S
Scott A. Bradford
Researcher at Agricultural Research Service
Publications - 164
Citations - 11480
Scott A. Bradford is an academic researcher from Agricultural Research Service. The author has contributed to research in topics: Colloid & Ionic strength. The author has an hindex of 56, co-authored 156 publications receiving 9705 citations. Previous affiliations of Scott A. Bradford include University of California, Riverside & United States Department of Agriculture.
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Recommendations for nutrient management plans in a semi-arid environment
TL;DR: In this article, the authors investigated the fate of nitrogen (N), phosphorus (P), potassium (K), and salts in a semi-arid environment (San Jacinto, CA).
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The Conjugation Window in an Escherichia coli K-12 Strain with an IncFII Plasmid.
Brendan Headd,Scott A. Bradford +1 more
TL;DR: A modified modeling approach is presented that accurately describes observed conjugation behavior under growing and nongrowing conditions and suggests that episodic growth in nutrient-depleted environments could result in more conjugated than sustained growth in a nutrient rich environment.
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DLVO Interaction Energies for Hollow Particles: The Filling Matters
TL;DR: The theoretical calculations show the evolution of vdW and total interaction energies for HPs with different interior fluids and shell thicknesses and help explain various experimental observations such as inhibited attachment and favorable aggregation for AHPs and favorable bubble coalescence.
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Nanobubble Retention in Saturated Porous Media under Repulsive van der Waals and Electrostatic Conditions
TL;DR: One-dimensional column experiments were conducted to investigate the transport, retention, and release of NBs in glass beads under different solution chemistry conditions, finding that NB concentrations in the effluent were reduced with an increase in ionic strength (IS) or a decrease in pH due to a reduction in the repulsive force between the glass surface and NBs.
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Minimizing Virus Transport in Porous Media by Optimizing Solid Phase Inactivation
TL;DR: The findings demonstrate the importance of solid phase inactivation, temperature, and storage periods in eliminating virus transport in porous media and has potential implications for managed aquifer recharge applications and guidelines to enhance the virus removal by controlling the temperature and aquifer residence time.