Biology Reference
In-Depth Information
Hurd CL (2000) Water motion, marine macroalgal physiology, and production. J Phycol
36:453-472
Hurd CL, Pilditch CA (2011) Flow-induced morphological variations affect diffusion boundary-
layer thickness of
Macrocystis pyrifera
(Heterokontophyta, Laminariales). J Phycol 47:341-351.
Hurd CL, Hepburn CD, Currie KI, Raven JA, Hunter KA (2009) Testing the effects of ocean
acidification on algal metabolism: considerations for experimental designs. J Phycol
45:1236-1251
Hurd CL, Cornwall CE, Currie K, Hepburn CD, McGraw CM, Hunter KA, Boyd PW (2011)
Metabolically-induced pH fluctuations by some coastal calcifiers exceed projected 22nd
century ocean acidification: a mechanism for differential susceptibility? Glob Change Biol
IPCC (2007) Climate Change 2007: The physical science basis. Summary for policymakers.
Contribution of working group I to the fourth assessment report. The International Panel on
Climate Change,
http://www.ipcc.ch/SPM2feb07.pdf
Jiang ZJ, Huang X-P, Zhang J-P (2010) Effects of CO
2
enrichment on photosynthesis, growth, and
biochemical composition of seagrass
Thalassia hemprichii
(Ehrenb.) Aschers. J Integr Plant
Biol 52:904-913. doi:
10.1111/j.1744-7909.2010.00991.x
Johnston AM (1991) The acquisition of inorganic carbon by marine macroalgae. Can J Bot
69:1123-1132
Johnston AM, Raven JA (1991) Effects of culture in high CO
2
on the photosynthetic physiology of
Fucus serratus
. Br Phycol J 25:75-82
Johnston AM, Maberly SC, Raven JA (1992) The acquisition of inorganic carbon by four red
macroalgae. Oecologia 92:317-326
Kang C-K, Choy EJ, Son Y, Lee J-K, Kim JK, Kim Y, Lee K-S (2008) Food web structure of a
restored macroalgal bed in the eastern Korean peninsula determined by C and N stable isotope
analyses. Mar Biol 153:1181-1198. doi:
10.1007/s00227-007-0890-y
Kevekordes K, Holland D, H
aubner N, Jenkin S, Koss R, Roberts S, Raven JA, Scrimgeour CM,
Shelly K, Stojkovic S, Beardall J (2006) Inorganic carbon acquisition by eight species of
Caulerpa
(Caulerpaceae, Chlorophyta). Phycologia 45:442-449. doi:
10.2216/05-55.1
Kremer BP (1981) Aspects of carbon metabolism in marine macroalgae. In: Barnes HB, Barnes M
(eds) Oceanography and marine biology: an annual review, 19. Aberdeen University Press,
Aberdeen, UK, pp 41-94
Kubler JE, Raven JA (1994) Consequences of light limitation for carbon acquisition in three
rhodophytes. Mar Ecol Prog Ser 110:203-209
Kubler JE, Johnston AM, Raven JA (1999) The effects of reduced and elevated CO2 and O2 on the
seaweed
Lomentaria articulata
. Plant Cell Environ 22:1303-1310
Kuffner IB, Andersson AJ, Jokiel PL, Rodgers KS, Mackenzie FT (2008) Decreased abundance of
crustose coralline algae due to ocean acidification. Nat Geosci 1:114-117. doi:
10.1038/
Laurand S, Riera P (2006) Trophic ecology of the supralittoral rocky shore (Roscoff, France): a
dual stable isotope (
d
€
13
15
C,
d
N) and experimental approach. J Sea Res 56:27-36. doi:
10.1016/
Maberly SC (1990) Exogenous sources of inorganic carbon for photosynthesis by marine
macroalgae. J Phycol 26:439-449
Maberly SC, Raven JA, Johnston AM (1992) Discrimination between
12
C and
13
C by marine
plants. Oecologia 91:481-492
Magnusson G, Larsson C, Axelsson L (1996) Effects of high CO
2
treatment on nitrate
and ammonium uptake by
Ulva lactuca
grown in different nutrient regimes. Sci Mar
60(Supplement 1):179-189
Martin S, Gattuso JP (2009) Response of Mediterranean coralline algae to ocean acidification and
elevated temperature. Glob Change Biol 15:2089-2100. doi:
10.1111/j.1365-2486.2009.01874.x
