Interspecific differences in dead plant buffering capacity alter the impact of acid rain on decomposition rates in tidal marshes

Interspecific differences in shade tolerance among woody species are considered a primary driving force underlying forest succession. However, variation in shade tolerance may be only one of many interspecific differences that cause species turnover. For example, tree species may differ in their sensitivity to herbivory. Nonetheless, existing conceptual models of forest dynamics rarely explicitly consider the impact of herbivores. We examined whether browsing by white-tailed deer ( Odocoileus virginianus Zimmermann) alters the relationship between light availability and plant performance. We monitored growth and survival for seedlings of six woody species over 2 years within six windthrow gaps and the nearby intact forest in the presence and absence of deer. Browsing decreased seedling growth for all species except beech ( Fagus grandifolia Ehrh.). More importantly, browsing altered growth rankings among species. Increased light availability enhanced growth for three species when excluded from deer, but browsing obscured these relationships. Browsing also reduced survival for three species; however, survival rankings did not significantly differ between herbivory treatments. Our results indicated that browsing and light availability operated simultaneously to influence plant growth within these forests. Thus, existing models of forest dynamics may make inaccurate predictions of the timing and composition of species reaching the canopy, unless they can account for how plant performance varies as a result of a variety of environmental factors, including herbivory.

Download Full-text

Establishing Growing Substrate pH with Compost and Limestone and the Impact on pH Buffering Capacity

HortScience ◽

10.21273/hortsci10990-16 ◽

2016 ◽

Vol 51 (9) ◽

pp. 1153-1158 ◽

Cited By ~ 2

Author(s):

Matthew D. Taylor ◽

Rachel Kreis ◽

Lidia Rejtö

Keyword(s):

Factorial Design ◽

Weight Ratio ◽

Green Plant ◽

Buffering Capacity ◽

Ph Buffering ◽

Initial Substrate ◽

Initial Ph ◽

The Impact ◽

Substrate Ph ◽

Ph Buffering Capacity

The pH of peatmoss generally ranges from 3.0 to 4.0 and limestone is typically added to raise pH to a suitable range. Compost is also used as a substrate component and typically has a high pH of 6.0 to 8.0. When using compost, lime rates must be reduced or eliminated. The two objectives of this study were to determine the resulting pH of substrates created with varying amounts of limestone and compost and assess the impact of the various amounts of limestone and compost on pH buffering capacity. Compost was created from a 1:1:1 weight ratio of a mixture of green plant material and restaurant food waste:horse manure:wood chips. The first experiment was a factorial design with five compost rates (0%, 10%, 20%, 30%, and 40% by volume), four limestone rates (0, 1.2, 2.4, and 3.6 g·L−1 substrate) with five replications. The experiment was conducted three times, each with a different batch of compost. With 0 lime, initial substrate pH increased from 4.5 to 6.7 as compost rate increased. This trend occurred at all other lime rates, which had pH ranges of 5.2–6.9, 5.6–7.0, and 6.1–7.1 for rates of 1.2, 2.4, and 3.6 g·L−1 substrate, respectively. Substrate pH increased significantly as either compost or lime rates increased. The second experiment was a factorial design with four compost rates by volume (0%, 10%, 20%, and 30%), the same four limestone rates as Expt. 1, and five replications. Each substrate treatment was titrated through incubations with six sulfuric acid rates (0, 0.1, 0.2, 0.4, or 0.7 mol of H+ per gram of dry substrate). Substrates with a similar initial pH had very similar buffering capacities regardless of the compost or limestone rate. These results indicate compost can be used to establish growing substrate pH similar to limestone, and this change will have little to no effect on pH buffering capacity.

Download Full-text

Buffering capacity of protein-based model food systems in the context of gastric digestion

Food & Function ◽

10.1039/c9fo01160a ◽

2019 ◽

Vol 10 (9) ◽

pp. 6074-6087 ◽

Cited By ~ 6

Author(s):

Yamile A. Mennah-Govela ◽

R. Paul Singh ◽

Gail M. Bornhorst

Keyword(s):

Protein Content ◽

Surface Area ◽

Food Systems ◽

Buffering Capacity ◽

Gastric Digestion ◽

Model Food ◽

Standardized Method ◽

The Impact

A standardized method to measure and quantify buffering capacity in the context of gastric digestion is proposed and the impact of protein content and surface area on buffering capacity was observed.

Download Full-text

Hydrology of temperate wetlands

Progress in Physical Geography Earth and Environment ◽

10.1177/030913339301700102 ◽

1993 ◽

Vol 17 (1) ◽

pp. 20-31 ◽

Cited By ~ 8

Author(s):

Denise J. Reed

Keyword(s):

Economic Importance ◽

Tidal Marshes ◽

Flooded Soils ◽

Wetland Function ◽

Temperate Wetlands ◽

The Impact ◽

Vegetation Species

The importance of wetlands as habitats for a variety of fauna and as areas with specialized vegetation, as well as their economic importance in many areas, is now widely recognized. Hydrology is important to the function of wetland systems and fundamental to the definition and delimitation of wetland areas. The ability of various vegetation species to withstand various degrees of flooding or flooded soils is a main characteristic of all wetlands, and recent studies have indicated that such adaptations result in a zonation of species within wetlands. However, competition between species may be more important in determining zonation in tidal marshes. The impact of human alterations to natural hydrology on wetland function can be severe and pristine wetlands remain in only a few areas.

Download Full-text

Acid soil and acid rain. The impact on the environment of nitrogen and sulphur cycling

Agriculture Ecosystems & Environment ◽

10.1016/0167-8809(88)90155-7 ◽

1988 ◽

Vol 20 (2) ◽

pp. 147-148

Author(s):

J.N.B. Bell

Keyword(s):

Acid Rain ◽

Acid Soil ◽

Sulphur Cycling ◽

The Impact

Download Full-text

Assessment of the petroleum hydrocarbon biodegradation potential of the sediment microbial community from an urban fringing tidal marsh of Northern New England

10.1101/279760 ◽

2018 ◽

Author(s):

Sinéad M. Ní Chadhain ◽

Jarett L. Miller ◽

John P. Dustin ◽

Jeff P. Trethewey ◽

Stephen H. Jones ◽

...

Keyword(s):

16S Rrna ◽

New England ◽

Microbial Communities ◽

Tidal Marsh ◽

Tidal Marshes ◽

Hydrocarbon Biodegradation ◽

Alkane Hydroxylase ◽

Great Bay Estuary ◽

Functional And Phylogenetic Diversity ◽

The Impact

AbstractWe assessed the impact of dodecane,n-hexane and gasoline on the microbial diversity of chronically polluted fringing tidal marsh sediment from the Great Bay Estuary of New Hampshire. Dilution cultures containing saturated alkane concentrations were sampled at zero, one and 10 days, andalkBandcyp153A1alkane hydroxylase gene libraries and 16S rRNA sequences were analyzed. The initial sediment had the most diverse alkane hydroxylase sequences and phylogenetic composition whereas treated sediments became less functionally and phylogenetically diverse with alkane substrates apparently enriching a few dominant taxa. All 1-and 10-day samples were dominated byPseudomonas-type alkane hydroxylase sequences except in dodecane treatments where primarilyRhodococcus--type alkane hydroxylases were detected. 16S rRNA profiling revealed that the Gammaproteobacteria, particularlyPseudomonas, dominated all one day samples, especially then-hexane and gasoline treatments (63.2 and 47.2% respectively) and the 10-dayn-hexane treatment (which contained 60.8%Pseudomonasand 18.6%Marinobacter).In contrast, the 10 days of dodecane treatment enriched for Actinobacteria (26.2%Rhodococcusand 32.4%Mycobacterium)and gasoline treatment enriched for Firmicutes (29.7%; mainlyBacillus, LysinibacillusandRumelibacillus).Our data indicate that fringing tidal marshes contain microbial communities with alkane-degrading abilities similar to larger meadow marshes, and support the hypothesis that alkane exposure reduces the functional and phylogenetic diversity of microbial communities in an alkane-specific manner. Further research to evaluate the ability of such fringing marsh communities to rebound to pre-pollutant diversity levels should be conducted to better assess the threat of petroleum to these habitats.

Download Full-text

Assessing the impact of acid rain and forest harvest intensity with the HD-MINTEQ model – soil chemistry of three Swedish conifer sites from 1880 to 2080

SOIL ◽

10.5194/soil-5-63-2019 ◽

2019 ◽

Vol 5 (1) ◽

pp. 63-77 ◽

Cited By ~ 4

Author(s):

Eric McGivney ◽

Jon Petter Gustafsson ◽

Salim Belyazid ◽

Therese Zetterberg ◽

Stefan Löfgren

Keyword(s):

Acid Rain ◽

Soil Solution ◽

Tree Growth ◽

Soil Chemistry ◽

Base Cations ◽

Mineral Weathering ◽

Solution Ph ◽

Weathering Rates ◽

Model Soil ◽

The Impact

Abstract. Forest soils are susceptible to anthropogenic acidification. In the past, acid rain was a major contributor to soil acidification, but, now that atmospheric levels of S have dramatically declined, concern has shifted towards biomass-induced acidification, i.e. decreasing soil solution pH due to tree growth and harvesting events that permanently remove base cations (BCs) from forest stands. We use a novel dynamic model, HD-MINTEQ (Husby Dynamic MINTEQ), to investigate possible long-term impacts of two theoretical future harvesting scenarios in the year 2020, a conventional harvest (CH, which removes stems only), and a whole-tree harvest (WTH, which removes 100 % of the above-ground biomass except for stumps) on soil chemistry and weathering rates at three different Swedish forest sites (Aneboda, Gårdsjön, and Kindla). Furthermore, acidification following the harvesting events is compared to the historical acidification that took place during the 20th century due to acid rain. Our results show that historical acidification due to acid rain had a larger impact on pore water chemistry and mineral weathering than tree growth and harvesting, at least if nitrification remained at a low level. However, compared to a no-harvest baseline, WTH and CH significantly impacted soil chemistry. Directly after a harvesting event (CH or WTH), the soil solution pH sharply increased for 5 to 10 years before slowly declining over the remainder of the simulation (until year 2080). WTH acidified soils slightly more than CH, but in certain soil horizons there was practically no difference by the year 2080. Even though the pH in the WTH and CH scenario decreased with time as compared to the no-harvest scenario (NH), they did not drop to the levels observed around the peak of historic acidification (1980–1990), indicating that the pH decrease due to tree growth and harvesting would be less impactful than that of historic atmospheric acidification. Weathering rates differed across locations and horizons in response to historic acidification. In general, the predicted changes in weathering rates were very small, which can be explained by the net effect of decreased pH and increased Al3+, which affected the weathering rate in opposite ways. Similarly, weathering rates after the harvesting scenarios in 2020 remained largely unchanged according to the model.

Download Full-text