Reproduced
with the permission of the Scottish Naturalist
Copyright:
May be used for private research. All other
rights reserved
By
ADRIAN
J. SHINE
Loch Ness and Morar Project
DAVID
S. MARTIN
Loch Ness and Morar Project
SENGA
BENNETT
Department of Applied Science,
University of Staffordshire
ROSALIND S. MARJORAM
Loch Ness and Morar Project
Introduction
A
theme recurring throughout the collected papers
on Loch Ness appearing in this Volume 105
(1993) of the Scottish Naturalist
is spatial variation along the 39 km basin of the loch.
Gradients
George
and Jones (1987) first explored gradients
in conductivity and chlorophyll-a
in the five largest Scottish lochs, during
the multi-disciplinary study by the Institute
of Terrestrial Ecology from 1977 to 1980 (Maitland,
1981); in general, phytoplankton gradients
reflected catchment richness. At Loch Ness, all samplings showed increased
conductivity and phytoplankton in the North
Basin. Figures
1a and 1b (37K) clearly show the much
larger proportion of base rich rock and arable
land in the two northern sub-catchments. Nevertheless, in terms of phosphorus at least,
the differences appear small in Jenkins' (1993)
Tables.
A
paradox arose, therefore, in the 1980s, since
acoustic observations showed a persistent
increase in fish numbers towards the south
(Shine and Martin, 1988). Since then, Kubecka, Duncan and Butterworth
(1993) and Shine, Martin and Marjoram (1993)
have confirmed this, and in the latter case
have also observed
The Scottish Naturalist:
Explanation of Spatial Biomass Gradients in
Loch Ness. p259
zooplankton maxima in the south, although
this appears to be more wind dependent. A clue to the paradox may lie in the
benthos studies.
Griffiths
and Martin (1993) note greater ostracod densities
in the South Basin. The nematodes, oligochaetes, Pisidia,
copepods, Cladocera and chironomids described
by Martin, Shine and Duncan (1993) also show
greater densities in the South Basin.
Core
Survey
Bennett
(1993), in a 27 core survey, has analysed
particle size and organic content along the
axis of the loch. The two Basins were found to be clearly divided
by a 'sill' of organically poor and higher
particle-size sands off the River Foyers (Figures
2a and 2b, 16K). On either side of this lie the two
deep Basins, of which the South Basin has
a 2.0% higher proportion of organic rich sand/silt
muds (28.72% - 29.29%) off the river mouths. The organic inputs to the South Basin,
however, are actually even higher, since the
total sedimentation rate, judged from a marker
layer thought to result from the great flood
in 1868 (Anon., 1868), is almost twice that
of the North Basin. The map (Figure
3, 4K) shows the much larger influence
of rivers in the narrower South Basin.
Catchment Differences
None
of this is surprising when the much larger
area of the southern catchments is considered
(Figure
1c), or the greater western rainfall
in the Caledonian and Moriston sub-catchments. Figure
1d demonstrates how this increases
their importance in terms of annual flow.
Mansfield
(1992) and Bracewell (1993) have shown that
lipids from organic matter in Loch Ness sediments
are indicative of higher terrestrial plant
detritus from the catchment rather than of
autochthonous material. It is therefore proposed that the density
gradients observed in fish, zooplankton and
benthos may be related to microbial utilisation
of the allochthonous inputs dominating the
South Basin, as opposed to the low primary
productivity which is also limited by light
attenuation due to the humic elements of these
inputs.
Bacteria
Levels
Based
upon light extinction and chlorophyll-a
data, it is estimated that the dissolved organic
carbon exudations for phytoplankton cannot
sustain the observed bacterial production
levels (Dr. Johanna Layborn-Parry and Mr.
M. Walton, pers.
The Scottish Naturalist:
Explanation of Spatial Biomass Gradients in
Loch Ness.p263
comm.) (Note 1). Also, bacterial numbers are relatively
high in the winter when primary productivity
is at its lowest but the river flows are at
their highest. During one sampling along the loch's axis,
bacterial numbers were found to double at
the southern end (Dr. R.I. Jones and Dr. Johanna
Layborn-Parry, pers. comm.) (Note 2).
Humic
inputs, previously thought to be recalcitrant,
have recently been shown to play important
roles in sustaining bacterial production (Moran
and Hodson, 1990). It seems possible that the higher zooplankton,
particularly the filter-feeding Cladocera
such as Daphnia
and Bosmina,
may utilise a microbial food source, possibly
through heterotrophic nanoflagellates and
ciliated protozoa (Porter, Feig and Vetter,
1983). In
this way, allochthonous inputs would find
their way to the fish.
Resource
Distribution
The
way in which inputs distribute their resources
is also of interest. Often the river water will be denser
than the loch surface water and will deliver
the sediment load as an interflow (Figure
4, 19K colour chart), which may account
for the large quantities of non-migrating
Cladocera sometimes found in and beneath the
thermocline. Once in the water column, the inputs
will be vigorously mixed and widely transported
by the turbulence induced by shear due to
wind stress (Figure
5, 5K). However, the deeper return current generated
by the prevailing south-west wind will tend
to confine inputs to the south.
Physical
Considerations
The regularity of the Loch Ness basin,
and its orientation south-west to north-east
in line with the prevailing winds, renders
it particularly physically dynamic. Furthermore, turbulence has been suggested
as a mechanism for aggregation of dissolved
organic matter (Wotton, 1984; Petersen, 1986). The role of aggregates (known in oceanography
as marine snow) is important, since in oligotrophic
waters aggregates provide centres of enhanced
microbial activity (Caron, Davies, Madin and
Sieburth, 1982 and 1986).
In May 1991, while the interflow (Figure
4) was being recorded off Urquhart
Bay, the water temperature only varied from
7.9oC at 15 m to 7.0oC
at 87 m, but with a suggestion of a weak thermocline
at about 80 m coinciding with the interflow
depth. A Marine Snow Camera, from the Institute of Oceanographic Sciences,
lowered from a fixed station 5.0 km to the
north, showed some
The
Scottish Naturalist: Explanation of Spatial
Biomass Gradients in Loch Ness.p265
interesting changes in the distribution of
particles (Mr. W. Hillier, pers comm.) (Note
3).
Figure
6a (8K) shows the greatest number
of particles to be above and within the thermocline
at between 60 m and 80 m. There is another smaller increase at 140 m. Figure
6b (10K), illustrating mean particle
size, and Figure
6c (23K), illustrating cumulative
frequencies, show that the change at 70 m
is confined almost entirely to an increase
in the population of the largest size category
(2.0 mm), which could be zooplankton, and
that the change at 140 m involves a relative
decrease in the smallest size class (0.5 mm). In terms of diameter, these appear
to correspond to a relative increase in particles
over 1.5 mm long, and a decrease in particles
of less than 1.0 mm long, respectively. Figure
6d (8K) shows the grey level (more
particles = lower grey level), and the notable
feature is the higher grey level below 100
m, thus indicating much clearer water, probably
the hypolimnion. One speculation is that these results may show
aggregation taking place and being confined
to two areas of possible turbulence.
Conclusion
In conclusion, it is proposed that
the gradients observed in the density of biota
along the loch's length can be ascribed to
allochthonous inputs of particulate and dissolved
organic matter in the South Basin. These would mostly be delivered to
the water column at depth as interflows, where
they may remain confined to the belt of turbulence
at the thermocline. They would then be transported along the loch
through shear, while they are utilised by
microbial plankton and passed up the food
chain. Thus
the cause of the biological gradients is to
be found in the sediments and its ultimate
effect in the southern fish concentrations.
Notes
1. M. Walton and Johanna Laybourn-Parry: Functional
Aspects of the Microbial Plankton in Loch
Ness. Paper read at British Ecological Society's
winter meeting and A.G.M., University of Lancaster,
15th-17th December 1992.
Johanna Laybourn-Parry and M. Walton: Studies of the Plankton of Loch
Ness - The Microbial Loop. Poster paper: displayed at British
Ecological Society's winter meeting and A.G.M.,
University of Lancaster, 15th-17th December
1992; and at Scottish Freshwater Group's 50th
Meeting, University of Stirling, 2nd-3rd February
1993. Later published as abstract (Laybourn-Parry
and Walton, 1993)
The
Scottish Naturalist: Explanation of Spatial
Biomass Gradients in Loch Ness.p268.
2. The Loch Ness and Morar Project's 'Length Run'
programme in support of the University of
Lancaster's study, funded by N.E.R.C. - Plankton Community Dynamics in a Large
Oligotrophic Freshwater System (Loch Ness).
3. A camera system designed to record 'aggregates'
in the marine environment.
Acknowledgements
The
authors would like to express their best thanks
to all the collaborators of the Loch Ness
and Morar Project whose diverse work has been
drawn upon in the construction of this hypothesis,
and in particular to Mr. William Hillier for
his analysis of the Marine Snow Camera data.
References
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Loch Ness. B.Sc. Dissertation, University
of Staffordshire.
Bracewell, C.E. (1993). A
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Received July 1993
Mr. Adrian J.
Shine, Loch Ness and Morar Project,
Loch Ness Centre,
DRUMNADROCHIT, Inverness-shire IV3 6TU.
Mr. David S.
Martin, Loch Ness and Morar Project,
Loch Ness Centre,
DRUMNADROCHIT, Inverness-shire IV3 6TU.
Miss Senga Bennett,
Loch Ness and Morar Project,
Loch Ness Centre,
DRUMNADROCHIT, Inverness-shire IV3 6TU.
Miss Rosalind
S. Marjoram, Loch Ness and Morar Project,
Loch Ness Centre,
DRUMNADROCHIT, Inverness-shire IV3 6TU.
