Gregory Lowry, PhD

CEINT Publications

A. Avellan, Simonin, M. , McGivney, E. , Bossa, N. , Spielman-Sun, E. , Rocca, J. D. , Bernhardt, E. S. , Geitner, N. K. , Unrine, J. M. , Wiesner, M. R. , and Lowry, G. V. , Gold nanoparticle biodissolution by a freshwater macrophyte and its associated microbiome, Nature Nanotechnology, 2018.
E. Spielman-Sun, Lombi, E. , Donner, E. , Avellan, A. , Etschmann, B. , Howard, D. L. , and Lowry, G. V. , Temporal evolution of copper distribution and speciation in roots of Triticum aestivum exposed to CuO, Cu(OH)2, and CuS nanoparticles, Environmental Science & Technology, 2018.
N. K. Geitner, Cooper, J. L. , Avellan, A. , Castellon, B. T. , Perrotta, B. G. , Bossa, N. , Simonin, M. , Anderson, S. M. , Inoue, S. , Hochella, M. F. , Richardson, C. John, Bernhardt, E. S. , Lowry, G. V. , Ferguson, P. L. , Matson, C. W. , King, R. S. , Unrine, J. M. , Wiesner, M. R. , and Hsu-Kim, H. , Size-Based Differential Transport, Uptake, and Mass Distribution of Ceria (CeO2) Nanoparticles in Wetland Mesocosms, Environmental Science & Technology, 2018.
J. D. Moore, Avellan, A. , Noack, C. W. , Guo, Y. , Lowry, G. V. , and Gregory, K. B. , Time-dependent bacterial transcriptional response to CuO nanoparticles differs from that of Cu2+ and provides insights into CuO nanoparticle toxicity mechanisms, Environmental Science: NanoEnvironmental Science: Nano, vol. 4, pp. 2321-2335, 2017.
A. Avellan, Stegemeier, J. P. , Gai, K. , Dale, J. , Hsu-Kim, H. , Levard, C. , O’Rear, D. , Hoelen, T. P. , and Lowry, G. V. , Speciation of Mercury in Selected Areas of the Petroleum Value Chain, Environmental Science & TechnologyEnvironmental Science & Technology, 2017.
X. Gao and Lowry, G. V. , Progress towards standardized and validated characterizations for measuring physicochemical properties of manufactured nanomaterials relevant to nano health and safety risks, NanoImpactNanoImpact, vol. 9, pp. 14-30, 2018.
G. Dublet, Pacheco, J. Lezama, Bargar, J. R. , Fendorf, S. , Kumar, N. , Lowry, G. V. , and Brown, Jr, G. E. , Partitioning of uranyl between ferrihydrite and humic substances at acidic and circum-neutral pH, Geochimica et Cosmochimica ActaGeochimica et Cosmochimica Acta, vol. 215, pp. 122-140, 2017.
A. L. Dale, Lowry, G. V. , and Casman, E. A. , Accurate and fast numerical algorithms for tracking particle size distributions during nanoparticle aggregation and dissolution, Environmental Science: NanoEnvironmental Science: Nano, vol. 4, pp. 89-104, 2017.
B. P. Espinasse, Geitner, N. K. , Schierz, A. , Therezien, M. , Richardson, C. J. , Lowry, G. V. , Ferguson, L. , and Wiesner, M. R. , Comparative Persistence of Engineered Nanoparticles in a Complex Aquatic Ecosystem, Environmental Science & Technology, 2018.
X. Gao, Spielman-Sun, E. , Rodrigues, S. M. , Casman, E. A. , and Lowry, G. V. , Time and Nanoparticle Concentration Affect the Extractability of Cu from CuO NP-Amended Soil, Environmental Science & TechnologyEnvironmental Science & Technology, 2017.
K. Gai, Hoelen, T. P. , Hsu-Kim, H. , and Lowry, G. V. , Mobility of Four Common Mercury Species in Model and Natural Unsaturated Soils, Environmental Science & TechnologyEnvironmental Science & Technology, vol. 50, no. 7, pp. 3342-3351, 2016.
S. C. Karcher, Harper, B. J. , Harper, S. L. , Hendren, C. O. , Wiesner, M. R. , and Lowry, G. V. , Visualization tool for correlating nanomaterial properties and biological responses in zebrafish, Environ. Sci.: Nano, 2016.
G. A. Sotiriou, Singh, D. , Zhang, F. , Chalbot, M. - C. G. , Spielman-Sun, E. , Hoering, L. , Kavouras, I. G. , Lowry, G. V. , Wohlleben, W. , and Demokritou, P. , Thermal decomposition of nano-enabled thermoplastics: Possible environmental health and safety implications, Journal of Hazardous Materials, vol. 305, pp. 87 - 95, 2016.
Z. Saunders, Noack, C. W. , Dzombak, D. A. , and Lowry, G. V. , Characterization of engineered alumina nanofibers and their colloidal properties in water, Journal of Nanoparticle Research, vol. 17, no. 3, 2015.
T. Phenrat, Thongboot, T. , and Lowry, G. V. , Electromagnetic Induction of Zerovalent Iron (ZVI) Powder and Nanoscale Zerovalent Iron (NZVI) Particles Enhances Dechlorination of Trichloroethylene in Contaminated Groundwater and Soil: Proof of Concept, Environmental Science & Technology, vol. 50, no. 2, pp. 872 - 880, 2016.

Pages