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New and multidisciplinary methods investigating Roman water management: aqueducts and castella in Rome and Pompeii - G. Wiplinger, ed. 2020. De aquaeductu urbis Romae. Sextus Iulius Frontinus and the Water of Rome: Proceedings of the International Frontinus Congress Rome, November 10–18, 2018. Babesch Supplementa 40. Leuven: Peeters. Pp. xxxiii, 403. ISBN 978-90-429-4311-7.

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G. Wiplinger, ed. 2020. De aquaeductu urbis Romae. Sextus Iulius Frontinus and the Water of Rome: Proceedings of the International Frontinus Congress Rome, November 10–18, 2018. Babesch Supplementa 40. Leuven: Peeters. Pp. xxxiii, 403. ISBN 978-90-429-4311-7.

Published online by Cambridge University Press:  29 August 2023

Duncan Keenan-Jones*
Affiliation:
University of Manchester
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Abstract

Type
Book Review
Copyright
Copyright © The Author(s), 2023. Published by Cambridge University Press

This volume presents the proceedings of the most important conference in studies of ancient Mediterranean water systems (given that the Cura Aquarum conference seems in abeyance), held only once every four years or so. Hence it represents a vital overview of recent work in the field. For reasons of space, this review will focus on the water supply of Rome (the conference's focus) and Pompeii.

The book starts with Anthony Jennings's gripping speculation about the assassination of Domitian and its aftermath, including the possible involvement of Frontinus (“Gods of Blood and Water: Frontinus and the Dead of Domitian,” 3–12). This is a novel and refreshing start to an academic volume. Then, in “The Aqueducts of Rome: Principles of Water Supply and Questions of Research” (53–64), Jens Köhler gives a succinct introduction to ancient Rome's water supply (useful for those with or without previous knowledge of the topic), which outlines the future possibilities and challenges. He highlights how dramatically the Aqua Marcia improved on those aqueducts that had gone before and outlines the many dangers these aqueducts faced: urban development, earthquakes, the ravages of time. Köhler interprets the increase in Tiber flooding during the Roman warm period as solely due to human impact, as he believes this to have been a predominantly dry period. While temperature reconstructions are broadly applicable across large areas of the Mediterranean, as Jennings's Table 1 (57) suggests, rainfall shows much more local variation. Surveys of recent research into cave and lake indicators (or proxies) of past rainfall have shown opposite rainfall trends in the northern (drier) and southern (wetter) Mediterranean.Footnote 1 The lack of rainfall proxies for central and southern Italy means it is not clear where the Tiber Basin falls between these two trends.Footnote 2 It was not clear to me how determining the number of aqueducts constructed could assist here, given that they seem often not to represent vital drinking water supply, but I agree that limestone deposits, called travertine or sinter, have promise. It is true that these deposits are more likely from aqueducts supplied by springs than by lakes, but we do see some spring-fed aqueducts without travertine (such as Rome's Aqua Virgo) and some river-fed aqueducts with travertine (such as Rome's Anio Novus and Vetus).Footnote 3 Köhler provides an excellent case study of the Aqua Alexandrina, with new information based on his own fieldwork. I would specify here the other possible identification of this aqueduct as the Aqua Antoniniana.Footnote 4 Köhler closes by alluding to travertine ripples and waves that can yield information about water speed and flow rate. The justification and details of this calculation have recently been published,Footnote 5 allowing its application to the Aqua Alexandrina if such waves can be found.

Luca Messina, Mauizio Pagano, and Riccardo Ribacchi (“In the Footsteps of Ashby: Colle Papese in the Tivoli Area,” 65–74) are properly cognizant of both the usefulness and limitations of Ashby's pioneering work on the Roman aqueducts, providing new data on a difficult stretch of ancient Rome's four Aniene aqueducts. The detailed fieldwork of Sotterranei di Roma (continuing on from previous publicationsFootnote 6) has turned up remains not found by Ashby, as well as rediscovering a lost Augustan cippus, in a welcome tale of increasing rather than decreasing evidence since Ashby's time. This work promises to solve the thorny problem of the attribution of sections to these aqueducts.

Edoardo Gautier di Confiengo and Elettra Santucci (“The Distribution of Aqua Claudia and Anio Novus in Rome,” 85–100) present an interesting piece on the distribution of the water of the Aqua Claudia and Anio Novus aqueducts within the city, based on thorough research in the literature coupled with field observation. Santucci's Figure 2 (p. 86) is a very useful depiction of the estimated distribution network. As a minor quibble, I would argue that the authors take too little consideration of the problems with Frontinus's measurements of the flow rate (quinariae),Footnote 7 particularly in aqueduct channels, but they present interesting reconsiderations of Frontinus's (and other) evidence elsewhere (e.g., in relation to the terminal castellum of the Anio Novus). This chapter is full of interesting new ideas and hypotheses to be tested, perhaps by analysing the composition of carbonate deposits in some of the cisterns mentioned and linking them to different aqueducts.Footnote 8 It will help chart the course for future study of water distribution within the city of Rome. On the basis of elevations, the authors argue that the Aqua Claudia or Anio Novus supplied the Nymphaeum Alexandri and Baths of Diocletian, and the arcades leading to them, rather than the Julia, Tepula, and Marcia. In particular, the chapter considers the nodes that linked the masonry aqueduct channels to the lead pipe distribution system, the castella aquae. Gautier di Confiengo and Santucci present a useful classification system that can be applied elsewhere. They divide castella into two main categories: those that connect the aqueduct channel to a reservoir and those whose function is purely distribution, containing no reservoirs (castella divisoria). The first category is further divided into three different classes:

  1. 1. lateral, which run alongside the aqueduct, divert part of the flow, store it and distribute it to pipes, and send the remaining flow back into the main aqueduct channel

  2. 2. terminal, which take all of the flow from the end of the aqueduct and distribute it to a piped distribution system, and

  3. 3. axial, which are on the main axis of the aqueduct, i.e. which take all the flow of the aqueduct and distribute it to the piped system and aqueduct channels.

Gautier and Santucci also give a general reconstruction of either an axial (most likely) or else a lateral castellum (Figure 5, where it is labelled a terminal castellum, but this cannot be right, according to their classification, as it sends some water back to an aqueduct channel). I wonder, however, if the pipes would often leave from the very base of the structure, since this would meant that the water could only rise to the water level of the lowest tank (no. 5 in their diagram). At times of high demand relative to supply, this would be near ground level, sacrificing the height maintained over nearly 100 km of aqueduct channel at the cost of hundreds of millions of sesterces. Perhaps we should imagine pipes also coming from the higher tank, no. 3, with their own valve, to preserve onward supply to the next castellum? It could be that pipes in A1–4 in the Vigna Belardi cistern actually supplied major or elevated structures nearby (such as nymphaea), rather than Room 1, under pressure, as the authors suggest for the “disappeared” castellum on the Esquiline (92–93). Further structures that would fit Gautier di Confiengo and Santucci's castellum schema are two cisterns at the upstream and downstream ends of the Parco Tor Tre Teste.Footnote 9 If these were castella and not just cisterns, they must have served the Aqua Antoniniana/Alexandrina (see discussion of the Köhler chapter above). Similarly, the Villa delle Vignacce cisternFootnote 10 may have been a castellum serving the Aquae Julia, Tepula, and/or Marcia. Both of these cisterns are much further from the city than those described by Gautier and Santucci, however, which may be evidence of considerable distribution of water to suburban properties, already suggested by Wilson.Footnote 11

Staying with distribution systems, Richard Olsson presents the results of work in progress involving his calculations of flow rates within the best-preserved system from the Roman world: Pompeii (“Aqueduct Water-Supply System in Pompeii,” 103–8). He estimates flowrates along the mains pipes running from the terminal castellum (to use Gautier di Confiengo and Santucci's classification) to the water towers (castella divisoria). Despite the well-preserved nature of Pompeii's system, almost all these mains pipes are missing and their size must be estimated, as must the functioning heights of the water towers, which have been damaged. Several further issues could be raised with Olsson's reconstruction. He has three mains pipes leading from the castellum to match the three holes leading from the castellum. Archaeological excavations in front of the castellum revealed only two trenches, however, for mains pipes. Mauri earlier suggested that a mains pipe from the central hole could have shared a trench with one of the two other mains pipes but also thought it likely that the central hole supplied a fountain immediately below it.Footnote 12 In addition, Olsson includes all water towers known in 2018 (and not the water tower in Regio V discovered in 2019, of course), but not all these water towers seem to have been operating at the same time.Footnote 13 All these issues introduce considerable uncertainty into Olsson's estimates. The uncertainty is not yet quantified, but he is prudent in rounding to the nearest whole number. Olsson stresses the importance of balance between inlets and outlets of the castella divisoria to avoid overflow from the tanks (inlet flow too large) or reduced supply to end users (inlet flow too small). It is very likely, however, that overflow did occur, since considerable carbonate deposits (travertine) have been left behind by evaporating water running down the side of the majority of water towers that supported the tanks (see Table 1 below), and this is unlikely to have been caused by leaks alone. Unless the outlets from the tanks (which are unknown) were much more restrictive of flow than the pipe roughness, at times the flow from the mains pipes into the tanks must have been greater than the outflows. The only water towers where little or no travertine is found are 5 (trace), 10, 11, 12 (trace), 13, and perhaps 6 (although this is unclear as it has been damaged and reconstructed in modern times). Towers 12 and 13 were probably out of use at the time of the eruption.Footnote 14 All the towers lacking travertine are located at the downstream end of the system, suggesting that, by this point, so much water had been drawn off upstream that demand was significantly outstripping supply. Recent work can be integrated here to investigate this balance. Monteleone and her co-authors have recently performed similar estimates of flow rate at the next stage downstream compared to Olsson's work: from the water towers to the public fountains,Footnote 15 using the same tower heights as Olsson, and from the water towers to two of the roughly 91 houses suppliedFootnote 16 by the piped system.Footnote 17 They have estimated the roughness of different pipes (an important factor in estimating the flow rate inside them) using endoscopy, microscopy, and laboratory experiments on preserved Roman pipes, yielding absolute roughness estimates of 0.1–0.5 mm. In this chapter, Olsson has not published details of his calculations, including roughness, so it is difficult to know if the two studies are comparable. The inflows and outflows (Olsson's mains, and the means and minima of Monteleone et al.'s fountains) for each water tower are shown in Table 1.

Table 1. Balances of input and output water flow capacities for the castellum, each water tower, and Pompeii's water system as a whole. (* Negative values represent greater output capacity than input capacity, where overflow of the tank should never happen; ** That is, total distribution system input).

Both input and output flow estimates represent the capacity of the pipe. It is clear that under Olsson's estimated mains inputs, the output capacities of mains pipes (Olsson) plus fountain and two house pipes (Monteleone et al.'s means) for towers 1, 3–12, and 14 would never be reached, let alone if the output capacity of pipes leading to baths and the further 89 or so private properties were added, as well as (for towers 3 and 5) unestimated mains pipes leading to unexcavated parts of the city. Thus, only at fountain 2, and possibly 13, depending on other outputs, should there ever be overflow. Given that travertine shows there was overflow in many more towers in the upstream system, there are a number of possible explanations:

  1. 1. The sizes of the pipes were different (during some periods at least) from those assigned in the calculations;

  2. 2. Taps were used at certain times to shut off some of the outflows from water towers with travertine; and/or

  3. 3. Olsson is using a larger roughness than Monteleone et al., decreasing Olsson's capacities.

There is a large discrepancy in the overall water system balance, considerably more than the combined output of the castellum, which represents the inflow into the system. The maximum sizes of the castellum outflow pipes are constrained by the holes in the castellum wall, so explanation 1 above would not improve this system imbalance and is less likely to explain the imbalance for so many individual water towers. Even where Monteleone's minimum pipe size and flow rate values are used (Table 1), the situation does not appreciably change. There are still many towers with substantial travertine deposits with negative or small positive balances where overflow shouldn't happen. Explanation 2 is very possible, given the large number (112) of taps found in Pompeii,Footnote 18 even if they weren't used so much to store water as to divert it.Footnote 19 We look forward to the full publication of Olsson's calculations to judge explanation 3, although, even here, a reduced roughness would also increase Olsson's mains pipes outflows to some degree. I suspect that he is underestimating the flows into the piped system and hence into each water tower, by choosing a roughness that is too large. I would also argue that balancing inflows and outflows in Pompeii's water system was not as important as he argues. There was likely storage of water in public and private castella at times of low demand, especially in the last phase of the city's water supply,Footnote 20 particularly if flow rates were as low as Olsson estimates.

Paul Kessener (“Frontinus’ Quinaria and Direct Discharge,” 321–32) addresses the thorny problem of the value of the quinaria and ancient measurement of flow rate. After reviewing previous approaches to the problem, Kessener makes many useful fluid mechanical observations regarding Roman measurement of flow rate, quinariae and castella divisoria, leavened with a thorough knowledge of post-Roman, pre-modern practice. He finishes with a novel mechanism that could have been used by ancient aquarii to measure flow rate, joining others conjectured by Blackman, Hodge, and Taylor:Footnote 21 a box with quinaria-sized orifices.

Charles R. Ortloff (“The Pont du Garde Aqueduct and Nemausus (Nîmes) Castellum: Insight into Roman Hydraulic Engineering Practice,” 333–48) also considers the castellum divisorium, both optimized and the example found at Nîmes, from a fluid mechanical point of view, while Jan Pieter Lubbers (“Planning and Building Aqueducts of Ancient Rome without the Use of Surveying Instruments,” 349–60) considers the surveying and construction of Rome's Anio Vetus aqueduct in depth. The volume also considers systems supplying Taurmenion, Split, Parion, Ephesus, Syedra, Gerasa, Sepphoris, and the province of Africa, as well as including sections devoted to Roman toilets, and chapters on wastewater in Ostia and water machines in medieval Arabic texts.

The quality of the contributions is variable but generally good. Some chapters were in need of further editing; for example, the otherwise welcome contribution by Cinti (“The Aqua Alsietina: An Unknown Aqueduct with the Worst Water in Rome: Resources and Instruments for a Correct Analysis and Interpretation of the Aqueduct,” 75–84) on the neglected Aqua Alsietina could have done with a little more peer review and editing to clarify the language and argument (e.g., Frontinus is said to refer to the Aqua Traiana; CIL VI.1261 describes “for certain” irrigation for private individuals from the Alsietina, when a more nuanced discussion is needed hereFootnote 22). The English of many contributions could be more idiomatic, but the meaning is almost always clear, and the authors’ facility with what for many of them is a second language is impressive.

The volume is handsomely illustrated, with many large color diagrams and pictures. As always, I found the endnotes annoying, necessitating constant flipping to the end of a chapter to chase down references (also for images that didn't face the text discussing them, such as that on the distribution of the Aqua Claudia and Anio Novus). All in all, this is an excellent and timely volume that covers exciting new research into water systems around the Roman Mediterranean. It is required reading for all those interested in pre-modern water management.

Footnotes

4 Coates-Stephens Reference Coates-Stephens1998; Hostetter et al. 2011.

7 For these, see Keenan-Jones et al. Reference Keenan-Jones, Motta, Garcia and Fouke2015.

9 Aicher Reference Aicher1995, 106–9.

10 Ashby Reference Ashby1935, 133–34.

References

Aicher, P. J. 1995. Guide to the Aqueducts of Ancient Rome. Wauconda, IL: Bolchazy-Carducci Publishers, Inc.Google Scholar
Ashby, T. 1935. The Aqueducts of Ancient Rome. Oxford: Oxford University Press.Google Scholar
Blackman, D. R. 1978. “The volume of water delivered by the four great aqueducts of Rome.” PBSR 46: 5272.Google Scholar
Coates-Stephens, R. 1998. “The walls and aqueducts of Rome in the Early Middle Ages, AD 500–1000.” JRS 88: 166–87.Google Scholar
Finné, M., Woodbridge, J., Labuhn, I., and Roberts, N.. 2019. “Holocene hydro-climatic variability in the Mediterranean: A synthetic multi-proxy reconstruction.” The Holocene 29, no. 5: 847–63. https://doi.org/10.1177/0959683619826634.CrossRefGoogle Scholar
Hodge, A. T. 1984. “How did Frontinus measure the Quinaria?AJA 88: 205–16.CrossRefGoogle Scholar
Hostetter, E., Fouke, B. W., and Lundstrom, C. C.. 2011. “The last flow of water to, and through, the Baths of Caracalla: Age, temperature and chemistry.” Journal of Ancient Topography. Rivista di Topografia antica 21: 5390.Google Scholar
Hu, H.-M., Michel, V., Valensi, P., Mii, H.-S., Starnini, E., Zunino, M., and Shen, C.-C.. 2022. “Stalagmite-inferred climate in the western Mediterranean during the Roman Warm Period.” Climate 10, no. 7. http://dx.doi.org/10.3390/cli10070093.CrossRefGoogle Scholar
Jansen, G. C. M. 2001. “Water pipe systems in the houses of Pompeii.” In Water Use and Hydraulics in the Roman City, ed. Koloski-Ostrow, A. O., 2740. AIA Colloquia and Conference Papers 3. Dubuque, IA: Kendall Hunt.Google Scholar
Keenan-Jones, D., Motta, D., Garcia, M. H., Sivaguru, M., Perillo, M., Shosted, R. K., and Fouk, B. W.. 2022. “Travertine crystal growth ripples record the hydraulic history of ancient Rome's Anio Novus aqueduct.” Scientific Reports 1/24/2022, 12, no. 1: 115.Google Scholar
Keenan-Jones, D. C. 2015. “Somma-Vesuvian ground movements and the water supply of Pompeii and the Bay of Naples.” AJA 119, no. 2: 191215.CrossRefGoogle Scholar
Keenan-Jones, D. C., Foubert, A., Motta, D., Fried, G., Sivaguru, M., Perillo, M., Waldsmith, J., Wang, H., Garcia, M. H., and Fouke, B. W.. 2014. “Hierarchical stratigraphy of travertine deposition in ancient Roman aqueducts.” In Lazio e Sabina 10 (Atti del convegno “Decimo incontro di studi sul Lazio e la Sabina”, Roma, 4–6 giugno 2013), ed. Calandra, E., Ghini, G., and Mari, Z., 293–95. Lavori e Studi della Soprintendenza per i Beni Archeologici del Lazio 10. Rome: Edizioni Quasar.Google Scholar
Keenan-Jones, D. C., Motta, D., Garcia, M. H., and Fouke, B. W.. 2015. “Travertine-based estimates of the amount of water supplied by ancient Rome's Anio Novus aqueduct.” JAS: Reports 3: 110.Google Scholar
Kessener, H. P. M. 2017. “Roman water taps and (two) paradigms.” In Wasserwesen zur Zeit des Frontinus / Bauwerke - Technik - Kultur, ed. Wiplinger, G. and Letzner, W., 371–79. Babesch Supplementa 32.4. Leuven: Peeters.Google Scholar
Labuhn, I., Finné, M., Izdebski, A., Roberts, N., and Woodbridge, J.. 2016. “Climatic changes and their impacts in the Mediterranean during the first millennium AD.” Late Antique Archaeology 12, no. 1: 6588.CrossRefGoogle Scholar
Maiuri, A. 1931. “Pozzi e condotture d'acqua nell'antica città. Scoperto di un antico pozzo presso Porta Vesuvio.NSc 39: 546–75.Google Scholar
Monteleone, M. C. 2020. “Le reti di distribuzione di acqua potabile in epoca romana. Fistule ritrovate e quantità di acqua erogata in due case Pompeiane.” In History of Engineering. Storia dell'Ingegneria. Proceedings of the 4th International Conference. Atti dell’8° Convegno Nazionale. Naples, 2020, 173–88. Naples: Cuzzolin.Google Scholar
Monteleone, M. C., Crapper, M., and Motta, D.. 2023. “The discharge of the pipelines supplying public fountains in Roman Pompeii.” JAS: Reports 47: 103769.Google Scholar
Motta, D., Keenan-Jones, D., Garcia, M. H., and Fouke, B. W.. 2017. “Hydraulic evaluation of the design and operation of ancient Rome's Anio Novus Aqueduct.” Archaeometry 59, no. 6: 1150–74.CrossRefGoogle Scholar
Pagano, M., Messina, L., Donix, M., Ribacchi, R., Cioli, D., and Placidi, M.. 2017. “Redrawing Ashby's maps. A GPS- and internet-based project for the documentation of the ancient aqueducts of Rome.” In Wasserwesen zur Zeit des Frontinus / Bauwerke - Technik - Kultur 40 Jahre Frontinus Gesellschaft Tagungsband des Internationalen Frontinus- Symposiums Trier, 25.-29. Mai 2016, ed. Wiplinger, G. and Letzner, W., 117–28. Babesch Supplementa 32.4. Leuven: Peeters.Google Scholar
Sivaguru, M., Fouke, K., Keenan-Jones, D. C., Motta, D., Garcia, M. H., and Fouke, B. W.. 2022. “Depositional and diagenetic history of travertine deposited within the Anio Novus aqueduct of ancient Rome.” In From the Guajira Desert to the Apennines, and from Mediterranean Microplates to the Mexican Killer Asteroid: Honoring the Career of Walter Alvarez, ed. Koeberl, C., Claeys, P., and Montanari, A., 541–69. Geological Society of America Special Papers 557. Boulder, CO: Geological Society of America.Google Scholar
Taylor, R. M. 2000. Public Needs and Private Pleasures: Water Distribution, the Tiber River and the Urban Development of Ancient Rome. Rome: ″L'Erma” di Bretschneider.Google Scholar
Wilson, A. I. 1999. “Deliveries extra urbem: aqueducts and the countryside.” JRA 12: 314–31.Google Scholar
Wilson, A. I. 2009. “Villas, horticulture and irrigation infrastructure in the Tiber Valley.” In Mercator Placidissimus: The Tiber Valley in Antiquity. New Research in the Upper and Middle River Valley (Proceedings of the Conference held at the British School at Rome, 27–28 Feb. 2004), ed. Patterson, H. and Coarelli, F., 731–68. Rome: Edizioni Quasar.Google Scholar
Zanchetta, G., Bini, M., Bloomfield, K., Izdebski, A., Vivoli, N., Regattieri, E., Isola, I., Drysdale, R. N., Bajo, P., Hellstrom, J. C., Wiśniewski, R., Fallick, A. E., Natali, S., and Luppichini, M.. 2021. “Beyond one-way determinism: San Frediano's miracle and climate change in central and northern Italy in Late Antiquity.” Climatic Change 165, no. 1–2: 25.CrossRefGoogle ScholarPubMed
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Table 1. Balances of input and output water flow capacities for the castellum, each water tower, and Pompeii's water system as a whole. (* Negative values represent greater output capacity than input capacity, where overflow of the tank should never happen; ** That is, total distribution system input).