Changes in baseline T-cell activation markers through week 12 and week 24 according to the linear regression model. a. by Tosi M. Mwakyandile (16408705)

Agreement between microscopy and qPCR analysis of MarBTN progression. by Rachael M. Giersch (22331947)

Detection of MarBTN-specific eDNA in tank water at late stages of MarBTN progression. by Rachael M. Giersch (22331947)

MarBTN-specific eDNA detection in each clam that was followed for MarBTN in hemolymph and eDNA. by Rachael M. Giersch (22331947)

Modeling the relationship between cancer level in hemolymph and MarBTN in tank eDNA. by Rachael M. Giersch (22331947)

Survival of soft-shell clams with MarBTN compared to control clams. by Rachael M. Giersch (22331947)

Projected decadal changes in seasonality in the hydrological cycle over the wetland regions. by Nic Gedney (19762301)

Monitoring Electrochemical Dynamics through Single-Molecule Imaging of hBN Surface Emitters in Organic Solvents by Eveline Mayner (17767827)

“…Through a sensing scheme based on redox-active species interactions with fluorescent emitters at the surface of hBN, we observe a region of a linear decrease in the number of emitters against increasingly positive potentials applied to a nearby electrode. …”

Monitoring Electrochemical Dynamics through Single-Molecule Imaging of hBN Surface Emitters in Organic Solvents by Eveline Mayner (17767827)

“…Through a sensing scheme based on redox-active species interactions with fluorescent emitters at the surface of hBN, we observe a region of a linear decrease in the number of emitters against increasingly positive potentials applied to a nearby electrode. …”

Data for Fig 1. by Rachael M. Giersch (22331947)

“…This study demonstrates the lethality of BTN, but the observation that about half of clams with BTN do not progress to death provides evidence suggesting that there may be a block to the progression of BTN in a large portion of clams in a population with this enzootic disease. …”

Decadal mean regional hydrology. by Nic Gedney (19762301)

Changepoint analysis in comparison of MarBTN-specific eDNA and cancer in hemolymph. by Rachael M. Giersch (22331947)

The contemporary, long-term seasonality in inundation over the whole of the Amazon basin. by Nic Gedney (19762301)

Percentage regional changes in decadal regional hydrology. by Nic Gedney (19762301)

Morphology, Growth Kinetics, and Porous Structure of Surfactant-Promoted Gas Hydrates: Roles of Subcooling and Surfactant Formulation by Belkacem Samar (19122984)

“…The porosity and pore sizes of the resulting porous structure decrease with increasing subcooling, down to values in the range of 40–50% and a few microns for the highest subcooling investigated (≈10 K). …”

Morphology, Growth Kinetics, and Porous Structure of Surfactant-Promoted Gas Hydrates: Roles of Subcooling and Surfactant Formulation by Belkacem Samar (19122984)

“…The porosity and pore sizes of the resulting porous structure decrease with increasing subcooling, down to values in the range of 40–50% and a few microns for the highest subcooling investigated (≈10 K). …”

Morphology, Growth Kinetics, and Porous Structure of Surfactant-Promoted Gas Hydrates: Roles of Subcooling and Surfactant Formulation by Belkacem Samar (19122984)

“…The porosity and pore sizes of the resulting porous structure decrease with increasing subcooling, down to values in the range of 40–50% and a few microns for the highest subcooling investigated (≈10 K). …”

Morphology, Growth Kinetics, and Porous Structure of Surfactant-Promoted Gas Hydrates: Roles of Subcooling and Surfactant Formulation by Belkacem Samar (19122984)

“…The porosity and pore sizes of the resulting porous structure decrease with increasing subcooling, down to values in the range of 40–50% and a few microns for the highest subcooling investigated (≈10 K). …”

Morphology, Growth Kinetics, and Porous Structure of Surfactant-Promoted Gas Hydrates: Roles of Subcooling and Surfactant Formulation by Belkacem Samar (19122984)

“…The porosity and pore sizes of the resulting porous structure decrease with increasing subcooling, down to values in the range of 40–50% and a few microns for the highest subcooling investigated (≈10 K). …”

Morphology, Growth Kinetics, and Porous Structure of Surfactant-Promoted Gas Hydrates: Roles of Subcooling and Surfactant Formulation by Belkacem Samar (19122984)

“…The porosity and pore sizes of the resulting porous structure decrease with increasing subcooling, down to values in the range of 40–50% and a few microns for the highest subcooling investigated (≈10 K). …”