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History of modern period domes

December 14, 2023

Domes built in the 19th, 20th, and 21st centuries benefited from more efficient techniques for producing iron and steel as well as advances in structural analysis.

Metal-framed domes of the 19th century often imitated earlier masonry dome designs in a variety of styles, especially in church architecture, but were also used to create glass domes over shopping arcades and hothouses, domes over locomotive sheds and exhibition halls, and domes larger than any others in the world. The variety of domed buildings, such as parliaments and capitol buildings, gasometers, observatories, libraries, and churches, were enabled by the use of reinforced concrete ribs, lightweight papier-mâché, and triangulated framing.

In the 20th century, planetarium domes spurred the invention by Walther Bauersfeld of both thin shells of reinforced concrete and geodesic domes. The use of steel, computers, and finite element analysis enabled yet larger spans. Tension membrane structure became popular for domed sports stadiums, which also innovated with rigid retractable domed roofs.

Nineteenth century edit

Developments edit

Materials edit

New production techniques allowed for cast iron and wrought iron to be produced both in larger quantities and at relatively low prices during the Industrial Revolution.[1] Most iron domes were built with curved iron ribs arranged radially from the top of the dome to a ring at the base. The material of choice for domes changed over the course of the 19th century from cast iron to wrought iron to steel.[2] Excluding domes that simply imitated multi-shell masonry, the century's chief development of the simple domed form may be metal framed domes such as the circular dome of Halle au Blé in Paris and the elliptical dome of Royal Albert Hall in London.[3]

The practice of building rotating domes for housing large telescopes became popular in the 19th century, with early examples using papier-mâché to minimize weight.[4]

Beginning in the late 19th century, the Guastavino family, a father and son team who worked on the eastern seaboard of the United States, further developed the masonry dome. They perfected a traditional Spanish and Italian technique for light, center-less vaulting using layers of tiles in fast-setting cement set flat against the surface of the curve, rather than perpendicular to it. The father, Rafael Guastavino, innovated with the use of Portland cement as the mortar, rather than the traditional lime and gypsum mortars, which allowed mild steel bar to be used to counteract tension forces.[5]

Although domes made entirely from reinforced concrete were not built before 1900, the church of Saint-Jean-de-Montmartre was designed by Anatole de Baudot with a small brick shell dome with reinforced concrete ribs.[6]

Structure edit

Proportional rules for an arch's thickness to span ratio were developed during the 19th century, based on catenary shape changes in response to weight loads, and these were applied to the vertical forces in domes. Edmund Beckett Denison, who had published a proof on the subject in 1871, wrote in a Domes article in the Ninth Edition of the Encyclopædia Britannica that the thickness to span ratio was lower for a dome than it was for an arch due to the more distributed loads of a dome.[7] Ideas on linear elasticity were formalized in the 19th century.[8]

The span of the ancient Pantheon dome, although matched during the Renaissance, remained the largest in the world until the middle of the 19th century.[9] The large domes of the 19th century included exhibition buildings and functional structures such as gasometers and locomotive sheds.[10]

Domes made of radial trusses were analyzed with a "plane frame" approach, rather than considering three dimensions, until an 1863 Berlin gasometer dome design by engineer Johann Wilhelm Schwedler that became known as the "Schwedler dome". He published the theory behind five such domes and a structural calculation technique in 1866. Schwedler's work on these axially symmetric shells was expanded by August Föppl in 1892 to apply to "other shell-type truss frameworks".[11] By the 1860s and 1870s, German and other European engineers began to treat iron domes as collections of short straight beams with hinged ends, resulting in light openwork structures. Other than in glasshouses, these structures were usually hidden behind ceilings.[12] Dome types that used lengths of rolled steel with riveted joints included "Schwedler domes", "Zimmermann domes", "lattice domes", and "Schlink domes".[11]

According to Irene Giustina, dome construction was one of the most challenging architectural problems until at least the end of the 19th century, due to a lack of knowledge about statics.[13] Rafael Guastavino's use of the recent development of graphic statics enabled him to design and build inexpensive funicular domes with minimal thickness and no scaffolding. The vaults were typically 3 inches thick and workers, standing on the completed portions, used simple templates, wires, and strings to align their work.[14]

Style edit

The historicism of the 19th century led to many domes being re-translations of the great domes of the past, rather than further stylistic developments, especially in sacred architecture.[15] The Neoclassical style popular at this time was challenged in the middle of the 19th century by a Gothic Revival in architecture, in what has been termed the "Battle of the Styles". This lasted from about 1840 to the beginning of the 20th century, with various styles within Classicism, such as Renaissance, Baroque, and Rococo revivals, also vying for popularity. The last three decades of this period included unusual combinations of these styles.[16]

Religious and royal buildings edit

 
Kazan Cathedral and Saint Isaac's Cathedral (background) in Russia.

Iron domes offered the lightness of timber construction along with incombustibility and higher strength, allowing for larger spans. Because domes themselves were relatively rare, the first examples made from iron date well after iron began to be used as a structural material.[2] Iron was used in place of wood where fire resistance was a priority. In Russia, which had large supplies of iron, some of the earliest examples of the material's architectural use can be found. Andrey Voronikhin built a large wrought iron dome over Kazan Cathedral in Saint Petersburg.[17] Built between 1806 and 1811, the 17.7 meter wide outer dome of the cathedral was one of the earliest iron domes.[18] The iron outer dome covers two masonry inner domes and is made of 15 mm thick sheets set end to end.[19]

An early example from Britain is within the fanciful iron-framed dome over the central building of the Royal Pavilion in Brighton, begun in 1815 by John Nash, the personal architect of King George IV.[20] The dome was not one of the prominent onion domes but instead the dome-like structure of twelve cast iron ribs resting on cast iron columns over Henry Holland's earlier saloon. It was completed in 1818–1819.[19]

The neoclassical Baltimore Basilica, designed by Benjamin Henry Latrobe like the Roman Pantheon for Bishop John Carroll, was begun in 1806 and dedicated in 1821, although the porch and towers would not be completed until the 1870s. An influence on the interior design may have been the Church of St. Mary in East Lulworth, England, where Bishop Carroll had been consecrated.[21] The central dome is 72 feet in diameter and 52 feet above the nave floor. The onion domes over the two towers were built according to Latrobe's designs. The church was extended to the east by 33 feet in 1890.[22] Before initial construction of the church was completed, two other neoclassical domed churches would be built in Baltimore. The First Independent (Unitarian) Church by Maximilian Godefroy was begun in 1817 and covered the interior space with a 55 foot wide shallow coffered dome on pendentives with an oculus at the center. To improve acoustics, the interior was modified. The First Baptist Church by Robert Mills, also known as "Old Red Top Church", was a domed cylindrical rotunda with a porch block and portico. The dome had a shallow exterior profile and its oculus was covered by a low lantern, called a monitor. It was completed in 1818 but demolished in 1878.[23]

In 1828, the eastern crossing tower of Mainz Cathedral was rebuilt by Georg Moller with a wrought iron dome.[24] The dome was made of flat iron sections and reinforced with ties that passed through the interior of the dome. Such dome reinforcement was one of the two established techniques, the other being the use of a combination of horizontal rings and vertical ribs.[10] The span may have been about 27 meters.[25] It was later removed in favor of the current structure.[26]

The Altes Museum in Berlin, built in 1828 by Karl Schinkel, included a dome in its entrance hall inspired by the Roman Pantheon.[27]

Large neoclassical domes include the Rotunda of Mosta in Malta, was completed in 1840 with a dome 38 meters wide, and San Carlo al Corso in Milan, completed in 1847 with a dome 32 meters wide.[28]

Saint Isaac's Cathedral, in Saint Petersburg, was built by 1842 with one of the largest domes in Europe. A cast iron dome nearly 26 meters wide, it had a technically advanced triple-shell design with iron trusses reminiscent of St. Paul's Cathedral in London.[29] The design for the cathedral was begun after the defeat of Napoleon in 1815 and given to a French architect, but construction was delayed. Although the dome was originally designed to be masonry, cast iron was used instead.[6]

Also reminiscent of St. Paul's dome and that of the Panthéon in Paris, both of which the original designer had visited, the dome of St. Nicholas' Church in Potsdam was added to the building from 1843 to 1849.[30] A dome was included as a possibility in the original late Neoclassical design of 1830, but as a wooden construction. Iron was used instead by the later architects.[31]

Other examples of framed iron domes include those of a synagogue in Berlin, by Schwedler in 1863, and the Bode Museum by Muller-Breslau in 1907.[32]

The wrought-iron dome of Royal Albert Hall in London was built from 1867 to 1871 over an elliptical plan by architect Henry Young Darracott Scott and structural design by Rowland Mason Ordish. It uses a set of curved trusses, like those of the earlier New Street Station in Birmingham, interrupted in the middle by a drum. The elliptical dome's span is 66.9 meters by 56.5 meters.[33]

The wrought-iron dome of St. Augustin's church in Paris dates from 1870 and spans 25.2 meters. A wrought-iron dome was also built over Jerusalem's Holy Sepulchre in 1870, spanning 23 meters.[34]

The dome over the Basilica of San Gaudenzio (begun in 1577) in Novara, Italy, was built between 1844 and 1880. Revisions by the architect during construction transformed what was initially going to be a drum, hemispherical dome, and lantern 42.22 meters tall into a structure with two superimposed drums, an ogival dome, and a thirty meter tall spire reaching 117.5 meters.[35] The architect, Alessandro Antonelli, who also built the Mole Antonelliana in Turin, Italy, combined Neoclassical forms with the vertical emphasis of the Gothic style.[36]

A large dome was built in 1881–1882 over the circular courtyard of the Devonshire Royal Hospital in England with a diameter of 156 feet.[37] It used radial trussed ribs with no diagonal ties.[32]

The dome of Pavia Cathedral, a building started in 1488, was completed with a large octagonal dome joined to the basilica plan of the church.[38]

Commercial buildings edit

Although iron production in France lagged behind Britain, the government was eager to foster the development of its domestic iron industry. In 1808, the government of Napoleon approved a plan to replace the burnt down wooden dome of the Halle au Blé granary in Paris with a dome of iron and glass, the "earliest example of metal with glass in a dome". The dome was 37 meters in diameter and used 51 cast iron ribs to converge on a wrought iron compression ring 11 meters wide containing a glass and wrought iron skylight. The outer surface of the dome was covered with copper, with additional windows cut near the dome's base to admit more light during an 1838 modification.[39] Cast-iron domes were particularly popular in France.[40]

In the United States, an 1815 commission to build the Baltimore Exchange and Custom House was awarded to Benjamin Henry Latrobe and Maximilian Godefroy for their design featuring a prominent central dome. The dome design was altered during construction to raise its height to 115 feet by adding a tall drum and work was completed in 1822. Signals from an observatory on Federal Hill were received at an observation post in the dome, providing early notice of arriving merchant vessels. The building was demolished in 1901–2.[41]

The Coal Exchange in London, by James Bunning from 1847 to 1849, included a dome 18 meters wide made from 32 iron ribs cast as single pieces. It was demolished in the early 1960s.[42]

Large temporary domes were built in 1862 for London's International Exhibition Building, spanning 48.8 meters.[34] The Leeds Corn Exchange, built in 1862 by Cuthbert Brodrick, features an elliptical plan dome 38.9 meters by 26.7 meters with wrought iron ribs along the long axis that radiate from the ends and others spanning the short axis that run parallel to each other, forming a grid pattern.[33]

 
The Galleria Umberto I in Italy.

Elaborate covered shopping arcades, such as the Galleria Vittorio Emanuele II in Milan and the Galleria Umberto I in Naples, included large glazed domes at their cross intersections.[43] [44] The dome of the Galleria Vittorio Emanuele II (1863–1867) rises to 145 feet above the ground and has the same span as the dome of St. Peter's Basilica, with sixteen iron ribs over an octagonal space at the intersection of two covered streets. It is named after the first king of a united Italy.[44]

The central market hall in Leipzig was built by 1891 with the first application of the "lattice dome" roof system developed by August Föppl from 1883. The dome covered an irregular pentagonal plan and was about 20 meters wide and 6.8 meters high.[11]

Vladimir Shukhov was an early pioneer of what would later be called gridshell structures and in 1897 he employed them in domed exhibit pavilions at the All-Russia Industrial and Art Exhibition.[45]

The dome of Sydney's Queen Victoria Building uses radial ribs of steel along with redundant diagonal bracing to span 20 meters. It was claimed to be the largest dome in the Southern Hemisphere when completed in 1898.[32]

Greenhouses and conservatories edit

Iron and glass glasshouses with curved roofs were popular for a few decades beginning shortly before 1820 to maximize orthogonality to the sun's rays, although only a few have domes. The conservatory at Syon Park was one of the earliest and included a 10.8 meter span iron and glass dome by Charles Fowler built between 1820 and 1827. The glass panes are set in panels joined by copper or brass ribs between the 23 main cast iron ribs. Another example was the conservatory at Bretton Hall in Yorkshire, completed in 1827 but demolished in 1832 upon the death of the owner. It had a 16 meter wide central dome of thin wrought iron ribs and narrow glass panes on a cast iron ring and iron columns. The glass acted as lateral support for the iron ribs.[46]

The Antheum at Brighton would have had the largest span dome in the world in 1833 at 50 meters but the circular cast-iron dome collapsed when the scaffolding was removed.[47]

Unique glass domes springing straight from ground level were used for hothouses and winter gardens, such as the Palm house at Kew (1844–48) and the Laeken winter garden near Brussels (1875–1876).[48] The Laeken dome spans the central 40 meters of the circular building, resting on a ring of columns. The Kibble Palace of 1865 was re-erected in 1873 in an enlarged form with a 16 meter wide central dome on columns. The Palm House at Sefton Park in Liverpool has an octagonal central dome, also 16 meters wide and on columns, completed in 1896.[49]

Libraries edit

The domed rotunda building of the University of Virginia was designed by Thomas Jefferson and completed in 1836.[27]

The British Museum Library constructed a new reading room in the courtyard of its museum building between 1854 and 1857. The round room, about 42.6 meters in diameter and inspired by the Pantheon, was surmounted by a dome with a ring of windows at the base and an oculus at the top. Hidden iron framing supported a suspended ceiling made of papier-mâché.[50] A cast iron dome was built between 1860 and 1867 over the reading room of the Bibliothèque nationale in Paris.[40]

Inspired by the prestigious British Museum reading room, the first iron dome in Canada was built in the early 1870s over the reading room of the Library of Parliament building in Ottawa. Unlike the British Museum room, the library, which opened in 1876, uses the Gothic style.[51]

The dome of the Thomas Jefferson Building of the Library of Congress, also inspired by the reading room dome at the British Museum, was built between 1889 and 1897 in a classical style. It is 100 feet wide and rises 195 feet above the floor on eight piers. The dome has a relatively low external profile to avoid overshadowing the nearby United States Capitol dome.[52]

The Boston Public Library (1887-1898) includes dome vaulting by Rafael Guastavino.[53]

Governmental buildings edit

 
The United States Capitol.
 
The Hungarian Parliament Building.
See also: List of state and territorial capitols in the United States

The design for the United States' national capitol building approved by George Washington included a dome modeled on the Pantheon, with a low exterior elevation. Subsequent design revisions resulted in a double dome, with a raised external profile on an octagonal drum, and construction did not begin until 1822. The interior dome was built of stone and brick except for the upper third, which was made of wood. The exterior dome was wooden and covered with copper sheeting.[54] The dome and building were completed by Charles Bulfinch in 1829.[55]

Most of the 50 state capitol buildings or statehouses with domes in the United States cover a central rotunda, or hall of the people, due to the use of a bicameral legislature. The Pennsylvania capitol building designed by Stephen Hills in Harrisburg was the earliest to combine all the elements that would subsequently become characteristic of state capitol buildings: dome, rotunda, portico, and two legislative chambers. Like the design of the national capitol, the design was chosen through a formal competition.[56] Early domed state capitol buildings include those of North Carolina (as remodeled by William Nichols), Alabama (in Tuscaloosa), Mississippi, Maine (1832), Kentucky, Connecticut (in New Haven), Indiana, North Carolina (as rebuilt), Missouri (very similar to Hills' Harrisburg design), Minnesota (later rebuilt), Texas, and Vermont (1832).[57]

The current dome over the United States Capitol building, although painted white and crowning a masonry building, is made of cast iron. The dome was built between 1855 and 1866, replacing a lower wooden dome with copper roofing from 1824.[58] It has a 30-meter diameter.[40] It was completed just two years after the Old St. Louis County Courthouse, which has the first cast iron dome built in the United States.[59] The initial design of the capitol dome was influenced by a number of European church domes, particularly St. Paul's in London, St. Peter's in Rome, the Panthéon in Paris, Les Invalides in Paris, and St. Isaac's Cathedral in St. Petersburg.[60] The architect, Thomas U. Walter, designed a double dome interior based on that of the Panthéon in Paris.[58]

Dome construction for state capitol buildings and county courthouses in the United States flourished in the period between the American Civil War and World War I.[61] Most capitols built between 1864 and 1893 were landmarks for their cities and had gilded domes.[62] Examples from the Gilded Age include those of California, Kansas, Connecticut, Colorado, Idaho, Indiana, Iowa, Wyoming, Michigan, Texas, and Georgia.[63] Many American state capitol building domes were built in the late 19th or early 20th century in the American Renaissance style and cover rotundas open to the public as commemorative spaces. Examples include the Indiana State House, Texas State Capitol, and the Wisconsin State Capitol.[64] American Renaissance capitols also include those of Rhode Island and Minnesota.[63]

The Reichstag Palace, built between 1883 and 1893 to house the Parliament of the new German Empire, included a dome made of iron and glass as part of its unusual mixture of Renaissance and Baroque components. Controversially, the 74 meter tall dome stood seven meters taller than the dome of the Imperial Palace in the city, drawing criticism from Kaiser Wilhelm II.[65] Hermann Zimmermann assisted the architect Paul Wallot in 1889, inventing the spatial framework for the dome over the plenary chamber. It is known as the "Zimmermann dome".[11]

The Hungarian Parliament Building was built in the Gothic style, although most of the 1882 design competition entries used Neo-Renaissance, and it includes a domed central hall. The large, ribbed, egg-shaped dome topped with a spire was influenced by the dome of the Maria vom Siege church in Vienna.[66] It has a sixteen sided outer shell with an iron skeleton that rises 96 meters high, and an inner shell star vault supported on sixteen stone pillars. The Dome Hall is used to display the coronation crown of Hungary and statuary of monarchs and statesmen. The dome was structurally complete by the end of 1895.[67]

Industrial buildings edit

The "first fully triangulated framed dome" was built in Berlin in 1863 by Johann Wilhelm Schwedler in a gasometer for the Imperial Continental Gas Association and, by the start of the 20th century, similarly triangulated frame domes had become fairly common.[68][45] Schwedler built three wrought-iron domes over gasholders in Berlin between 1876 and 1882 with spans of 54.9 meters, one of which survives. Six similar Schwedler-type domes were used over gasholders in Leipzig beginning in 1885 and in Vienna using steel, in the 1890s. Rather than using traditional iron ribs, the domes consist of a thinner arrangement of short straight iron bars connected with pin joints in a lattice shell, with cross-bracing provided by light iron rods.[69]

Tombs edit

The dome of Grant's Tomb in New York City was built by Rafael Guastavino in 1890.[53][70]

Twentieth century edit

Developments edit

American state capitol domes built in the twentieth century include those of Arizona, Mississippi, Pennsylvania, Wisconsin, Idaho, Kentucky, Utah, Washington, Missouri, and West Virginia. The West Virginia capitol building has been called the last American Renaissance capitol.[71]

Wooden domes in thin-wall shells on ribs were made until the 1930s.[72] After World War II, steel and wooden laminate structural members made with waterproof resorcinol glues were used to create domes with grid-patterned wooden support structures, such as the 100 meter diameter Skydome in Flagstaff, Arizona.[73]

Stand-alone dome structures were used to house public utility facilities in the 20th century.[74] The "Fitzpatrick dome", designed by John Fitzpatrick as an inexpensive structure to store winter road service sand and salt, has been used in countries around the world.[75][76] The first was built in 1968.[76] The domes have twenty sides and are normally 100 feet in diameter and a little more than 50 feet tall. The conical shape is meant to conform to the 45 degree slope of a pile of wet sand. They are built on concrete footings and covered with asphalt shingles.[77]

Guastavino tile edit

The Guastavino family, a father and son team who worked on the eastern seaboard of the United States, built vaults using layers of tiles in hundreds of buildings in the late 19th and early 20th centuries, including the domes of the Basilica of St. Lawrence in Asheville, North Carolina, and St. Francis de Sales Roman Catholic Church in Philadelphia, Pennsylvania.[78] The dome over the crossing of the Cathedral of St. John the Divine in New York City was built by the son in 1909. A part-spherical dome, it measures 30 meters in diameter from the top of its merging pendentives, where steel rods embedded in concrete act as a restraining ring. With an average thickness 1/250th of its span, and steel rods also embedded within the pendentives, the dome "looked forward to modern shell construction in reinforced concrete."[5]

Steel and concrete edit

 
The Kresge Auditorium in Massachusetts.

Domes built with steel and concrete were able to achieve very large spans.[40] The West Baden Springs Hotel in Indiana was built in 1903 with the largest span dome in the world at 200 feet. Its metal and glass skin was supported by steel trusses resting on metal rollers to allow for expansion and contraction from temperature changes. It was surpassed in span by the Centennial Hall of Max Berg.[79]

The 1911 dome of the Melbourne Public Library reading room, presumably inspired by the British Museum, had a diameter of 31.5 meters and was briefly the widest reinforced concrete dome in the world until the completion of the Centennial Hall.[6] The Centennial Hall was built with reinforced concrete in Breslau, Germany (today Poland), from 1911–13 to commemorate the 100-year anniversary of the uprising against Napoleon. With a 213 foot wide central dome surrounded by stepped rings of vertical windows, it was the largest building of its kind in the world.[80] Other examples of ribbed domes made entirely of reinforced concrete include the Methodist Hall in Westminster, London, the Augsburg Synagogue, and the Orpheum Theater in Bochum.[6] The 1928 Leipzig Market Hall by Deschinger and Ritter featured two 82 meter wide domes.[40]

The thin domical shell was further developed with the construction of two domes in Jena, Germany in the early 1920s. To build a rigid planetarium dome, Walther Bauersfeld constructed a triangulated frame of light steel bars and mesh with a domed formwork suspended below it. By spraying a thin layer of concrete onto both the formwork and the frame, he created a 16 meter wide dome that was just 30 millimeters thick. The second dome was still thinner at 40 meters wide and 60 millimeters thick.[81] These are generally taken to be the first modern architectural thin shells.[82] These are also considered the first geodesic domes.[83] Beginning with one for the Deutsches Museum in Munich, 15 domed projection planetariums using concrete shells up to 30 meters wide had been built in Europe by 1930, and that year the Adler Planetarium in Chicago became the first planetarium to open in the Western Hemisphere.[84] Planetarium domes required a hemispherical surface for their projections, but most 20th century shell domes were shallow to reduce the material costs, simplify construction, and reduce the volume of air needing to be heated.[85]

In India, the Viceroy's House in New Delhi was designed in 1912-1913 by Edwin Lutyens with a dome.[86]

Although an equation for the bending theory of a thick spherical shell had been published in 1912, based on general equations from 1888, it was too complex for practical design work. A simplified and more approximate theory for domes was published in 1926 in Berlin. The theory was tested using sheet metal models with the conclusion that the membrane stresses in domes are small with little reinforcement required, especially at the top, where openings could be cut for light. Only the concentrated stresses at point supports required heavy reinforcement.[85] Early examples used a relatively thick bordering girder to stabilize exposed edges. Alternative stabilization techniques include adding a bend at these edges to stiffen them or increasing the thickness of the shell itself at the edges and near the supports.[87] In 1933–34, Spanish engineer-architect Eduardo Torroja, with Manuel Sanchez, designed the Market Hall in Algeciras, Spain, with a thin shell concrete dome. The shallow dome is 48 meters wide, 9 centimeters thick, and supported at points around its perimeter.[88] The indoor stadium for the 1936 Olympic Games in Berlin used an oval dome of concrete shell 35 meters wide and 45 meters long.[89]

The use of metal structures in Italy was reduced in the first half of the 20th century by autarchy and the demands of the world wars.[90] Steel became broadly used in building construction in the 1930s.[91] A shortage of steel following World War II and the demonstrated vulnerability of exposed steel to damage from intense fires during the war may have contributed to the popularity of concrete architectural shells beginning in the late 1940s. In the 1960s, improvements in welding and bolting techniques and higher labor costs made steel frames more economical.[85]

Popularized by a 1955 article on the work of Félix Candela in Mexico, architectural shells had their heyday in the 1950s and 1960s, peaking in popularity shortly before the widespread adoption of computers and the finite element method of structural analysis. Notable examples of domes include the Kresge Auditorium at MIT, which has a spherical shell 49 meters wide and 89 millimeters thick, and the Palazzetto dello Sport, with a 59 meter wide dome designed by Pier Luigi Nervi.[92]

Built from 1955 to 1957, the prestressed concrete dome of the main exhibition hall of the Belgrade Fair has a span of 106 meters. It was designed by Branko Žeželj, using a pre-stressing system developed by him, and was the largest dome in the world until 1965. It remains the largest dome in Europe.[93]

Reticular and geodesic domes edit

 
The Amundsen-Scott South Pole Station in Antarctica.

Structurally, geodesic domes are also considered shells when the loads are borne by the surface polygons, as in the Kaiser Dome, but are considered space grid structures when the loads are borne by point-to-point members.[94] A geodesic dome made of welded steel tubes was made in 1935 for the aviary of the Rome Zoo.[90] Aluminum reticular domes allow for large dimensions and short building times, suitable for sports arenas, exhibition centers, auditoriums, or storage facilities. The Dome of Discovery exhibition hall was built in London in 1951.[95] It was the largest domed building in the world at the time, 365 feet wide.[96][97] Other aluminum domes include the 61 meter wide "Palasport" in Paris (1959) and the 125 meter wide "Spruce Goose Dome" in Long Beach, California.[95]

Although the first examples were built 25 years earlier by Walther Bauersfeld, the term "geodesic domes" was coined by Buckminster Fuller, who received a patent for them in 1954. Geodesic domes have been used for radar enclosures, greenhouses, housing, and weather stations.[98] Early examples in the United States include a 53-foot-wide dome for the Ford Rotunda in 1953 and a 384-foot-diameter dome for the Baton Rouge facility of the Union Tank Car Company in 1958, the largest clear-span structure in the world at that time.[99] The U.S. Pavilion at Expo 67 in Montreal, Quebec, Canada, was enclosed by a 76.5-meter-wide and 60-meter-tall dome made of steel pipes and acrylic panels. It is used today as a water monitoring center.[100] Other examples include the Amundsen-Scott South Pole Station, which was used from 1975 to 2003, and the Eden Project in the UK, built in 2000.[101]

Tension and membranes edit

 
The Millennium Dome in the UK.

Tensegrity domes, patented by Buckminster Fuller in 1962 from a concept by Kenneth Snelson, are membrane structures consisting of radial trusses made from steel cables under tension with vertical steel pipes spreading the cables into the truss form. They have been made circular, elliptical, and other shapes to cover stadiums from Korea to Florida.[102] While the first permanent air supported membrane domes were the radar domes designed and built by Walter Bird after World War II, the temporary membrane structure designed by David Geiger to cover the United States pavilion at Expo '70 was a landmark construction. Geiger's solution to a 90% reduction in the budget for the pavilion project was a "low profile cable-restrained, air-supported roof employing a superelliptical perimeter compression ring". Its very low cost led to the development of permanent versions using teflon-coated fiberglass and within 15 years the majority of the domed stadiums around the world used this system, including the Silverdome in Pontiac, Michigan.[103] The restraining cables of such domes are laid diagonally to avoid the sagging perimeter found to occur with a standard grid.[104]

Tension membrane design has depended upon computers, and the increasing availability of powerful computers resulted in many developments being made in the last three decades of the 20th century.[105] Weather-related deflations of some air-supported roofs led David Geiger to develop a modified type, the more rigid "Cabledome", that incorporated Fuller's ideas of tensegrity and aspension rather than being air-supported.[106][104] The pleated effect seen in some of these domes is the result of lower radial cables stretching between those forming trusses in order to keep the membrane in tension. The lightweight membrane system used consists of four layers: waterproof fiberglass on the outside, insulation, a vapor barrier, then an acoustic insulation layer. This is semitransparent enough to fulfill most daytime lighting needs beneath the dome. The first large span examples were two Seoul, South Korea, sports arenas built in 1986 for the Olympics, one 93 meters wide and the other 120 meters wide. The Georgia Dome, built in 1992 on an oval plan, uses instead a triangulated pattern in a system patented as the "Tenstar Dome".[107] In Japan, the Izumo Dome was built in 1992 with a height of 49 meters and a diameter of 143 meters. It uses a PTFE-coated glass fiber fabric.[108] The first cable dome to use rigid steel frame panels as roofing instead of a translucent membrane was begun for an athletic center in North Carolina in 1994.[109] The Millennium Dome was completed as the largest cable dome in the world with a diameter of 320 meters and uses a different system of membrane support, with cables extending down from the 12 masts that penetrate the membrane.[110]

Retractable domes and stadiums edit

 
Ōita Stadium in Japan.

The higher expense of rigid large span domes made them relatively rare, although rigidly moving panels is the most popular system for sports stadiums with retractable roofing.[104][111] With a span of 126 meters, Pittsburgh's Civic Arena featured the largest retractable dome in the world when completed for the city's Civic Light Opera in 1961. Six of its eight sections could rotate behind the other two within three minutes, and in 1967 it became the home of the Pittsburgh Penguins hockey team.[112]

The Assembly Hall arena at the University of Illinois Urbana-Champaign was completed in 1963 with a concrete saucer dome spanning 400 feet. The edge of the dome was post-tensioned with more than 600 miles of steel cable.[113] The first domed baseball stadium, the Astrodome in Houston, Texas, was completed in 1965 with a rigid 641 foot wide steel dome filled with 4,596 skylights. Other early examples of rigid stadium domes include the steel frame Superdome of New Orleans and the cement Kingdome of Seattle.[104] The Louisiana Superdome has a span of 207 meters.[114] Stockholm's 1989 Ericsson Globe, an arena for ice hockey, earned the title of largest hemispherical building in the world with a diameter of 110 meters and height of 85 meters.[115]

Montreal's Olympic Stadium featured a retractable membrane roof in 1988, although repeated tearing led to its replacement with a non-retractable roof. The SkyDome of Toronto opened in 1989 with a rigid system in four parts: one that is fixed, two that slide horizontally, and one that rotates along the edge of the 213 meter wide span. In Japan, the 1993 Fukuoka Dome featured a 222-meter dome in three parts, two of which rotated under the third.[116]

Twenty-first century edit

The variety of modern domes over sports stadiums, exhibition halls, and auditoriums have been enabled by developments in materials such as steel, reinforced concrete and plastics.[117] Their uses over department stores and "futuristic video-hologram entertainment centres" exploit a variety of non-traditional materials.[118] The use of design processes that integrate numerical control machines, computer design, virtual reconstructions, and industrial prefabrication allow for the creation of dome forms with complex geometry, such as the 2004 ellipsoid bubbles of Nardini Company's production district designed by Massimiliano Fuksas.[119]

Ōita Stadium was built in 2001 as a mostly fixed semi-spherical roof 274 meters wide with two large membrane-covered panels that can slide down from the center to opposite sides.[116] Singapore's National Stadium was completed in 2014 with the largest dome in the world at 310 meters in span. It uses a post-tensioned concrete ring beam to support steel trusses that enable two halves of a section of the dome to retract.[120]

References edit

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  2. ^ a b Sutherland 2000, p. 111.
  3. ^ Mainstone 2001, p. 241.
  4. ^ Lippincott 2008, p. 26.
  5. ^ a b Mainstone 2001, p. 129.
  6. ^ a b c d Cowan 1983, p. 191.
  7. ^ Cowan 1977, p. 17.
  8. ^ Bellini 2017, p. 3.
  9. ^ Cowan 1983, p. 183.
  10. ^ a b Kohlmaier & Von Sartory 1991, p. 126.
  11. ^ a b c d Kurrer 2012.
  12. ^ Sutherland 2000, pp. 116, 118.
  13. ^ Giustina 2003, p. 1033.
  14. ^ Allen 2004, pp. 69, 71.
  15. ^ Stephenson, Hammond & Davi 2005, p. 190.
  16. ^ Miller & Clinch 1998, p. 30.
  17. ^ Gayle & Gayle 1998, pp. 13, 18, 26.
  18. ^ Skempton 2002, p. 785.
  19. ^ a b Sutherland 2000, p. 112.
  20. ^ Gayle & Gayle 1998, p. 23.
  21. ^ Alexander 2004, pp. 71–73.
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  27. ^ a b Silk, Gildenhard & Barrow 2017, p. 257.
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  51. ^ Young 1995, pp. 20, 22, 89, 100.
  52. ^ Cole & Reed 1997, p. 25.
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  55. ^ King 2000, pp. 88–89.
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  65. ^ Rizzoni 2009, p. 186.
  66. ^ Moravánszky 1998.
  67. ^ Villám et al. 2006, pp. 67–68, 74.
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  69. ^ Sutherland 2000, pp. 116–117, 119, 127.
  70. ^ Stern 1995, p. 754.
  71. ^ King 2000, pp. 93, 97.
  72. ^ Misztal 2017, p. 253.
  73. ^ Misztal 2017, pp. 137–139.
  74. ^ Misztal 2017, p. 137.
  75. ^ Fairley 2019, p. 217.
  76. ^ a b APWA 1972, p. 11.
  77. ^ Cohn & Fleming 1974, p. 106.
  78. ^ Ochsendork & Freeman 2010.
  79. ^ Mitchell 1985, pp. 267–268.
  80. ^ Sharp 2002, p. 49.
  81. ^ Mainstone 2001, p. 134.
  82. ^ Bradshaw et al. 2002, p. 693.
  83. ^ Langmead & Garnaut 2001, p. 131.
  84. ^ Marche 2005.
  85. ^ a b c Cowan 1977, p. 20.
  86. ^ Silk, Gildenhard & Barrow 2017, p. 261.
  87. ^ Muttoni 2011, p. 106.
  88. ^ Langmead & Garnaut 2001, p. 303.
  89. ^ Cowan 1977, p. 19.
  90. ^ a b Morganti et al. 2019, p. 838.
  91. ^ Misztal 2017, p. 86.
  92. ^ Bradshaw et al. 2002, pp. 693–694, 697.
  93. ^ Jelica & Sedmak 2020, pp. 1833–1834.
  94. ^ Bradshaw et al. 2002, p. 705.
  95. ^ a b Skejić, Boko & Torić 2015, p. 1081.
  96. ^ Sharp 2002, p. 187.
  97. ^ Cadbury-Brown 2001, p. 63.
  98. ^ Langmead & Garnaut 2001, pp. 131–132.
  99. ^ Zung 2002, p. 26.
  100. ^ Langmead & Garnaut 2001, p. 132.
  101. ^ Kádár 2011, p. 26.
  102. ^ Levy & Salvadori 2002, pp. 322–323.
  103. ^ Bradshaw et al. 2002, pp. 701–702.
  104. ^ a b c d Charlier.
  105. ^ Bradshaw et al. 2002, pp. 700, 703.
  106. ^ Bradshaw et al. 2002, p. 703.
  107. ^ Nenadović 2010, pp. 58–60.
  108. ^ Silk, Gildenhard & Barrow 2017, p. 260.
  109. ^ Nenadović 2010, p. 59.
  110. ^ Barnes & Dickson 2000, p. 13.
  111. ^ Friedman & Farkas 2011, p. 49.
  112. ^ Van Den Heuvel 2008, pp. 161–162.
  113. ^ Petroski 2011, p. 114.
  114. ^ Cowan 1983, p. 193.
  115. ^ Glenday 2008, p. 365.
  116. ^ a b Friedman & Farkas 2011, pp. 42–43, 46.
  117. ^ McNeil 2002, p. 882.
  118. ^ Hourihane 2012, p. 303.
  119. ^ Morganti et al. 2019, p. 841.
  120. ^ Lewis & King 2014, p. 127.

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December 14, 2023
history, modern, period, domes, domes, built, 19th, 20th, 21st, centuries, benefited, from, more, efficient, techniques, producing, iron, steel, well, advances, structural, analysis, metal, framed, domes, 19th, century, often, imitated, earlier, masonry, dome,. Domes built in the 19th 20th and 21st centuries benefited from more efficient techniques for producing iron and steel as well as advances in structural analysis Metal framed domes of the 19th century often imitated earlier masonry dome designs in a variety of styles especially in church architecture but were also used to create glass domes over shopping arcades and hothouses domes over locomotive sheds and exhibition halls and domes larger than any others in the world The variety of domed buildings such as parliaments and capitol buildings gasometers observatories libraries and churches were enabled by the use of reinforced concrete ribs lightweight papier mache and triangulated framing In the 20th century planetarium domes spurred the invention by Walther Bauersfeld of both thin shells of reinforced concrete and geodesic domes The use of steel computers and finite element analysis enabled yet larger spans Tension membrane structure became popular for domed sports stadiums which also innovated with rigid retractable domed roofs Contents 1 Nineteenth century 1 1 Developments 1 1 1 Materials 1 1 2 Structure 1 1 3 Style 1 2 Religious and royal buildings 1 3 Commercial buildings 1 4 Greenhouses and conservatories 1 5 Libraries 1 6 Governmental buildings 1 7 Industrial buildings 1 8 Tombs 2 Twentieth century 2 1 Developments 2 2 Guastavino tile 2 3 Steel and concrete 2 4 Reticular and geodesic domes 2 5 Tension and membranes 2 6 Retractable domes and stadiums 3 Twenty first century 4 References 5 BibliographyNineteenth century editDevelopments edit Materials edit New production techniques allowed for cast iron and wrought iron to be produced both in larger quantities and at relatively low prices during the Industrial Revolution 1 Most iron domes were built with curved iron ribs arranged radially from the top of the dome to a ring at the base The material of choice for domes changed over the course of the 19th century from cast iron to wrought iron to steel 2 Excluding domes that simply imitated multi shell masonry the century s chief development of the simple domed form may be metal framed domes such as the circular dome of Halle au Ble in Paris and the elliptical dome of Royal Albert Hall in London 3 The practice of building rotating domes for housing large telescopes became popular in the 19th century with early examples using papier mache to minimize weight 4 Beginning in the late 19th century the Guastavino family a father and son team who worked on the eastern seaboard of the United States further developed the masonry dome They perfected a traditional Spanish and Italian technique for light center less vaulting using layers of tiles in fast setting cement set flat against the surface of the curve rather than perpendicular to it The father Rafael Guastavino innovated with the use of Portland cement as the mortar rather than the traditional lime and gypsum mortars which allowed mild steel bar to be used to counteract tension forces 5 Although domes made entirely from reinforced concrete were not built before 1900 the church of Saint Jean de Montmartre was designed by Anatole de Baudot with a small brick shell dome with reinforced concrete ribs 6 Structure edit Proportional rules for an arch s thickness to span ratio were developed during the 19th century based on catenary shape changes in response to weight loads and these were applied to the vertical forces in domes Edmund Beckett Denison who had published a proof on the subject in 1871 wrote in a Domes article in the Ninth Edition of the Encyclopaedia Britannica that the thickness to span ratio was lower for a dome than it was for an arch due to the more distributed loads of a dome 7 Ideas on linear elasticity were formalized in the 19th century 8 The span of the ancient Pantheon dome although matched during the Renaissance remained the largest in the world until the middle of the 19th century 9 The large domes of the 19th century included exhibition buildings and functional structures such as gasometers and locomotive sheds 10 Domes made of radial trusses were analyzed with a plane frame approach rather than considering three dimensions until an 1863 Berlin gasometer dome design by engineer Johann Wilhelm Schwedler that became known as the Schwedler dome He published the theory behind five such domes and a structural calculation technique in 1866 Schwedler s work on these axially symmetric shells was expanded by August Foppl in 1892 to apply to other shell type truss frameworks 11 By the 1860s and 1870s German and other European engineers began to treat iron domes as collections of short straight beams with hinged ends resulting in light openwork structures Other than in glasshouses these structures were usually hidden behind ceilings 12 Dome types that used lengths of rolled steel with riveted joints included Schwedler domes Zimmermann domes lattice domes and Schlink domes 11 According to Irene Giustina dome construction was one of the most challenging architectural problems until at least the end of the 19th century due to a lack of knowledge about statics 13 Rafael Guastavino s use of the recent development of graphic statics enabled him to design and build inexpensive funicular domes with minimal thickness and no scaffolding The vaults were typically 3 inches thick and workers standing on the completed portions used simple templates wires and strings to align their work 14 Style edit The historicism of the 19th century led to many domes being re translations of the great domes of the past rather than further stylistic developments especially in sacred architecture 15 The Neoclassical style popular at this time was challenged in the middle of the 19th century by a Gothic Revival in architecture in what has been termed the Battle of the Styles This lasted from about 1840 to the beginning of the 20th century with various styles within Classicism such as Renaissance Baroque and Rococo revivals also vying for popularity The last three decades of this period included unusual combinations of these styles 16 Religious and royal buildings edit nbsp Kazan Cathedral and Saint Isaac s Cathedral background in Russia Iron domes offered the lightness of timber construction along with incombustibility and higher strength allowing for larger spans Because domes themselves were relatively rare the first examples made from iron date well after iron began to be used as a structural material 2 Iron was used in place of wood where fire resistance was a priority In Russia which had large supplies of iron some of the earliest examples of the material s architectural use can be found Andrey Voronikhin built a large wrought iron dome over Kazan Cathedral in Saint Petersburg 17 Built between 1806 and 1811 the 17 7 meter wide outer dome of the cathedral was one of the earliest iron domes 18 The iron outer dome covers two masonry inner domes and is made of 15 mm thick sheets set end to end 19 An early example from Britain is within the fanciful iron framed dome over the central building of the Royal Pavilion in Brighton begun in 1815 by John Nash the personal architect of King George IV 20 The dome was not one of the prominent onion domes but instead the dome like structure of twelve cast iron ribs resting on cast iron columns over Henry Holland s earlier saloon It was completed in 1818 1819 19 The neoclassical Baltimore Basilica designed by Benjamin Henry Latrobe like the Roman Pantheon for Bishop John Carroll was begun in 1806 and dedicated in 1821 although the porch and towers would not be completed until the 1870s An influence on the interior design may have been the Church of St Mary in East Lulworth England where Bishop Carroll had been consecrated 21 The central dome is 72 feet in diameter and 52 feet above the nave floor The onion domes over the two towers were built according to Latrobe s designs The church was extended to the east by 33 feet in 1890 22 Before initial construction of the church was completed two other neoclassical domed churches would be built in Baltimore The First Independent Unitarian Church by Maximilian Godefroy was begun in 1817 and covered the interior space with a 55 foot wide shallow coffered dome on pendentives with an oculus at the center To improve acoustics the interior was modified The First Baptist Church by Robert Mills also known as Old Red Top Church was a domed cylindrical rotunda with a porch block and portico The dome had a shallow exterior profile and its oculus was covered by a low lantern called a monitor It was completed in 1818 but demolished in 1878 23 In 1828 the eastern crossing tower of Mainz Cathedral was rebuilt by Georg Moller with a wrought iron dome 24 The dome was made of flat iron sections and reinforced with ties that passed through the interior of the dome Such dome reinforcement was one of the two established techniques the other being the use of a combination of horizontal rings and vertical ribs 10 The span may have been about 27 meters 25 It was later removed in favor of the current structure 26 The Altes Museum in Berlin built in 1828 by Karl Schinkel included a dome in its entrance hall inspired by the Roman Pantheon 27 Large neoclassical domes include the Rotunda of Mosta in Malta was completed in 1840 with a dome 38 meters wide and San Carlo al Corso in Milan completed in 1847 with a dome 32 meters wide 28 Saint Isaac s Cathedral in Saint Petersburg was built by 1842 with one of the largest domes in Europe A cast iron dome nearly 26 meters wide it had a technically advanced triple shell design with iron trusses reminiscent of St Paul s Cathedral in London 29 The design for the cathedral was begun after the defeat of Napoleon in 1815 and given to a French architect but construction was delayed Although the dome was originally designed to be masonry cast iron was used instead 6 Also reminiscent of St Paul s dome and that of the Pantheon in Paris both of which the original designer had visited the dome of St Nicholas Church in Potsdam was added to the building from 1843 to 1849 30 A dome was included as a possibility in the original late Neoclassical design of 1830 but as a wooden construction Iron was used instead by the later architects 31 Other examples of framed iron domes include those of a synagogue in Berlin by Schwedler in 1863 and the Bode Museum by Muller Breslau in 1907 32 The wrought iron dome of Royal Albert Hall in London was built from 1867 to 1871 over an elliptical plan by architect Henry Young Darracott Scott and structural design by Rowland Mason Ordish It uses a set of curved trusses like those of the earlier New Street Station in Birmingham interrupted in the middle by a drum The elliptical dome s span is 66 9 meters by 56 5 meters 33 The wrought iron dome of St Augustin s church in Paris dates from 1870 and spans 25 2 meters A wrought iron dome was also built over Jerusalem s Holy Sepulchre in 1870 spanning 23 meters 34 The dome over the Basilica of San Gaudenzio begun in 1577 in Novara Italy was built between 1844 and 1880 Revisions by the architect during construction transformed what was initially going to be a drum hemispherical dome and lantern 42 22 meters tall into a structure with two superimposed drums an ogival dome and a thirty meter tall spire reaching 117 5 meters 35 The architect Alessandro Antonelli who also built the Mole Antonelliana in Turin Italy combined Neoclassical forms with the vertical emphasis of the Gothic style 36 A large dome was built in 1881 1882 over the circular courtyard of the Devonshire Royal Hospital in England with a diameter of 156 feet 37 It used radial trussed ribs with no diagonal ties 32 The dome of Pavia Cathedral a building started in 1488 was completed with a large octagonal dome joined to the basilica plan of the church 38 Commercial buildings edit Although iron production in France lagged behind Britain the government was eager to foster the development of its domestic iron industry In 1808 the government of Napoleon approved a plan to replace the burnt down wooden dome of the Halle au Ble granary in Paris with a dome of iron and glass the earliest example of metal with glass in a dome The dome was 37 meters in diameter and used 51 cast iron ribs to converge on a wrought iron compression ring 11 meters wide containing a glass and wrought iron skylight The outer surface of the dome was covered with copper with additional windows cut near the dome s base to admit more light during an 1838 modification 39 Cast iron domes were particularly popular in France 40 In the United States an 1815 commission to build the Baltimore Exchange and Custom House was awarded to Benjamin Henry Latrobe and Maximilian Godefroy for their design featuring a prominent central dome The dome design was altered during construction to raise its height to 115 feet by adding a tall drum and work was completed in 1822 Signals from an observatory on Federal Hill were received at an observation post in the dome providing early notice of arriving merchant vessels The building was demolished in 1901 2 41 The Coal Exchange in London by James Bunning from 1847 to 1849 included a dome 18 meters wide made from 32 iron ribs cast as single pieces It was demolished in the early 1960s 42 Large temporary domes were built in 1862 for London s International Exhibition Building spanning 48 8 meters 34 The Leeds Corn Exchange built in 1862 by Cuthbert Brodrick features an elliptical plan dome 38 9 meters by 26 7 meters with wrought iron ribs along the long axis that radiate from the ends and others spanning the short axis that run parallel to each other forming a grid pattern 33 nbsp The Galleria Umberto I in Italy Elaborate covered shopping arcades such as the Galleria Vittorio Emanuele II in Milan and the Galleria Umberto I in Naples included large glazed domes at their cross intersections 43 44 The dome of the Galleria Vittorio Emanuele II 1863 1867 rises to 145 feet above the ground and has the same span as the dome of St Peter s Basilica with sixteen iron ribs over an octagonal space at the intersection of two covered streets It is named after the first king of a united Italy 44 The central market hall in Leipzig was built by 1891 with the first application of the lattice dome roof system developed by August Foppl from 1883 The dome covered an irregular pentagonal plan and was about 20 meters wide and 6 8 meters high 11 Vladimir Shukhov was an early pioneer of what would later be called gridshell structures and in 1897 he employed them in domed exhibit pavilions at the All Russia Industrial and Art Exhibition 45 The dome of Sydney s Queen Victoria Building uses radial ribs of steel along with redundant diagonal bracing to span 20 meters It was claimed to be the largest dome in the Southern Hemisphere when completed in 1898 32 Greenhouses and conservatories edit Iron and glass glasshouses with curved roofs were popular for a few decades beginning shortly before 1820 to maximize orthogonality to the sun s rays although only a few have domes The conservatory at Syon Park was one of the earliest and included a 10 8 meter span iron and glass dome by Charles Fowler built between 1820 and 1827 The glass panes are set in panels joined by copper or brass ribs between the 23 main cast iron ribs Another example was the conservatory at Bretton Hall in Yorkshire completed in 1827 but demolished in 1832 upon the death of the owner It had a 16 meter wide central dome of thin wrought iron ribs and narrow glass panes on a cast iron ring and iron columns The glass acted as lateral support for the iron ribs 46 The Antheum at Brighton would have had the largest span dome in the world in 1833 at 50 meters but the circular cast iron dome collapsed when the scaffolding was removed 47 Unique glass domes springing straight from ground level were used for hothouses and winter gardens such as the Palm house at Kew 1844 48 and the Laeken winter garden near Brussels 1875 1876 48 The Laeken dome spans the central 40 meters of the circular building resting on a ring of columns The Kibble Palace of 1865 was re erected in 1873 in an enlarged form with a 16 meter wide central dome on columns The Palm House at Sefton Park in Liverpool has an octagonal central dome also 16 meters wide and on columns completed in 1896 49 Libraries edit The domed rotunda building of the University of Virginia was designed by Thomas Jefferson and completed in 1836 27 The British Museum Library constructed a new reading room in the courtyard of its museum building between 1854 and 1857 The round room about 42 6 meters in diameter and inspired by the Pantheon was surmounted by a dome with a ring of windows at the base and an oculus at the top Hidden iron framing supported a suspended ceiling made of papier mache 50 A cast iron dome was built between 1860 and 1867 over the reading room of the Bibliotheque nationale in Paris 40 Inspired by the prestigious British Museum reading room the first iron dome in Canada was built in the early 1870s over the reading room of the Library of Parliament building in Ottawa Unlike the British Museum room the library which opened in 1876 uses the Gothic style 51 The dome of the Thomas Jefferson Building of the Library of Congress also inspired by the reading room dome at the British Museum was built between 1889 and 1897 in a classical style It is 100 feet wide and rises 195 feet above the floor on eight piers The dome has a relatively low external profile to avoid overshadowing the nearby United States Capitol dome 52 The Boston Public Library 1887 1898 includes dome vaulting by Rafael Guastavino 53 Governmental buildings edit nbsp The United States Capitol nbsp The Hungarian Parliament Building See also List of state and territorial capitols in the United States The design for the United States national capitol building approved by George Washington included a dome modeled on the Pantheon with a low exterior elevation Subsequent design revisions resulted in a double dome with a raised external profile on an octagonal drum and construction did not begin until 1822 The interior dome was built of stone and brick except for the upper third which was made of wood The exterior dome was wooden and covered with copper sheeting 54 The dome and building were completed by Charles Bulfinch in 1829 55 Most of the 50 state capitol buildings or statehouses with domes in the United States cover a central rotunda or hall of the people due to the use of a bicameral legislature The Pennsylvania capitol building designed by Stephen Hills in Harrisburg was the earliest to combine all the elements that would subsequently become characteristic of state capitol buildings dome rotunda portico and two legislative chambers Like the design of the national capitol the design was chosen through a formal competition 56 Early domed state capitol buildings include those of North Carolina as remodeled by William Nichols Alabama in Tuscaloosa Mississippi Maine 1832 Kentucky Connecticut in New Haven Indiana North Carolina as rebuilt Missouri very similar to Hills Harrisburg design Minnesota later rebuilt Texas and Vermont 1832 57 The current dome over the United States Capitol building although painted white and crowning a masonry building is made of cast iron The dome was built between 1855 and 1866 replacing a lower wooden dome with copper roofing from 1824 58 It has a 30 meter diameter 40 It was completed just two years after the Old St Louis County Courthouse which has the first cast iron dome built in the United States 59 The initial design of the capitol dome was influenced by a number of European church domes particularly St Paul s in London St Peter s in Rome the Pantheon in Paris Les Invalides in Paris and St Isaac s Cathedral in St Petersburg 60 The architect Thomas U Walter designed a double dome interior based on that of the Pantheon in Paris 58 Dome construction for state capitol buildings and county courthouses in the United States flourished in the period between the American Civil War and World War I 61 Most capitols built between 1864 and 1893 were landmarks for their cities and had gilded domes 62 Examples from the Gilded Age include those of California Kansas Connecticut Colorado Idaho Indiana Iowa Wyoming Michigan Texas and Georgia 63 Many American state capitol building domes were built in the late 19th or early 20th century in the American Renaissance style and cover rotundas open to the public as commemorative spaces Examples include the Indiana State House Texas State Capitol and the Wisconsin State Capitol 64 American Renaissance capitols also include those of Rhode Island and Minnesota 63 The Reichstag Palace built between 1883 and 1893 to house the Parliament of the new German Empire included a dome made of iron and glass as part of its unusual mixture of Renaissance and Baroque components Controversially the 74 meter tall dome stood seven meters taller than the dome of the Imperial Palace in the city drawing criticism from Kaiser Wilhelm II 65 Hermann Zimmermann assisted the architect Paul Wallot in 1889 inventing the spatial framework for the dome over the plenary chamber It is known as the Zimmermann dome 11 The Hungarian Parliament Building was built in the Gothic style although most of the 1882 design competition entries used Neo Renaissance and it includes a domed central hall The large ribbed egg shaped dome topped with a spire was influenced by the dome of the Maria vom Siege church in Vienna 66 It has a sixteen sided outer shell with an iron skeleton that rises 96 meters high and an inner shell star vault supported on sixteen stone pillars The Dome Hall is used to display the coronation crown of Hungary and statuary of monarchs and statesmen The dome was structurally complete by the end of 1895 67 Industrial buildings edit The first fully triangulated framed dome was built in Berlin in 1863 by Johann Wilhelm Schwedler in a gasometer for the Imperial Continental Gas Association and by the start of the 20th century similarly triangulated frame domes had become fairly common 68 45 Schwedler built three wrought iron domes over gasholders in Berlin between 1876 and 1882 with spans of 54 9 meters one of which survives Six similar Schwedler type domes were used over gasholders in Leipzig beginning in 1885 and in Vienna using steel in the 1890s Rather than using traditional iron ribs the domes consist of a thinner arrangement of short straight iron bars connected with pin joints in a lattice shell with cross bracing provided by light iron rods 69 Tombs edit The dome of Grant s Tomb in New York City was built by Rafael Guastavino in 1890 53 70 Twentieth century editDevelopments edit American state capitol domes built in the twentieth century include those of Arizona Mississippi Pennsylvania Wisconsin Idaho Kentucky Utah Washington Missouri and West Virginia The West Virginia capitol building has been called the last American Renaissance capitol 71 Wooden domes in thin wall shells on ribs were made until the 1930s 72 After World War II steel and wooden laminate structural members made with waterproof resorcinol glues were used to create domes with grid patterned wooden support structures such as the 100 meter diameter Skydome in Flagstaff Arizona 73 Stand alone dome structures were used to house public utility facilities in the 20th century 74 The Fitzpatrick dome designed by John Fitzpatrick as an inexpensive structure to store winter road service sand and salt has been used in countries around the world 75 76 The first was built in 1968 76 The domes have twenty sides and are normally 100 feet in diameter and a little more than 50 feet tall The conical shape is meant to conform to the 45 degree slope of a pile of wet sand They are built on concrete footings and covered with asphalt shingles 77 Guastavino tile edit The Guastavino family a father and son team who worked on the eastern seaboard of the United States built vaults using layers of tiles in hundreds of buildings in the late 19th and early 20th centuries including the domes of the Basilica of St Lawrence in Asheville North Carolina and St Francis de Sales Roman Catholic Church in Philadelphia Pennsylvania 78 The dome over the crossing of the Cathedral of St John the Divine in New York City was built by the son in 1909 A part spherical dome it measures 30 meters in diameter from the top of its merging pendentives where steel rods embedded in concrete act as a restraining ring With an average thickness 1 250th of its span and steel rods also embedded within the pendentives the dome looked forward to modern shell construction in reinforced concrete 5 Steel and concrete edit nbsp The Kresge Auditorium in Massachusetts Domes built with steel and concrete were able to achieve very large spans 40 The West Baden Springs Hotel in Indiana was built in 1903 with the largest span dome in the world at 200 feet Its metal and glass skin was supported by steel trusses resting on metal rollers to allow for expansion and contraction from temperature changes It was surpassed in span by the Centennial Hall of Max Berg 79 The 1911 dome of the Melbourne Public Library reading room presumably inspired by the British Museum had a diameter of 31 5 meters and was briefly the widest reinforced concrete dome in the world until the completion of the Centennial Hall 6 The Centennial Hall was built with reinforced concrete in Breslau Germany today Poland from 1911 13 to commemorate the 100 year anniversary of the uprising against Napoleon With a 213 foot wide central dome surrounded by stepped rings of vertical windows it was the largest building of its kind in the world 80 Other examples of ribbed domes made entirely of reinforced concrete include the Methodist Hall in Westminster London the Augsburg Synagogue and the Orpheum Theater in Bochum 6 The 1928 Leipzig Market Hall by Deschinger and Ritter featured two 82 meter wide domes 40 The thin domical shell was further developed with the construction of two domes in Jena Germany in the early 1920s To build a rigid planetarium dome Walther Bauersfeld constructed a triangulated frame of light steel bars and mesh with a domed formwork suspended below it By spraying a thin layer of concrete onto both the formwork and the frame he created a 16 meter wide dome that was just 30 millimeters thick The second dome was still thinner at 40 meters wide and 60 millimeters thick 81 These are generally taken to be the first modern architectural thin shells 82 These are also considered the first geodesic domes 83 Beginning with one for the Deutsches Museum in Munich 15 domed projection planetariums using concrete shells up to 30 meters wide had been built in Europe by 1930 and that year the Adler Planetarium in Chicago became the first planetarium to open in the Western Hemisphere 84 Planetarium domes required a hemispherical surface for their projections but most 20th century shell domes were shallow to reduce the material costs simplify construction and reduce the volume of air needing to be heated 85 In India the Viceroy s House in New Delhi was designed in 1912 1913 by Edwin Lutyens with a dome 86 Although an equation for the bending theory of a thick spherical shell had been published in 1912 based on general equations from 1888 it was too complex for practical design work A simplified and more approximate theory for domes was published in 1926 in Berlin The theory was tested using sheet metal models with the conclusion that the membrane stresses in domes are small with little reinforcement required especially at the top where openings could be cut for light Only the concentrated stresses at point supports required heavy reinforcement 85 Early examples used a relatively thick bordering girder to stabilize exposed edges Alternative stabilization techniques include adding a bend at these edges to stiffen them or increasing the thickness of the shell itself at the edges and near the supports 87 In 1933 34 Spanish engineer architect Eduardo Torroja with Manuel Sanchez designed the Market Hall in Algeciras Spain with a thin shell concrete dome The shallow dome is 48 meters wide 9 centimeters thick and supported at points around its perimeter 88 The indoor stadium for the 1936 Olympic Games in Berlin used an oval dome of concrete shell 35 meters wide and 45 meters long 89 The use of metal structures in Italy was reduced in the first half of the 20th century by autarchy and the demands of the world wars 90 Steel became broadly used in building construction in the 1930s 91 A shortage of steel following World War II and the demonstrated vulnerability of exposed steel to damage from intense fires during the war may have contributed to the popularity of concrete architectural shells beginning in the late 1940s In the 1960s improvements in welding and bolting techniques and higher labor costs made steel frames more economical 85 Popularized by a 1955 article on the work of Felix Candela in Mexico architectural shells had their heyday in the 1950s and 1960s peaking in popularity shortly before the widespread adoption of computers and the finite element method of structural analysis Notable examples of domes include the Kresge Auditorium at MIT which has a spherical shell 49 meters wide and 89 millimeters thick and the Palazzetto dello Sport with a 59 meter wide dome designed by Pier Luigi Nervi 92 Built from 1955 to 1957 the prestressed concrete dome of the main exhibition hall of the Belgrade Fair has a span of 106 meters It was designed by Branko Zezelj using a pre stressing system developed by him and was the largest dome in the world until 1965 It remains the largest dome in Europe 93 Reticular and geodesic domes edit nbsp The Amundsen Scott South Pole Station in Antarctica Structurally geodesic domes are also considered shells when the loads are borne by the surface polygons as in the Kaiser Dome but are considered space grid structures when the loads are borne by point to point members 94 A geodesic dome made of welded steel tubes was made in 1935 for the aviary of the Rome Zoo 90 Aluminum reticular domes allow for large dimensions and short building times suitable for sports arenas exhibition centers auditoriums or storage facilities The Dome of Discovery exhibition hall was built in London in 1951 95 It was the largest domed building in the world at the time 365 feet wide 96 97 Other aluminum domes include the 61 meter wide Palasport in Paris 1959 and the 125 meter wide Spruce Goose Dome in Long Beach California 95 Although the first examples were built 25 years earlier by Walther Bauersfeld the term geodesic domes was coined by Buckminster Fuller who received a patent for them in 1954 Geodesic domes have been used for radar enclosures greenhouses housing and weather stations 98 Early examples in the United States include a 53 foot wide dome for the Ford Rotunda in 1953 and a 384 foot diameter dome for the Baton Rouge facility of the Union Tank Car Company in 1958 the largest clear span structure in the world at that time 99 The U S Pavilion at Expo 67 in Montreal Quebec Canada was enclosed by a 76 5 meter wide and 60 meter tall dome made of steel pipes and acrylic panels It is used today as a water monitoring center 100 Other examples include the Amundsen Scott South Pole Station which was used from 1975 to 2003 and the Eden Project in the UK built in 2000 101 Tension and membranes edit nbsp The Millennium Dome in the UK Tensegrity domes patented by Buckminster Fuller in 1962 from a concept by Kenneth Snelson are membrane structures consisting of radial trusses made from steel cables under tension with vertical steel pipes spreading the cables into the truss form They have been made circular elliptical and other shapes to cover stadiums from Korea to Florida 102 While the first permanent air supported membrane domes were the radar domes designed and built by Walter Bird after World War II the temporary membrane structure designed by David Geiger to cover the United States pavilion at Expo 70 was a landmark construction Geiger s solution to a 90 reduction in the budget for the pavilion project was a low profile cable restrained air supported roof employing a superelliptical perimeter compression ring Its very low cost led to the development of permanent versions using teflon coated fiberglass and within 15 years the majority of the domed stadiums around the world used this system including the Silverdome in Pontiac Michigan 103 The restraining cables of such domes are laid diagonally to avoid the sagging perimeter found to occur with a standard grid 104 Tension membrane design has depended upon computers and the increasing availability of powerful computers resulted in many developments being made in the last three decades of the 20th century 105 Weather related deflations of some air supported roofs led David Geiger to develop a modified type the more rigid Cabledome that incorporated Fuller s ideas of tensegrity and aspension rather than being air supported 106 104 The pleated effect seen in some of these domes is the result of lower radial cables stretching between those forming trusses in order to keep the membrane in tension The lightweight membrane system used consists of four layers waterproof fiberglass on the outside insulation a vapor barrier then an acoustic insulation layer This is semitransparent enough to fulfill most daytime lighting needs beneath the dome The first large span examples were two Seoul South Korea sports arenas built in 1986 for the Olympics one 93 meters wide and the other 120 meters wide The Georgia Dome built in 1992 on an oval plan uses instead a triangulated pattern in a system patented as the Tenstar Dome 107 In Japan the Izumo Dome was built in 1992 with a height of 49 meters and a diameter of 143 meters It uses a PTFE coated glass fiber fabric 108 The first cable dome to use rigid steel frame panels as roofing instead of a translucent membrane was begun for an athletic center in North Carolina in 1994 109 The Millennium Dome was completed as the largest cable dome in the world with a diameter of 320 meters and uses a different system of membrane support with cables extending down from the 12 masts that penetrate the membrane 110 Retractable domes and stadiums edit nbsp Ōita Stadium in Japan The higher expense of rigid large span domes made them relatively rare although rigidly moving panels is the most popular system for sports stadiums with retractable roofing 104 111 With a span of 126 meters Pittsburgh s Civic Arena featured the largest retractable dome in the world when completed for the city s Civic Light Opera in 1961 Six of its eight sections could rotate behind the other two within three minutes and in 1967 it became the home of the Pittsburgh Penguins hockey team 112 The Assembly Hall arena at the University of Illinois Urbana Champaign was completed in 1963 with a concrete saucer dome spanning 400 feet The edge of the dome was post tensioned with more than 600 miles of steel cable 113 The first domed baseball stadium the Astrodome in Houston Texas was completed in 1965 with a rigid 641 foot wide steel dome filled with 4 596 skylights Other early examples of rigid stadium domes include the steel frame Superdome of New Orleans and the cement Kingdome of Seattle 104 The Louisiana Superdome has a span of 207 meters 114 Stockholm s 1989 Ericsson Globe an arena for ice hockey earned the title of largest hemispherical building in the world with a diameter of 110 meters and height of 85 meters 115 Montreal s Olympic Stadium featured a retractable membrane roof in 1988 although repeated tearing led to its replacement with a non retractable roof The SkyDome of Toronto opened in 1989 with a rigid system in four parts one that is fixed two that slide horizontally and one that rotates along the edge of the 213 meter wide span In Japan the 1993 Fukuoka Dome featured a 222 meter dome in three parts two of which rotated under the third 116 Twenty first century editThe variety of modern domes over sports stadiums exhibition halls and auditoriums have been enabled by developments in materials such as steel reinforced concrete and plastics 117 Their uses over department stores and futuristic video hologram entertainment centres exploit a variety of non traditional materials 118 The use of design processes that integrate numerical control machines computer design virtual reconstructions and industrial prefabrication allow for the creation of dome forms with complex geometry such as the 2004 ellipsoid bubbles of Nardini Company s production district designed by Massimiliano Fuksas 119 Ōita Stadium was built in 2001 as a mostly fixed semi spherical roof 274 meters wide with two large membrane covered panels that can slide down from the center to opposite sides 116 Singapore s National Stadium was completed in 2014 with the largest dome in the world at 310 meters in span It uses a post tensioned concrete ring beam to support steel trusses that enable two halves of a section of the dome to retract 120 References edit Gayle amp Gayle 1998 p 14 a b Sutherland 2000 p 111 Mainstone 2001 p 241 Lippincott 2008 p 26 a b Mainstone 2001 p 129 a b c d Cowan 1983 p 191 Cowan 1977 p 17 Bellini 2017 p 3 Cowan 1983 p 183 a b Kohlmaier amp Von Sartory 1991 p 126 a b c d Kurrer 2012 Sutherland 2000 pp 116 118 Giustina 2003 p 1033 Allen 2004 pp 69 71 Stephenson Hammond amp Davi 2005 p 190 Miller amp Clinch 1998 p 30 Gayle amp Gayle 1998 pp 13 18 26 Skempton 2002 p 785 a b Sutherland 2000 p 112 Gayle amp Gayle 1998 p 23 Alexander 2004 pp 71 73 Zanow amp Johnston 2010 p 22 Alexander 2004 pp 83 85 Gayle amp Gayle 1998 p 24 Sutherland 2000 p 119 Landeshauptstadt Mainz 2013 a b Silk Gildenhard amp Barrow 2017 p 257 Cowan 1977 p 11 Gayle amp Gayle 1998 p 26 Fraser 1996 p 129 Scheunemann amp Omilanowska 2012 p 203 a b c Sutherland 2000 p 117 a b Sutherland 2000 p 116 a b Sutherland 2000 pp 115 119 Zanon et al 2001 Filemio 2009 pp 139 141 Pevsner amp Williamson 1978 p 114 Castex 2008 p xli Gayle amp Gayle 1998 pp 22 23 a b c d e Hourihane 2012 p 304 Alexander 2004 pp 75 78 Sutherland 2000 p 115 Coleman 2006 p 32 a b Castex 2008 pp 56 58 a b Dimcic 2011 p 8 Sutherland 2000 p 113 Sutherland 2000 pp 114 119 Kohlmaier amp Von Sartory 1991 pp 126 127 Sutherland 2000 pp 114 115 British Museum Young 1995 pp 20 22 89 100 Cole amp Reed 1997 p 25 a b Allen 2004 p 69 Allen 2001 p 146 King 2000 pp 88 89 King 2000 pp 89 90 King 2000 pp 90 92 94 a b aoc gov Condit 1968 p 27 Allen 2001 p 226 Mitchell 1985 p 262 Seale 1975 p 14 a b King 2000 p 93 Goodsell 1993 pp 294 298 299 Rizzoni 2009 p 186 Moravanszky 1998 Villam et al 2006 pp 67 68 74 Mainstone 2001 p 171 Sutherland 2000 pp 116 117 119 127 Stern 1995 p 754 King 2000 pp 93 97 Misztal 2017 p 253 Misztal 2017 pp 137 139 Misztal 2017 p 137 Fairley 2019 p 217 a b APWA 1972 p 11 Cohn amp Fleming 1974 p 106 Ochsendork amp Freeman 2010 Mitchell 1985 pp 267 268 Sharp 2002 p 49 Mainstone 2001 p 134 Bradshaw et al 2002 p 693 Langmead amp Garnaut 2001 p 131 Marche 2005 a b c Cowan 1977 p 20 Silk Gildenhard amp Barrow 2017 p 261 Muttoni 2011 p 106 Langmead amp Garnaut 2001 p 303 Cowan 1977 p 19 a b Morganti et al 2019 p 838 Misztal 2017 p 86 Bradshaw et al 2002 pp 693 694 697 Jelica amp Sedmak 2020 pp 1833 1834 Bradshaw et al 2002 p 705 a b Skejic Boko amp Toric 2015 p 1081 Sharp 2002 p 187 Cadbury Brown 2001 p 63 Langmead amp Garnaut 2001 pp 131 132 Zung 2002 p 26 Langmead amp Garnaut 2001 p 132 Kadar 2011 p 26 Levy amp Salvadori 2002 pp 322 323 Bradshaw et al 2002 pp 701 702 a b c d Charlier Bradshaw et al 2002 pp 700 703 Bradshaw et al 2002 p 703 Nenadovic 2010 pp 58 60 Silk Gildenhard amp Barrow 2017 p 260 Nenadovic 2010 p 59 Barnes amp Dickson 2000 p 13 Friedman amp Farkas 2011 p 49 Van Den Heuvel 2008 pp 161 162 Petroski 2011 p 114 Cowan 1983 p 193 Glenday 2008 p 365 a b Friedman amp Farkas 2011 pp 42 43 46 McNeil 2002 p 882 Hourihane 2012 p 303 Morganti et al 2019 p 841 Lewis amp King 2014 p 127 Bibliography editAlexander Robert L 2004 Hayward Mary Ellen Shivers Frank R Jr eds The Architecture of Baltimore An Illustrated History illustrated ed JHU Press ISBN 978 0 801 87806 0 a href Template Cite book html title Template Cite book cite book a CS1 maint multiple names editors list link Allen Edward 2004 Guastavino Dieste and the Two Revolutions in Masonry Vaulting In Anderson Stanford ed Eladio Dieste Innovation in Structural Art illustrated ed Princeton Architectural Press pp 66 93 ISBN 978 1 568 98371 4 Allen William C 2001 Senate Document 106 29 History of the United States Capitol A Chronicle of Design Construction and Politics U S Government Printing Office The APWA Reporter Volumes 39 40 American Public Works Association 1972 The United States Capitol Dome Architect of the Capitol retrieved November 28 2010 Barnes Michael R Dickson Michael 2000 Preface and Overview The Evolution of Longspan Lightweight Structures In Barnes Michael R Dickson Michael eds Widespan Roof Structures illustrated ed Thomas Telford ISBN 978 0 727 72877 7 Bellini Federico 2017 8 Vaults and Domes Statics as an Art In Mallgrave Harry Francis Payne Alina eds Companion to the History of Architecture Volume I Renaissance and Baroque Architecture John Wiley amp Sons Ltd doi 10 1002 9781118887226 wbcha009 ISBN 978 1 118 88722 6 Bradshaw Richard Campbell David Gargari Mousa Mirmiran Amir Tripeny Patrick June 1 2002 Special Structures Past Present and Future PDF Journal of Structural Engineering Madrid American Society of Civil Engineers ASCE 128 6 691 709 doi 10 1061 ASCE 0733 9445 2002 128 6 691 British Museum Reading Room British Museum retrieved October 13 2011 Cadbury Brown H T 2001 A Good Time and a Half Was Had by All Twentieth Century Architecture Great Britain The Twentieth Century Society 5 1 24 JSTOR 41861909 Castex Jean 2008 Architecture of Italy Reference Guides to National Architecture Westport CT Greenwood Press ISBN 978 0 313 32086 6 Charlier Claude 1988 After a While Nothing Seems Strange in a Stadium with a Lid Smithsonian retrieved February 28 2013 Cohn Morris Mandel Fleming Rodney R eds 1974 Managing Snow Removal and Ice Control Programs A Practical Guide to the How When where and why of Effective Public Work Practices Issue 42 of Special report American Public Works Association American Public Works Association Cole John Young Reed Henry Hope 1997 Small Herbert ed The Library of Congress the Art and Architecture of the Thomas Jefferson Building illustrated ed W W Norton amp Company ISBN 978 0 393 04563 5 Coleman Peter 2006 Shopping Environments illustrated ed Routledge ISBN 978 0 750 66001 3 Condit Carl W 1968 American Building Materials and Techniques from the First Colonial Settlements to the Present 2nd ed University of Chicago Press first cast iron dome Cowan Henry J 1977 A History of Masonry and Concrete Domes in Building Construction Building and Environment Great Britain Pergamon Press 12 1 24 doi 10 1016 0360 1323 77 90002 6 hdl 2027 mdp 39015041999635 Cowan Henry J 1983 Domes Ancient and Modern Journal of the Royal Society of Arts Royal Society for the Encouragement of Arts Manufactures and Commerce 131 5320 181 198 JSTOR 41373544 Dimcic Milos 2011 Structural Optimization of Grid Shells Based on Genetic Algorithms Forschungsbericht 32 PDF Stuttgart Institut fur Tragkonstruktionen und Konstruktives Entwerfen ISBN 978 3 922302 32 2 Fairley Grant D 2019 Up to the Cottage Memories of Muskoka Lulu Press Inc ISBN 978 1 329 27064 0 Filemio Valentina 2009 Guarini Juvarra e Antonelli Segni e Simboli per Torino In Williams Kim ed Nexus Network Journal 11 1 Architecture and Mathematics Springer Science amp Business Media ISBN 978 3 764 38974 1 Fraser Derek 1996 Buildings of Europe Berlin Manchester UK Manchester University Press ISBN 0 7190 4022 1 Friedman Noemi Farkas Gyorgy 2011 Roof Structures in Motion On Retractable and Deployable Roof Structures Enabling Quick Construction or Adaptation to External Excitations PDF Concrete Structures pp 41 50 Gayle Margot Gayle Carol 1998 Cast iron architecture in America the significance of James Bogardus illustrated ed W W Norton amp Company ISBN 978 0 393 73015 9 Giustina Irene 2003 On the art and the culture of domes Construction in Milan and Lombardy in the late sixteenth and in the first half of the seventeenth century PDF Proceedings of the First International Congress on Construction History Madrid Spain Sociedad Espanola de Historia de la Construccion pp 1033 1042 Glenday Craig ed 2008 Guinness World Records 2008 Bantam Books ISBN 978 0 553 58995 5 Goodsell Charles T 1993 Political Meanings of the American State Capitol Journal of Architectural and Planning Research Locke Science Publishing Company Inc 10 4 294 307 JSTOR 43029096 Hourihane Colum ed 2012 The Grove Encyclopedia of Medieval Art and Architecture Oxford University Press ISBN 978 0 19 539536 5 Jelica Mirjana Sedmak Aleksandar 2020 The Largest Pre stressed Concrete Dome in the World the Case Study of Hall 1 of the Belgrade Fair Procedia Structural Integrity Elsevier B V 28 1833 1838 doi 10 1016 j prostr 2020 11 006 S2CID 229615052 Kadar Balint 2011 World Exhibitions as Laboratories for Structural Innovation Periodica Polytechnica Architecture Budapest University of Technology and Economics 42 1 23 31 doi 10 3311 pp ar 2011 1 03 Retrieved April 8 2014 King Julia 2000 The American Dome Symbol of Democracy Domes Papers Read at the Annual Symposium of the Society of Architectural Historians of Great Britain Society of Architectural Historians of Great Britain pp 83 98 Kohlmaier Georg Von Sartory Barna 1991 Houses of Glass a Nineteenth Century Building Type Translated by John C Harvey illustrated ed MIT Press ISBN 978 0 262 61070 4 Kurrer Karl Eugen 2012 The History of the Theory of Structures From Arch Analysis to Computational Mechanics John Wiley amp Sons p 848 ISBN 978 3 433 60134 1 St Martin s Cathedral 1000 years of city history Landeshauptstadt Mainz 2013 retrieved February 20 2013 Langmead Donald Garnaut Christine 2001 Encyclopedia of Architectural and Engineering Feats 3rd ed ABC CLIO ISBN 978 1 57607 112 0 Levy Matthys Salvadori Mario 2002 Why buildings Fall Down How Structures Fail illustrated reprint ed W W Norton amp Company ISBN 978 0 393 31152 5 Lewis Clive King Mike 2014 Designing the world s largest dome the National Stadium roof of Singapore Sports Hub The IES Journal Part A Civil amp Structural Engineering Taylor amp Francis 7 3 127 150 doi 10 1080 19373260 2014 911485 S2CID 110806778 Lippincott Kristen 2008 DK Eyewitness Books Astronomy Penguin ISBN 978 0 756 64349 2 Mainstone Rowland J 2001 Developments in Structural Form 2nd ed Architectural Press ISBN 978 0 7506 5451 7 Marche Jordan 2005 Theaters of Time and Space American Planetaria 1930 1970 Rutgers University Press ISBN 978 0 813 53766 5 McNeil Ian ed 2002 An Encyclopaedia of the History of Technology Routledge ISBN 978 1 134 98165 6 Miller Judith Clinch Tim 1998 Classic Style illustrated ed Simon and Schuster ISBN 978 0 684 84997 3 Misztal Barbara 2017 Wooden Domes History and Modern Times Springer ISBN 978 3 319 65741 7 Mitchell James H 1985 The Noble Dome The Antioch Review Antioch Review Inc 43 3 261 271 doi 10 2307 4611482 JSTOR 4611482 Moravanszky Akos 1998 Competing Visions Aesthetic Invention and Social Imagination in Central European Architecture 1867 1918 illustrated ed MIT Press ISBN 978 0 262 13334 0 Morganti R Tosone A Abita M Di Donato D 2019 Symbol and technique of steel domes in Italy in Cruz Paulo J S ed Structures and Architecture Bridging the Gap and Crossing Borders Proceedings of the Fourth International Conference on Structures and Architecture ICSA 2019 July 24 26 2019 Lisbon Portugal CRC Press pp 835 842 ISBN 978 1 351 85815 1 Muttoni Aurelio 2011 The Art of Structures EPFL Press ISBN 978 2 940 22238 4 Nenadovic Aleksandra 2010 Development Characteristics and Comparative Structural Analysis of Tensegrity Type Cable Domes PDF Spatium 22 22 57 66 doi 10 2298 spat1022057n Ochsendork John Freeman Michael 2010 Guastavino Vaulting The Art of Structural Tile illustrated ed Princeton Architectural Press ISBN 978 1 56898 741 5 Petroski Henry 2011 Engineering Arches and Domes American Scientist Sigma Xi The Scientific Research Honor Society 99 2 111 115 doi 10 1511 2011 89 111 JSTOR 23019241 Retrieved December 14 2018 Pevsner Nikolaus 1978 Derbyshire Revised by Elizabeth Williamson illustrated reprint ed Yale University Press ISBN 978 0 140 71008 3 Rizzoni Giovanni 2009 The Form of Parliaments amp European Identity In Rorato Laura Saunders Anna eds The Essence and the Margin National Identities and Collective Memories in Contemporary European Culture The Netherlands Rodopi pp 183 198 ISBN 978 9 042 02571 4 Scheunemann Juergen Omilanowska Malgorzata 2012 DK Eyewitness Travel Guide Berlin Penguin ISBN 978 0 756 69114 1 Seale William 1975 Symbol as Architecture Design Quarterly Walker Art Center 94 95 14 15 doi 10 2307 4090872 JSTOR 4090872 Sharp Dennis 2002 20th Century Architecture A Visual History 3rd illustrated ed Images Publishing ISBN 978 1 864 70085 5 Silk Michael Gildenhard Ingo Barrow Rosemary 2017 The Classical Tradition Art Literature Thought illustrated ed John Wiley amp Sons ISBN 978 1 405 15550 2 Skempton A W 2002 A biographical dictionary of civil engineers in Great Britain and Ireland 1500 1830 illustrated ed Thomas Telford ISBN 978 0 7277 2939 2 Skejic Davor Boko Ivica Toric Neno 2015 Aluminium as a material for modern structures PDF Gradevinar 67 11 1075 1085 doi 10 14256 JCE 1395 2015 Stephenson Davis Hammond Victoria Davi Keith F 2005 Visions of Heaven the Dome in European Architecture illustrated ed Princeton Architectural Press ISBN 978 1 56898 549 7 Stern Robert A M Mellins Thomas Fishman David 1995 New York 1960 Architecture and Urbanism Between the Second World War and the Bicentennial New York Monacelli Press ISBN 1 885254 02 4 OCLC 32159240 OL 1130718M Sutherland James 2000 19th Century Iron and Glass Domes Domes Papers Read at the Annual Symposium of the Society of Architectural Historians of Great Britain Society of Architectural Historians of Great Britain pp 111 130 Van Den Heuvel Dirk 2008 The Challenge of Change Dealing with the Legacy of the Modern Movement illustrated ed IOS Press ISBN 978 1 586 03917 2 Villam Judit Szabo Daniel Gyarmati Gyorgy Soltesz Istvan Sisa Jozsef 2006 The Hungarian National Assembly PDF Translated by Zsuzsa Boronkay Roe Budapest Office of the National Assembly ISBN 978 963 87318 5 2 Young Carolyn Ann 1995 The Glory of Ottawa Canada s First Parliament Buildings illustrated ed McGill Queen s Press MQUP ISBN 978 0 7735 1227 6 Zanon Paolo Bursi Oreste S Erlicher Silvano Zonta D Clemente Paolo Indirli M 2001 Intervention Scenarios on the Basilica of San Gaudenzio Dome in Novara 7th International Seminar on Seismic Isolation Passive Energy Dissipation and Active Control of Vibrations of Structures Assisi Italy October 2 5 2001 Assisi Italy Retrieved May 17 2015 Zanow Lois Johnston Sally 2010 Monuments to Heaven Baltimore s Historic Houses of Worship illustrated ed AuthorHouse ISBN 978 1 452 08537 1 Zung Thomas T K 2002 Buckminster Fuller Anthology for the New Millennium Macmillan ISBN 978 0 312 28890 7 Retrieved from https en wikipedia org w index php title History of modern period domes amp oldid 1167002974, wikipedia, wiki, book, books, library,

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