls and finds, vol 256. Geological Society, Special Publications, London, pp 267–289
Falk J (2005) Free-choice environmental learning: framing the discussion. Environ Educ Res 11:265–280
Fan Y, Li S, Liu S, Peng H, Song G, Smith T (2022) The distribution of the desert meteorites in China and their classi-fication. Meteorit Planet Sci 57:683–701
Folco L, Rastelli N (2002) The meteorite collection of the Museo Nazionale dell’Antartide in Siena. Meteorit Planet Sci 35:A189–A198
Folco L, Peri F, Pezzotta F (2002) The meteorite collection of the Civico Planetario and the Museo Civico di Storia Naturale in Milan, Italy. Meteorit Planet Sci 37:B95–B103
Folco L, Rastelli N (2000) The meteorite collection of the Museo Nazionale dell'Antartide in Siena. Meteorit Planet Sci 35(S5):A189–A198
Forrest R (2013) Museum atmospherics: the role of the exhibition environment in the visitor experience. Visit Stud 16:201–216
Franza A, Pratesi G (2020) Julius Obsequens’s book, Liber Prodigiorum: a Roman era record of meteorite falls, fireballs, and other celestial phenomena. Meteorit Planet Sci 55:1697–1708
Franza A, Pratesi G (2021) Meteorites as a scientific heritage. Conserv Patrim 36:106–121
Franza A, Petti C, Pratesi G (2021a) More than just a rock collection. The meteorite collection of the Italian Geologist Teodoro Monticelli (1759–1845). Earth Sci Hist 40:39–67
Franza A, Faggi D, Morelli M, Pratesi G (2021b) Lodi (Italy) 1972: a cold meteorite case closed. Museologia Scientifica 15:96–106
Franza A, Faggi D, Morelli M, Pratesi G (2022) Cataloging Italian Meteorite Museum Collections Using the BN-PL National Standard: a case study. Catalog Classif Q 60:266–296
Fratini F, Rescic S, Pittaluga D (2022) Serpentinite and ophicalcite in the architecture of eastern Liguria and as decoration of Tuscan religious buildings. Resour Policy 75:102505
Gardiol D, PRISMA Team (2019) News from the Italian PRISMA fireball network. In: Proceedings of the International Meteor Conference, Pezinok-Modra, Slovakia, pp 81–86.
Gardiol D, Cellino A, Di Martino M (2016) PRISMA, Italian network for meteors and atmospheric studies. In: Proceedings of the 35th International Meteor Conference Egmond. International Meteor Organization, Hove, Belgium, p 76
Gardiol D, Cuppone T, Ascione G, Barghini D, Carbognani A, Di Martino M, Di Carlo M, Ianniello F, Pratesi G, Riva W, Rubino E, Russo P, Stirpe G, Valeri D, Volpicelli CA (2021a) A successful example of citizen science within the PRISMA network applied to the 15th March 2021 bolide over Italy. In: 15th Europlanet Science Congress 2021, held virtually, 13–24 September 2021, id. EPSC2021–208.
Gardiol D, Barghini D, Buzzoni A et al (2021b) Cavezzo, the first Italian meteorite recovered by the PRISMA fireball network. Orbit, trajectory, and strewn-field. Mon Not R Astron Soc 501:1215–1227
Georgopoulou P, Koliopoulos D, Meunier A (2021) The dissemination of elements of scientific knowledge in archaeological museums in greece: socio-cultural, epistemological and communicational/educational aspects. Sci Cult 7:31–44
Georgopoulou P, Meli K, Koliopoulos D (2022) An interpretive and pedagogical approach of archaeological collections in the light of natural sciences: the notion of Science Educative Islet. Rev Sci Math ICT Educ 16:49–75
Gharib I, Shohdy M (2023) Lighting and emotions: a brief review. J Des Sci Appl Arts 4:84–92
Giovannini E (2007) Musei, biblioteche e Wunderkammer. La «Museografia» di Caspar Friedrich Neickel e la sua prima traduzione dal Tedesco. Comunicare 7:153–168
Golia M (2015) Meteorite: nature and culture. Reaktion Books, London
Gounelle M (2006) The meteorite fall at L’Aigle and the Biot report: exploring the cradle of meteoritics. In: McCall GJH, Bowden AJ, Howart RJ (eds) The history of meteoritics and key meteorite collections: fireballs, falls and finds, vol 256. Geological Society, Special publications, London, pp 73–89
Gounelle M, Zolensky ME (2014) The Orgueil meteorite: 150 years of history. Meteorit Planet Sci 49:1769–1794
Grady M, Pratesi G, Moggi Cecchi V (2014) Atlas of meteorites. Cambridge University Press, Cambridge
Graser A (2023) Light up–the potential of light in museum architecture. Birkhäuser, Basel
Greshake A (2006) History of the meteorite collection at the Mseum für Naturkunde, Berlin. Geol Soc Spec Publ 256(1):135–151
Hanks Hourston L, Hale J, MacLead S (2012) Introduction: museum making: the place of narrative. In: McLead S, Hanks Hourston L, Hale J (eds) Museum making. Narratives, architectures, exhibitions. Routledge, Oxon, pp xix–xxiii
Hearth S, Robbins C (2022) Mineral display as embodiments of geological thought and colonial invisibility. J Nat Sci Collect 10:3–17
Herd RK (2002) The National Meteorite Collection of Canada. Meteorit Planet Sci 37:A62
Hincapie M, Cifuentes LM, Valencia-Arias A, Quiroz-Fabra J (2023) Geoheritage and immersive technologies: bibliometric analysis and literature review. Episodes 46:101–115
Hutson ML, Pugh RN, Ruzicka AM (2006) Public Outreach and education with meteorites involving a museum exhibit, website, and teacher workshops. In: Proceedings of 37th Annual Lunar and Planetary Science Conference, League City, Texas, 13–17 March 2006, abstract no. 1095.
Ivanova MA, Nazarov MA (2006) History of the meteorite collection of the Russian Academy of Sciences. Geol Soc Spec Publ 256(1):219–236
Jamin JB (2017) La Conférence de Madrid (1934). Histoire d’une manifestation internationale à l’origine de la muséographie moderne/ The Madrid conference (1934). History of an international event at the origin of modern museography. Il Capitale Culturale 15:73–101
Jencquel KF (1727) Museographia oder Anleitung zum rechten Begriff und nützlicher Anlegung der Museorum, oder Raritäten-Kammern. M. Hubert, Leipzig und Bresslan.
Jeong JH, Lee KH (2006) The physical environment in museums and its effects on visitors’ satisfaction. Build Environ 41:963–969
Koeberl C, Brandstätter F, Harzhauser M, Riedl-Dorn C (2018) History and importance of the geoscience collections at the Natural History Museum Vienna. In: Rosenberg, GD, Clary RM (eds) Museums at the Forefront of the History and Philosophy of Geology: History Made, History in the Making. Geological Society of America 2018, Boulder, Special Paper, vol 535, pp 131–161.
Komarac T, Ozretic-Dosen D, Skare V (2020) Managing edutainment and perceived authenticity of museum visitor experience: insights from qualitative study. Mus Manag Curatorship 35:160–181
Lustrino M (2021) Luminescence in the mineral realm to teach basic physics concepts. J Educ Learn 10:83–95
Macdonald S (1998) Exhibitions of power and powers of exhibition. An introduction to the politics of display. In: Macdonald S (ed) The politics of display. Museum, science, culture. Routledge, London, pp 1–21
MacDonald S (2007) Exploring the role of touch in connoisseurship and the identification of objects. In: Pye E (ed) The power of touch handling objects in museum and heritage context. Routledge, New York, pp 107–120
Madiedo JM (2012) The virtual Museum for Meteorites. In: Proceedings of European Planetary Science Congress 2012, Madrid, Spain, 23–28 September 2012, abstract no. EPSC2012–3.
Madiedo JM (2013) The Virtual Museum for Meteorites: an Online Tool for Researchers, Educators and Students. In: Proceedings of European Planetary Science Congress 2013, London, UK, 08–13 September 2013, abstract no. EPSC2013–5.
Marandino M, Achiam M, De Oliveira A (2015) The diorama as a means for biodiversity education. In: Tunnicliffe S, Scheersoi A (eds) Natural history dioramas. Springer, Dordrecht, pp 251–266
Marandino M, Bueno J, Achiam M, Laurini C (2019) Teaching and learning biodiversity with dioramas. In: Scheersoi A, Tunnicliffe S (eds) Natural history dioramas—traditional exhibits for current educational themes. Springer, Cham, pp 185–200
Marvin UB (2006) Meteorites in history: an overview from the Renaissance to the 20th century. In: McCall GJH, Bowden AJ, Howart RJ (eds) The history of meteoritics and key meteorite collections: fireballs, falls and finds, vol 256. Geological Society. Special Publications, London, pp 15–71
McCubbin FM, Herd CD, Yada T, Hutzler A, Calaway MJ, Allton JH, Corrigan CM, Fries MD, Harrington AD, McCoy TJ, Mitchell JL, Regberg AB, Righter K, Snead CJ, Tait KT, Zolenski ME, Zeigler RA (2019) Advanced curation of astromaterials for planetary science. Space Sci Rev 215:1–81
Moormann A, Bélanger C (2019) Dioramas as (Scientific) models in natural history museums. In: Scheersoi A, Tunnicliffe S (eds) Natural history dioramas–traditional exhibits for current educational themes. Springer, Cham, pp 101–112
Montanari E (2022) Museographic Heritage. Conserving and Enhancing the Exhibition Design Culture, Aracne
Morelli M, Franza A, Faggi D, Pratesi G (2023) The catalog of the meteorite collection of the Italian Museum of Planetary Sciences in Prato (Italy). Meteorit Planet Sci 58:945–954
Morrissey KA (2002) Pathways among objects and museum visitors. In: Paris SG (ed), Perspectives on object-centered learning in museums, Lawrence Erlbaum Associates Publishers, Mahwah, New Jersey, London, pp 258–272
Mortensen MF (2012) Museographic transposition: the development of a museum exhibit on animal adaptations to darkness. Éducation Et Didactique 4–1:115–138
Muñoz-Espadas MJ, Martínez‐Frías J, Lunar R, Sánchez B, Sánchez J (2002) The meteorite collection of the National Museum of Natural Sciences, Madrid, Spain: an updated catalog. Meteorit Planet Sci 37(S12):B89–B94
Nicolaisen LB, Achiam M (2020) The implied visitor in a planetarium exhibition. Mus Manag Curatorship 35:143–159
Parades RT (2021) Museography and performativity: performance design for impossible objects and immersive displays. In: Achiam M, Haldrup M, Drotner K (eds) Experimental museology. Institutions, representations, users. Routledge, Oxon, pp 35–49
Perchiazzi N, D’Orazio M, Folco L (2004) The meteorite collection at Museo di Storia Naturale, Pisa University, Italy. Meteorit Planet Sci 39:A171–A176
Pérez-Sanagustín M, Parra D, Verdugo R, García-Galleguillos G, Nussbaum M (2016) Using QR codes to increase user engagement in museum-like spaces. Comput Hum Behav 60:73–85
Pinto GÁ, Flores L, Martínez R (2020) Museos interactivos de ciencia y la alfabetización científica: Rol del Museo del Meteorito. Ápice Revista De Educación Científica 4:63–72
Pratesi G (2012) Per aspera ad astra. La collezione di meteoriti. In: Pratesi G (ed) Il Museo di Storia Naturale dell’Università degli Studi di Firenze. Firenze University Press, Firenze, pp 127–141
Pratesi G, Morelli M, Rossi AP, Ori GG (2005) Chemical compositions of impact melt breccias and target rocks from the Tenoumer impact crater, Mauritania. Meteorit Planet Sci 40:1653–1672
Pratesi G, Moggi Cecchi V, Greenwood RC, Franchi IA, Hammond SJ, Di Martino M, Barghini D, Taricco C, Carbognani A, Gardiol D (2021) Cavezzo—The double face of a meteorite: Mineralogy, petrography, and geochemistry of a very unusual chondrite. Meteorit Planet Sci 56:1125–1150
Pye E (2016) Handling objects in museum and heritage contexts. Routledge, New York
Rappolt-Schlichtmann G, Daley SG (2013) Providing access to engagement in learning: the potential of Universal Design for Learning in museum design. Curator 56:307–321
Reiss M (2015) The cultural history and learning affordances of natural history dioramas. In: Tunnicliffe S, Scheersoi A (eds) Natural history dioramas. Springer, Dordrecht, pp 279–289
Rodrigues J, Costa e Silva E, Pereira DI (2023) How can geoscience communication foster public engagement with geoconservation? Geoheritage 15:32
Rounds J (2004) Strategies for the curiosity‐driven museum visitor. Curator: The Museum J 47(4):389–412
Russell S, Grady MM (2006) A history of the meteorite collection at the Natural History Museum, London. Geol Soc Spec Publ 256(1):153–162
Russo F, Sisto M (2023) Career in geology: an educational project in geosciences for the enhancement of student learning in STEM disciplines. Geosciences 13:50
Sinitò D, Fugazzotto M, Stroscio A, Coccato A, Allegra D, Barone G, Mazzoleni P, Stanco F (2020) I-PETER (Interactive platform to experience tours and education on the rocks): A virtual system for the understanding and dissemination of mineralogical-petrographic science. Pattern Recognit Lett 131:85–90
Soares BB (2021) Towards a reflexive museology: the history of ICOFOM and the creation of a contemporary discipline for museum theory. In: Tzortzaki D, Keramidas S (eds) Theory of museology. Main school of thought 1960–2000. Norvegian Institute of Athens, Athens, pp 139–161
Sospedra-Roca R, Hernàndez-Cardona FX, Feliu-Torruella M, Boj-Cullell I (2022) Social museography and sustainable historical heritage. Sustainability 14:6665
Tanelli G, Benvenuti M, Costagliola P, Dini A, Lattanzi P, Maineri C, Mascaro I, Ruggieri G (2001) The iron mineral deposits of Elba Island: state of the art. Ofioliti 26:239–248
Tokar S (2004) Universal design in North American museums with hands-on science exhibits. Visit Stud 7:6–10
Torrens E, Barahona A (2012) Why are some evolutionary trees in natural history museums prone to being misinterpreted? Evol Educ Outreach 5:76–100
Trevisani E (2011) History of the Vigarano meteorite (Emilia-Romagna, Italy) and recovery of an important part of the main mass. Rend Fis Acc Lincei 22:315–326
Van Geert F (2019) In situ interpretation and ex situ museum display of geology. New opportunities for a geoheritage based dialogue? Int J Geoheritage Parks 7(3):129–144
Vartanian O, Navarrete G, Chatterjee A, Fich LB, Leder H, Modroño C, Rostrup N, Skov M, Corradi G, Nadal M (2019) Preference for curvilinear contour in interior architectural spaces: evidence from experts and nonexperts. Psychol Aesthet Creat Arts 13:110–116
Veninata C (2020) Dal Catalogo generale dei beni culturali al knowledge graph del patrimonio culturale italiano: Il progetto ArCo. DigItalia 15:43–56
Wang S, De Oliveira GS, Djebbara Z, Gramann K (2022) The embodiment of architectural experience: a methodological perspective on neuro-architecture. Front Hum Neurosci 16:833528
Wilson RJ (2018) Natural history heritage. Place and politics. Routledge, New York
Zanda B, Egal A, Steinhaus A, Bouley S, Colas F, Ferrière L, Vida D, Villepoix H, Maquet L, Antier K, Vernazza P, Sans-Joffre P, Gattacceca J, Vaubaillon J, Jenniskens P, Baziotis I, Gounelle M, Fripon/Vigie-Ciel Teams F (2023) Recovery and Planned Study of the Saint-Pierre-le-Viger Meteorite: An Achievement of the Fripon/Vigie-Ciel Citizen Science Program. 86th Annual Meeting of the Meteoritical Society, held 13–18 August, 2023 in Los Angeles, California/Virtual. LPI Contribution No. 2990, id. 6206
Zhisheng WANG, Nagai Y (2020) Research into the improvement of museum visitor’s emotional response levels to artificial lighting designs based on interdisciplinary creativity. J Eng Res 8:1–19
Acknowledgements
The authors thank all the MISP staff and the President of the Parsec Foundation. This work is dedicated to Dr. Daniele Mannocci, Prof. Curzio Cipriani, Prof. Piergiorgio Malesani, and Prof. Loris Macci, who encouraged the MISP creation and Arch. Marco Cecchi, who supported the architectural project.
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Open access funding provided by Università degli Studi di Firenze within the CRUI-CARE Agreement. This study was founded by the Municipality of Prato under Grant Agreement No. PRAT22PARSEC_MetSciPlan.
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Conceptualization, G.P., A.F. Writing—original draft preparation, A.F. Writing—review and editing, A.F., G.P. Architectural project, P.R.P Acquisition of funding, M.M.
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Pratesi, G., Franza, A., Morelli, M. et al. Look at me! The museographic project beneath the Italian Museum of Planetary Sciences in Prato (Italy). Rend. Fis. Acc. Lincei 35, 705–718 (2024). https://doi.org/10.1007/s12210-024-01257-6
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DOI: https://doi.org/10.1007/s12210-024-01257-6