Alconétar Bridge[A. 1] Puente de Alconétar | |
|---|---|
 Remains of the Alconétar Bridge with its flattened arches | |
| Coordinates | 39°45′14″N6°26′14″W / 39.753838°N 6.437345°W /39.753838; -6.437345 |
| Crosses | Tagus |
| Locale | Garrovillas de Alconétar,Cáceres Province,Extremadura,Spain |
| Heritage status | Listed ascultural heritage of Spain |
| Characteristics | |
| Design | Segmentalarch bridge |
| Material | Stone,Roman concrete |
| Total length | 290 m (950 ft) [incl. approaches] |
| Width | 6.55–6.80 m (21.5–22.3 ft) |
| Height | Minimum 12.50 m (41.0 ft) |
| Longest span | 15 m (49 ft) |
| No. of spans | Ca. 18 [incl. flood outlets] |
| History | |
| Designer | PossiblyApollodorus of Damascus |
| Construction end | Probably reign ofTrajan orHadrian (98–138 AD) |
| Location | |
 Interactive map of Alconétar Bridge[A. 1] | |
TheAlconétar Bridge (Spanish:Puente de Alconétar), also known asPuente de Mantible, was aRoman segmental arch bridge in theExtremadura region,Spain. Theancient structure, which featured flattened arches with a span-to-rise ratio of 4–5:1, is one of the earliest of its kind.[1] Its design suggests that the bridge was erected in the early 2nd century AD by the emperorsTrajan orHadrian, possibly under the guidance ofApollodorus of Damascus, the most famous architect of the time.[2]
The almost 300 m long Alconétar Bridge served as a crossing point for the RomanVia de la Plata, the most important north–south connection in westernHispania,[3] over theTagus, the longest river of theIberian Peninsula. It presumably remained in service until theReconquista, after which numerousearly modern reconstruction attempts by Spanish engineers failed. The ruins, which were mainly to be found on the right river bank, were relocated from their original position in 1970 when theAlcántara reservoir was created.
The historic Alconétar Bridge, which should not be confused with the monumentalAlcántara Bridge further downstream, spanned the Tagus not far from the mouth of theAlmonte, in the heart of the SpanishCáceres Province in the Extremadura region.[4] A modern motorway and a railway, which cross the Tagus in the immediate vicinity, underline the historical importance of this crossing point between northern and southern Spain.[4] During the building of the Alcántara Dam in 1970, the remains of the bridge were moved from their original site to a meadow six kilometers to the north, close to the municipality ofGarrovillas de Alconétar.[5] By contrast, few traces are left of the neighbouring ancient bridge over the river Almonte.[6]
In theclassical period, the Alconétar Bridge was part of theRoman roadIter ab Emerita Caesaraugustam, that was later calledVia de la Plata. This important inner Iberian connection led from the provincial capitalMérida in the south, through the river valleys ofAlagón, Tiétar and Tagus to the north, then on to the western part ofMeseta Central, passing the major town ofSalamanca.[7] Its terminal point wasAstorga in north-western Spain.[3] The Via de la Plata was one of the four main routes which were established byAugustus (30 BC–14 AD) and his successors for military control of the peninsula and for facilitating the exploitation of the rich Spanish silver and gold mines.[3]
Apart from the junction over the Tagus, the remains of four other ancient bridges can be found along the road: one over the Albarregas, another over the Aljucén, a third close to Caparra and a fourth over theTormes.[8] In the hills overlooking the Alconétar Bridge, a Romanmansio with the name ofTurmulus (Spanish: "Ad Túrmulos") was established, according to the then customary distance intervals.[6] It was the fourth of a total number of sixteen between Mérida and Astorga.[9]
The exact construction date of the Puente de Alconétar is unknown because of missing literary andepigraphic sources.[10] Its segmental arches suggest that it was built in the early 2nd century AD, more specifically during the reign of the emperors Trajan (98–117 AD) or Hadrian (117–138 AD), as the use of this arch form was typical of that era. Both rulers were born in the southern Spanish province ofBaetica and Trajan is known to have ordered the restoration of theIter ab Emerita Caesaraugustam when he came to power.[11] Segmental arches were often employed by Trajan's court architect Apollodorus of Damascus, such as inTrajan's Forum and most notably in the greatest civil engineering achievement of its time,Trajan's Bridge, which rested on twenty hugeconcrete piers and was used during theDacian Wars for moving troops across the more than 1,000 m (3,300 ft) wideDanube.[12]
Moorish geographers make no mention of the Alconétar Bridge, even though they praise theRoman bridge of Alcántara which also leads across the Tagus.[13] There is some evidence that a community called Alconétar, Alconétara or Alcontra (Arabic: "small bridge") existed at least temporarily – probably an indirect reference to the high-rising bridge of Alcántara.[6] It also remains unknown why the bridge of Alconétar is calledPuente de Mantible in the local vernacular, an expression which alludes to the legend ofCharlemagne and hisTwelve Paladins.[14]
The bridge was probably in use until the time of the Reconquista, when the Tagus constituted the border between theChristian and the Moorish realm from the 11th to the 13th century, and the frequent clashes might have easily made the ancient bridge unusable.[15] According to another theory, the water could have begun to wash away the ancient foundations at the time.[15]
The Alconétar Bridge first appears in records in 1231 and, again, in 1257, when it is explicitly referred to as being in use.[16] It was probably repaired by theKnights Templar who had taken control of the bridge as well as the village in the meantime.[16] The extant arches 1 and 3, both of which are not of Roman fabric, are assumed to date back to this period.[16] Around 1340, however, the bridge was apparently unusable again, so that a ferry service was established to cross the river, which is also recorded at later times.[16] On the site of the ancient way station, a fortress was erected in theMiddle Ages;[17] its tower built of Romanspolia emerges from the Alcántara reservoir at low water.
Several attempts to reopen the bridge in the early modern era proved unsuccessful. In 1553, the architectRodrigo Gil de Hontañón calculated a cost of 80,000Ducats for the reconstruction of the bridge without ever realising his plans. The construction project of Alonso de Covarrubias and Hernán Ruiz of 1560 never went beyond the planning stage, and neither did another project between 1569 and 1580.[7]
In the 18th century two further attempts to repair the bridge failed, in 1730 and 1760–70. The latter plan of the military engineer José García Galiano included a complete reconstruction with three large-span segmental arches. The planning sketch shows that already at that time the remaining arches were limited to the right bank, a finding confirmed by the drawing of Fernando Rodríguez from 1797 and engravings inAlexandre de Labordes'Voyage pittoresque de l'Espagne a few years later.[7] The reconstruction sketch produced by Rodriguez (see diagram below) shows the profile of the bridge, rising evenly and dominated by three central arches in the centre of the river. These arches are flanked by a further nine segmental arches on both sides. The symmetry of the arches suggests that, in lieu of the fortification on the right bank viewed upstream, there might have been another segmental arch in Roman times.[18]
The basis for the modern scientific analysis of the bridge was laid out by the civil engineer Antonio Prieto in his 1925 survey, which details the condition of the bridge before its relocation in 1970. Although this was a serious attempt to reconstruct the bridge as close to the original as possible, the Spanish scholar Durán points out that slight changes to the main body can never be avoided in the course of such a difficult undertaking.[19]
The Alconétar Bridge has been classified as "historical heritage" since 1931 by the Spanish authorities.[20]
Main feature of the Alconétar Bridge was the segmental shape of its arches,[21] which were rather uncommon in ancient bridge building: in a survey of Roman bridges in Hispania, only one in ten showed the same characteristics, the vast majority being of semi-circular design.[22] According to Prieto, the bridge had sixteenarches, not including theflood openings on the right approach, with the following spans (estimates are in square brackets):
Other sources however vary from eleven to fifteen arches.[23] The total length of the rectilinear structure was 290 m (950 ft), of which 190 m (620 ft) spanned the riverbed at low water.[6] If one adds the clear span of the arches and assumes, on the basis of the preservedpiers, an average pier thickness of 4.4 m (14 ft), then the distance between both bridge ramps was 244 m (801 ft) (= 178 + 15 x 4.4), which corresponded to a river cross section of 73%.[5] By comparison, the corresponding discharge profiles for the Roman bridgesof Córdoba,of Mérida andSalamanca were 62%, 64% and 80% respectively.[24]
Most of the surviving fabric was concentrated on the right bank of the Tagus where the current was less strong; a number of pier stumps rose just above the water surface in the middle of the river, whilst on the left bank a further two piers remained standing, next to which the leftabutment followed.[25] The parts of the bridge moved to a safe place were essentially (see images): the right bridge ramp with its two arch-shaped flood openings, the piers 1, 2, and 3 with the remains of 4 and 6, as well as thevaults 1 and 3.[5] The other scarce remains were submerged by the flooding of the Alcantara reservoir in 1970.[26]
The approach to the ramp is 42 m (138 ft) long and 6.55–6.80 m (21.5–22.3 ft) wide.[23] The clear spans of its two segmental arches are 6.95 m (22.8 ft) and 7.40 m (24.3 ft),[23] which corresponds to a span-to-rise ratio of 4.0 and 3.3 to 1 respectively.[27] The accurately fitting inclined contact surface of the springings clearly proves the Roman origin of these arches.[28] With an extraordinary width of 1.20 m (3 ft 11 in), thevoussoirs appear oversized in relation to the span (arch slenderness of 1:5.8 and 6.2 respectively).[23] In contrast, the two surviving bridge arches no. 1 and 3 are instable substitutions, made of carelessly laid rubble.[29] The date of these arches is unknown, as with all other repairs; possibly they were built in the period of the Knights Templar.[16]
Equally evidently of post-classical origin is the masonry of the first two piers above the lowercornice, which projects from all piers at the same height.[30] The superstructure of these piers could have been reconstructed for adrawbridge[30] or a tower, which, according to an illustration in theVoyage Pittoresque, rested upon pier 2.[17] In contrast, the third pier has still preserved its original Roman character up to the top at 12.50 m (41.0 ft). Its carefully workedashlar and the second cornice, which ran along all ancient piers, provide us with the most distinct impression of the original shape of the Roman bridge.[31]
In particular, it is possible to reconstruct relatively precisely the rise of the Roman segmental arches on the basis of the angles of the inclined stone supports at thespringing level.[17] Thus, the third arch originally described acircular sector of 95°,[23] which points to a span-to-rise ratio of about 4–5 to 1 for the other segmental arches.[17] This value is supported by de Labordes' engravings which depict an intact Roman segmental arch spanning the adjoining fourth bay as late as the early 19th century.[30] Along with other early examples, such asLimyra Bridge and thePonte San Lorenzo, the Alconétar Bridge therefore ranks among the oldest segmental arched bridges in the world. Its existence demonstrates that, in contrast to what had previously been widely believed and taught, Roman bridge builders possessed intimate knowledge of flattened arches.[32]
The pier thicknesses, measuring 4.25 m (13.9 ft), 4.45 m (14.6 ft) and 4.55 m (14.9 ft), increase slightly towards the middle of the river, while the distances between the piers increase from 7.30 m (24.0 ft) to 10.20 m (33.5 ft).[18] The fifth and ultimate pier, which carries the distinctive nickname "Bishop's table", takes an advanced position in the riverbed and possesses by far the largest cross-section (8.10 m (26.6 ft)). It may be of medieval origin and could have served as a base for a watchtower, replacing two ancient arches.[33] All five piers are strengthened on the upstream face by pointedcutwaters.[34]
The facing of the piers consists of localgranite ashlar, set in parallel courses without the use ofmortar or iron ties (opus quadratum); their interior, as those of the ramps, was filled withRoman concrete, a common method applied for Roman bridges.[35] Outwardly, the flattened arches must have lent the bridge a rather elongated appearance, with its roadway following a horizontal or slightly convex line.[36]
| Bridge part | Galiano (ca. 1770) | Rodríguez (1797) | Prieto (1925)[A. 2] | Durán (2004)[A. 3] |
|---|---|---|---|---|
| Span 1st floodway | 6.86 m (22.5 ft) | 7.04 m (23.1 ft) | 7.00 m (22.97 ft) | 6.95 m (22.8 ft) |
| Ramp thickness | 10.60 m (34.8 ft) | 11.63 m (38.2 ft) | 12.00 m (39.37 ft) | 14.00 m (45.93 ft) |
| Span 2nd floodway | 7.40 m (24.3 ft) | 7.10 m (23.3 ft) | 7.50 m (24.6 ft) | 7.40 m (24.3 ft) |
| Ramp thickness | 12.90 m (42.3 ft) | 11.65 m (38.2 ft) | 13.00 m (42.65 ft) | 13.50 m (44.3 ft) |
| Span 1st arch | 7.50 m (24.6 ft) | 7.62 m (25.0 ft) | 7.30 m (24.0 ft) | 7.30 m (24.0 ft) |
| Thickness 1st pier | 5.60 m (18.4 ft) | 4.17 m (13.7 ft) | 4.25 m (13.9 ft) | 4.25 m (13.9 ft) |
| Span 2nd arch | 9.00 m (29.53 ft) | 8.44 m (27.7 ft) | 8.20 m (26.9 ft) | 8.10 m (26.6 ft) |
| Thickness 2nd pier | 5.60 m (18.4 ft) | 4.19 m (13.7 ft) | 4.25 m (13.9 ft) | 4.45 m (14.6 ft) |
| Span 3rd arch | 9.86 m (32.3 ft) | 8.92 m (29.3 ft) | 8.95 m (29.4 ft) | 8.50 m (27.9 ft) |
| Thickness 3rd pier | 5.50 m (18.0 ft) | 4.21 m (13.8 ft) | 4.25 m (13.9 ft) | 4.55 m (14.9 ft) |
| Span 4th arch | 10.10 m (33.1 ft) | 10.32 m (33.9 ft) | 10.15 m (33.3 ft) | 10.20 m (33.5 ft) |
| Thickness 4th pier | 4.81 m (15.8 ft) | 4.80 m (15.7 ft) | ||
| Span 5th arch | 12.03 m (39.5 ft) | 11.00 m (36.09 ft) | ||
| Thickness 5th pier | 6.21 m (20.4 ft) | |||
| Span 6th arch | 16.72 m (54.9 ft) | 12.00 m (39.37 ft) | ||
| Thickness 6th pier | 6.21 m (20.4 ft) | |||
| Span 7th arch | 8.92 m (29.3 ft) | 13.00 m (42.65 ft) | ||
| Thickness 7th pier | 6.21 m (20.4 ft) | |||
| Span 8th arch | 16.74 m (54.9 ft) | 14.00 m (45.93 ft) | ||
| Thickness 8th pier | 6.21 m (20.4 ft) | |||
| Span 9th arch | 11.93 m (39.1 ft) | 15.00 m (49.21 ft) | ||
| Thickness 9th pier | 4.79 m (15.7 ft) | |||
| Span 10th arch | 10.22 m (33.5 ft) | 14.00 m (45.93 ft) | ||
| Thickness 10th pier | 4.19 m (13.7 ft) | |||
| Span 11th arch | 8.82 m (28.9 ft) | 13.00 m (42.65 ft) | ||
| Thickness 11th pier | 4.19 m (13.7 ft) | |||
| Span 12th arch | 8.38 m (27.5 ft) | 12.00 m (39.37 ft) | ||
| Thickness 12th pier | 4.19 m (13.7 ft) | |||
| Span 13th arch | 11.00 m (36.09 ft) | |||
| Thickness 13th pier | ||||
| Span 14th arch | 10.00 m (32.81 ft) | |||
| Thickness 14th pier | ||||
| Span 15th arch | 9.30 m (30.5 ft) | |||
| Thickness 15th pier | ||||
| Span 16th arch | 9.10 m (29.9 ft) |
{{citation}}: CS1 maint: location missing publisher (link)
Media related toAlconétar Bridge at Wikimedia Commons
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| Geographic | |
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39°45′14″N6°26′14″W / 39.753838°N 6.437345°W /39.753838; -6.437345
