1. Stephen Jay Gould, Evolution Scientist, Author, Dies at 60 _____ Appreciation _____ The Scientist Who Wrote Rings Around The Earth (The Washington Post, May 21, 2002) The Scientist Who Wrote Rings Around The Earth By Richard Pearson Washington Post Staff Writer Tuesday, May 21, 2002; Page B06 Stephen Jay Gould, 60, a Harvard University professor of zoology and geology who became one of the most widely recognized scientists in the world for his graceful, lucid and downright entertaining writings about science, died of lung cancer May 20 at his home in New York. Dr. Gould, a Harvard professor since 1967, gained fame among contemporary scientists as a gifted and controversial student of evolutionary biology, and he conducted notable research in invertebrate paleontology. He became famous for his modification of some of the theories of Charles Darwin. The general public came to know him for his explanations of scientific phenomena that were as understandable as they were authoritative. He wrote more than 20 best-selling books and 300 consecutive monthly essay columns, "This View of Life," for Natural History magazine from 1974 until 2001. His books included "Ever Since Darwin: Reflections in Natural History," "Bully for Brontosaurus: Reflections in Natural History," "Wonderful Life: The Burgess Shale and the Nature of History," "Dinosaur in a Haystack: Reflections in Natural History," "Hen's Teeth and Horse's Toes: Further Reflections in Natural History" and "Rocks of Ages: Science and Religion in the Fullness of Life." E-Mail This Article Printer-Friendly Version Subscribe to The Post

12. The intertidal zone is the shoreline between the high and low water mark Emersion presents the biggest challenge to the intertidal community: Water loss = desiccation Temperature fluctuations = can be either too hot or too cold Salinity fluctuations = increased by heating, decreased by rain/runoff Restriction of feeding = most organisms can feed only at high tide Adaptation to these physical challenges produces great diversity in lifestyles: sessile/mobile, deposit/detrital/filter feeding, reproductive strategy, epifaunal/cryptic 1) SPACE LIMITATION: Intertidal populations are usually limited by space, not food or nutrients. 2) VERTICAL ZONATION: Most rocky shores have a distinct pattern of vertical zonation. The upper limit of a zone is often set by physical factors, the lower limit by biological ones (predation, competition for space or food, symbiosis). 3) ECOLOGICAL “SUCCESSION” in the intertidal zone: there is a fairly predictable succession of organisms following a disturbance event.

13. Adaptation to these physical challenges produces great diversity in lifestyles: sessile/mobile, deposit/detrital/filter feeding, reproductive strategy, epifaunal/cryptic 1) SPACE LIMITATION: Intertidal populations are usually limited by space, not food or nutrients. 2) VERTICAL ZONATION: Most rocky shores have a distinct pattern of vertical zonation. The upper limit of a zone is often set by physical factors, the lower limit by biological ones (predation, competition for space or food, symbiosis). 3) ECOLOGICAL “SUCCESSION” in the intertidal zone: there is a fairly predictable succession of organisms following a disturbance event.

18. Adaptation to these physical challenges produces great diversity in lifestyles: sessile/mobile, deposit/detrital/filter feeding, reproductive strategy, epifaunal/cryptic 1) SPACE LIMITATION: Intertidal populations are usually limited by space, not food or nutrients. 2) VERTICAL ZONATION: Most rocky shores have a distinct pattern of vertical zonation. The upper limit of a zone is often set by physical factors, the lower limit by biological ones (predation, competition for space or food, symbiosis). 3) ECOLOGICAL “SUCCESSION” in the intertidal zone: there is a fairly predictable succession of organisms following a disturbance event.

19. Uncovered >50% of the time Covered >75% of the time Rarely uncovered – Spring low tides

22. Littorina keenae, periwinkle

23. Acmaea (limpet)

26. Giant Limpet

28. Stenoplax (chiton)

30. Chiton - Tonicella lineata. Photo by D. Brumbaugh

31. Balanus (barnacle)

32. Thais preying on Balanus

33. Pollicipes (gooseneck barnacle)

35. Nucella emarginata – the dogwhelk

37. Mytilus californianus

38. Mytilus and Haliotis (mussels and abalone)

41. Pisaster

42. Astrometis

46. Anthropleura (sea anemone)

48. Anthropleura clone

50. Phragmatapoma californiana – colonial tube worm

51. Tube worms

52. Pachygrapsus (shore crab)

53. Pagurus (hermit crab)

54. Pugettia producta – kelp crab

55. Strongylocentrotus purpuratus in holes

56. Strongylocentrotus purpuratus

57. Adaptation to these physical challenges produces great diversity in lifestyles: sessile/mobile, deposit/detrital/filter feeding, reproductive strategy, epifaunal/cryptic 1) SPACE LIMITATION: Intertidal populations are usually limited by space, not food or nutrients. 2) VERTICAL ZONATION: Most rocky shores have a distinct pattern of vertical zonation. The upper limit of a zone is often set by physical factors, the lower limit by biological ones (predation, competition for space or food, symbiosis). 3) ECOLOGICAL “SUCCESSION” in the intertidal zone: there is a fairly predictable succession of organisms following a disturbance event.

59. Flatworm

60. Segmented worm

61. Chama (closed)

62. Chama (dead)

64. Nudibranch

66. Hopkinsia (nudibranch)

68. Gibbonsia montereyensis – crevice sculpin

69. Aplysia

75. Brittle Star

77. Sea cucumber (Sticapus)

78. Pelvetia

79. Sinus membrane

81. Fucus

82. Fucus distichus

83. Fucus mat

84. Palm seaweed Postelsia

85. Phyllospadix, surfgrass

86. In Science (1995)

87. W.G. Hewatt, Stanford student, 1930