Burroughs Wellcome: Geometry and Rudolph's Design

Burroughs Welcome building. Image courtesy of Joseph W. Molitor architectural photographs. Located in Columbia University, Avery Architectural & Fine Arts Library, Department of Drawings & Archives

Burroughs Welcome building. Image courtesy of Joseph W. Molitor architectural photographs. Located in Columbia University, Avery Architectural & Fine Arts Library, Department of Drawings & Archives

Paul Rudolph’s sketch study for the East elevation of administration wing of the Burroughs Wellcome building in North Carolina. © The Estate of Paul Rudolph, The Paul Rudolph Heritage Foundation

Paul Rudolph’s sketch study for the East elevation of administration wing of the Burroughs Wellcome building in North Carolina. © The Estate of Paul Rudolph, The Paul Rudolph Heritage Foundation

THE UNITY oF ARCHITECTURE AND GEOMETRY

Geometry emerging out of wild nature? In fact, this is a natural formation—perhaps showing that nature itself has inherent geometric tendencies. Pyrite cubic crystals on marlstone. Photo by Carles Millan. Image courtesy of Wikimedia Commons.

Geometry emerging out of wild nature? In fact, this is a natural formation—perhaps showing that nature itself has inherent geometric tendencies. Pyrite cubic crystals on marlstone. Photo by Carles Millan. Image courtesy of Wikimedia Commons.

“Architecture is. . . .at least the geometric pattern of things, of life, of the human and social world.”

— Frank Lloyd Wright

Architects and geometry—are they not eternally linked? Even in the most organically curvilinear design, a trained eye can detect the underlying geometric order.

Perhaps their indissoluble marriage can be traced to the essence the architectural task. Rocco Leonardis—an architect and friend of Paul Rudolph’s—has stated it this way:

“Architects create wholes."

and such is the power (and flexibility) of geometry that it is the prime discipline and tool by which architects can bring a sense of order and “wholeness”—unity—to their designs.

POWER IN WRIGHTIAN GEOMETRIES

An ornamental detail from a Frank Lloyd Wright building in Pennsylvania. Hexagonal shapes are implicit in the forms Wright used here.. Image courtesy of Montgomery County Planning Commission via Wikimedia Commons.

An ornamental detail from a Frank Lloyd Wright building in Pennsylvania. Hexagonal shapes are implicit in the forms Wright used here.. Image courtesy of Montgomery County Planning Commission via Wikimedia Commons.

Among the founders of Modern architecture no one knew this better than Frank Lloyd Wright.

It’s worth underlining that Wright was one of the most powerful influences on Paul Rudolph—something he never failed to acknowledge. Wright’s impact on Rudolph started from a very young age. Rudolph recounts:

“I was twelve or fourteen when I first saw a Frank Lloyd Wright house. That was in Florence, Alabama. I forget how I knew about this house, but I did, so I got my parents to drive over. . . . .There are very few architects whose work I would go out of my way to see, but I would always go to see anything, even the worst, of Wright’s.”

Hexagonal seat back for the “Peacock Chair” which Frank Lloyd Wright designed, in the early 1920’s, for the Imperial Hotel in Japan. Photo by Tim Evanson. Image courtesy of Wikimedia Commons.

Hexagonal seat back for the “Peacock Chair” which Frank Lloyd Wright designed, in the early 1920’s, for the Imperial Hotel in Japan. Photo by Tim Evanson. Image courtesy of Wikimedia Commons.

And no one had greater virtuosity than Wright, when it came to utilizing geometry for generating and taming architectural form.

As an example: Wright’s floor plans often utilized geometric grids. But although he was a master at using orthogonal [square] grids for the layout of residences and other building types, he used a variety of grids: triangular, diamond, and hexagonal. One can see this in a number of Wright’s works, from smaller objects to which he turned his attention (like a chair for the Imperial Hotel he designed in Japan) -to- his elaborately developed and detailed floor plans for the Price Tower (one of which is shown below).

Price+tower+single+floor+plan.jpg

In the three Wright house designs, shown below, he uses geometric grids (one diamond and two hexagonal) to help regulate the placement of walls and other elements.

Berger house.

Berger house.

Bazett House

Bazett House

Richardson house.

Richardson house.

RUDOLPH: CRYSTAL GEOMETRY IN THE ELEVATIONS

A crystal, Labradorite—in this example, showing a hexagonal geometry. Photograph by Martin Thoma. Image courtesy of Wikimedia Commons.

A crystal, Labradorite—in this example, showing a hexagonal geometry. Photograph by Martin Thoma. Image courtesy of Wikimedia Commons.

Hexagonal geometry is of particular interest, as it relates to several examples of Rudolph’s work—and, in particular, to one of Rudolph’s best buildings: the US headquarters and research center that he designed for the pharmaceutical giant, Burroughs Wellcome.

What’s also interesting—and is manifest in Burroughs Wellcome’s design—are what appear to be the geometries associated with nature’s crystals. At Burroughs Wellcome, this is most noticeable in his use of “extended” hexagons—the kind where the form appears to be stretched out.

Nature provides an abundance of examples, both from mineral and snow crystals.

ABOVE: Pale blue transparent beryl crystal, surrounded by hexagonal crystals of muscovite. Photo by Carles Millan. Image courtesy of Wikimedia Commons.RIGHT: A snow crystal, in which extended hexagonal geometries can be seen. Image by the Electron a…

ABOVE: Pale blue transparent beryl crystal, surrounded by hexagonal crystals of muscovite. Photo by Carles Millan. Image courtesy of Wikimedia Commons.

RIGHT: A snow crystal, in which extended hexagonal geometries can be seen. Image by the Electron and Confocal Microscopy Laboratory, Agricultural Research Service, U. S. Department of Agriculture.

snow+crystals.jpg

In Rudolph’s design these extended crystal volumes appear to pulse forward and backward, giving a sense that the building has a vivid metabolism of its own—a most appropriate symbolism for a major center for biomedical research!

A general view of one wing of the Burroughs Wellcome Building, showing the that the crystalline geometry primarily manifested along its ends. Image courtesy of the Wellcome Collection.

A general view of one wing of the Burroughs Wellcome Building, showing the that the crystalline geometry primarily manifested along its ends. Image courtesy of the Wellcome Collection.

The extended hexagonal volumes, pushing forward and receding, at one end of the building.. Image courtesy of the Massachusetts Institute of Technology, photograph by G. E. Kidder Smith

The extended hexagonal volumes, pushing forward and receding, at one end of the building.. Image courtesy of the Massachusetts Institute of Technology, photograph by G. E. Kidder Smith

Nobel Prize winners Gertrude Elion and William Hitchings, who did much of their research work at Burroughs Wellcome. Photo by Will & Deni McIntyre. Courtesy GSK RTP Heritage Center.

Nobel Prize winners Gertrude Elion and William Hitchings, who did much of their research work at Burroughs Wellcome. Photo by Will & Deni McIntyre. Courtesy GSK RTP Heritage Center.

Main Building Addition from 1976. It manifests extended hexagon geometries, but in a stacked and rhythmic pattern. © The Estate of Paul Rudolph, The Paul Rudolph Heritage Foundation.

Main Building Addition from 1976. It manifests extended hexagon geometries, but in a stacked and rhythmic pattern. © The Estate of Paul Rudolph, The Paul Rudolph Heritage Foundation.

Rudolph extended these geometries into his design for the interiors—showing up in hallways, passages, and the dramatic dining room that he created for one of the building’s additions.

ABOVE: Dining Room, designed by Rudolph. © The Estate of Paul Rudolph, The Paul Rudolph Heritage Foundation. RIGHT: Hexagonal derived geometry at a doorway passage. Photo by Henry L. Kampenhoefner. © Paul Rudolph Heritage Foundation

ABOVE: Dining Room, designed by Rudolph. © The Estate of Paul Rudolph, The Paul Rudolph Heritage Foundation. RIGHT: Hexagonal derived geometry at a doorway passage. Photo by Henry L. Kampenhoefner. © Paul Rudolph Heritage Foundation

beehive+doorway+-+Henry+L.+Kamphoefner.jpg

RUDOLPH: CRYSTAL GEOMETRY IN THE PLANNING

Like any architectural design, Burroughs Wellcome went thorough development, revision, and refinement. An early design scheme of Rudolph’s shows the building’s entry plaza would have featured large stepped areas. These would have created an impressive, ziggurat-like entry experience (and visual platform) for the building. While we can’t argue with the final (and superb) design that was built, it is intriguing to contemplate what the entry experience of the building would have been like, had they gone forward with this earlier approach.

Early scheme for the building. ©The Estate of Paul Rudolph, The Paul Rudolph Heritage Foundation.

Early scheme for the building. ©The Estate of Paul Rudolph, The Paul Rudolph Heritage Foundation.

Detail of rendering of early scheme. ©The Estate of Paul Rudolph, The Paul Rudolph Heritage Foundation.

Detail of rendering of early scheme. ©The Estate of Paul Rudolph, The Paul Rudolph Heritage Foundation.

Rudolph freely admitted that he was influenced by everything he experienced—or as he put it:

“Well, I am influenced by everything I see, hear, feel, smell, touch, and so on.”

So discerning the exact influences any of his designs is never easy, if at all possible. Indeed, architects are rarely—if ever!—completely conscious of how they arrive at their design solutions. Looking at the above stair-focused design, one might sense an echo of the ziggurat forms of the stepped pyramids of ancient Egypt or Mexico—but the designs could just as well have derived from other sources, like the kind of rectilinear structure of the below quartz titanium crystal.

This example of a natural quartz crystal rainbow titanium cluster presents an intruding set of rectilinear geometries.

This example of a natural quartz crystal rainbow titanium cluster presents an intruding set of rectilinear geometries.

Nature’s crystals—or inspiration for stairs?

Nature’s crystals—or inspiration for stairs?

YOU CAN HELP SAVE BURROUGHS WELLCOME !

Image courtesy of Joseph W. Molitor architectural photographs. Located in Columbia University, Avery Architectural & Fine Arts Library, Department of Drawings & Archives

Image courtesy of Joseph W. Molitor architectural photographs. Located in Columbia University, Avery Architectural & Fine Arts Library, Department of Drawings & Archives

The Burroughs Wellcome building is threated with imminent demolition.

It’s loss would be a disaster—a titanic waste of our nation’s cultural heritage. Remember:

When a great building is destroyed, there are no second chances.

NOW— THERE ARE TWO THINGS YOU CAN DO:

  • Sign the petition to save Burroughs Wellcome— Please sign it here.

  • We can keep you up-to-date with bulletins about the latest developments. To get them, please join our foundation’s mailing list: you’ll get all the updates, (as well as other Rudolphian news.)—you can sign-up at the bottom of this page.

Rudolph at work:  Architect—and master of geometry.

Rudolph at work: Architect—and master of geometry.