Assessment of time-dependent capacity of driven piles in Ohio soils

Heron, Matthew Joseph

30 May 2019

No description available.

Civil Engineering

pile setup

Ohio soils

driven piles

setup factor

soil properties

Resilient modulus prediction using neural network algorithm

Hanittinan, Wichai

20 September 2007

No description available.

resilient modulus

M-E PDG

Pavement design

Ohio soils

artificial neural networks

An Investigation of Fertilizer-Derived Uranium in Ohio Agricultural Soils

Calero, Adolfo Eberhard

29 September 2020

No description available.

Agriculture

Analytical Chemistry

Environmental Science

Geochemistry

Geographic Information Science

Soil Sciences

Uranium

Ohio Soils

Phosphorus Fertilizer

Soil Chemistry

Agricultural Soils

Management Practices

Biological potential and diffusion limitation of methane oxidation in no-till soils

Prajapati, Prajaya

21 May 2014

Indiana University-Purdue University Indianapolis (IUPUI) / Long term no-till (NT) farming can improve the CH4 oxidation capacity of agricultural lands through creation of a favorable soil environment for methanotrophs and diffusive gas transport. However, limited data is available to evaluate the merit of that contention. Although the potential for biological CH4 oxidation may exist in NT soils, restricted diffusion could limit expression of that potential in fine-textured soils. A study was conducted to assess the CH4 oxidation potential and gaseous diffusivity of soils under plow till (PT) and NT for > 50 years. Intact cores and composite soils samples (0-10 and 10-20 cm) were collected from NT and PT plots located at a well-drained site (Wooster silt loam) and at a poorly-drained (Crosby silt loam) site in Ohio. Adjacent deciduous forest soils were also sampled to determine maximum rate expected in undisturbed soils in the region. Regardless of study sites and soil depth, CH4 oxidation rate (measured at near ambient CH4) and oxidation potential (Vmax, measured at elevated CH4) were 3-4 and 1.5 times higher in NT than in PT soils, respectively. Activity in the NT soils approached (66-80 %) that in the forest soils. Half saturation constants (Km) and threshold for CH4 oxidation (Th) were lower in NT (Km: 100.5 µL CH4 L-1; Th: 0.5 µL CH4 L-1) than in PT soils (Km: 134 µL CH4 L-1; Th: 2.8 µL CH4 L-1) suggesting a greater affinity of long-term NT soils for CH4, and a possible shift in methanotrophic community composition. CH4 oxidation rates were lower in intact soil cores compared to sieved soils, suggesting that CH4 oxidation was limited by diffusion, a factor that could lead to lower field-measured CH4 uptake than suggested by biological oxidation capacity measured in the laboratory. Regardless of soil drainage characteristic, long-term NT resulted in significantly higher (2-3 times) CH4 diffusivity (mean: 2.5 x 10-3 cm2 s-1) than PT (1.5 x 10-3 cm2 s-1), probably due to improved soil aggregation and greater macro-pores volume in NT soils. Overall, these results confirm the positive impact of NT on the restoration of the biological (Vmax, Km and Th) and physical (diffusivity) soil attributes essential for CH4 uptake in croplands. Long-term implementation of NT farming can therefore contribute to the mitigation of CH4 emission from agriculture.

Methylotrophic bacteria -- Research

Biogeochemistry -- Research

Gases in microorganisms

Soil chemistry -- Analysis

Drainage

Soil texture

Soil physics

Methane -- Research -- Analysis

Developing Consolidation Characteristics of Ohio Soils Using GIS

Papke, Mark Kenneth, P.E.

16 May 2011

No description available.

Civil Engineering

Engineering

Geographic Information Science

Geological

Geology

Geotechnology

Information Technology

Sedimentary Geology

Soil Sciences

Transportation

Transportation Planning

Cc

Cr

Ohio Compression Index Correlations

Consolidation

Oedometer

Compression Index of Ohio Soils

GIS

Schmertmann

Pacheco Silva

Ohio Clays

Compression Index

Settlement