Lecture

Spin Echo Formation: Fundamentals of Biomedical Imaging

Related lectures (32)

Explores spin echoes, coherence transfer, product operator formalism, and the INEPT experiment in NMR spectroscopy.

Introduces the fundamentals of spin relaxation in magnetic resonance, covering spin-lattice and spin-spin relaxation, and rotational motion in liquids.

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Covers the basic steps in magnetic resonance, including NMR experiments and signal averaging.

Spin Coherence: Double Quantum Coherence

Explores spin echo, quadrupolar echoes, and double quantum coherence in spin dynamics.

NMR Experiments: Basics and Applications

Explores the basic steps in magnetic resonance, including INEPT pulse sequences and two-dimensional NMR experiments like COSY and NOESY.

Spin Relaxation: Examples and Mechanisms

Explores spin relaxation mechanisms in magnetic resonance, with examples like protein structure determination and solid benzene.

Quantum Description of Pulsed NMR

Explores the quantum principles behind Pulsed NMR Spectroscopy, including Zeeman interaction and spin manipulation through radiofrequency irradiation.

Nuclear Overhauser Effect

Explores the Nuclear Overhauser effect in magnetic resonance and its impact on spin relaxation and enhancement.

Introduction to Magnetic Resonance

Covers the fundamental principles of magnetic resonance and its applications in chemistry.

Quantum Sensing with Single Spins

Covers quantum sensing with single spins, focusing on the Nitrogen-Vacancy center in diamond and its applications in antiferromagnetic materials.

Intro to Quantum Sensing with Diamond NV Centers

Introduces quantum sensing with diamond NV centers, covering properties, applications, and techniques.

Neural Signals and Signal Processing

Explores nuclear magnetic resonance, MRI principles, pulse sequences, image reconstruction, safety considerations, and volume normalization in brain imaging.

Experimental Techniques: NMR Echo

Explores the concept of echo in NMR experiments using pi pulses.

Spectroscopy Fundamentals

Covers the fundamentals of spectroscopy, including tools, color, Doppler effect, and molecular behavior.

Spin-Spin Couplings: Properties and Applications

Explores spin-spin couplings, dipolar couplings, and their impact on NMR spectra and molecular structures.

Bloch equations: MR signal basics

Explores Bloch equations, MR signal basics, T₁ measurement, and signal intensity factors.

Basic Steps in Magnetic Resonance

Covers the basic steps in magnetic resonance, including spins, energy levels, and NMR spectroscopy.

NMR Experiments: Basic Principles

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Dynamic Nuclear Polarization

Introduces Dynamic Nuclear Polarization in magnetic resonance, emphasizing efficient nuclear spin diffusion and the impact of electron concentration.

Effect of relaxation on magnetization

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