Helgoländer Meeresuntersuchungen

, Volume 41, Issue 1, pp 1–43 | Cite as

Seepocken der deutschen Küstengewässer

  • Gertraud Luther


Barnacles of German coastal waters. An attempt is made to provide a guide for the identification of seven barnacle species occurring in German coastal waters of the western Baltic and the North Sea. Variations in morphological characters observed in sessile adults are described, and figures drawn to differentiate the larvae of the nauplius and cypris stage. The information available on the distribution and ecology of the barnacles considered is reviewed.


  1. Abel, C. & Subclew, H. J., 1960. Trockenresistenz vonBalanus improvisus. — Naturwissenschaften47, 117.CrossRefGoogle Scholar
  2. Barnes, H., 1953. Size variations in the cyprids of some common barnacles, — J. mar. biol. Ass. U. K.32, 297–304.Google Scholar
  3. Barnes, H., 1957. Process of restoration and synchronisation in marine ecology. The spring diatom increase and the “spawning” of the common barnacleBalanus balanoides (L.). — Annls biol., Copenh.33, 67–85.Google Scholar
  4. Barnes, H., 1958. Regarding the southern limits ofBalanus balanoides (L.). — Oikos9, 139–157.Google Scholar
  5. Barnes, H., 1963. Light, temperature and breeding ofBalanus balanoides. — J. mar. biol. Ass. U. K.43, 717–727.Google Scholar
  6. Barnes, H., 1971. A review of some factors affecting settlement and adhesion in the cyprids of some common barnacles. In: Adhesion in biological systems. Ed. by R. S. Manly. Acad. Press, New York, 89–111.Google Scholar
  7. Barnes, H. & Powell, H. T., 1950. The development, general morphology and subsequent elimination of barnacle populations,Balanus crenatus andB. balanoides, after a heavy initial settlement. — J. Anim. Ecol.19, 175–179.Google Scholar
  8. Barnes, H. & Powell, H. T., 1954.Onchidoris fusca Müller, a predator of barnacles. — J. Anim. Ecol.23, 361–363.Google Scholar
  9. Barnes, H. & Crisp, D. J., 1956. Evidence of self-fertilization in certain species of barnacles. — J. mar. biol. Ass. U. K.35, 631–639.Google Scholar
  10. Barnes, H. & Costlow, J. D., 1961. Larval stage ofBalanus balanus (L.) da Costa. — J. mar. biol. Ass. U. K.41, 59–68.Google Scholar
  11. Barnes, H. & Healy, M. J. R., 1965. Biometrical studies on some common cirripedes. I.Balanus balanoides: Measurements of the scuta and terga of animals from a wide geographical range. — J. mar. biol. Ass. U. K.45, 779–789.Google Scholar
  12. Barnes, H. & Stone, R. L., 1973. The general biology ofVerruca stroemia (O. F. Müller). II. Reproductive cycle, population structure, and factors affecting release of nauplii. — J. exp. mar. Biol. Ecol.12, 279–297.Google Scholar
  13. Barnes, H. & Barnes, M., 1974. The responses during development of the embryos of some common cirripedes to wide changes in salinity. — J. exp. mar. Biol. Ecol.15, 197–202.Google Scholar
  14. Barnes, H. & Klepal, W., 1974. The general biology ofVerruca stroemia (O. F. Müller). IV. Effect of salinity and temperature on survival, behaviour and osmotic relations. — J. exp. mar. Biol. Ecol.14, 37–46.CrossRefGoogle Scholar
  15. Barnes, H. & Barnes, M., 1975. The general biology ofVerruca stroemia (O. F. Müller). V. Effect of feeding, temperature, and light regime on breeding and moulting cycles. — J. exp. mar. Biol. Ecol.19, 228–232.Google Scholar
  16. Barnes, H., Finlayson, D. M. & Piatigorsky, J., 1963. The effect of desiccation and anaerobic conditions on the behaviour, survival and general metabolism of three common cirripedes. — J. Anim. Ecol.32, 233–252.Google Scholar
  17. Barnes, H., Reed, R. & Topinka, J. A., 1970. The behaviour on impaction by solids, of some common cirripedes and relation to their normal habitat. — J. exp. mar. Biol. Ecol.5, 70–87.CrossRefGoogle Scholar
  18. Barnes, H., Barnes, M. & Klepal, W., 1972. Some cirripedes of the French Atlantic coast. — J. mar. biol. Ass. U. K.41, 187–194.Google Scholar
  19. Barnett, B. E. & Crisp, D. J., 1979. Laboratory studies of gregarious settlement inBalanus balanoides andElminius modestus in relation to competition between these species. — J. mar. biol. Ass. U. K.59, 581–590.Google Scholar
  20. Barnett, B. E., Edwards, S. C. & Crisp, D. J., 1979. A field study of settlement behaviour inBalanus balanoides andElminius modestus (Cirripedia: Crustacea) in relation to competition between them. — J. mar. biol. Ass. U. K.59, 575–580.Google Scholar
  21. Bassindale, R., 1936. The developmental stages of three English barnacles,Balanus balanoides (Linn.),Chthamalus stellatus (Poli), andVerruca stroemia (O. F. Müller). —Proc. zool Soc. Lond. 1936, 57–74.Google Scholar
  22. Bassindale, R., 1964. British barnacles, with keys and notes for identification of the species. Acad. Press, London, 88 pp. (Synopses of the British Fauna, 14).Google Scholar
  23. Bocquet-Védrine, J., 1963. Structure du test calcaire chezChthamalus stellatus (Poli). — C. r. hebd. Séanc. Acad. Sci., Paris257, 1350–1352.Google Scholar
  24. Boëtius, J., 1952. Some notes on the relation to the substratum ofLepas anatifera L. andLepas fascicularis E. et S. — Oikos4, 312–317.Google Scholar
  25. Bourget, E., 1977. Shell structure in sessile barnacles. — Naturaliste can.104, 281–323.Google Scholar
  26. Broch, H., 1924.Cirripedia thoracica von Norwegen und dem norwegischen Nordmeer. Eine systematische und biologisch-tiergeographische Studie. — Vidensk. Skr., Kristiania (Mat.-nat. Kl.)17, 1–121.Google Scholar
  27. Buchholz, H., 1951. Die Larvenformen vonBalanus improvisus. — Kieler Meeresforsch.8, 49–57.Google Scholar
  28. Campbell, A. C., 1977. Der Kosmos-Strandführer. Kosmos, Stuttgart, 320 pp.Google Scholar
  29. Carli, A., 1966. Osservazioni sui Cirripedi della costa ligureChthamalus stellatus (Poli) eChthamalus depressus (Poli). — Boll. Musei Ist. biol. Univ. Genova34, 117–137.Google Scholar
  30. Connell, J., 1961a. Effects of competition, predation byThais lapillus, and other factors on natural populations of the barnacleBalanus balanoides. — Ecol. Monogr.31, 61–104.Google Scholar
  31. Connell, J., 1961b. The influence of interspecific competition and other factors on the distribution of the barnacleChthamalus stellatus. — Ecology42, 710–723.Google Scholar
  32. Connell, J., 1975. Some mechanisms producing structure in natural communities: a model and evidence from field experiments. In: Ecology and evolution of communities. Ed. by M. L. Cody & J. M. Diamond. Belknap Press, Cambridge, Mass. 460–490.Google Scholar
  33. Costlow, J. D., 1956. Shell development inBalanus improvisus Darwin. — J. Morphol.99, 349–415.CrossRefGoogle Scholar
  34. Crisp, D. J., 1950. Breeding and distribution ofChthamalus stellatus. — Nature, Lond.166, 311–312.Google Scholar
  35. Crisp, D. J., 1955. The behaviour of barnacle cyprids in relation to water movement over a surface. —J. exp. Biol.32, 569–590.Google Scholar
  36. Crisp, D. J., 1957. Effect of low temperature on the breeding of marine animals. — Nature, Lond.179, 1138–1139.Google Scholar
  37. Crisp, D. J., 1958. The spread ofElminius modestus Darwin in north-west Europe. — J. mar. biol Ass. U.K.37, 483–520.Google Scholar
  38. Crisp, D. J., 1962. Planktonic stages of the CirripediaBalanus balanoides (L) andBalanus balanus (L) from north temperate waters. — Crustaceana3, 207–221.Google Scholar
  39. Crisp, D. J., 1964. Surface chemistry, a factor in the settlement of marine invertebrate larvae. — Bot. Gothoburg.3, 51–65.Google Scholar
  40. Crisp, D. J., 1974. Factors influencing the settlement of marine invertebrate larvae. In: Chemoreception in marine organisms. Ed. by P. T. Grant & A. M. Mackie. Acad. Press, London, 177–265.Google Scholar
  41. Crisp, D. J. & Barnes, H., 1954. The orientation and distribution of barnacles at settlement, with particular reference to surface contour. — J. Anim. Ecol.23, 142–162.Google Scholar
  42. Crisp, D. J. & Bourget, E., 1985. Growth in barnacles. — Adv. mar. Biol.22, 1–200.Google Scholar
  43. Crisp, D. J. & Davies, P. A., 1955. Observations in vivo on the breeding ofElminius modestus grown on glass slides. — J. mar. biol. Ass. U.K.34, 357–380.Google Scholar
  44. Crisp, D. J. & Meadows, P. S., 1962. The chemical basis of gregariousness in cirripedes. — Proc. R. Soc. (B)156, 500–520.Google Scholar
  45. Crisp, D. J. & Meadows, P. S., 1963. Absorbed layers: the stimulus to settlement in barnacles. — Proc. R. Soc. (B)158, 364–384.Google Scholar
  46. Crisp, D. J. & Ritz, D. A. 1967. Changes in temperature tolerance ofBalanus balanoides during its life cycle. — Helgoländer wiss. Meeresunters.15, 98–111.CrossRefGoogle Scholar
  47. Crisp, D. J. & Patel, B., 1969. Environmental control of the breeding of three boreo-arctic cirripedes. —Mar. Biol.2, 283–295.CrossRefGoogle Scholar
  48. Crisp, D. J., Southward, A. J. & Southward, E. C., 1981. The distribution of the intertidal barnaclesChthamalus stellatus, Chthamalus montagui andEuraphia depressa. — J. mar. biol. Ass. U.K.61, 359–380.Google Scholar
  49. Daniel, A., 1957. Illumination and its effect on the settlement of barnacle cyprids. — Proc. zool. Soc. Lond.129, 305–313.Google Scholar
  50. Daniel, A., 1958. The development and metamorphosis of three species of sessile barnacles. — J. Madras Univ.28, 23–47.Google Scholar
  51. Darwin, C., 1851. A monograph on the subclass Cirripedia, with figures of all species. Ray Soc. London, 400 pp.Google Scholar
  52. Darwin, C., 1854. A monograph on the subclass Cirripedia, with figures of all species. Ray Soc., London, 684 pp.Google Scholar
  53. Davenport, J., 1976. A comparative study of the behaviour of some barnacles exposed to fluctuating sea water concentrations. — J. mar. biol. Ass. U.K.56, 889–907.Google Scholar
  54. Emson, R. H., 1977. The feeding and consequent role ofEulalia viridis (Polychaeta) in intertidal communities. — J. mar. biol. Ass. U.K.57, 93–96.Google Scholar
  55. Fales, D. E., 1928. The light-receptive organs of certain barnacles. — Biol. Bull. mar. biol. Lab., Woods Hole54, 534–547.Google Scholar
  56. Fischer-Piette, E. & Prenant, M., 1956. Distribution des cirripèdes intercotidaux d'Espagne septentrionale. — Bull. Cent. Étud. Rech. scient., Biarritz1, 7–19.Google Scholar
  57. Foster, B. A., 1967. A guide to the littoral balanomorph barnacles of New Zealand. — Tuatara15, 75–86.Google Scholar
  58. Foster, B. A., 1969. Tolerance of high temperatures by some intertidal barnacles. — Mar. Biol.4, 326–332.Google Scholar
  59. Foster, B. A., 1970. Responses and acclimitation to salinity in the adults of some balanomorph barnacles. — Phil. Trans. R. Soc. (B)256, 377–400.Google Scholar
  60. Foster, B. A., 1971. On the determinants of the upper limit of intertidal distribution of barnacles (Crustacea, Cirripedia). — J. Anim. Ecol.45, 33–48.Google Scholar
  61. Grainger, F. & Newell, G. E., 1965. Aerial respiration inBalanus balanoides. — J. mar. biol. Ass. U.K.45, 469–479.Google Scholar
  62. Gutmann, W. F., 1960. Funktionelle Morphologie vonBalanus balanoides. — Abh. senckenberg, naturf. Ges.500, 1–43.Google Scholar
  63. Gutmann, W. F., 1961. Die Siedlungsweise der SeepockeBalanus balanus. — Natur Volk91, 171–181.Google Scholar
  64. Gutmann, W. F., 1962. Beobachtungen zum Formproblem der Seepockenschale. — Natur Mus. Frankf.,92, 193–200.Google Scholar
  65. Hancock, D. A., 1955. The feeding behaviour of starfish on Essex oyster bed. — J. mar. biol. Ass. U.K.34, 313–331.Google Scholar
  66. Hancock, D. A., 1957. The feeding behaviour of the sea urchinPsammechinus miliaris (Gmelin) in the laboratory. — Proc. zool. Soc. Lond.129, 255–262.Google Scholar
  67. Herz, L. E., 1933. The morphology of the later stages ofBalanus crenatus Bruguiere. — Biol. Bull. mar. biol. Lab., Woods Hole64, 432–442.Google Scholar
  68. Hoek, P. P. C., 1909. Die Cirripedien des nordischen Planktons, VIII. — Nord. Plank.11, 265–331.Google Scholar
  69. Houghton, D. R. & Stubbings, H. G., 1963. On the vertical distribution ofElminius modestus. — J. Anim. Ecol.32, 193–201.Google Scholar
  70. Jones, L. W. G. & Crisp, D. J., 1954. The larval stages of the barnacleBalanus improvisus Darwin. —Proc. zool. Soc. Lond.123, 765–780.Google Scholar
  71. Kaestner, A., 1967. Lehrbuch der speziellen Zoologie. Fischer, Stuttgart,1, (2), 849–1242.Google Scholar
  72. Klepal, W., 1971.Chthamalus stellatus (Poli) undChthamalus depressus (Poli) in der Adria. — J. exp. mar. Biol. Ecol.7, 271–294.CrossRefGoogle Scholar
  73. Klepal, W. & Barnes, H., 1975. Further observations on the ecology ofChthamalus depressus (Poli). —J. exp. mar. Biol. Ecol.17, 269–296.CrossRefGoogle Scholar
  74. Knight-Jones, E. W., 1953. Laboratory experiments on gregariousness during setting inBalanus balanoides and other barnacles. — J. exp. Biol.30, 583–598.Google Scholar
  75. Knight-Jones, E. W. & Waugh, G., 1949. On the larval development ofElminius modestus Darwin. —J. mar. biol. Ass. U.K.28, 413–428.Google Scholar
  76. Knight-Jones, E. W. & Moyse, J., 1961. Intraspecific competition in sedentary marine animals. —Symp. Soc. exp. Biol.15, 72–95.Google Scholar
  77. Kalosváry, G. von. 1939. Über die Variablität der Cirripedien-UnterartChthamalus stellatus stellatus (Poli). — Zool. Anz.127, 159–169.Google Scholar
  78. Kolosváry, G. von, 1941. Die Formenkreise der Chthamaliden. — Zool, Anz.133, 67–81.Google Scholar
  79. Krüger, P., 1927. Cirripedia. — Tierw. Nord-u. Ostsee10d, 1–40.Google Scholar
  80. Krüger, P., 1940. Cirripedia. — Bronn's Kl. Ordn. Tierreichs5 (Abt. 1, 3), 1–560.Google Scholar
  81. Kühl, H., 1950. Über die normale und die durch Gifte beeinflußte Metamorphose vonBalanus improvisus Darwin. — Verh. dt. zool. Ges.1949, 158–167.Google Scholar
  82. Kühl, H., 1951. Vergleichende biologische Untersuchungen über den Hafenbewuchs. — Verh. dt. zool. Ges.1950, 233–244.Google Scholar
  83. Kühl, H., 1953. Über das Aufsuchen des Siedlungsplatzes durch die Cyprislarven vonBelanus improvisus Darwin. — Verh. dt. zool. Ges.1952, 189–200.Google Scholar
  84. Kühl, H. 1954. Über das Auftreten vonElminius modestus Darwin in der Elbmündung. — Helgoländer wiss. Meeresunters.5, 53–56.CrossRefGoogle Scholar
  85. Kühl, H., 1963. Die Verbreitung vonElminius modestus Darwin (Cirripedia Thoracica) an der deutschen Küste. — Crustaceana5, 99–111.Google Scholar
  86. Kühl, H., 1967. Observations on the ecology of barnacles in the Elbe estuary. — Proc. Symp. Crustacea, mar. biol. Ass. India.3, 965–975.Google Scholar
  87. Kühl, H., 1968. Schiffsbewuchs und Hafenbewuchs. Deutsche Häfen 2 (Wilhelmshaven, Bremerhaven). — Schiff Hafen20, (8), 3–6.Google Scholar
  88. Larman, V. N. & Gabbott, P. A., 1975. Settlement of cyprid larvae ofBalanus balanoides andElminius modestus induced by extracts of adult barnacles and other marine animals. — J. mar. biol. Ass. U.K.55, 183–190.Google Scholar
  89. Le Reste, L., 1965. Contribution à l'étude des larves de cirripèdes dans le golfe de Marseille. — Rec. Trav. Stn mar. Endoume38, (54), 33–121.Google Scholar
  90. Lewis, J. R., 1964. The ecology of rocky shores. Engl. Univ. Press, London, 323 pp.Google Scholar
  91. Lochhead, J. H., 1936. On the feeding mechanism of the nauplius ofBalanus perforatus Bruguière. —J. Linn. Soc. (Zool.)39, 429–442.Google Scholar
  92. Luther, G., 1976. Bewuchsuntersuchungen auf Natursteinsubstraten im Gezeitenbereich des Nordsylter Wattenmeeres. — Helgoländer wiss. Meeresunters.28, 145–166.Google Scholar
  93. Meadows, P. S., 1969. Settlement, growth and competition in sublittoral populations of barnacles. —Hydrobiologia33, 65–92.CrossRefGoogle Scholar
  94. Moore, H., 1935. The biology ofBalanus balanoides. IV. Relation to environmental factors. — J. mar. biol. Ass. U.K.20, 279–307.Google Scholar
  95. Moore, H. & Kitching, F. A., 1939. The biology ofChthamalus stellatus (Poli). — J. mar. biol. Ass. U. K.23, 521–541.Google Scholar
  96. Moyse, J., 1963. A comparison of the value of various flagellates and diatoms as food for barnacle larvae. — J. Cons. perm. int. Explor. Mer28, 175–187.Google Scholar
  97. Moyse, J. & Hui, E., 1981. Avoidance byBalanus balanoides cyprids of settlement on conspecific adults. — J. mar. biol. Ass. U. K.61, 449–460.Google Scholar
  98. Moyse, J. & Knight-Jones, E. W., 1967. Biology of cirripede larvae. — Proc. Symp. Crustacea, mar. biol. Ass. India2, 595–611.Google Scholar
  99. Newell, R. C., 1970. Biology of intertidal animals. Logos Press, London, 555 pp.Google Scholar
  100. Newman, W. & Ross, A., 1976. Revision of the barnacles, including a catalogue of the species. —Mem. S. Diego Soc. nat. Hist.9, 1–108.Google Scholar
  101. Paine, R. T., 1974. Intertidal community structure. Experimental studies on the relationship between a dominant competitor and its principal predator. — Oecologia15, 93–120.CrossRefGoogle Scholar
  102. Parke, M. W. & Moore, H., 1935. The biology ofBalanus balanoides. II. Algal infection on the shell. —J. mar. biol. Ass. U. K.20, 49–63.Google Scholar
  103. Patel, B., 1959. The influence of temperature on the reproduction and moulting ofLepas anatifera L. under laboratory conditions. — J. mar. biol. Ass. U. K.38, 589–597.Google Scholar
  104. Powell, H. T., 1954. Occurrence ofChthamalus stellatus (Poli) in Fair Isle and Shetland. — Nature, Lond.173, 119–120.Google Scholar
  105. Pyefinch, K. A., 1948a. Methods of identification of the larvae ofBalanus balanoides (L.),Balanus crenatus Brug. andVerruca stroemia (O. F. Müller). — J. mar. biol. Ass. U. K.27, 451–463.Google Scholar
  106. Pyefinch, K. A., 1948b. Notes on the biology of cirripedes. — J. mar. biol. Ass. U. K.27, 464–503.Google Scholar
  107. Pyefinch, K. A., 1948c. The larval stages ofBalanus crenatus Brug. — Proc. zool. Soc. Lond.118, 916–923.Google Scholar
  108. Rainbow, P. S., 1984. An introduction to the biology of British littoral barnacles. — Fld. Stud.6, 1–51.Google Scholar
  109. Relini, G., 1969. La distribuzione dei cirripedi toracici nei mari Italiana. — Arch. bot. biogeogr. ital.4, 168–186.Google Scholar
  110. Remane, A., 1962. Cirripedia, Rankenfüßer. In: Handbuch der Biologie. Hrsg. von L. von Bertalanffy. Akad. Verl. Ges. Athenaion, Konstanz6 (1), 271–272.Google Scholar
  111. Ritz, D. A. & Crisp, D. J., 1970. Seasonal changes in feeding rate inBalanus balanoides. — J. mar. biol. Ass. U. K.50, 223–240.Google Scholar
  112. Runnström, S., 1925. Zur Biologie und Entwicklung vonBalanus balanoides (Linné). — Bergens Mus. Årb. (Naturv. R.)5, 1–46.Google Scholar
  113. Runnström, S., 1927. Über die Plattenentwicklung vonVerruca stroemia. — Bergens Mus. Årb. (Naturv. R.)3, 1–10.Google Scholar
  114. Schäfer, W., 1938. Die geologische Bedeutung von Bohr-Organismen in tierischen Hartteilen, aufgezeigt an Balaniden-Schill der Innenjade. — Senckenbergiana20, 304–312.Google Scholar
  115. Schäfer, W., 1952. Biologische Bedeutung der Ortswahl bei Balaniden-Larven. — Senckenbergiana33, 235–246.Google Scholar
  116. Schütz, L., 1969. Ökologische und biologische Untersuchungen an den Balaniden der Kieler Bucht (Crustacea, Cirripedia). — Faun.-ökol. Mitt.3, 269–277.Google Scholar
  117. Smith, F. G. W., 1946. Effect of water currents upon attachment and growth of barnacles. — Biol. Bull. mar. biol. Lab., Woods Hole90, 51–70.Google Scholar
  118. Smith, F. G. W., 1948. Surface illumination and barnacle attachment. — Biol. Bull. mar. biol. Lab., Woods Hole94, 33–39.Google Scholar
  119. Southward, A. J., 1955. On the behaviour of barnacles. I. The relation of cirral and other activities to temperature. — J. mar. biol. Ass. U.K.34, 403–422.Google Scholar
  120. Southward, A. J., 1957. On the behaviour of barnacles. III. Further observations on the influence of temperature and age on cirral activity. — J. mar. biol. Ass. U.K.36, 323–334.Google Scholar
  121. Southward, A. J., 1958. Note on the temperature tolerance of some intertidal animals in relation to environmental temperatures and geographical distribution. — J. mar. biol. Ass. U. K.37, 49–66.Google Scholar
  122. Southward, A. J., 1962. On the behaviour of barnacles. IV. The influence of temperature on cirral activity and survival of some warm-water species. — J. mar. biol. Ass. U.K.42, 163–177.Google Scholar
  123. Southward, A. J., 1964a. The relationship between temperature and rhythmic cirral activity in some cirripedes considered in connection with their geographical distribution. — Helgoländer wiss. Meeresunters.10, 391–403.CrossRefGoogle Scholar
  124. Southward, A. J., 1964b. On the European species ofChthamalus stellatus (Cirripedia). — Crustaceana6, 241–254.Google Scholar
  125. Southward, A. J., 1967. Recent change in abundance of intertidal barnacles in south-west England: a possible effect of climatic deterioration. — J. mar. biol. Ass. U.K.47, 81–95.Google Scholar
  126. Southward, A. J., 1976. On the taxonomic status and distribution ofChthamalus stellatus (Cirripedia) in the north-east Atlantic region: with a key to the common intertidal barnacles of Britain. —J. mar. biol. Ass. U.K.56, 1007–1028.Google Scholar
  127. Southward, A. J. & Crisp, D. J., 1954. Recent change in the distribution of the intertidal barnaclesChthamalus stellatus Poli andBalanus balanoides L. in the British Isles. — J. Anim. Ecol.23, 163–177.Google Scholar
  128. Southward, A. J. & Crisp, D. J., 1956. Fluctuations in the distribution and abundance of intertidal barnacles. — J. mar. biol. Ass. U.K.35, 211–229.Google Scholar
  129. Southward, A. J. & Crisp, D. J., 1963. Barnacles of European waters. In: Catalogue of main marine fouling organisms. Organisation for Economic Cooperation and Development, Paris,1, 1–46.Google Scholar
  130. Southward, A. J. & Crisp, D. J., 1965. Activity rhythms of barnacles in relation to respiration and feeding. — J. mar. biol. Ass. U.K.45, 161–185.Google Scholar
  131. Stone, R. L. & Barnes, H., 1973. The general biology ofVerruca stroemia (O. F. Müller). I. Geographical and regional distribution: cirral activity and feeding. — J. exp. mar. Biol. Ecol.12, 167–185.CrossRefGoogle Scholar
  132. Subklew, H. J., 1969. Zur Ökologie vonBalanus improvisus. — Limnologica7, 1–147.Google Scholar
  133. Thörner, E. & Ankel, W. E., 1966. Die EntenmuschelLepas fascicularis in der Nordsee. — Natur Mus. Frankf.96, 209–220.Google Scholar
  134. Thompson, J. V., 1830. Zoological researches and illustrations: on the Cirripedes or barnacles. King & Ridings, Cork,1 (4), 69–88.Google Scholar
  135. Visscher, J. P., 1928. Reaction of the cyprid larvae of barnacles at time of attachment. — Biol. Bull. mar. biol. Lab., Woods Hole54, 327–335.Google Scholar
  136. Visscher, J. P. & Luce, R. H., 1928. Reactions of the cyprid larvae of barnacles to light with special reference to spectral colours. — Biol. Bull. mar. biol. Lab., Woods Hole54, 336–350.Google Scholar
  137. Walker, G., 1971. A study of the cement apparatus of the cypris larva of the barnacleBalanus balanoides. — Mar. Biol.9, 205–212.CrossRefGoogle Scholar
  138. Walley, L. J., 1965. The development and function of the oviducal gland inBalanus balanoides. — J. mar. biol. Ass. U.K.45, 115–128.Google Scholar
  139. Weiss, C. M., 1947. The effect of illumination and stage of tide on the attachment of barnacle cyprids. — Biol. Bull. mar. biol. Lab., Woods Hole93, 240–249.Google Scholar
  140. Weltner, W., 1892. Nachträge zur Fauna von Helgoland III, zur Cirripedienfauna von Helgoland. —Zool. Jb. (Syst. Ökol. Geogr. Tiere)6, 453–455.Google Scholar
  141. Wolf, P. de, 1973. Ecological observations on the mechanisms of dispersal of barnacle larvae during planktonic life and settling. — Neth. J. Sea Res.6, 1–129.Google Scholar
  142. Yule, A. B. & Walker, G., 1984. The adhesion of the barnacleBalanus balanoides to slate surfaces. —J. mar. biol. Ass. U.K.64, 147–156.Google Scholar

Copyright information

© Biologische Anstalt Helgoland 1987

Authors and Affiliations

  • Gertraud Luther
    • 1
  1. 1.Biologische Anstalt Helgoland (Litoralstation)List/SyltBundesrepublik Deutschland

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