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The Bea Evenson Foundation is the centerpiece of the Plaza de Balboa in Balboa Park, San Diego.  The San Diego Natural History Museum is seen in the background
The Bea Evenson Foundation is the centerpiece of the Plaza de Balboa in Balboa Park, San Diego. The San Diego Natural History Museum is seen in the background.
Location: Balboa Park, San Diego, California
Image ID: 14590  
The Bea Evenson Foundation is the centerpiece of the Plaza de Balboa in Balboa Park, San Diego.  The San Diego Natural History Museum is seen in the background
The Bea Evenson Foundation is the centerpiece of the Plaza de Balboa in Balboa Park, San Diego. The San Diego Natural History Museum is seen in the background.
Location: Balboa Park, San Diego, California
Image ID: 14591  
The Bea Evenson Foundation is the centerpiece of the Plaza de Balboa in Balboa Park, San Diego.  The San Diego Natural History Museum is seen in the background
The Bea Evenson Foundation is the centerpiece of the Plaza de Balboa in Balboa Park, San Diego. The San Diego Natural History Museum is seen in the background.
Location: Balboa Park, San Diego, California
Image ID: 14592  
The Bea Evenson Foundation is the centerpiece of the Plaza de Balboa in Balboa Park, San Diego.  The San Diego Natural History Museum is seen in the background
The Bea Evenson Foundation is the centerpiece of the Plaza de Balboa in Balboa Park, San Diego. The San Diego Natural History Museum is seen in the background.
Location: Balboa Park, San Diego, California
Image ID: 14593  
The Bea Evenson Foundation is the centerpiece of the Plaza de Balboa in Balboa Park, San Diego.  The San Diego Natural History Museum is seen in the background
The Bea Evenson Foundation is the centerpiece of the Plaza de Balboa in Balboa Park, San Diego. The San Diego Natural History Museum is seen in the background.
Location: Balboa Park, San Diego, California
Image ID: 14594  
Badwater, California.  Badwater, at 282 feet below sea level, is the lowest point in North America.  9000 square miles of watershed drain into the Badwater basin, to dry and form huge white salt flats, Death Valley National Park
Badwater, California. Badwater, at 282 feet below sea level, is the lowest point in North America. 9000 square miles of watershed drain into the Badwater basin, to dry and form huge white salt flats.
Location: Badwater, Death Valley National Park, California
Image ID: 15581  
Badwater, California.  Badwater, at 282 feet below sea level, is the lowest point in North America.  9000 square miles of watershed drain into the Badwater basin, to dry and form huge white salt flats, Death Valley National Park
Badwater, California. Badwater, at 282 feet below sea level, is the lowest point in North America. 9000 square miles of watershed drain into the Badwater basin, to dry and form huge white salt flats.
Location: Badwater, Death Valley National Park, California
Image ID: 15592  
Badwater, California.  Badwater, at 282 feet below sea level, is the lowest point in North America.  9000 square miles of watershed drain into the Badwater basin, to dry and form huge white salt flats, Death Valley National Park
Badwater, California. Badwater, at 282 feet below sea level, is the lowest point in North America. 9000 square miles of watershed drain into the Badwater basin, to dry and form huge white salt flats.
Location: Badwater, Death Valley National Park, California
Image ID: 15593  
Badwater, California.  Badwater, at 282 feet below sea level, is the lowest point in North America.  9000 square miles of watershed drain into the Badwater basin, to dry and form huge white salt flats, Death Valley National Park
Badwater, California. Badwater, at 282 feet below sea level, is the lowest point in North America. 9000 square miles of watershed drain into the Badwater basin, to dry and form huge white salt flats.
Location: Badwater, Death Valley National Park, California
Image ID: 15594  
Badwater, California.  Badwater, at 282 feet below sea level, is the lowest point in North America.  9000 square miles of watershed drain into the Badwater basin, to dry and form huge white salt flats, Death Valley National Park
Badwater, California. Badwater, at 282 feet below sea level, is the lowest point in North America. 9000 square miles of watershed drain into the Badwater basin, to dry and form huge white salt flats.
Location: Badwater, Death Valley National Park, California
Image ID: 15595  
Badwater, California.  Badwater, at 282 feet below sea level, is the lowest point in North America.  9000 square miles of watershed drain into the Badwater basin, to dry and form huge white salt flats, Death Valley National Park
Badwater, California. Badwater, at 282 feet below sea level, is the lowest point in North America. 9000 square miles of watershed drain into the Badwater basin, to dry and form huge white salt flats.
Location: Badwater, Death Valley National Park, California
Image ID: 15611  
Badwater, California.  Badwater, at 282 feet below sea level, is the lowest point in North America.  9000 square miles of watershed drain into the Badwater basin, to dry and form huge white salt flats, Death Valley National Park
Badwater, California. Badwater, at 282 feet below sea level, is the lowest point in North America. 9000 square miles of watershed drain into the Badwater basin, to dry and form huge white salt flats.
Location: Badwater, Death Valley National Park, California
Image ID: 15612  
Badwater, California.  Badwater, at 282 feet below sea level, is the lowest point in North America.  9000 square miles of watershed drain into the Badwater basin, to dry and form huge white salt flats, Death Valley National Park
Badwater, California. Badwater, at 282 feet below sea level, is the lowest point in North America. 9000 square miles of watershed drain into the Badwater basin, to dry and form huge white salt flats.
Location: Badwater, Death Valley National Park, California
Image ID: 15622  
Badwater, California.  Badwater, at 282 feet below sea level, is the lowest point in North America.  9000 square miles of watershed drain into the Badwater basin, to dry and form huge white salt flats, Death Valley National Park
Badwater, California. Badwater, at 282 feet below sea level, is the lowest point in North America. 9000 square miles of watershed drain into the Badwater basin, to dry and form huge white salt flats.
Location: Badwater, Death Valley National Park, California
Image ID: 15623  
Badwater, California.  Badwater, at 282 feet below sea level, is the lowest point in North America.  9000 square miles of watershed drain into the Badwater basin, to dry and form huge white salt flats, Death Valley National Park
Badwater, California. Badwater, at 282 feet below sea level, is the lowest point in North America. 9000 square miles of watershed drain into the Badwater basin, to dry and form huge white salt flats.
Location: Badwater, Death Valley National Park, California
Image ID: 15624  
The Bea Evenson Fountain is the centerpiece of the Plaza de Balboa in Balboa Park, San Diego.  The San Diego Natural History Museum is seen in the background
The Bea Evenson Fountain is the centerpiece of the Plaza de Balboa in Balboa Park, San Diego. The San Diego Natural History Museum is seen in the background.
Location: Balboa Park, San Diego, California
Image ID: 22176  
The Bea Evenson Fountain is the centerpiece of the Plaza de Balboa in Balboa Park, San Diego.  The San Diego Natural History Museum is seen in the background
The Bea Evenson Fountain is the centerpiece of the Plaza de Balboa in Balboa Park, San Diego. The San Diego Natural History Museum is seen in the background.
Location: Balboa Park, San Diego, California
Image ID: 22177  
The San Diego Museum of Natural History, Balboa Park, San Diego.  The San Diego Natural History Museum is the place to find dinosaur bones and get a close up look at insects, birds and organic matter that make our outside world so interesting. Renovated in 2001, a new wing has doubled the museums original 65,000 square feet of floor space to about 150,000 square feet
The San Diego Museum of Natural History, Balboa Park, San Diego. The San Diego Natural History Museum is the place to find dinosaur bones and get a close up look at insects, birds and organic matter that make our outside world so interesting. Renovated in 2001, a new wing has doubled the museums original 65,000 square feet of floor space to about 150,000 square feet.
Location: Balboa Park, San Diego, California
Image ID: 22178  
The San Diego Museum of Natural History, Balboa Park, San Diego.  The San Diego Natural History Museum is the place to find dinosaur bones and get a close up look at insects, birds and organic matter that make our outside world so interesting. Renovated in 2001, a new wing has doubled the museums original 65,000 square feet of floor space to about 150,000 square feet
The San Diego Museum of Natural History, Balboa Park, San Diego. The San Diego Natural History Museum is the place to find dinosaur bones and get a close up look at insects, birds and organic matter that make our outside world so interesting. Renovated in 2001, a new wing has doubled the museums original 65,000 square feet of floor space to about 150,000 square feet.
Location: Balboa Park, San Diego, California
Image ID: 22186  
The Mandelbrot Fractal.  Fractals are complex geometric shapes that exhibit repeating patterns typified by self-similarity, or the tendency for the details of a shape to appear similar to the shape itself.  Often these shapes resemble patterns occurring naturally in the physical world, such as spiraling leaves, seemingly random coastlines, erosion and liquid waves.  Fractals are generated through surprisingly simple underlying mathematical expressions, producing subtle and surprising patterns.  The basic iterative expression for the Mandelbrot set is z = z-squared + c, operating in the complex (real, imaginary) number set, Mandelbrot set
The Mandelbrot Fractal. Fractals are complex geometric shapes that exhibit repeating patterns typified by self-similarity, or the tendency for the details of a shape to appear similar to the shape itself. Often these shapes resemble patterns occurring naturally in the physical world, such as spiraling leaves, seemingly random coastlines, erosion and liquid waves. Fractals are generated through surprisingly simple underlying mathematical expressions, producing subtle and surprising patterns. The basic iterative expression for the Mandelbrot set is z = z-squared + c, operating in the complex (real, imaginary) number set.
Species: Mandelbrot fractal, Mandelbrot set
Image ID: 10370  
The Mandelbrot Fractal.  Fractals are complex geometric shapes that exhibit repeating patterns typified by self-similarity, or the tendency for the details of a shape to appear similar to the shape itself.  Often these shapes resemble patterns occurring naturally in the physical world, such as spiraling leaves, seemingly random coastlines, erosion and liquid waves.  Fractals are generated through surprisingly simple underlying mathematical expressions, producing subtle and surprising patterns.  The basic iterative expression for the Mandelbrot set is z = z-squared + c, operating in the complex (real, imaginary) number set, Mandelbrot set
The Mandelbrot Fractal. Fractals are complex geometric shapes that exhibit repeating patterns typified by self-similarity, or the tendency for the details of a shape to appear similar to the shape itself. Often these shapes resemble patterns occurring naturally in the physical world, such as spiraling leaves, seemingly random coastlines, erosion and liquid waves. Fractals are generated through surprisingly simple underlying mathematical expressions, producing subtle and surprising patterns. The basic iterative expression for the Mandelbrot set is z = z-squared + c, operating in the complex (real, imaginary) number set.
Species: Mandelbrot fractal, Mandelbrot set
Image ID: 10371  
The Mandelbrot Fractal.  Fractals are complex geometric shapes that exhibit repeating patterns typified by self-similarity, or the tendency for the details of a shape to appear similar to the shape itself.  Often these shapes resemble patterns occurring naturally in the physical world, such as spiraling leaves, seemingly random coastlines, erosion and liquid waves.  Fractals are generated through surprisingly simple underlying mathematical expressions, producing subtle and surprising patterns.  The basic iterative expression for the Mandelbrot set is z = z-squared + c, operating in the complex (real, imaginary) number set, Mandelbrot set
The Mandelbrot Fractal. Fractals are complex geometric shapes that exhibit repeating patterns typified by self-similarity, or the tendency for the details of a shape to appear similar to the shape itself. Often these shapes resemble patterns occurring naturally in the physical world, such as spiraling leaves, seemingly random coastlines, erosion and liquid waves. Fractals are generated through surprisingly simple underlying mathematical expressions, producing subtle and surprising patterns. The basic iterative expression for the Mandelbrot set is z = z-squared + c, operating in the complex (real, imaginary) number set.
Species: Mandelbrot fractal, Mandelbrot set
Image ID: 10372  
The Mandelbrot Fractal.  Fractals are complex geometric shapes that exhibit repeating patterns typified by self-similarity, or the tendency for the details of a shape to appear similar to the shape itself.  Often these shapes resemble patterns occurring naturally in the physical world, such as spiraling leaves, seemingly random coastlines, erosion and liquid waves.  Fractals are generated through surprisingly simple underlying mathematical expressions, producing subtle and surprising patterns.  The basic iterative expression for the Mandelbrot set is z = z-squared + c, operating in the complex (real, imaginary) number set, Mandelbrot set
The Mandelbrot Fractal. Fractals are complex geometric shapes that exhibit repeating patterns typified by self-similarity, or the tendency for the details of a shape to appear similar to the shape itself. Often these shapes resemble patterns occurring naturally in the physical world, such as spiraling leaves, seemingly random coastlines, erosion and liquid waves. Fractals are generated through surprisingly simple underlying mathematical expressions, producing subtle and surprising patterns. The basic iterative expression for the Mandelbrot set is z = z-squared + c, operating in the complex (real, imaginary) number set.
Species: Mandelbrot fractal, Mandelbrot set
Image ID: 10373  
The Mandelbrot Fractal.  Fractals are complex geometric shapes that exhibit repeating patterns typified by self-similarity, or the tendency for the details of a shape to appear similar to the shape itself.  Often these shapes resemble patterns occurring naturally in the physical world, such as spiraling leaves, seemingly random coastlines, erosion and liquid waves.  Fractals are generated through surprisingly simple underlying mathematical expressions, producing subtle and surprising patterns.  The basic iterative expression for the Mandelbrot set is z = z-squared + c, operating in the complex (real, imaginary) number set, Mandelbrot set
The Mandelbrot Fractal. Fractals are complex geometric shapes that exhibit repeating patterns typified by self-similarity, or the tendency for the details of a shape to appear similar to the shape itself. Often these shapes resemble patterns occurring naturally in the physical world, such as spiraling leaves, seemingly random coastlines, erosion and liquid waves. Fractals are generated through surprisingly simple underlying mathematical expressions, producing subtle and surprising patterns. The basic iterative expression for the Mandelbrot set is z = z-squared + c, operating in the complex (real, imaginary) number set.
Species: Mandelbrot fractal, Mandelbrot set
Image ID: 10374  
Detail within the Mandelbrot set fractal.  This detail is found by zooming in on the overall Mandelbrot set image, finding edges and buds with interesting features.  Fractals are complex geometric shapes that exhibit repeating patterns typified by self-similarity, or the tendency for the details of a shape to appear similar to the shape itself.  Often these shapes resemble patterns occurring naturally in the physical world, such as spiraling leaves, seemingly random coastlines, erosion and liquid waves.  Fractals are generated through surprisingly simple underlying mathematical expressions, producing subtle and surprising patterns.  The basic iterative expression for the Mandelbrot set is z = z-squared + c, operating in the complex (real, imaginary) number set, Mandelbrot set
Detail within the Mandelbrot set fractal. This detail is found by zooming in on the overall Mandelbrot set image, finding edges and buds with interesting features. Fractals are complex geometric shapes that exhibit repeating patterns typified by self-similarity, or the tendency for the details of a shape to appear similar to the shape itself. Often these shapes resemble patterns occurring naturally in the physical world, such as spiraling leaves, seemingly random coastlines, erosion and liquid waves. Fractals are generated through surprisingly simple underlying mathematical expressions, producing subtle and surprising patterns. The basic iterative expression for the Mandelbrot set is z = z-squared + c, operating in the complex (real, imaginary) number set.
Species: Mandelbrot fractal, Mandelbrot set
Image ID: 10376  
Detail within the Mandelbrot set fractal.  This detail is found by zooming in on the overall Mandelbrot set image, finding edges and buds with interesting features.  Fractals are complex geometric shapes that exhibit repeating patterns typified by self-similarity, or the tendency for the details of a shape to appear similar to the shape itself.  Often these shapes resemble patterns occurring naturally in the physical world, such as spiraling leaves, seemingly random coastlines, erosion and liquid waves.  Fractals are generated through surprisingly simple underlying mathematical expressions, producing subtle and surprising patterns.  The basic iterative expression for the Mandelbrot set is z = z-squared + c, operating in the complex (real, imaginary) number set, Mandelbrot set
Detail within the Mandelbrot set fractal. This detail is found by zooming in on the overall Mandelbrot set image, finding edges and buds with interesting features. Fractals are complex geometric shapes that exhibit repeating patterns typified by self-similarity, or the tendency for the details of a shape to appear similar to the shape itself. Often these shapes resemble patterns occurring naturally in the physical world, such as spiraling leaves, seemingly random coastlines, erosion and liquid waves. Fractals are generated through surprisingly simple underlying mathematical expressions, producing subtle and surprising patterns. The basic iterative expression for the Mandelbrot set is z = z-squared + c, operating in the complex (real, imaginary) number set.
Species: Mandelbrot fractal, Mandelbrot set
Image ID: 10377  
Detail within the Mandelbrot set fractal.  This detail is found by zooming in on the overall Mandelbrot set image, finding edges and buds with interesting features.  Fractals are complex geometric shapes that exhibit repeating patterns typified by self-similarity, or the tendency for the details of a shape to appear similar to the shape itself.  Often these shapes resemble patterns occurring naturally in the physical world, such as spiraling leaves, seemingly random coastlines, erosion and liquid waves.  Fractals are generated through surprisingly simple underlying mathematical expressions, producing subtle and surprising patterns.  The basic iterative expression for the Mandelbrot set is z = z-squared + c, operating in the complex (real, imaginary) number set, Mandelbrot set
Detail within the Mandelbrot set fractal. This detail is found by zooming in on the overall Mandelbrot set image, finding edges and buds with interesting features. Fractals are complex geometric shapes that exhibit repeating patterns typified by self-similarity, or the tendency for the details of a shape to appear similar to the shape itself. Often these shapes resemble patterns occurring naturally in the physical world, such as spiraling leaves, seemingly random coastlines, erosion and liquid waves. Fractals are generated through surprisingly simple underlying mathematical expressions, producing subtle and surprising patterns. The basic iterative expression for the Mandelbrot set is z = z-squared + c, operating in the complex (real, imaginary) number set.
Species: Mandelbrot fractal, Mandelbrot set
Image ID: 10379  
Detail within the Mandelbrot set fractal.  This detail is found by zooming in on the overall Mandelbrot set image, finding edges and buds with interesting features.  Fractals are complex geometric shapes that exhibit repeating patterns typified by self-similarity, or the tendency for the details of a shape to appear similar to the shape itself.  Often these shapes resemble patterns occurring naturally in the physical world, such as spiraling leaves, seemingly random coastlines, erosion and liquid waves.  Fractals are generated through surprisingly simple underlying mathematical expressions, producing subtle and surprising patterns.  The basic iterative expression for the Mandelbrot set is z = z-squared + c, operating in the complex (real, imaginary) number set, Mandelbrot set
Detail within the Mandelbrot set fractal. This detail is found by zooming in on the overall Mandelbrot set image, finding edges and buds with interesting features. Fractals are complex geometric shapes that exhibit repeating patterns typified by self-similarity, or the tendency for the details of a shape to appear similar to the shape itself. Often these shapes resemble patterns occurring naturally in the physical world, such as spiraling leaves, seemingly random coastlines, erosion and liquid waves. Fractals are generated through surprisingly simple underlying mathematical expressions, producing subtle and surprising patterns. The basic iterative expression for the Mandelbrot set is z = z-squared + c, operating in the complex (real, imaginary) number set.
Species: Mandelbrot fractal, Mandelbrot set
Image ID: 10380  
Detail within the Mandelbrot set fractal.  This detail is found by zooming in on the overall Mandelbrot set image, finding edges and buds with interesting features.  Fractals are complex geometric shapes that exhibit repeating patterns typified by self-similarity, or the tendency for the details of a shape to appear similar to the shape itself.  Often these shapes resemble patterns occurring naturally in the physical world, such as spiraling leaves, seemingly random coastlines, erosion and liquid waves.  Fractals are generated through surprisingly simple underlying mathematical expressions, producing subtle and surprising patterns.  The basic iterative expression for the Mandelbrot set is z = z-squared + c, operating in the complex (real, imaginary) number set, Mandelbrot set
Detail within the Mandelbrot set fractal. This detail is found by zooming in on the overall Mandelbrot set image, finding edges and buds with interesting features. Fractals are complex geometric shapes that exhibit repeating patterns typified by self-similarity, or the tendency for the details of a shape to appear similar to the shape itself. Often these shapes resemble patterns occurring naturally in the physical world, such as spiraling leaves, seemingly random coastlines, erosion and liquid waves. Fractals are generated through surprisingly simple underlying mathematical expressions, producing subtle and surprising patterns. The basic iterative expression for the Mandelbrot set is z = z-squared + c, operating in the complex (real, imaginary) number set.
Species: Mandelbrot fractal, Mandelbrot set
Image ID: 10381  
Detail within the Mandelbrot set fractal.  This detail is found by zooming in on the overall Mandelbrot set image, finding edges and buds with interesting features.  Fractals are complex geometric shapes that exhibit repeating patterns typified by self-similarity, or the tendency for the details of a shape to appear similar to the shape itself.  Often these shapes resemble patterns occurring naturally in the physical world, such as spiraling leaves, seemingly random coastlines, erosion and liquid waves.  Fractals are generated through surprisingly simple underlying mathematical expressions, producing subtle and surprising patterns.  The basic iterative expression for the Mandelbrot set is z = z-squared + c, operating in the complex (real, imaginary) number set, Mandelbrot set
Detail within the Mandelbrot set fractal. This detail is found by zooming in on the overall Mandelbrot set image, finding edges and buds with interesting features. Fractals are complex geometric shapes that exhibit repeating patterns typified by self-similarity, or the tendency for the details of a shape to appear similar to the shape itself. Often these shapes resemble patterns occurring naturally in the physical world, such as spiraling leaves, seemingly random coastlines, erosion and liquid waves. Fractals are generated through surprisingly simple underlying mathematical expressions, producing subtle and surprising patterns. The basic iterative expression for the Mandelbrot set is z = z-squared + c, operating in the complex (real, imaginary) number set.
Species: Mandelbrot fractal, Mandelbrot set
Image ID: 10382