CHAPTER 1
Background
Last week Engineer Nerviâs latest building, Romeâs Palazetto dello Sport, was in full operation with a solid calendar of basketball games, boxing matches, and fencing competitions. Neither the appreciative spectators, gazing at the soaring, concrete-ribbed dome free of any obstructing pillars, nor the art critics, who praised it as âa masterpiece of creative genius ⊠perfectionâ would believe that Nervi had no esthetic scheme in mind. But it was a fact that he had merely worked out an orderly system for transmitting the flow of the great domeâs stress along the most logical and economical lines. ⊠An artist to his fingertips, Engineer Nervi protests that his buildings, which he likes to call âcoveringsâ or âspace limits,â are simply âa rigid interpretation of structural necessities.â Says he: âBeauty does not come from decorative effects, but from structural coherence.â
âRosamond Bernier, âPoetry in Concreteâ
The Palazetto dello Sport, the smaller of two indoor arenas designed and constructed by Pier Luigi Nervi for Romeâs 1960 Olympics, was an assertion of Italian pride and recovery; just a dozen years after World War II ended, the country had been awarded the Games as a symbol of the countryâs recovery and reentry into the global community. Italy was one of the brightest, best-performing economies in the world, and it had already earned a reputation for sophisticated design. From Olivetti typewriters to Ferrari automobiles, Italian had become an adjective for well-crafted, thoughtfully designed, stylish goods. The Palazetto was just the latest design triumph for the country, and its engineer and builder, Pier Luigi Nervi, fulfilled the international pressâs image of the Italian design maestro: stylish; fluent in the languages of manufacturing, building craft, and fine art; able to reel off a pithy quote that hinted at greater poetic and philosophical meanings behind the deceptively simple object at hand. Yet the ease with which Nervi spoke about his work masked a calculating mind, a competitive business sense, and an intensity that had marked his ascent from prosaic professional beginnings. Even the graceful Palazetto, with its mesmerizing, sunflower-like roof, had come about through Nerviâs artful skill at winning competitive bids. Commissioned even before Rome had been awarded the Olympics, the project had been a gamble by its designers and its clients. Nervi had helped to assemble the tender documents, which favored his patented construction processes. No other builder could compete with his firmâs bid. Like many of Nerviâs buildings, the Palazettoâs poetic grace and simplicity emerged from very worldly circumstances.
FIGURE 1.1. Palazetto dello Sport, Rome, 1957. (Photo by the author)
Nerviâs emergence on the international scene in the 1950s and 1960s came at a hopeful moment for architecture and engineering. Optimism about the postwar successes of urban planning, affordable materials such as aluminum and high-strength steel, the reconstruction of Europeâs cities and towns along scientific lines, and new constructive types such as the curtain wall and the space frame promised unlimited possibilities for the postwar world. These developments occurred at a sanguine moment in the cultural perception of science and technology. Salkâs polio vaccine, the harnessing of nuclear energy, and the construction of vast works of public infrastructure all offered hope for tangible advances in daily life. The world was primed during these decades to welcome a figure who embodied the optimism inherent in such technical progress, especially one who was as fluent in the quantitative achievements of the sciences as in the cultural traditions of a reemergent Europe. C. P. Snowâs 1959 lament on the distance between the âtwo culturesâ of the sciences and the humanities highlighted the global hunger for figures who could bridge this gap. An architect-engineer whose innovative, technically advanced approach could also recall in viewersâ minds the vaults of the Romans and the domes of Baroque Italy, whose designs felt equally at home in Rome, Paris, New York, Montreal, and Sydney, and whose writings were full of literate allusions to architectural history and to detailed descriptions of shell engineering, was destined for international acclaim in such a climate.
Nervi was well-read in the classics and in engineering theory, literate in his writing, fluent in static conceptions and architectural composition, and fascinated by the history of architecture and by current developments in concrete and steel design around the world. His designs synthesized movements in the arts, the sciences, and Italyâs industrial climate into works that were evocative and engaging even for those who might not make the historical links between his 1957 dome for the Palazetto and that of the Pantheon, for instance, a mere 4 kilometers away. Nerviâs best works were evocative in a way that appealed to specialists and the public alike. One may not have understood the cultural allusions or the sophisticated structural or constructional techniques involved, but Nerviâs spacesâin particular his public spacesânever failed to captivate. Time magazine extolled his ability to âraise pure structure to artâ and to make raw concrete âcompete with marbleâ for sheer architectural beauty. Winthrop Sargeantâs 1960 profile for the New Yorker called him a âvirtuosoâ in reinforced concrete, whose structures were âas exciting ⊠as a sopranoâs perfectly placed high C or an athleteâs powerful, controlled broad jump.â
Such comparisons to Nervi as an artist or an athlete, a musician or a poet were common throughout his career, but references to him as an architect were technically incorrect. Nervi was trained as an engineer and builder. He had no formal educations or qualifications as an architect, although his sons Vittorio (1930â) and Antonio (1925â1979) did. In conversation he referred to himself as âan engineer in the contracting businessâ and to his buildings as âcoverings.â This did not stop others from comparing him to the great master builders of the eraâLudwig Mies van der Rohe, Frank Lloyd Wright, Alvar Aalto, among othersâbut Nerviâs practice and his built work presented a thorough challenge to typical architecture as practice during the era. Nervi insisted that his forms arose not from sculptural ideals or historic precedent but rather from ironclad economic and static logic. The signatures of their creation were to be found more in the marks of their constructive processes than in their overall forms or appearances.
It is easiest to place Nervi in the pantheon of twentieth-century engineering, among those who pioneered and developed the techniques of thin-shell concrete construction. Like Robert Maillart, Eduardo Torroja y Miret, and FĂ©lix Candela, Nerviâs greatest engineering contributions came with his incredible roof spans, achieved with thin structures in which economy and inherent visual appeal were intertwined. Two of Nerviâs domesâthe Palazetto dello Sport and the Norfolk Scope Arenaâset engineering records for clear-span concrete domes. Only Torroja, however, matched Nervi in producing a published philosophy. Nervi wrote in structural engineering, architectural, and popular journals, first as a guest critic for Casabella in the 1930s, and later as a public voice for engineering as the integration of ethics and aesthetics. Costruire coret-tamente (Constructing Correctly), published in Italy in 1955 and then as Structures in the United States in 1956, summarized his philosophyâit was the designerâs responsibility to consider efficiency and economy above all, but within this remit expressive possibilities and architectural beauty could always be foundâin its very title. He enjoyed a late career as a professor, teaching structural design to architects at the University of Rome, Tor Sapienza, from 1945 to 1961, and in 1961 he delivered the Charles Eliot Norton Lectures in Poetry at Harvard, refining his philosophy and linking his own work to âtechnically correctâ and aesthetically satisfying work from the pastâthe Gothic in particular. Published in 1965 as Aesthetics and Technology in Building, these lectures codified the thinking that had coalesced through over forty years of practice in both design and construction.
Nerviâs upbringing, education, and early experiences are inseparable from his later career. Indeed, they prepared him for the integrated approach that marked his greatest work. Born in northern Italy in 1891 to a family headed by a postal official, Nervi had an itinerant childhood, living for a time in Savona. The family moved on to Ancona, a port town on the Adriatic graced by a domed Romanesque cathedral. There Nervi attended a secondary school run by the Piarists, a Catholic order devoted to educating the poor by integrating them with middle-class children. As the son of a government clerk, Nervi would have gained admission in the latter category, suggesting a conscious choice by devout and socially aware parents. The Piarists professed a disciplined pedagogy similar to the Jesuits, and the ascetic surroundings, classmates from diverse economic strata, and challenging classwork in Ancona undoubtedly influenced the young Nervi. Rigor in thought and discipline in economy accompanied him throughout his life. While he would later play down his religious beliefs, Nervi professed to being spiritual in a way that reflected northern Italyâs reticent character and Piarist humility.
Fascinated by aircraft throughout his youth and having shown a gift for mathematics and science, Nervi left Ancona for university studies at Bologna, and it was there that his approach to engineering was forged. As Micaela Antonucci has shown, Bolognese culture in the 1910s was pulled between tradition and progress in engineering and the arts, creating a vibrant but charged atmosphere. Among other figures, the Futurist artist-architect Antonio SantâElia taught at the cityâs Accademia di Belle Arti, but the conservative atmosphere that permeated the Scuola di Applicazione per Ingegneri di Bologna, where Nervi studied, would have tempered such influences. As its name suggests, the school adopted a professional approach. While in touch with contemporary developments, it balanced theory with real-world experience from teachers who were engaged in construction and design.
Those industries were in the midst of important changes in the first decades of the twentieth century that brought new materials and calculation techniques. Most important was concreteâs emergence as a viable alternative to steel and masonry. Beginning with experiments in Britain and France in the late eighteenth and early nineteenth centuries, developments in concrete technology transformed rough, rammed-earth and mortar techniques into a new construction typology. The fortuitous development of iron in parallel with concrete soon led to hybrids. Concrete itself relies on the chemical adhesion of cured cement to hold sand and stone aggregates within a fixed matrix; this works well in compression, but such adhesion is unreliable in tension. Reinforcing tensile or bending elements with iron bars gives concrete much greater strength while adding little to its cost. Reinforced concrete construction gained traction in domestic building in France by the 1850s, but it remained a crude material, its reinforcement more akin to tie rods than to monolithic reinforcement. Its application in houses, theaters, and churches in France through the 1870s proved its durability, strength, and economy compared to iron and other emergent forms of construction. More innovative reinforced concrete emerged in the work of Joseph Monier (1823â1906) in France and British Ă©migrĂ© Ernest Ransome (1852â1917) in the western United States. The more important development for Italyâand for Nervi in particularâcame in the 1890s with French constructeur François Hennebiqueâs (1842â1921) patented system, which he licensed to established contractors throughout Europe over the next decades. The Hennebique system featured numerous technical improvements over the hodgepodge of systems available throughout the continent. More importantly, as Peter Collins notes, its license came with a consulting arrangement with Hennebique himself, and a publicity machine that broadcast the materialâs revolutionary achievements and potential.
By the time Nervi arrived at Bologna, the Hennebique system was well-known but still revolutionary. Hennebiqueâs contributions to the 1900 Paris Exhibition placed the material and his system on the world stage, in particular a curvilinear staircase in the Petit Palais that offered evidence of concreteâs potential for plastic form and its deployment in the framed floors of the exhibitionâs enormous main buildings and temporary structures that emphasized its economy. Contractors built more than fifteen hundred projects on the Hennebique system every year by the turn of the century. Steel remained prevalent in the United States, even as fires in Philadelphia and Baltimore underlined its vulnerability and further proved concreteâs inherent resistance to heat and flame. Southern Europeâlacking necessary natural resources and thus a native steel industryâtook to the new material quickly. The low cost and ready availability of concreteâs ingredients, in particular limestone and aggregates, made it uniquely suited for Italy.
FIGURE 1.2. The Hennebique system (1890s)
Concrete was not only an improvement in economy, it was...