Aqua Virgo


The Aqua Virgo was one of the eleven Roman aqueducts that supplied the city of ancient Rome. The aqueduct fell into disuse with the fall of the Western Roman Empire, but was fully restored nearly a millennium later during the Italian Renaissance to take its current form as the Acqua Vergine. The Aqua Virgo was completed in 19 BC by Marcus Agrippa, during the reign of the emperor Augustus. Its source is just before the 8th milestone north of the Via Collatina, in a marshy area about 3 km from the Via Praenestina. It was also supplemented by several feeder channels along its course. The name is thought to be derived from the purity and clarity of the water because it does not chalk significantly. According to a legend repeated by Frontinus, thirsty Roman soldiers asked a young girl for water who directed them to the springs that later supplied the aqueduct; Aqua Virgo was named after her.
Along its more-than-20 km length, the aqueduct dropped only 4m to reach Rome in the centre of the Campus Martius. At its height, the aqueduct was capable of supplying more than 100,000 cubic metres of water every day. The aqueduct ran underground for nearly all of its length except the last stretch of 1,835m running on arches in the Campus Martius area, of which one section remains in via del Nazzareno. Claudius renovated it 46 AD as witnessed by an inscription on the architrave which states that he rebuilt large sections of the aqueduct at this point because Caligula had removed stone for use in constructing an amphitheatre.
In 537 CE, the Goths besieging Rome tried to use this underground channel as a secret route to invade Rome according to Procopius. After deteriorating with the fall of the Western Roman Empire, the Aqua Virgo was repaired by Pope Adrian I in the 8th century. In 1453, Pope Nicholas V made a complete restoration and extensive remodelling from its source to its terminus points between the Pincio and the Quirinale and within Campo Marzio and consecrated it Acqua Vergine. This also led the water to the Trevi Fountain and the fountains of Piazza del Popolo, which it still serves today. In the 1930s, a pressurised version was built, the Acqua Vergine Nuovo, separate from the other channels. The aqueduct can be visited below the Spanish Steps and the Villa Medici, where a spiral staircase in perfect condition still leads to the underground conduit.

Written sources on ancient Roman aqueducts

, a Roman architect who worked for Caesar and Augustus, wrote the De Architectura, or in English, On Architecture. One concept contained in the De Architectura is that the quality of an architectural work depends on the social relevance of an artist’s work, not the form or workmanship of the work itself. Another assertion from Vitruvius is that a structure must exhibit the three qualities of firmitas, utilitas, and vinustas.
Sextus Julius Frontinus wrote the Aqueducts of Rome which is a study of the water supply of the Roman Empire. He points out that the welfare of the urban community of Rome depends on the quality of the water supply.

Route through Rome

Much research has been done on the aqueducts of ancient Rome, primarily to chart the course of these aqueducts from their sources in Rome and secondarily, tracing their routes from the points of entry to the terminal distribution centers or castella. Complementing the aqueducts already in use not only in terms of geographical distribution but also in functions served, the Aqua Virgo was one of the most specialized main aqueducts of ancient Rome. The Aqua Virgo entered the city from the north over the Pincian and ran 700 paces from a point of entry under the Horti Lucullani to a place in the Campus Martius in front of the Saepta Julia. Easily being traceable today, the 700 paces spanning arches starts in the triangle formed by the modern-day streets of Capo le Case, Due Macelli, and South Giuseppe. From this point, it ran to the Trevi Fountain where it then turned westward and crossed the Via Lata at the Palazzo Sciarra. Crossing many arches from this point still more arches were discovered in 1871 even though Frontinus wrote that they ended at the Saepta, also short of the 700 paces he described for their length. After later interpretation, it has been found that the aqueduct’s arches did continue along the Via del Seminario to a point east of the Pantheon.
During the 17th century extensive lead piping was found in front of the church of Saint Ignazio where many believed this to be the terminal distribution for the aqueduct although this theory has since been put to scrutiny in the light of recent evidence. Due to the main reasons for the Aqua Virgo of supplying Agrippa’s baths as well as supply water to the inadequately served regions VII, IX, and XIV in the city of Rome the aqueduct continued beyond the Pantheon and the baths. The water was carried across the bridge of Agrippa after it was first transported from the low area of the Campus Martius over the higher ground of the ridge surrounding the Pantheon basin by using the baths drainage system as well as the Stagnum and the Euripus where it was drained into the Tiber River.

Construction tools

Levels

Besides standard water levels similar to those used by contractors today, other kinds of levels were in use during ancient Roman times.
Vitruvius explains that while the chorobates may seem to be superior to the dioptra in a project such as the aqueducts, the chorobates is not immune to wind disturbing the plummets on the device the dioptra and water levels were immune to this.
Many lifting tools would have been in use during the Roman times in the construction of temples, tall buildings, bridges, and arches to move large stone blocks and materials from for example a quarry to the job site and then lifted into place.
It is to be made of bronze. The lower part consists of two similar cylinders at a small distance apart, with outlet pipes. These pipes converge like the prongs of a fork, and meet in a vessel placed in the middle. In this vessel, valves are to be accurately fitted above the top openings of the pipes. And the valves by closing the mouths of the pipes retain what has been forced by air into the vessel. Above the vessel, a cover like an inverted funnel is fitted and attached, by a pin well wedged, so that the force of the incoming water may not cause the cover to rise. On the cover of the pip, which is called a trumpet, is jointed to it, and made vertical. The cylinders have, below the lower mouths of the pipes, valves inserted above the openings in their bases. Pistons are now inserted from above rounded on the lathe, and well oiled. Being thus enclosed in the cylinders, they are worked with piston rods and levers. The air and water in the cylinders, since the valves close the lower openings, the pistons drive onwards. By such inflation and the consequent pressure, they force the water through the orifices of the pipes into the vessel. The funnel receives water and forces it out by pneumatic pressure through a pipe. A reservoir is provided, and in this way water is supplied from below for fountains.

Construction

Most of the ancient aqueducts were gravity systems, that is by ensuring the source was higher than the termination and plotting a uniform course for the aqueduct to follow a downward gradient, gravity would provide all the power needed for the water to flow. The aqueducts were for most of their length, channels about 50 cm to one meter below ground, tunnels, and pipes and only the final stretches of the aqueducts used arches. The channels were made of three kinds of material, masonry, lead pipes, and terracotta. These channels were made using a “cut and cover” technique where the channel path was cut into the ground and then covered in order to easily access the channels that were in need of repair. The floors and walls of the channels were lined with cement and the roof was usually a vault. The cement was usually as high as the water would reach, which was meant to be about a half to two thirds full. Lining the walls and floor with cement served three purposes, protect against leaks and seepage, to provide a smooth contact surface, and to make the contact surface continuous and joint free from one end to the other.
In order to maintain the slight downward gradient, the aqueducts didn’t follow a direct route to Rome but instead used the lay of the land. Typically, the gradient was shallow to make the water flow slower so less repairs would be needed due to quicker water flows causing damage and too shallow of a gradient meant that the water would not flow at all. Different degrees of gradient were used for different reasons. While traveling through a tunnel for example, a steeper gradient could be used to speed up water flow. Since inside the tunnel repairs were less likely to be needed the water could flow at a higher rate requiring a steeper gradient and then once through the tunnel the gradient would need to increase in order for the water to be slowed back down to its average speed. In later times, the use of high arches across valleys and plains were employed for the aqueducts and some were even as high as 27m off the ground.

Costs

The aqueducts at first were financed mainly through wealth collected from war and the patronage of wealthy individuals. Taxes also served to help finance the building by taxation on conquered people because the aqueducts were never meant to pay for themselves but serve as a benefit to the people of Rome. In Republic times the private use of aqueduct water was not common, only the overflow water was sold to individuals. In Imperial times the construction of more aqueducts meant that more water was available to be sold for private use.

Locating the source

The source of the water was an empirical science in that when the source was obvious such as a spring, lake, or stream, the engineer had to determine the quality of the water. The engineer had to test the taste, clarity, and flow of the water as well as the physique and complexity of the local people who drank it. Soils and rock types were also used as indicators. Clay was regarded as a poor source while red tufa was considered pure.

Acqua Vergine

The Acqua Vergine is the Renaissance restoration of the Aqua Virgo aqueduct. In 1453, Pope Nicholas V renovated the main channels of the Aqua Virgo and added numerous secondary conduits under Campo Marzio. The original terminus, called a mostra, which means showpiece, was the stately, dignified wall fountain designed by Leon Battista Alberti in Piazza dei Crociferi. Due to several additions and modifications to the end-most points of the conduits during the years that followed, during the Renaissance and Baroque periods, the Acqua Vergine culminated in several magnificent mostre - the Trevi Fountain and the fountains of Piazza del Popolo.

Courses

Two separate aqueducts emerge from the source for the Acqua Vergine unlike the Aqua Virgo:
Today, as in days of old, the Acqua Vergine is regarded to furnish some of the purest drinking-water in Rome, reputed for its restorative qualities. Many people to this day can be seen filling containers for drinking and cooking in its splendid fountains, including: