Winter conditions are rapidly changing in temperate ecosystems, particularly for those that experience periods of snow and ice cover. Relatively little is known of winter ecology in these systems, due to a historical research focus on summer 'growing seasons'. We executed the first global quantitative synthesis on under-ice lake ecology, including 36 abiotic and biotic variables from 42 research groups and 101 lakes, examining seasonal differences and connections as well as how seasonal differences vary with geophysical factors. Plankton were more abundant under ice than expected; mean winter values were 43.2% of summer values for chlorophyll a, 15.8% of summer phytoplankton biovolume and 25.3% of summer zooplankton density. Dissolved nitrogen concentrations were typically higher during winter, and these differences were exaggerated in smaller lakes. Lake size also influenced winter-summer patterns for dissolved organic carbon (DOC), with higher winter DOC in smaller lakes. At coarse levels of taxonomic aggregation, phytoplankton and zooplankton community composition showed few systematic differences between seasons, although literature suggests that seasonal differences are frequently lake-specific, species-specific, or occur at the level of functional group. Within the subset of lakes that had longer time series, winter influenced the subsequent summer for some nutrient variables and zooplankton biomass.
Measurements of diatom oxygen isotopes (δ 18Odiatom) hold the potential to provide an important additional source of palaeoceanographic information in regions depleted in carbonates. However, despite analyses of
We present a new palaeoenvironmental record of hydrological variability in Lake Baikal, based on re-modelled d 18 O diatom values of diatom silica (d 18 O modelled ), where the residual contaminants are identified and compensated for using electron optical imaging and whole-sample geochemistry. d 18 O modelled interpretations are based on the balance between rivers with high d 18 O values and rivers with low d 18 O values. Isotopic variability is related to latitudinal differences in precipitation which feed these rivers. The d 18 O modelled record suggests that rather moist conditions prevailed in the Lake Baikal region during the latter stages of the Younger Dryas. Throughout the Holocene, episodes of low d 18 O modelled values are, in general, in good agreement with increases in percentage haematite-stained grains in North Atlantic sediments (indicative of ice-rafted debris events). Rivers with southerly catchments dominate fluvial input especially between c. 3.3 and 2 cal ka BP, concurrent with high precipitation in the Lake Baikal region.
[1] Establishing a time frame for the development of the modern halocline and stratified water column in the subarctic North Pacific has significant paleoclimatic implications. is likely to be reflective of conditions beneath the mesothermal structure and/or spring conditions when warmer sea surface temperatures are not present in the region. These results are consistent with the development of the modern halocline system at 2.73 Ma with year-round stratification of the water column and a strengthened seasonal thermocline during the summer to early winter period, resulting in one of the largest summer to winter temperature gradients in the open ocean. The onset of stratification would also have led to a warm pool of surface water from circa 2.73 Ma, which may have provided a potential source of extra moisture needed to supply the growing North American ice sheets at this time.
Abstract. A range of future climate scenarios are projected for high
atmospheric CO2 concentrations, given uncertainties over future human
actions as well as potential environmental and climatic feedbacks. The
geological record offers an opportunity to understand climate system
response to a range of forcings and feedbacks which operate over multiple
temporal and spatial scales. Here, we examine a single interglacial during
the late Pliocene (KM5c, ca. 3.205±0.01 Ma) when atmospheric CO2 exceeded pre-industrial concentrations, but were similar to today and to the lowest emission scenarios for this century. As orbital forcing and
continental configurations were almost identical to today, we are able to
focus on equilibrium climate system response to modern and near-future
CO2. Using proxy data from 32 sites, we demonstrate that global mean
sea-surface temperatures were warmer than pre-industrial values, by ∼2.3 ∘C for the combined proxy data (foraminifera Mg∕Ca and
alkenones), or by ∼3.2–3.4 ∘C (alkenones
only). Compared to the pre-industrial period, reduced meridional gradients and
enhanced warming in the North Atlantic are consistently reconstructed. There
is broad agreement between data and models at the global scale, with
regional differences reflecting ocean circulation and/or proxy signals. An
uneven distribution of proxy data in time and space does, however, add
uncertainty to our anomaly calculations. The reconstructed global mean
sea-surface temperature anomaly for KM5c is warmer than all but three of the
PlioMIP2 model outputs, and the reconstructed North Atlantic data tend to
align with the warmest KM5c model values. Our results demonstrate that even
under low-CO2 emission scenarios, surface ocean warming may be expected to exceed model projections and will be accentuated in the higher
latitudes.
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