Your search keyword '"Alexandrea M. Rice"' showing total 4 results

1. Predicting Foliar Nutrient Concentrations across Geologic Materials and Tree Genera in the Northeastern United States Using Spectral Reflectance and Partial Least Squares Regression Models

Author

Wenxiu Teng, Qian Yu, Ivan C. Mischenko, Alexandrea M. Rice, and Justin B. Richardson

Subjects

Environmental sciences, GE1-350, Physical geography, GB3-5030

Abstract

Spectral data can potentially offer a rapid assessment of nutrients in leaves and reveal information about the geologic history of the soil. This study evaluated the capability of the partial least squares regression (PLSR) for estimating foliar macro- and micronutrients (Ca, Mg, K, P, Mn, and Zn) using spectral data (400 to 2,450 nm). First, filter-based wavelength selection was conducted to reduce the independent variables. PLSR performance was then assessed across 4 geologic materials (coarse glacial till, glaciofluvial, melt-out till, and outwash) and 4 dominant tree genera (Acer, Betula, Fagus, and Quercus) in the northeastern United States. The spectral ranges 400 to 500 nm and 1,800 to 2,450 nm were found to be the most important spectral regions for estimating foliar nutrient concentrations. The developed PLSR model predicted 6 foliar nutrients with moderate to high accuracy (adjusted R2 from 0.60 to 0.75). Foliar macronutrient concentrations were estimated with higher accuracy (mean adj. R2 = 0.69) than micronutrient concentrations (mean adj. R2 = 0.635). The prediction for the individual tree genera group and the individual geologic materials group outperformed the combined group; for instance, the adj. R2 for estimating Ca and P was 39% higher for American beech (Fagus grandifolia) than all tree genera combined. Spectral measurements combined with wavelength selection and PLSR models can potentially be used to quantify foliar macro- and micronutrients at regional scales, and taking into account geologic materials and tree genera will improve this prediction.

Published

2024

2. Tree variability limits the detection of nutrient treatment effects on sap flux density in a northern hardwood forest

Author

Alexandrea M. Rice, Mariann T. Garrison-Johnston, Arianna J. Libenson, and Ruth D. Yanai

Subjects

Sap flux density, Thermal dissipation, Nitrogen, Phosphorus, Calcium silicate, MELNHE, Medicine, Biology (General), QH301-705.5

Abstract

The influence of nutrient availability on transpiration is not well understood, in spite of the importance of transpiration to forest water budgets. Soil nutrients have the potential to affect tree water use through indirect effects on leaf area or stomatal conductance. For example, following addition of calcium silicate to a watershed at Hubbard Brook, in New Hampshire, streamflow was reduced for 3 years, which was attributed to a 25% increase in evapotranspiration associated with increased foliar production. The first objective of this study was to quantify the effect of nutrient availability on sap flux density in a nitrogen, phosphorus, and calcium addition experiment in New Hampshire in which tree diameter growth, foliar chemistry, and soil nutrient availability had responded to treatments. We measured sap flux density in American beech (Fagus grandifolia, Ehr.), red maple (Acer rubrum L.), sugar maple (Acer saccharum Marsh.), white birch (Betula papyrifera Marsh.), or yellow birch (Betula alleghaniensis Britton.) trees, over five years of experiments in five stands distributed across three sites. In 2018, 3 years after a calcium silicate addition, sap flux density averaged 36% higher in trees in the treatment than the control plot, but this effect was not very significant (p = 0.07). Our second objective was to determine whether this failure to detect effects with greater statistical confidence was due to small effect sizes or high variability among trees. We found that tree-to-tree variability was high, with coefficients of variation averaging 39% within treatment plots. Depending on the species and year of the study, the minimum difference in sap flux density detectable with our observed variability ranged from 46% to 352%, for a simple ANOVA. We analyzed other studies reported in the literature that compared tree water use among species or treatments and found detectable differences ranging from 16% to 78%. Future sap flux density studies could benefit from power analyses to guide sampling intensity. Including pretreatment data, in the case of manipulative studies, would also increase statistical power.

Published

2022

3. Protocol for route restoration in California’s desert renewable energy conservation plan area

Author

Ka-Voka R. Jackson, Todd C. Esque, Lesley A. DeFalco, Lauren J. Price, Andrew C. Johnson, Sara J. Scoles-Sciulla, Caroline S. Woods, Amy Fesnock-Parker, Kristin E. Forgrave, Alexandrea M. Rice, and Jeffery K. Childers

Subjects

Desert (philosophy), business.industry, Environmental protection, Conservation Plan, Environmental science, business, Protocol (object-oriented programming), Renewable energy

Published

2021

4. Long‐term Nitrogen Addition Decreases Organic Matter Decomposition and Increases Forest Soil Carbon

Author

Susan E. Washko, Adrienne E. Coble, Jun-Jian Wang, Nicholas Baldauf, Kate Lajtha, Brittany Johnson, Sarah J. Wurzbacher, Myrna J. Simpson, Lauren Wind, Richard D. Bowden, and Alexandrea M. Rice

Subjects

chemistry.chemical_classification, Chemistry, Soil organic matter, Soil Science, Biomass, chemistry.chemical_element, 04 agricultural and veterinary sciences, Soil carbon, 010501 environmental sciences, Plant litter, 01 natural sciences, Nitrogen, Soil respiration, Agronomy, 040103 agronomy & agriculture, Litter, 0401 agriculture, forestry, and fisheries, Organic matter, 0105 earth and related environmental sciences

Abstract

Eastern North American forests receive anthropogenically elevated nitrogen (N) deposition that alters soil processes and forest productivity. We examined N deposition effects on soil carbon (C) and N in temperate, N-rich forest plots fertilized annually (100 kg N ha⁻¹ y⁻¹) since 1993. After nearly two decades, soil C in O, A, and upper 50 cm of B horizons of N-addition plots was 17% greater (14.2 ± 0.7 kg C m⁻²) than control plots. Aboveground tree biomass growth and litterfall were not affected by fertilization. Fine root mass (0–1 mm) was 34% greater in N-addition plots, but did not explain soil C increases. Rather, reduced decomposition of litter and soil organic matter drove C increases in N-addition plots. Decomposition rates of black cherry, sugar maple, and mixed leaf litter were 43, 67, and 36%, greater, respectively, in control than N-addition plots. Light fraction organic matter was greater in N-addition plots than in control plots, due to either enhanced root production or decreased decomposition of soil organic matter. Soil respiration was reduced, and microbial biomass in O, A, and upper-B horizons was lower in N-addition plots than controls. The soil microbial community composition was also altered dramatically with N additions. Recalcitrant organic matter enzyme activity (peroxidase) was reduced in the O-horizon by N addition. Available Ca, Mg, and K were reduced in O and A horizons by N fertilization. These results suggest that chronic elevated atmospheric N inputs can increase forest soil C storage by decreasing decomposition, however the long-term stability of this additional C sequestration is unknown.

Published

2019