Microscopy: Resolution (Jeff Lichtman)
Learn more: https://www.ibiology.org/talks/resolu... The resolution of a microscope can be defined as the smallest distance at which two small objects can still be seen as separate objects. This lecture discusses various criteria for resolution, the factors that influence resolution in the lateral and axial planes, and how to sample an image adequately using a camera or confocal microscope, such that the full optical resolution is retained.
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Microscopy: What Is Light? (Bo Huang)
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Microscopy: Resolution in Microscopy (Jeff Lichtman)
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Using Immersion Objectives
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Jeff Lichtman: Connectomics: Mapping the Brain | Harvard Department of Physics
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Microscopy: Abbe Diffraction (Kurt Thorn)
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Microscopy: Super-Resolution: Structured Illumination Microscopy (SIM) (David Agard)
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Something is jamming GPS over Europe. Here's what we found
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How AI Cracked the Protein Folding Code and Won a Nobel Prize
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Microscopy: Point Spread Function (Jeff Lichtman)
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Google Maps is unreasonably fast. Let me explain
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Stefan Hell: MINFLUX Nanoscopy: Superresolution post Nobel
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Microscopy: Diffraction (Jeff Lichtman)
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SDDRC - Introduction to microscopy
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Markus Sauer - Super-resolution expansion microscopy - Imaging ONEWORLD
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Can the Brain's Structure Reveal its Function? - Jeff Lichtman
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But why would light "slow down"? | Visualizing Feynman's lecture on the refractive index
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The Point Spread Function
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Introduction to Confocal Microscopy
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Xiaowei Zhuang (Harvard/HHMI) Part 1: Super-Resolution Fluorescence Microscopy
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