Janet Echelman's Aerial Sculpture over the Rose Kennedy Greenway
The sculpture is made by hand-splicing rope and knotting twine into an interconnected mesh of more than a half-million nodes. When any one of its elements moves, every other element is affected. Monumental in scale and strength yet delicate as lace, it fluidly responds to ever-changing wind and weather. Its fibers are 15 times stronger than steel yet incredibly lightweight, making the sculpture able to lace directly into three skyscrapers as a soft counterpoint to hard-edged architecture. It is a physical manifestation of interconnectedness and strength through resiliency.
In daylight the porous form blends with sky when looking up, and casts shadow-drawings onto the ground below. At night it becomes an illuminated beacon. The artwork incorporates dynamic light elements which reflect the changing effects of wind. Sensors around the site register fiber movement and tension and this data directs the color of light projected onto the sculpture’s surface.
Janet Echelman's Aerial Sculpture over the Rose Kennedy Greenway
The sculpture is made by hand-splicing rope and knotting twine into an interconnected mesh of more than a half-million nodes. When any one of its elements moves, every other element is affected. Monumental in scale and strength yet delicate as lace, it fluidly responds to ever-changing wind and weather. Its fibers are 15 times stronger than steel yet incredibly lightweight, making the sculpture able to lace directly into three skyscrapers as a soft counterpoint to hard-edged architecture. It is a physical manifestation of interconnectedness and strength through resiliency.
In daylight the porous form blends with sky when looking up, and casts shadow-drawings onto the ground below. At night it becomes an illuminated beacon. The artwork incorporates dynamic light elements which reflect the changing effects of wind. Sensors around the site register fiber movement and tension and this data directs the color of light projected onto the sculpture’s surface.