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World Heritage List – Sweden

  UNESCO World Heritage List –  

  Riksantikvarieämbetet

 

Cultural

  Södra Ölands odlingslandskap

The southern part of the island of Öland in the Baltic Sea is dominated by a vast limestone plateau. Human beings have lived here for some five thousand years and adapted their way of life to the physical constraints of the island. As a consequence, the landscape is unique, with abundant evidence of continuous human settlement from prehistoric times to the present day (more…)

The Birka archaeological site is located on Björkö Island in Lake Mälar and was occupied in the 9th and 10th centuries. Hovgården is situated on the neighbouring island of Adelsö. Together, they make up an archaeological complex which illustrates the elaborate trading networks of Viking-Age Europe and their influence on the subsequent history of Scandinavia. Birka was also important as the site of the first Christian congregation in Sweden, founded in 831 by St Ansgar (more:  Birka vikingastaden,  Strömmas webbplats)

      Gammelstads kyrkstad i Luleå 

Gammelstad, at the head of the Gulf of Bothnia, is the best-preserved example of a ‘church village’, a unique kind of village formerly found throughout northern Scandinavia. The 424 wooden houses, huddled round the early 15th-century stone church, were used only on Sundays and at religious festivals to house worshippers from the surrounding countryside who could not return home the same day because of the distance and difficult travelling conditions (more…)

  Engelsbergs bruk

Sweden’s production of superior grades of iron made it a leader in this field in the 17th and 18th centuries. This site is the best-preserved and most complete example of this type of Swedish ironworks (more…)

  Hansestaden Visby

A former Viking site on the island of Gotland, Visby was the main centre of the Hanseatic League in the Baltic from the 12th to the 14th century. Its 13th-century ramparts and more than 200 warehouses and wealthy merchants’ dwellings from the same period make it the best-preserved fortified commercial city in northern Europe (more…)

  Falu gruva

The enormous mining excavation known as the Great Pit at Falun is the most striking feature of a landscape that illustrates the activity of copper production in this region since at least the 13th century. The 17th-century planned town of Falun with its many fine historic buildings, together with the industrial and domestic remains of a number of settlements spread over a wide area of the Dalarna region, provide a vivid picture of what was for centuries one of the world’s most important mining areas (more…)

  Örlogsstaden Karlskrona

Karlskrona is an outstanding example of a late-17th-century European planned naval city. The original plan and many of the buildings have survived intact, along with installations that illustrate its subsequent development up to the present day (more…)

  Tanums hällristningsområde

The rock carvings in Tanum, in the north of Bohuslän, are a unique artistic achievement not only for their rich and varied motifs (depictions of humans and animals, weapons, boats and other subjects) but also for their cultural and chronological unity. They reveal the life and beliefs of people in Europe during the Bronze Age and are remarkable for their large numbers and outstanding quality (more…)

  Drottningholms slottsområde

The Royal Domain of Drottningholm stands on an island in Lake Mälar in a suburb of Stockholm. With its castle, perfectly preserved theatre (built in 1766), Chinese pavilion and gardens, it is the finest example of an 18th-century north European royal residence inspired by the Palace of Versailles (more…)

  Skogskyrkogården i Stockholm

This Stockholm cemetery was created between 1917 and 1920 by two young architects, Asplund and Lewerentz, on the site of former gravel pits overgrown with pine trees. The design blends vegetation and architectural elements, taking advantage of irregularities in the site to create a landscape that is finely adapted to its function. It has had a profound influence in many countries of the world  (more…)

  Fyra mätpunkter i Struves meridianbåge

  The Struve Arc is a chain of survey triangulations stretching from Hammerfest in Norway to the Black Sea, through 10 countries and over 2,820 km. These are points of a survey, carried out between 1816 and 1855 by the astronomer Friedrich Georg Wilhelm Struve, which represented the first accurate measuring of a long segment of a meridian. This helped to establish the exact size and shape of the planet and marked an important step in the development of earth sciences and topographic mapping. It is an extraordinary example of scientific collaboration among scientists from different countries, and of collaboration between monarchs for a scientific cause. The original arc consisted of 258 main triangles with 265 main station points. The listed site includes 34 of the original station points, with different markings, i.e. a drilled hole in rock, iron cross, cairns, or built obelisks (more…)

  Grimetons sändarstation

The Varberg Radio Station at Grimeton in southern Sweden (built 1922–24) is an exceptionally well-preserved monument to early wireless transatlantic communication. It consists of the transmitter equipment, including the aerial system of six 127-m high steel towers. Although no longer in regular use, the equipment has been maintained in operating condition. The 109.9-ha site comprises buildings housing the original Alexanderson transmitter, including the towers with their antennae, short-wave transmitters with their antennae, and a residential area with staff housing. The architect Carl Åkerblad designed the main buildings in the neoclassical style and the structural engineer Henrik Kreüger was responsible for the antenna towers, the tallest built structures in Sweden at that time. The site is an outstanding example of the development of telecommunications and is the only surviving example of a major transmitting station based on pre-electronic technology (more…)

Natural

  Höga kusten och sedan 2006 även omfattande Kvarkens skärgård i Finland

  The Kvarken Archipelago (Finland) and the High Coast (Sweden) are situated in the Gulf of Bothnia, a northern extension of the Baltic Sea. The 5,600 islands of the Kvarken Archipelago feature unusual ridged washboard moraines, ‘De Geer moraines’, formed by the melting of the continental ice sheet, 10,000 to 24,000 years ago. The Archipelago is continuously rising from the sea in a process of rapid glacio-isostatic uplift, whereby the land, previously weighed down under the weight of a glacier, lifts at rates that are among the highest in the world. As a consequence islands appear and unite, peninsulas expand, and lakes evolve from bays and develop into marshes and peat fens. The High Coast has also been largely shaped by the combined processes of glaciation, glacial retreat and the emergence of new land from the sea. Since the last retreat of the ice from the High Coast 9,600 years ago, the uplift has been in the order of 285 m which is the highest known ”rebound”. The site affords outstanding opportunities for the understanding of the important processes that formed the glaciated and land uplift areas of the Earth”s surface ( more…)

Mixed

  Lapplands världsarv (Laponia)

The Arctic Circle region of northern Sweden is the home of the Saami, or Lapp people. It is the largest area in the world (and one of the last) with an ancestral way of life based on the seasonal movement of livestock. Every summer, the Saami lead their huge herds of reindeer towards the mountains through a natural landscape hitherto preserved, but now threatened by the advent of motor vehicles. Historical and ongoing geological processes can be seen in the glacial moraines and changing water courses (more: Sametinget, Laponia)

Properties submitted on the Tentative List

Farms of Hälsingland, Hälsingland countryside (2005)

   Hälsingegårdar

  The farmhouses of Hälsingland represent a unique expression of farm architecture springing from the ancient right of farmers to own forest and land and more than a thousand years of agriculture. A relatively limited area of fertile valleys within a forested landscape in northern Sweden contains around two thousand timber farms, many of them substantial constructions with two or three dwelling-houses with attached barns and other outbuildings.

Known with some justifi cation as “wooden castles”, these are magnifi cent building complexes from the 18th and 19th centuries: timbered two or threestorey buildings with up to nine or eleven window axles and carved multicoloured porches based on the design of Classical temples. The interiors consist of richly decorated rooms with friezes of Bible stories or typically Gustavian Rococo walls with natural landscapes, fl owers, fruit baskets and birds. Each region had its decorative painters and carpenters each with their own specialities. This forms a remarkable collection of farms in the Gustavian style (le style gustavien), with Nordic/neoclassical proportions in its wood, architecture, symmetry, tranquillity and dignity. The grand manor house style has clearly provided inspiration, but here, the paintings are given unique expression with strong decorative ambitions in which the panorama wallpapers or elegant textile decorations of the early 19th century are imitated and varied with painting or printed wallpapers. The farms often have two – sometimes three — dwelling houses, one of which was often linked to the outbuildings to form a large complex. An entire house, or fl oor of a house, was reserved for special occasions and used only for storage at other times. These houses or rooms have been very little used and are often in their original condition, thus preserving intact the authentic building traditions of their era.

The farm environment also contains a number of outbuildings designed to meet the needs of the farm. Historical traditions are clearly visible in Järvsö and Ljusdal, with their ancient yard structures, gates and grain stores, some of which were built as early as the 14th and 15th centuries. In the Voxna river valley, the outbuildings were often linked to the dwelling houses to form gigantic architectural formations.

Nowhere in the Nordic region are such magnifi cent farms preserved in such numbers. Nor has the landscape changed signifi cantly since the golden era of the early 19th century. Buildings and agricultural land retain their original appearance. A number of areas have been selected to represent the various types of big farm. All enjoy statutory protection in Sweden as sites of national interest. One farm is a cultural reserve, and several are heritage-listed buildings. This intact agricultural and architectural environment, with its medieval roots and its construction dating mainly from the 18th and early 19th centuries, is unique in Europe, as is the size of its timbered farmhouses. The Hälsingland farms are a hymn to freedom and democracy, a reminder of what can be achieved by industrious people living securely off their own land.

The Rise of Systematic Biology (2009)

   Linnaean taxonomy

“The Rise of Systematic Biology” is a tentative serial nomination of thirteen sites in eight countries (see Table 1), suggested by Sweden, representing the foundation of the science of systematic biology. The sites together form the arena where the science developed strongly due to the Swedish scientist Carl Linnaeus (1707-1778) and his international scientific network. The Swedish sites are described in short. The authenticity in the sites is to a large extent present in remnant organism populations once used to develop the science.

Table 1. Sites tentatively included in the serial nomination “The Rise of Systematic Biology”. Only the Swedish component parts are included here. The other component parts will be included when each State Party has agreed to participate in the serial nomination and has included their site in the tentative list.

Site number Site Name State Party Province or  Region, Municipality Coordinates of Centre Point Area (km2)
I Linnés Råshult Sweden County of Kronoberg, Älmhult 56° 36′ 57″ N14° 12′ 00″ E 0.464
II Linnéträdgårdenand Linnémuseet Sweden County of Uppsala, Uppsala 59° 51′ 44″ N17° 38′ 02″ E 0.012
IIIA Herbationes Upsalienses, Hågadalen-Nåsten Nature Reserve Sweden County of Uppsala, Uppsala 59° 49′ 7″ N   17° 34′ 25″ E 17
IIIB Herbationes Upsalienses, Fäbodmossen Nature Reserve Sweden County of Uppsala, Uppsala 59° 56′ 35″ N17° 19′ 18″ E 1.525
IIIC Herbationes Upsalienses, Årike Fyris Sweden County of Uppsala, Uppsala 59° 81′ 67″ N17° 67′ 32″ E Not yet defined
IV Linnés Hammarby Sweden County of Uppsala, Uppsala 59° 49′ 02″ N17° 46′ 36″ E 2.70

The science of systematic biology

Systematic biology is the study of biological diversity and its origin. The discipline includes collection, naming, classification and describing of organisms as well as a reconstruction of their evolutionary history. Systematic biology has developed strongly during the last decades, partly due to improved molecular techniques and more powerful computers. This has increased our knowledge of how life on earth has developed and how organisms are related to one another.

   The Tree of Life, Carolus Linnaeus’ systematic categorization of living things.

Many scientific disciplines depend on the results from systematic biology. Analyses of evolutionary processes  rely on well-founded hypotheses of evolutionary relationships. A reliable identification of species is a prerequisite for scientific work involving organisms of any kind, especially in applied science, for example agriculture, horticulture and pharmacognosy.

Species are currently going extinct all over the world at an accelerating rate. Many of these species are yet unknown to us. Although hitherto more than 1.8 million species have been described, estimates of the number of undescribed species range from 5 million to over 50 million.

The rise of systematic biology

Systematic biology stands out among biological sciences in being dependent on research on historical collections and publications. The starting points in this research are two works by Linnaeus, Species plantarum published in 1753 for systematic botany Systema naturae 10th ed. published in 1758 for systematic zoology. Names and descriptions of species before these publications are not considered by contemporary scientists. The reason for this is Linnaeus’ consistent use in these publications of short names for species, names that later developed into the currently used binary or binomial nomenclature.

Scientists and historians generally consider the works of Carl Linnaeus as cornerstones in the main foundation of systematic biology. The reasons for this are manifold, not only those governed by nomenclature as mentioned above. Although Linnaeus’ scientific deeds (which are described more in detail in next chapter) were based on works by earlier scientists – that he greatly acknowledged – he managed to create a development of the science strong enough to transform systematic biology from a marginal part of medicine into a discipline of its own, a discipline that later developed into the several branches of biological sciences that we see today.

Before Linnaeus, systematic biology was a historia naturalis that dealt mainly with observations of different objects in nature to help classify and identify important species used for medicinal purposes. Linnaeus transformed systematic biology into a state of scientia, a science with a philosophy, system and book of rules, equivalent to disciplines like law, theology and philosophy.

This transformation created by Linnaeus could only be carried out through observations of a large number of organisms from different regions of the world. The observed organisms were gathered by Linnaeus himself, by scientists in his large network, and by his students during expeditions to different parts of the world. Although the driving force in this development was Linnaeus himself, it resulted in a collaborative work involving himself, his students, and his fellow scientists.

The metaphoric name “The Rise of  Systematic Biology” has been chosen for the series of sites in this tentative serial cultural landscape nomination to reflect the strong development of the science during the time of Carl Linnaeus.

How Linnaeus developed systematic biology

Linnaeus’ development of systematic biology started with pre-academic observations in the fields of southern Sweden during the 1710’s and 1720’s, where he made his first studies that eventually led to a classification of plants by the number of stamens and pistils. He began academic studies, initially at Lund University and then at Uppsala University, both in Sweden. A lack of lecturers at the universities made him at this stage in many ways an autodidactic scholar, although he studied and greatly acknowledged former scientists like  Caspar Bauhin (1560-1624),  John Ray (1627-1705) and Joseph Pitton de Tournefort (1656-1708).

  

In Uppsala he developed his classification scheme further together with his fellow student Peter Artedi. Together they divided the organisms between them. Linnaeus was in charge of plant classification and Artedi of fish classification, and they entered into a pact to publish each other’s works if one of them should die. During this time Linnaeus developed the classification of plants based on numbers of stamens and pistils. He also argued strongly that these were the sexual organs of plants.

During an academic journey to Holland 1735-1738 Linnaeus defended a doctoral thesis in Medicine on malaria. He also managed to get funding for publication of one of the manuscripts that he had brought from Sweden, Systema naturae

During his stay in Holland, Linnaeus published a number of fundamentally important books, such as Biblioteca botanica in 1736 listing all literature in botany, Fundamenta botanica in 1736 with principles and rules to be followed in the classification and naming of plants, Genera plantarum in 1737 with all plant genera and rules for delimiting them, and Critica botanica in 1737 with nomenclatural rules for plants. His friend and scientific colleague Peter Artedi died in Amsterdam 1735, and Linnaeus was left to publish Artedi’s grand work on fish systematics.

During his three years abroad, Linnaeus interacted with some of the most important botanists and zoologists at the time, such as Herman Boerhaave, Gronovius (1668-1738), Hans Sloane (1660-1753), Johann Jakob Dillenius (1687-1747) and Bernhard de Jussieu (1699-1777). This network of scientists became important to Linnaeus’ own development and to his impact on the European scientific community, something that has become reflected in his great, international correspondence. The scientific network was as important in the 18th century as it is today for the development of science.

In 1741 Linnaeus became professor of medicine at Uppsala University in Sweden. This platform made it possible for him to further develop his scientific methods and try out different ideas. He extended the botanical garden Hortus Upsaliensis and filled it with plant species that he received as gifts from scientists in his network and also with different animal species. The garden was constructed as to facilitate the teaching and understanding of his sexual classification system. As he was a charismatic and skilled teacher with splendid rhetoric and great enthusiasm, he managed to create a network of talented students who could test his hypotheses and extend his collections.  No less that 186 doctoral theses were written and defended under his presidium. He developed an excursion system around Uppsala, Herbationes Upsalienses, influenced by i.a. Bernhard de Jussieu’s excursions around Paris. During the excursions he used teaching methods that were to inspire his students to explore the unknown flora and fauna within Sweden and abroad. His scientific network expanded internationally in the same rate that his name became known all over the western world.

Linnaeus was one of the persons who founded the Royal Swedish Academy of Sciences in 1739, and through his contacts there he managed to help funding the expeditions that his students made to remote areas. The students were well trained in methods for collecting, observing and describing. To collect, name and classify species was not only of importance to scientists, but was a part of a global economy developing in the 18th century focusing on investigating the utility of nature. Because of this, the development of systematic biology created effects that influenced the essentials of the life of humanity.

During Linnaeus’ time in Uppsala some important corner stones in systematic biology were published. In 1751 he published Philosophia botanica, a concise book describing the philosophy, rules and methods of systematic botany, part of which is valid still.  In 1753 his most important work in botany, Species plantarum, was published. This was a flora of all known plant species in the world. Most of the around 8000 species in this book had been observed by Linnaeus himself, his students or trusted scientists in his network.

The main ambition of Linnaeus’ scientific reformation was intelligibility in communication. This resulted in several books of rules. His work aimed at totality, expressed in the global Species plantarum, but it also nourished local knowledge through works like Flora svecica and Fauna svecica. He inspired his students to undertake expeditions to foreign countries, sowing the seeds of curiosity in the meadows around Uppsala. He aimed at order and simplicity and structured his flowerbeds in strict quarters, but was amazed by the rich diversity of life, a diversity that never seemed to cease, but with time made the systematic work overwhelming and almost going over the brink. An international legion of scientists would soon stand prepared to continue the development of systematic biology from the base worked out by Linnaeus.

Development of systematic biology after Linnaeus

The simplified and artificial systems constructed by Linnaeus were not able to last for long, and the first developments were made by himself. He admitted already in 1735 in the first edition of Systema naturae that the sexual system of plants was artificial and must later be replaced by a natural system. He tried to develop a natural system, starting already in 1738 in Classes plantarum by describing 65 natural orders of plants. He never managed to construct a fully developed natural classification. Apart from the problems connected with an artificial science, Linnaeus was also aware of the problems that the biblical rules of natural sciences caused when confronted with the complex variation among and in organisms. In 1744 he wrote a thesis stating that there was a possibility that speciation through hybridization may occur within the plant kingdom. However, it was too early for such theories to develop in the society, and he and his scholars had to leave many questions unanswered.

The development of systematic biology after Linnaeus went rapidly towards a natural system where species with overall similarity would be classified together, as opposed to Linnaeus’ artificial sexual system where the number of stamens and anthers were emphasized. The natural system arose first in France, where Linnaeus had one of his greatest scientific opponents Georges-Louis Leclerc de Buffon (1707-1788) who disagreed on imposing an artificial order on the disorderly natural world. Buffon’s theories, together with earlier works in France by Michel Adanson (1727-1806) and the pre-Linnaean scientist Joseph Pitton de Tournefort (1656-1708) made way for the natural system presented in 1789 in Genera plantarum,  published by Antoine Laurent de Jussieu (1748-1836), a scientist in Jardin des Plantes in Paris.

Linnaeus’ great collections had been sold to London by the family, and in 1788 the Linnean Society of London was founded to take care of the collections and create a meeting place for the cultivation of the science of natural history. The United Kingdom was to play an important part in the development of systematic biology during the 19th century. A development of the natural system was worked out by the botanist Robert Brown (1773­-1858), partly due to his immense collections from Australia. Earlier investigations of the continent had been carried out during the voyages by Captain James Cook when the Linnaean scholar Daniel Solander and Sir Joseph Banks visited the now famous Botany Bay south of Sydney. The high number of species they collected pointed towards the need for a natural system that could cope with earth’s biodiversity.

The shift of paradigm caused by the theory of evolution would become the most important theory change affecting systematic biology. However, it took more than 100 years until the theory could be fully applied within this science. Early versions of evolutionary theories had been suggested during the 19th century, the most important one by the Jean-Baptiste de Lamarck (1744-1829) in France, but it was not until Charles Darwin (1809-1882) and Alfred Russel Wallace (1823-1913) presented their hypothesis at the Linnean Society of London in 1858 that a theory of evolution made a great impact. Systematic biology eventually aimed at basing their classifications on the new theory, but for decades theories on evolutionary trees were based on personal analyses of similarities and differences between organisms that could not be tested. Concurrently, the systems of plants and animals were growing huge with an increasing number of species new to science.

In 1950, the German biologist Willi Hennig (1913-1976) presented revolutionary new ideas that became the foundation of the cladistic era of systematic biology. He proposed that only shared-derived features (“synapomorphies”) could be used to infer relationships, and that classifications should be based on such phylogenetic relationships rather than on overall similarity. Moreover, the taxonomic units (species, genera etc.) should include all descendants of a single ancestor (the “rule of monophyly”). The molecule carrying the genetic information of life forms, DNA, had already been detected in 1953 by James D. Watson (1928-) and Francis Crick (1916-2004), and a few decades later the development of the polymerase chain reaction (PCR) facilitated DNA sequencing immensely. Together with the concurrent development of more powerful computers and analytical programs, this enabled a widespread use of DNA sequence data to infer relationships among organisms.

  The science of systematic biology is currently in a phase of strong development. New species are continually being discovered, and the importance of systematic work is now widely acknowledged. National and global documentation of organisms are as much on the agenda today as it was in the 18th century. For example, Sweden has recently launched “The Swedish Taxonomy Initiative”, which aims at identifying and describing all Swedish multicellular organisms.

Our understanding of how different organisms have diversified through the process of evolution is rapidly increasing. Refined methods for phylogenetic analyses, species identification by molecular markers, and the rapid extinction of species on earth are issues in focus for the modern scientist. Seemingly trivial issues, like the naming of species, are of central importance. Although systematic biology of today may seem far away from that founded by Carl Linnaeus in the 18th century, the tools serving scientists describing new species may indeed be traced back to his works. Furthermore, a main concern is still that we, Homo sapiens, are dependent on the cobweb of species on earth, and that in order to study or use other life forms we need to know their names and understand their history as well as their context. There is no other possible alternative for the future.

The role of each component part in the rise of systematic biology

The foundation of systematic biology laid out by Linnaeus and his scientific network was totally dependent on the possibility to observe a large enough number of organisms. These were observed by scientists in their natural habitat, then generally collected and further analysed dead or alive. Large collections of preserved organisms are kept in museums all over the world. Living organisms are kept in gardens, zoological parks and in bacterial and fungal cultures. For each species described, a certain individual is assigned as a type specimen and preserved. There is a connection between the type specimen and its original population in nature.

Since systematic biology is a science based on observations of organisms, a World Heritage Site reflecting the foundation of the science must be defined in areas where descendants still exist of organisms once studied and preserved by scientists. This could be a field collection area or a historical garden. Such extant populations are not only of cultural value, they are also of great scientific value; if type specimens would be destroyed in the museums – like when the Berlin herbarium was bombed during the second world war – interchangeable collections can be made in extant populations. A recent example is when in 2002 a neotype (a type specimen selected as a substitute for a missing or insufficient original type) was needed for the species common cotoneaster Cotoneaster integerrimus, described by Linnaeus. The neotype was collected in an extant population along one of the excursion trails in Herbationes Upsalienses.

In the tentative serial cultural landscape nomination of a World Heritage Site named “The Rise of Systematic Biology”, component parts will be included with extant populations consisting of descendants to the once collected individuals that contributed to the foundation of systematic biology by Carl Linnaeus and scientists within his network. The component parts below all carry such populations, in many cases preserved due to the fame of the unique scientific achievements connected to them. Some of these sites also include preserved buildings and structures from the 18th century. The extant populations have a strongly probable continuous local history since the 18th century.

The different component parts complete each other, and together they represent “The Rise of Systematic Biology. The component parts in Sweden were central for the development of the science as carried out by Carl Linnaeus: his initial study site (Råshult), his garden, research facilities and excursion sites in Uppsala (see Description chapter below).

The garden sites in Europe and USA are examples of gardens important for the exchange of plants and animals within science and with a connection to Linnaeus’ development of the science. Linnaeus visited Chelsea Physic Garden in the 1730’s, a visit that influenced him and gave him contacts. The scientific connection to England became important to his own development of science as well as the later development of systematic biology in England. The increased knowledge of North American species was channelled via England, as well as the grand discoveries of flora and fauna in other parts of the world. Linnaeus’ student Daniel Solander, well trained in Linnaeus’ methods, had an influence on the development of systematic biology through his collections together with Banks in Australia and other places. The botanical garden of Leiden was an important place for Linnaeus’ development as a scientist, and he worked in this garden during his stay in Holland. The garden bears traces of great botanists such as Clusius, Boerhaave and Van Royen. The garden still harbours a number of plants studied by Linnaeus and planted by the scientists that influenced him. Among these are plants from Clusius’ time and numerous plants introduced into the garden by his mentors Boerhaave and Van Royen and by botanists he greatly admired such as Paul Hermann. The original Clusius Garden dating from 1592-94 has recently been reconstructed on its original site, and the garden is annex to the old Academy Building still serving as the ceremonial centre of Leiden University where Linnaeus attended lectures by Boerhaave and other Leiden scholars. Jardin des plantes in Paris is where Linnaeus got most of his plants from when he restored the Hortus Upsaliensis. Prof. Bernhard de Jussieu in Paris was an important contact to Linnaeus. Paris inspired Linnaeus to create the Herbationes Upsalienses. The French scientist Buffon opposed greatly to his theories, and the lack of idolization of Linnaeus in France created a vacant space that made it possible to develop the science further by creating a natural system. This work was made by Antoine de Jussieu, who was active in Jardin des Plantes in Paris. The garden contains several trees and plants still surviving from the 18th century.

John Bartram (1699-1777) founded a botanic garden on his farm in Philadelphia in 1728, and traveled widely throughout the colonies of British North America. He had a wide correspondence with European and American scientists and amateurs, including Linnaeus, and together with his friend Benjamin Franklin, Bartram helped found the American Philosophical Society in Philadelphia in 1743. About 1733 John Bartram began a correspondence with the London merchant Peter Collinson (1694-1768), who soon became middleman for a scientific trade in seeds, plants, and natural history specimens. Bartram’s plants were exchanged with Miller, Catesby, and Sloane in London, Dillenius at Oxford, and Gronovius at Leiden. When the first edition of Linnaeus’s Systema naturae was published in Leiden in 1735, Peter Collinson forwarded a copy to James Logan in Philadelphia. Logan also served as an encourager for Bartram, and together in the summer of 1736 the two studied Linnaeus’ system. Bartram was soon applying Linnaeus’ method and examining stamens and styles, often under magnification. Distance forced Bartram and Linnaeus to carry on a desultory correspondence, but information and plant specimens from Bartram passed to Linnaeus through Collinson in London and Gronovius at Leiden. Linnaeus dubbed Bartram “the greatest natural botanist in the world.” Linnaeus’s student, Pehr Kalm visited Bartram during his stay in North America, 1748-51. Kalm was taken with Bartram’s “peculiar genius” for natural philosophy and natural science, and Bartram shared much of his knowledge and many of his plants with Kalm. Kalm was based on the Delaware, opposite Philadelphia, during his stay in North American and most of his collections were made in the area. Collections from this area, which included the former colony of New Sweden, also reached Linnaeus in other ways. Among other species Linnaeus studied a raccoon that he kept as a pet in Uppsala, observed and finally dissected and described. When Kalm returned to Sweden he provided a wealth of new material for Linnaeus. Kalm’s collections increased Linnaeus’ knowledge greatly and they served as a direct inspiration for him to initiate the important work Species plantarum published in 1753.

Bartram’s garden and part of his farm are today preserved as Bartram’s Garden, the oldest botanic garden in the USA. The area is a vivid place for learning and inspiration, and still carries many traces from the 18th century. The garden site is intact and Bartram’s house, largely built with his own hands, survives as well as his 1760 greenhouse. Many of the plants Bartram sent to Europe have been identified through thorough research by Prof. Mark Laird and Bartram Curator, Joel T. Fry. Around a dozen of species are hitherto identified as authentic from Bartram’s garden, and some of them have possibly spread in the area as invasive species.

Three collection areas are included on three continents. In these areas collections were made that became important to the central development of science directly or to local development of systematic biology. Several students of Linnaeus collected plants and animals around the Cape, but few made such extensive collections as Carl Peter Thunberg and Anders Sparrman who made expeditions in and around Table Mountain, among other places in the Cape region. Sparrman described some well-known animals like the African Buffalo and the now extinct Quagga. Thunberg made extensive collections and wrote the first Flora of South Africa, investigations that became important to the development of systematic biology in southern Africa. Ever since the exploration of the southern tip of Africa was initiated, Table Mountain has been treated as a living laboratory. Given its immense visual impact, it has attracted the attention of scores of biodiversity and natural history scholars. Table Mountain National Park is located on the Cape Peninsula, the south-western extremity of Africa. It stretches from Signal Hill in the north (33° 54′ S, 18° 24′ E) to Cape Point in the south (34° 21′ S, 18° 29′ E) and includes Table Mountain. Due to the extraordinary biodiversity and scenic landscapes, the Table Mountain National Park was declared a Natural World Heritage Site in 2003. Within an area of 471km2, 2285 indigenous plant species occur making the Cape Peninsula flora one of the richest for any similar-sized area, both in the Cape Floral Kingdom and elsewhere in the world.

Carl Peter Thunberg carried on from South Africa to Japan. In a time when Japan was isolated from the rest of the world, he arrived to the country disguised as a Dutchman to collect plants. Together with other foreigners, he was isolated on the island Dejima outside Nagasaki. From there he managed to make collections that became the foundation of the Flora of Japan. He traded his knowledge in medicine against plants, and extracted flowering plants from the fodder brought to the animals on Dejima. He was allowed to make one journey to Edo (Tokyo), where he managed to collect several plant species, many of them in the Hakone Mountains area. The island Dejima is today reconstructed with some original elements still preserved. Hakone National Park still carries an authentic part of the Tokaido road on which Thunberg travelled, and around Hakone populations remain of the flora that Thunberg once collected.

Daniel Solander was one of Linnaeus’ most skilled students, selected by Linnaeus to become his successor. However, after having moved to London to promote the new systematic biology he eventually lost contact with Linnaeus. Together with Sir Joseph Banks he collected new species all over the world on one of James Cook’s voyages. In Australia they made important collections that contributed to the development of a natural system by the English scientist Robert Brown. The area where many important collections were made is today known as Botany Bay, where many of the populations once collected by Banks and Solander remain. One of the species, an icon for the area, is Banksia serrata, named in honour of Banks. The area of 4.9 km² is a national park protected under Australian government law managed by New South Wales National Parks and Wildlife Service.

Apart from the component parts described above, it must here be mentioned that the collected individuals, i.e. the museum specimens, once collected from these populations are of uttermost value to science, especially Linnaeus’ natural collection kept in London by the Linnean Society of London. These can, however, not be included in this nomination.

Description – Component Parts of “The Rise of Systematic Biology”

I. Sweden – Linnés Råshult, Älmhult

  Every great scientific achievement has its roots in initial observations. The scientific revolution that Linnaeus made in systematic biology started when he in his childhood and youth performed his first studies of the local flora and fauna in the parish Stenbrohult in southern Sweden. During this naïve stage of his scientific development, Linnaeus botanised in the vegetation typical of the 18th century, where he studied stamens and pistils in flowering plants, observations that later developed in the sexual system.

Linnaeus was born in Råshult in the parish Stenbrohult. The homestead, an agricultural vicarage, held a species-rich garden created by his father, a garden that according to Linnaeus himself sparked off his great interest in plants. At the age of two years, Linnaeus and his family moved to a vicarage not far from Råshult, close to the parish church. However, the family retained the farm in Råshult as a compensation for an extended household now including Linnaeus grandmother, who had become a widow. The family could easily walk between the two homesteads on the church road connecting the two places.

Linnaeus grew up in an intellectual home. His father and uncle were both knowledgeable in medicinal plants, reading was encouraged in the vicarage, as was knowledge about plants. Linnaeus received classical, medicinal books from his father, like “Historia plantarum” by Theophrastus, and further knowledge was given to him later by his tutor in secondary school, Johan Rothman. The intellectual environment nurtured Linnaeus’ perceptual mind. So did a strong relationship to the Swedish countryside in a time of history when meadows and forests had a colourful biodiversity of flowering plants.

As a teenager, Linnaeus explored the meadows and forests within the parish. Using the classification by the French scientist Tournefort, he was puzzled to find unidentifiable plants not included in that work. To find the answers to his growing number of questions he turned to both books and nature. Already as a teenager he felt the need to complete his library with a book of his own, Örtaboken (The Book of Herbs), written by hand between 1725 and 1727. The young Linnaeus naturally must have spent much of his time in the meadows and fields belonging to the vicarage in Stenbrohult parish, and Råshult was an obvious base for his nature studies.

Today the meadows of Råshult are a cultural reserve where the agricultural landscape since many years is managed by 18th century methods. The other meadows, once studied by Linnaeus in the parish, are since long overgrown and their vegetation changed, but in Råshult the vegetation has been preserved by the local society treasuring Linnaeus’ memory. Especially the latest years’ management in Råshult has resulted in an almost explosive expansion of authentic populations common in Linnaeus’ Stenbrohult in the 18th century. Plants that earlier were rare are now common in the meadows: viper’s grass Scorzonera humilis, arnica Arnica montana, quaking grass Briza media, bitter vetch Lathyrus linifolius, lesser butterfly orchid Platanthera bifolia, heath spotted orchid Dactylorhiza maculata, lousewort Pedicularis sylvatica, marsh gentian Gentiana pneumonanthe. This historical vegetation type in Råshult is the only one present not only in the parish Stenbrohult, but in the whole of Kronoberg county.

The father’s vicarage garden was described by Linnaeus in Adonis Stenbrohultensis 1732. The father started planting the garden at Råshult, and moved parts of it at to the vicarage at Stenbrohult church. A dozen species from the garden in Råshult have survived there, for example elderflower Sambucus nigra, lilac Syringa vulgaris, orange daylily Hemerocallus fulva, red currants Ribes rubrum, and small grape hyacinth Muscari botryoides.

The buildings in Råshult are positioned in the same place as in the time when Linnaeus family lived there.  One of the buildings was reconstructed and made a museum in 1930, furnished as a typical vicarage of early 18th century. A reconstruction of Linnaeus’ father’s special garden structure is made on the same area as the original garden was laid out, with flowerbeds shaped as a dining table with chairs for guests.

Linnés Råshult is a cultural reserve since 2002, managed by the Kronoberg County Adminstrative Board, the buildings are protected by Swedish law as notable buildings since 1977.

 II. Sweden – The Linnaeus Garden (Linnéträdgården) and the Linnaeus Museum (Linnémuseet), Uppsala

  The garden of Uppsala University, Hortus Upsaliensis, was central to Linnaeus’ scientific work, which makes it a living complement to his writing and his natural collection to anyone who wishes to understand the Linnaean era of systematic biology. The garden was the living source to the fundamental global flora Species plantarum.

 After 1741, when Linnaeus became a professor at Uppsala University, the botanical garden soon became a central place for Linnaeus scientific reformation and foundation of systematic biology. The garden had been strongly deteriorated after a fire, but with help from scientists in his network, Linnaeus managed to increase the number of species from 300 to more than 3000. Having visited grand gardens in Europe, like those of Leiden, London and Paris, he wanted his new creation to outdo them all. The Court Architect and Director of the Public Works Carl Hårleman drew a garden plan of a straight symmetric “jardin à la française” with trimmed hedges and parallel parterres, the university gave more land and funding for a new greenhouse, and the new garden was built during 1743-1745.

The new garden became an important research facility to Linnaeus where he performed many of his studies. Apart from systematic research some studies concerned night behaviour of plants, cultivation of the Chinese rhubarb root, and how to tell the time from the opening and closing of flowering plants by the horologium florae. However, the main purpose of the garden was that of a lecturing room. Linnaeus could here demonstrate not only medicinal plants to the students, but also ongoing research. The species were ordered according to the sexual systems. The students could learn the habitats of different plant species needed through three different wet habitat areas, partly created from a well in the garden. These were the first ecological plantations made in a botanical garden. Spring and autumn quarters as well as annual and perennial quarters helped the students to understand the phenology of plants. The economic and geographic aspects of plants could be studied in hedges of different quality and species as well as in a collection of Swedish tree species. Foreign medicinal plants were imported and tried out in the garden to make cultivation of them in Sweden possible. Linnaeus’ international contacts and the travels by his students were reflected in the species composition of the garden. Scientists from Europe came to Uppsala to visit the garden, as it had become the largest in the world in number of species. There was also a collection of living animal species, for example different species of monkeys, kept in special pole houses, peacocks and a raccoon.

Uppsala botanical garden was moved to a new location when King Gustaf III in 1794 donated the Castle Garden in Uppsala to Uppsala University to honour the memory of Linnaeus. The property of the old botanical garden was used by the students. The main greenhouse was converted into housing, but the warmhouses on the side still carry traces from flowerbeds inside.

The Swedish Linnaeus Society was founded in 1917 in order to preserve as much as possible of the Linnaeus heritage. In 1923 the Society reconstructed Linnaeus’ botanical garden. Flowerbeds and hedges were recreated in their exact positions, as found out from preserved detailed building plans from the 1740’s. The middle axis path has remained in the garden over the years, authentic material from rubbish heaps and parterres are continuously found in the earth layer and the pressure from the artesian well fills the central dam, one of the three ecological plantation areas restored. Around 1500 plants of the same species as Linnaeus grew here were returned from the new botanical garden. Some of these were authentic specimens, and other authentic species were later planted in the garden. Examples are liverwort Hepatica nobilis and winter blooming bergenia Bergenia crassifolia and other species from Hammarby, as well as royal fern Osmunda regalis and aspen Populus tremula from Linnaeus’ observation sites in Sweden. A few species have always remained in the garden, like gageas Gagea spp., yellow wood anemone Anemone ranunculoides, noble fumitory Corydalis nobilis and wild tulip Tulipa sylvestris. The garden is still used for demonstrations of plants for schools and visitors.

In the forecourt of the garden we find the old professor’s home, now the Linnaeus museum. This is where Linnaeus lived a short time as a student in Prof. Olof Rudbeck the younger’s home and where he later moved in himself as a professor in 1743 and stayed until his death in 1778. The house was, like the garden, in a deteriorated state, and Linnaeus had it partly rebuilt. The ceiling was elevated so that rooms could be built in the attic, and when finished the house had 12 rooms in total. Special rooms were furnished as library, natural cabinet and lecture room. The greater part of his scientific work was written in this house. Linnaeus held both university lectures and private lectures in the home, as it was easier to demonstrate living plants so close to the garden. From the library he could keep a watching eye on the garden and the gardeners.

After Linnaeus’ death in 1778, the house was inhabited by a succession of professors in medicine as well as in music until 1935. The Swedish Linnaean Society, founded in 1917, had taken initiative to an antiquarian investigation, which lead to a reconstruction of Linnaeus’ home. With help from relatives to Linnaeus the house could be furnished with authentic objects and the museum could open in 1935.

A visit to the Linnaeus museum in the Linnaeus garden elucidates Linnaeus’ scientific work as well as his family life. In Linnaeus’ study there are scientific instruments, such as his microscope, compass and botanical knife. His herbarium cupboard and other museum cupboards are standing here, and one room displays conserved species from the 18th century collections of Uppsala University. His study is furnished with original furniture. The world famous portrait, picturing Linnaeus in Samish costume while in Holland, emphasizing his scientific work, hangs in the lecture room.

The Linnaeus Garden with the Linnaeus Museum is national property and protected by Swedish law as notable buildings since 1935 and 1993, respectively.

III. Sweden – Herbationes Upsalienses (Linnéstigarna), Uppsala

  Teaching was an important part of Linnaeus scientific activities. He used what we would call modern methods to inspire the students. By teaching them his new efficient methods, his philosophy and practical science he made them part of his network. The students thus became important in the development of systematic biology, either by contributing to Linnaeus knowledge of organisms by sending him collections from their expeditions, or making a career of their own and extend the scientific scope.

Excursions became a central part of Linnaeus’ teachings, inspired from similar excursions in Paris, London, Göttingen and Halle, driven by his philosophy “During excursions one may see every plant in its natural habitat, from which a mindful observer may not only get a great pleasure, but also a more thorough knowledge about the plants.” A number of excursions ended the spring lectures under the name Herbatio­nes Upsalienses.

The rules for the excursions were strict and described in Philosophia botanica. There were eight excursion trails, along which most plants and animal species around Uppsala had been seen. The clothing should be purposeful and loose fitting. The students should bring proper reference works and col­lection devices into the field. One student was assigned by Linnaeus to keep order of the group. Another student would shoot the birds to be studied. A third student became a secretary, annotating every word uttered by the teacher during the excursion. These protocols are preserved and give us information on which species the students saw. The students divided into groups to collect plants, animals and minerals, and Linnaeus regularly demonstrated their findings, a teaching method very inspiring to the students.

Linnaeus could use the excursions to select talented stu­dents capable of performing good research in systematic biology. Herbationes Upsalienses were a first expedition into nature, in a safe, controlled manner. They became an important breeding ground for new scientists and a scientific network around Linnaeus was created in the field. Since the species along the trails were studied repeatedly by Linnaeus with new students every year, they became the base for the fundamental works Species plantarum in 1753 and Systema naturae in 1758. The excursions also worked as an arena for experimenting with scientific methods. Linnaeus tested his short trivial names (later developing into binary nomenclature) in his group of students before final publication in Species plantarum. Herbationes Upsalienses were to Linnaeus and his students what a scientific laboratory is to a contemporary scientist and his lab group.

The Herbationes Upsalienses are today partly reconstructed. Three excursions (1, 6 and 8, see Fig. 3) were constructed by Uppsala municipality in collaboration with Swedish Linnaean Society in 1978. In the preparations of the Linnaeus tercentenary in 2007 those were redrawn in collaboration with the project Linnaean Landscapes and a fourth excursion (no 4) added. The last four excursions (2, 3, 5 and 7) are currently under reconstruction.

Around 1000 plant species and 500 animal species are known from the protocols. The Herbationes Upsalienses excursion paths has been surveyed during 2009 to find remaining plant populations. At leasts 300 of the plants do still thrive along the excursion trails. Three areas with a protected biodiversity along the Herbationes Upsalienses trails are currently under protection by Swedish law. Two of these are Nature Reserves and known to contain species populations once studied by Linnaeus and his students, Hågadalen-Nåsten Nature Reserve and Fäbodmossen Nature Reserve. The third, Årike Fyris, is a reserve to be and its landscape is currently proctected under Swedish Law.

IIIA. Sweden – Hågadalen-Nåsten Nature Reserve, Uppsala

  The Hågadalen-Nåsten Nature Reserve includes two trails of Herbationes Upsalienses, Herbatio Gottsundensis in the Eastern part and Herbatio Hogensis in the Northern part. These excursions are relatively well-documented by student protocols from Linnaeus’ excursion, especially Herbatio Gottsundensis. A high number of species once studied by Linnaeus and his students still thrive in this nature reserve, 160 species were found in an inventory made 2009. Some examples are oak Quercus robur, common buckthorne Rhamnus cathartica, fly honeysuckle Lonicera xylosteum, spurge laurel Daphne mezereum and common toothwort Lathraea squamaria. Elements like Norby well and the Håga river are still positioned in the same localities as in the 18th century.

IIIB. Sweden – Fäbodmossen Nature Reserve, Uppsala

  The Fäbodmossen Nature Reserve is positioned West of the ending point of the present reconstruction of Herbatio Jumkilensis. Linnaeus and his students went by horse and carriage all the way to Jumkil Parish to stay overnight and next day wander through the vast forests of Jumkil. The western part of this excursions went through extensive bogs, sometimes including Fäbodmossen, which is a preserved bog area where vegetation has not been destroyed by draining and ditching. Classical populations from this excursion are still present in Fäbodmossen Nature Reserve, like moor-king Pedicularis sceptrum-carolinum, bog rosemary Andromeda polifolia, marsh ledum Ledum palustre and common hair moss Polytrichum commune. 13 species remaining from Linnaeus’ time were found in the bog area during 2009.

Since the 18th century, Fäbodmossen has never been drained or ditched.

IIIC. Sweden – Årike Fyris, Uppsala

  The area Årike Fyris is a landscape protected area planned to become either a municipal Nature Reserve or a municipal Culture Reserve within a few years time. It is positioned South of Uppsala town on both sides of River Fyris.It includes Kungsängen Nature Reserve, which is a Natura 2000-area, and the Nature Reserve Nåntuna Lund and a Natura 2000 area along Sävja River that joins with the Fyris River within the area.  The excursion paths Herbatio Danensis and Herbatio Ultunensis cross the Årike Fyris area, and over 100 species remain from Linnaeus time according to an inventory made 2009. The most famous of these is the naturalized Snakeshead Fritillary Fritillaria meleagris.

IV. Linnaeus’ Hammarby (Linnés Hammarby), Uppsala

In 1758 Linnaeus bought the farmstead Hammarby 10 km SE of Uppsala with some adjacent village houses. This became his first private property. He soon developed the area into a private research station and held his private lectures for international students there during the summers. He built a manor for his family, his scientific activities and some of his collections. Later on he built a specially designed museum for his natural collections, which he also moved out from Uppsala. He laid out botanical gardens, flowerbeds and planted trees and hedges. Initially he transferred plants from Hortus Upsaliensis, and later he planted seeds that he received as gifts. He stayed in Hammarby all summer, but visited the Hortus Upsaliensis regularly. He received scientists and celebrities from Sweden and abroad as visitors in Hammarby, for example Lord Baltimore III from England and crown prince Gustaf of Sweden, both attracted by his fame as a scientist.

Linnés Hammarby is a property with unique remnants from the foundation of systematic biology. Linnaeus’ study (Fig. 4) in the main building was never used after his death, and many details in the room bears direct trace from his hand. A wallpaper consisting of plates of American plants drawn by Plumier in the work Plantarum americanarum. These plates were once glued to the wall by Linnaeus and are still present in the same position as he put them. In the adjacent bedroom the walls are covered with hand-coloured plates drawn by Ehret and published in the work Plantae selectae. Some of the plates carry his handwriting. Along the ceiling in the study there are several details that remain from Linnaeus’ scientific activities, such as paper images of different bird species glued on the ceiling spline, an oil-painting of his Coat of Arm placed above the entrance door, a personal proverb written above the bedroom door and oil-paintings of monkeys and a raccoon, animals that he kept alive for his studies. His writing chair remains in the room at a desk by the window, a place where he wrote many of his manuscripts. The whole atmosphere in this unique study gives a strong sense of presence of a scientist who managed to create an important development of systematic biology.

The large natural collection of Uppsala University, mainly gathered by Linnaeus and his scientific network, was threatened by a fire in 1766. He then built a special museum at Hammarby that would accommodate his own collections. After having moved his natural collections to Hammarby he had to go there also in the winter when he needed to study his natural collections. The building is beautifully preserved in an original state on the top of a hill on the property. The actual collections were sold to England in 1784 and are today managed by the Linnean Society of London as the world’s most treasured organism collection in systematic biology. However, the little empty museum in Hammarby and the collections are forever connected with one another. Left in the museum in Sweden is Linnaeus’ lecture chair and the student benches used in his private lectures. Outside the museum there is a flattened surface on the moraine hill, once made to create an outside lecture room. The museum is a unique scientific landmark from a time when systematic biology was founded and spread from this place to many countries in the world.

Hammarby is also the site where the strongest biological cultural heritage from the Linnaean era of systematic biology is to be found. The structures of botanical plantations, such as the Siberian garden, shrub quarters and single trees planted by Linnaeus remain relatively undisturbed. Two parterres in the main yard are reconstructed, and some perennials in the main garden remain where once planted. Almost 50 plant species have survived where once planted or naturalized within and around the property, some of the most striking are belladonna scopola Scopolia carniolica, Russian peashrub Caragana frutex, St Lucie cherry Prunus mahaleb, dog’s mercury Mercurialis perennis, barrenwort Epimedium alpinum, turk’s head lily Lilium martagon and Hammarby houseleek Jovibarba globifera. Some animals studied and described by Linnaeus and his students are still to be found on the property, such as the stild bees, for example Fabricius nomad bee Nomada fabriciana and a the Burgundy snail Helix pomatia. The surrounding area has recently become a cultural reserve, where 18th century agricultural methods will help expanding the once common, but now diminishing populations from the 18th century agricultural landscape. Examples of species that were common in the Hammarby landscape, but now rare are maiden pink Dianthus deltoids, wild thyme Thymus serpyllifolium and carline thistle Carlina vulgaris, species that Linnaeus used in his lectures in the fields.

Linnaeus had the possibility to try out planting experiments in his garden and in the surrounding farmland. The Hammarby estate was not as formalized as the Hortus Upsaliensis, and thus easier to use for dynamic planting. He focused on plants that would contribute to the economy of the country and help the single farmer to increase his outcome. He planted purple willow Salix purpurea in the fields as he wanted to use it to bind his oats. He built a Hortus Sibiricus to investigate whether plants from Russia could survive in Sweden and be of use in the poor northern part of the country. He also planted Siberian crab apple Malus baccata here to try out grafting and search for the original apple species.  The apple and willow are still growing in their original places.

The remote position of this property in the countryside in one of the least populated countries in the Western world, once the centre of systematic biology, thereafter left without larger reconstructions, presently with a high number of cultural entities remaining, puts Hammarby in a class of its own as a preserved cultural site and landmark of one single scientific field, the systematic biology.

The central part of Linnaeus’ property of Hammarby has been a museum since 1879 and is currently protected under Swedish law as a notable building (1935 and 1993). It is owned by the National Property Board, which manages it together with Uppsala University. The surrounding area is a cultural reserve since 2007 owned by Uppsala Akademiförvaltning and managed by the County Administrative Board of Uppsala.

Justification of Outstanding Universal Value

The areas of the proposed world heritage nomination named “The Rise of Systematic Biology” together represent a cultural and biological heritage that is unique in reflecting one of the scientific fields of basic need to humanity: systematic biology. To be able to pass on information on organisms important for our survival we are dependent on knowing the names of the organisms around us.

The transformation of the science of systematic biology was mainly due to the work of a single person, Carl Linnaeus. Because of this, the sites connected with this development are tightly linked with one another and reflect also the scientific network at the time. There are reasons to as why the biodiversity of these sites are well documented. Linnaeus taught and practised careful documentation as part of the observational methods that he linked to the science. Plant and animals specimens were carefully collected and preserved and are still available in the museums. Moreover, the extensive correspondence within Linnaeus’ network has been preserved to a large part, and is a great source of information.

The biodiversity of the selected places and historic man-made remnants, such as buildings, flowerbeds and greenhouses are mainly preserved because of their great scientific and cultural importance. Many of them have been protected by law for a century or more.

Every site has its own importance, but together they are of outstanding universal value. Included are the central sites of the scientific environment of Carl Linnaeus in Sweden. Some of the world’s most important collection sites at the time, in Asia, Australia and Africa, are included as are important representatives of the scientific network of botanical gardens. Some of these sites, like Jardin des Plantes in France and Botany Bay National Park in Australia, were important to the scientific development that continued after the Linnaean era, a development that became a prerequisite for the science of today and the radiation into several disciplines within biology.

The four sites in Sweden are unique in many ways by being the actual places where the scientific ideas were born by Linnaeus and the inner circle of his network. The preserved flora and fauna together form an outstanding trace of the scientific activities performed in the areas. The garden structures from the 18th century help the visitors to understand the historical context of the places. The two preserved homes, positioned in the traces of their 18th century gardens, show to a high degree Linnaeus’ scientific work and deed.


Satements of authenticity and/or integrity

Much of the authenticity in the sites of “The Rise of Systematic Biology” is found in extant populations of once studied plants and animals at the different sites. The discussion on authenticity of living organisms has been a vivid part of the science systematic biology due to the type concept. The compulsory assignment of a type specimen was introduced well after Linnaeus’ death. A type specimen is a collected individual that connects a name to a living organism, and thus connects the name to the population where the specimen once was collected and to its taxonomic unit. Accordingly, there has been a period from Linnaeus’ time and onwards when valid names were published, but no type specimen assigned. A demanding task for systematic biologists has therefore been to define which population the scientist referred to when a certain species was described and named. In the absence of specimens, extant populations known to have been studied by the author(s) of a name can then be collected and used.

Extant populations related to a certain specimens may be genetically related to the original organism in different ways. An organism in an extant population may be identical to the once studied individual if it is asexually propagated, i.e. cloned. More often, it is the result of a sequence of sexual propagations with several genetic recombinations involved.  The extant population should have a non-broken continuity in the area since the time when the first specimen was collected.

The sites in “The Rise of Systematic Biology” all have authentic populations with organisms related to those studied by the scientists who contributed to the initial development of systematic biology. Apart from the living material, authentic elements found on the sites are different garden structures, houses, roads and landscapes.

At the four Swedish sites the degree of integrity varies among the sites.

  In Råshult, the vegetation today is the same as that studied by the young Linnaeus. The flora has not been introduced to the area, but retrieved from the same populations that Linnaeus studied. The topology and geography is the same as in the 18th century and 18th century cultivation methods promote the historical flora and fauna. A few garden plants as kept by Linnaeus’ father still thrive. Elements in the farm yard and the main building are authentic.

The Linnaeus garden with the Linnaeus museum is authentic in its main structures, the plant material and elements in the house structures. The Linnaeus museum is filled with authentic furniture and objects and historic findings hidden in the double flooring have been made. The resurrected garden with its intricate teaching system gives a visitor the same experience as it gave a visitor in the 18th century.  The soil frequently reveals authentic objects from rubbish heaps continuously found in the area.

The Herbationes Upsalienses holds the largest amount of authentic populations identified by the protocols from the many excursions held there by Linnaeus and his students. Landscapes and structures of fields and meadows remain in some areas the same as in the 18th century. Due to the high degree of field studies in Uppsala since Linnaeus’ time, the continuity of the populations is possible to establish. Recently, as described above, material along the Herbationes trails have been selected as a neotype for a Linnaean name.

Linnés Hammarby is remarkably intact in many ways. Here we find Linnaeus’ study still as he left it during his lifetime, never inhabited since. The museum, once hosting the most important natural collection in the world, still stands intact on the property, surrounded by extant populations of species that Linnaeus included in the collections. The surrounding area is currently transformed into an 18th century agricultural landscape with a biodiversity of that time, enhancing rare species that were common when Linnaeus lived there.

Comparison with other similar properties

There is no other property on the World Heritage List that embodies the science systematic biology. “The Rise of Systematic Biology” is fully unique. The authentic populations and material structures present in the sites included are together a full representation of the foundation of systematic biology not able to find anywhere else.

Taken one by one, each area has its comparable site. Historic gardens like Kew Garden in the United Kingdoms and Orto Botanico in Padua, Italy, have a similar history part of the scientific history. However, none of these were directly involved in the initiation of systematic biology made by Linnaeus, and their unique values are based on other criteria.

There are some World Heritage Sites strongly connected to biological sciences, like the World Heritage Site Galapagos Islands in Ecuador, which were crucial for Charles Darwin’s formulation of the evolutionary theory. However, the science heritage of extant populations is not described in detail in the documentation nor used as authenticity. The islands have their unique values in the endemic species, not only species studied specifically by Darwin. Also the Table Mountain (part of the World Heritage Site Cape Floral Region), partner in “The Rise of Systematic Biology” is on the World Heritage List. However, it is the unique flora and fauna belonging to the Cape Floral Region that stands out as the main values of this site in the documentation.  In combination with the other sites in “The Rise of Systematic Biology” the scientific value of the site is emphasized.

In no site on the World Heritage List has extant populations been regarded as part of the authenticity of the property. This unique form of authenticity would be possible only for a scientific world heritage of a science focusing on a pan-global study of all organism groups, systematic biology.

VIKING MONUMENTS AND SITES / Birka and Hovgården (2011)

Part of transnational serial nomination

Birka N59 20 06 E17 32 33

Hovgården N59 21 36 E17 32 00

The Viking serial nomination comprises land-, sea- and townscapes stretching from the North Atlantic to the Baltic Sea. Among the thousands of Viking sites from the eighth to the twelfth centuries AD, these nine nominated properties from six nations are outstanding examples representing the wide diversity of this early maritime culture.

In the Viking Age the Norse peoples – the Vikings – developed a maritime culture which had an enormous impact on Northern Europe and beyond.  Within Scandinavia the Viking Period witnessed the transformation from tribal to state societies and a change of religions.  The three Christian kingdoms that developed from this transformation, and out of which the present Nordic States evolved, were by the end of the Viking Age an integral part of Europe.  Thus, in modern times, Viking culture has contributed significantly to the creation of cultural coherence, symbolic values and cultural identity in the Nordic region and it continues to hold immense public appeal world-wide.  This culture and its heritage developed in close interaction within a unique natural environment. It is composed of distinctive urban landscapes and monuments. The culture also produced one of the world’s great literatures: the Sagas, Eddic poetry and runic inscriptions.

Harnessing the technology of the ship, Nordic peoples used the sea for expansion, exploration, long-distance trade and overseas settlement.  The travels of the Vikings brought them across the Baltic Sea and down the Russian rivers as far as the Black and Caspian Seas to Byzantium and the Caliphate of Baghdad, as well as west out into the Atlantic.  They were the first to settle in Iceland and the first Europeans to reach Greenland and North America about 1000 AD.  In so doing, the Vikings were the first people to succeed in opening routes across the northern hemisphere from North America to Asia, thus connecting different cultural regions of the earth.  Adapted to very diverse types of natural environments, success was on the one hand in the use, and at times ecological misuse, of regional resources, and, on the other hand, in the development of social and political systems. This combination formed the basis for a rich cultural region.  Internally, Scandinavia witnessed an economic, religious and social transformation aided by a boom in internal and cross-cultural communication during the Viking period.  New institutions were developed, smaller regions were merged into larger units and the Scandinavians took part in European development on a larger scale.  Scandinavia at the time of King Knut, in the early 11th century, was vastly different from the Scandinavia that was visited by the missionary Ansgar in the early 9th century.

The component parts cover a wide temporal and spatial range. They are of exceptional quality and diversity. They include trading towns, harbours, defensive structures, production sites, burial monuments, and assembly sites. Viewed as a whole these sites bear witness to the extent of Viking social and cultural development.

DESCRIPTION OF COMPONENT PART

The archaeological site of the proto-town Birka and the nearby royal estate of Hovgården together form an almost unique site, the greatest and most impressive Viking-age site in Sweden and, perhaps, in Scandinavia. They lie on two islands in the lake Mälar, ca 30 km W of Stockholm.

The earliest known Christian congregation in Sweden is known to have been founded in Birka by St Ansgar in 831.

Birka on the western part of the ca 1,5 x 2 km big island Björkö is today visible through its hillfort, the town rampart and ca 3000 grave mounds on cemeteries surrounding the black Earth, the cultural debris with the remnants of the Viking-age settlement. Contemporary jetties and harbours lie along the shoreline.

Since 1931, the conservation programme for the site has restored the 19th century agricultural landscape, a prototype for all ancient monuments’ conservation in Sweden.

Birka is connected to the nearby Hovgården/Alsnöhus site on the Adelsö island. This Viking-age and medieval royal estate lies at the Adelsö church with a number of great mounds, a cemetery, a contemporary harbour with a runic stone and the foundations for a 13th century brick palace on the top of a built-up mound of soil.

The runic text mentions an 11th century king Håkon, his bailiff and the upplandic district Roden. The site is a well-known meeting-place for the medieval Royal Council which in 1279 decided here about the feudal system in Sweden.

Birka and Hovgården is the center of the unique and well preserved historical landscape of the Lake Mälaren area containing thousands of Viking Age settlements, visible cemeteries and several thousand rune stones. Hovgården is one of several Viking Age and Medieval royal manors whose importance in the administrative infrastructure is expressed in monumental burial mounds and cemeteries. Birka is a multi-cultural urban society and the center linking this region with the international network of market places and towns which began to be established under Carolingian leadership during the 700s. At Birka, raw materials such as furs and metals were collected for trade with Western Europe, and craftsmen from the Rhineland area established themselves as the suppliers of their products to Birka’s surrounding area. After the mid-800s, the eastern routes to Byzantium and Bagdad were opened and the Russian taiga zone became the main fur-producing area. Rich evidence of these eastern contacts is found both at Birka and Hovgården and in the graves in Birka’s large hinterland. Birka was part of an extensive social and economic infrastructure including Western Europe, the Caliphate and Byzantium which is expressed in weight systems and coinage.

Birka’s role as one of the most important early marketplaces/towns of this kind is expressed not least in the early urban legislation which is known in the Nordic area as Bjärköa- or Birkerätt (Bjärköa or Birke Law). Birka was also one of the first known targets for early Christian missions during the 800s through the work of Saint Anskar.

Justification of Outstanding Universal Value

The selection of sites bears an exceptional testimony to a unique cultural tradition in which the ship became the essential feature. Due to the natural environment of lakes, rivers and sea the use of waterways and the development of navigational skills had a long tradition. In the Viking Age ship technology was taken to a new level. Vikings were the first to settle in Iceland and the first Europeans to reach Greenland and North America about 1000 AD.  In so doing, the Vikings were the first people to succeed in opening routes across the North Atlantic to North America and eastward to the Russian Plain and Byzantium, connecting continents and cultural regions. Internally, Scandinavia witnessed an economic, religious and social transformation aided by a boom in internal and cross-cultural communication during the Viking period.  The component parts represent key attributes of Viking culture while the ship is the common feature throughout. In modern times, Viking culture has contributed significantly to the creation of cultural coherence, symbolic values and cultural identity in the Nordic region, and it continues to hold immense public appeal world-wide.  The component parts demonstrate clearly the key features; expansion, cultural communication and a strong narrative tradition past and present.

Satements of authenticity and/or integrity

Birka on the western part of the ca 1,5 x 2 km big island Björkö is today visible through its hillfort, the town rampart and ca 3000 visible grave mounds on cemeteries surrounding the black Earth, the cultural debris with the remnants of the Viking-age settlement. Contemporary jetties and harbours lie along the shoreline. Birka is connected to the nearby Hovgården/Alsnöhus site on the Adelsö island. This Viking-age and medieval royal estate lies at the Adelsö church with a number of great mounds, a cemetery, a contemporary harbour with a runic stone and the foundations for a 13th century brick palace on the top of a built-up mound of soil.

Comparison with other similar properties

The transnational project unites properties already appointed as Viking Age World Heritage with the newly nominated sites of Danevirke and Hedeby as well as Grobiņa, the Danish fortresses, the Vestfold burial mounds and Hyllestad quern stone quarry. They all rank among the most important historical places in the Viking Age and have moreover, as archaeological sites, contributed essential insights into Scandinavian culture of this period. In this period the Nordic region developed from being a peripheral zone of Europe to being an integrated component of the Christian West. Of exceptional value is the good condition of preservation displayed by the project’s combined monuments, ideally complemented by Old Iceland’s rich supply of written records and by other outstanding archaeological finds such as the ships from Gokstad, Oseberg and Roskilde. Corresponding nominations for the period between the 8th and the 12th century AD have to date not been represented on the World Heritage List.

For the component part:

Birka has to be seen against the context of the other emporia of this period, from Staraya Ladoga to Dublin. The only sites that are comparable with Birka in terms of degree of conservation and accessibility are Hedeby/Haithabu (Germany) and to a lesser extent Dorestad (Netherlands). Most of the others, such as Ribe, Aarhus, Hamburg, York, and Dublin, are beneath the existing towns and cities. The wealth and diversity of the material excavated at Birka indicates that it was one of the most important sites of this group.

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