An Investigation of Soil Nutrient Concentrations and its Relations to the Possible Sugar Maple (Acer saccharum) Decline in the Paul Smith’s College Sugar Bush
Mon, 12/05/2011 - 11:50
Abstract: Sugar maple (Acer saccharum) is an abundant tree specie that can be found almost everywhere in New England. Sugar maples can be used as timber logs, but they are primarily a great source for producing maple syrup. These trees are a vast source of income for a lot of people. Paul Smith’s College annually produces range from $25,000-$30,000 from the syrup production at their sugar bush. There are currently 1400 taps out in the sugar bush. The purpose of this study is to determine if sugar maples are on a decline in the Paul Smith’s College Sugar Bush. There have been many tests and studies done on variables that affect sugar maple growth. Many different variables such as the effects of climate, nutrient concentrations, light, ozone, oxidative stress, elevated CO2, precipitation, other trees, invasive species and mycorrhizal fungi were studied to determine how they affect soil nutrient concentrations, which ultimately affects the ability of sugar maple to survive and thrive. These studies have shown that sugar maples in New England are on a steady decline. All of the studies I have found have focused on the big picture in regard to sugar maple decline, and none on the local level, like the Paul Smith’s College Sugar Bush. The purpose of my study is to determine whether or not the sugar maples in the sugar bush are on a decline and if they are will that information influence the college’s management plan for its sugar bush. This project collected and developed data that helped determine whether sugar maples in the sugar bush are on a decline. With this new information the college will be able to determine what they would like to do with the sugar bush in the future years to come.
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File Attachments: Mark Bouquin Final Capstone.doc
Removal of Japanese Barberry (Berberis thunbergii) in a Hardwood Forest in Northwest Connecticut
Mon, 12/05/2011 - 09:57
Abstract: Japanese barberry is an invasive shrub that has overtaken and invaded the forest land of New England. Once established, Japanese barberry grows into dense populations that affect forest regeneration, and availability of different nutrients in the soil. This study focused on determining the most time efficient way to remove Japanese barberry from an area. The amount of time it took to complete each removal method was compared with how effective each method was. The effectiveness of each method was based upon how many stems were removed, and how many stems sprouted after a treatment occurred. Four methods were used which included; root severing, cutting stems, burning stems and a herbicide foliar application. It was found that digging stems took a large amount of time, while stem cutting and burning took a moderate amount of time, and the use of herbicide took a small amount of time. It was found that root severing was the least effective method, producing a high amount of new stems and taking the longest time. Herbicide treatment of stems was the most effective method, producing no new stems after treatment and taking a short amount of time to complete. Out of all the methods, two methods had equal expenses. This study has determined the most efficient and least effective way to remove Japanese barberry from a typical New England hardwood stand.
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File Attachments: Capstone Paper.docx
Changes in aquatic communities resulting from interactions between climate change and invasive aquatic plants in the Adirondacks.
Thu, 02/09/2012 - 11:26
Abstract: Global climate change can act synergistically with invasive species leading to shifts in ecosystem structure and function. We assessed how a rise in water temperature influenced the potential competitive advantage of an invasive aquatic plant, Eurasian watermilfoil, (Myriophyllum spicatum) over a co-occurring native species northern watermilfoil (M. sibiricum). We also examined the interrelationship between water temperature, watermilfoil, and the aquatic ecosystem including periphyton growth and zooplankton abundance. The study was conducted using replicated mesocosms (3785-liter), with water heaters used to provide a range of temperatures. We found that increasing water temperature promoted the likely competitive advantage of the invasive species, M. spicatum: Survival of M. sibiricum plants was lower than that of M. spicatum across all temperature treatments with a mean survival rate of 24% and 96% respectively. M. sibiricum also showed significantly slower rates of plant growth (mean growth of 3.3 cm compared to 7.6 cm for M. spicatum) and reduced vigor compared to M. spicatum, with an average of less than half the number of growing meristems. Zooplankton densities averaged over 20 times higher in mesocosms with M. sibiricum compared to those with the invasive M. spicatum. Periphyton biomass was best explained by water temperature with an increase in growth in warmer water. Our study confirms that in the face of global climate change, the invasive M. spicatum will continue to exert dominance over its native counterpart. Our results also provide compelling evidence that the combined effects of climate change and invasive aquatic plants can dramatically alter aquatic ecosystems.
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Major: Environmental Sciences, Fisheries and Wildlife Science, Forestry, Natural Resources Management and Policy
File Attachments: Climate change and milfoil draft FINAL.doc