Phase 2 significant effects. by Wendy C. Crone (2262169)

Phase 1 significant effects. by Wendy C. Crone (2262169)

eCoral: How Electrolysis Could Restore Seawater Conditions Ideal for Coral Reefs by Eric W. Lees (8946101)

“…We conclude that near the negative electrodes, the cathodes, seawater pH, supersaturation, and carbonate concentration all increase significantly. Electrolysis of seawater, therefore, can be used to restore preindustrial ocean conditions locally to save coral reefs, an approach termed eCoral here. …”

eCoral: How Electrolysis Could Restore Seawater Conditions Ideal for Coral Reefs by Eric W. Lees (8946101)

“…We conclude that near the negative electrodes, the cathodes, seawater pH, supersaturation, and carbonate concentration all increase significantly. Electrolysis of seawater, therefore, can be used to restore preindustrial ocean conditions locally to save coral reefs, an approach termed eCoral here. …”

eCoral: How Electrolysis Could Restore Seawater Conditions Ideal for Coral Reefs by Eric W. Lees (8946101)

“…We conclude that near the negative electrodes, the cathodes, seawater pH, supersaturation, and carbonate concentration all increase significantly. Electrolysis of seawater, therefore, can be used to restore preindustrial ocean conditions locally to save coral reefs, an approach termed eCoral here. …”

eCoral: How Electrolysis Could Restore Seawater Conditions Ideal for Coral Reefs by Eric W. Lees (8946101)

“…We conclude that near the negative electrodes, the cathodes, seawater pH, supersaturation, and carbonate concentration all increase significantly. Electrolysis of seawater, therefore, can be used to restore preindustrial ocean conditions locally to save coral reefs, an approach termed eCoral here. …”

eCoral: How Electrolysis Could Restore Seawater Conditions Ideal for Coral Reefs by Eric W. Lees (8946101)

“…We conclude that near the negative electrodes, the cathodes, seawater pH, supersaturation, and carbonate concentration all increase significantly. Electrolysis of seawater, therefore, can be used to restore preindustrial ocean conditions locally to save coral reefs, an approach termed eCoral here. …”

eCoral: How Electrolysis Could Restore Seawater Conditions Ideal for Coral Reefs by Eric W. Lees (8946101)

“…We conclude that near the negative electrodes, the cathodes, seawater pH, supersaturation, and carbonate concentration all increase significantly. Electrolysis of seawater, therefore, can be used to restore preindustrial ocean conditions locally to save coral reefs, an approach termed eCoral here. …”

eCoral: How Electrolysis Could Restore Seawater Conditions Ideal for Coral Reefs by Eric W. Lees (8946101)

“…We conclude that near the negative electrodes, the cathodes, seawater pH, supersaturation, and carbonate concentration all increase significantly. Electrolysis of seawater, therefore, can be used to restore preindustrial ocean conditions locally to save coral reefs, an approach termed eCoral here. …”

eCoral: How Electrolysis Could Restore Seawater Conditions Ideal for Coral Reefs by Eric W. Lees (8946101)

“…We conclude that near the negative electrodes, the cathodes, seawater pH, supersaturation, and carbonate concentration all increase significantly. Electrolysis of seawater, therefore, can be used to restore preindustrial ocean conditions locally to save coral reefs, an approach termed eCoral here. …”

eCoral: How Electrolysis Could Restore Seawater Conditions Ideal for Coral Reefs by Eric W. Lees (8946101)

“…We conclude that near the negative electrodes, the cathodes, seawater pH, supersaturation, and carbonate concentration all increase significantly. Electrolysis of seawater, therefore, can be used to restore preindustrial ocean conditions locally to save coral reefs, an approach termed eCoral here. …”

eCoral: How Electrolysis Could Restore Seawater Conditions Ideal for Coral Reefs by Eric W. Lees (8946101)

“…We conclude that near the negative electrodes, the cathodes, seawater pH, supersaturation, and carbonate concentration all increase significantly. Electrolysis of seawater, therefore, can be used to restore preindustrial ocean conditions locally to save coral reefs, an approach termed eCoral here. …”

eCoral: How Electrolysis Could Restore Seawater Conditions Ideal for Coral Reefs by Eric W. Lees (8946101)

“…We conclude that near the negative electrodes, the cathodes, seawater pH, supersaturation, and carbonate concentration all increase significantly. Electrolysis of seawater, therefore, can be used to restore preindustrial ocean conditions locally to save coral reefs, an approach termed eCoral here. …”

eCoral: How Electrolysis Could Restore Seawater Conditions Ideal for Coral Reefs by Eric W. Lees (8946101)

“…We conclude that near the negative electrodes, the cathodes, seawater pH, supersaturation, and carbonate concentration all increase significantly. Electrolysis of seawater, therefore, can be used to restore preindustrial ocean conditions locally to save coral reefs, an approach termed eCoral here. …”

Autophagy is significantly increased in the healthy older brains compared to the younger brains in post-mortem tissues. by Shreyasi Chatterjee (3531506)

Primers used for RT-PCR in this study. by Liaoxun Lu (179293)

Subjects:

Complete Treg depletion by sorting Foxp3-eGFP-negative T cells for adoptive transfer. by Liaoxun Lu (179293)

Subjects:

PD-1-deficient T cells dramatically outcompete wildtype T cells <i>in vivo</i> in the absence of natural Tregs during chronic <i>S</i>. <i>japonicum</i> infection. by Liaoxun Lu (179293)

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PD-1 deficiency suppresses Th2 differentiation and promotes IFN-γ production in liver T cells of the <i>S</i>. <i>japonicum</i> infected mice. by Liaoxun Lu (179293)

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PD-1 deficiency does obviously not change B cell and CD11b⁺ myeloid cell IHC staining in livers following <i>S</i>. <i>japonicum</i> infection. by Liaoxun Lu (179293)

Subjects: