Michael Tayler
@michael-tayler.bsky.social
- Scientist in Barcelona, Spain
- Develops atomic and nuclear spin sensors for #NMR #MRI #MEG and other #QuantumTechnology
- Please also follow @nmrduino.bsky.social
Migrating from X. Will post on both apps for a while.
- Develops atomic and nuclear spin sensors for #NMR #MRI #MEG and other #QuantumTechnology
- Please also follow @nmrduino.bsky.social
Migrating from X. Will post on both apps for a while.
4. Hardware
Whether using frugal off-the-shelf parts, or involving exotic detection methods, e.g., radioactivity, there should be something of interest to everyone.
Whether using frugal off-the-shelf parts, or involving exotic detection methods, e.g., radioactivity, there should be something of interest to everyone.
February 23, 2025 at 7:18 AM
4. Hardware
Whether using frugal off-the-shelf parts, or involving exotic detection methods, e.g., radioactivity, there should be something of interest to everyone.
Whether using frugal off-the-shelf parts, or involving exotic detection methods, e.g., radioactivity, there should be something of interest to everyone.
3. Pulse sequences
High-field methods can be used in alternative ways. For example composite pulses, usually employed to compensate errors, can be used to exclude fields from interacting with certain spins.
High-field methods can be used in alternative ways. For example composite pulses, usually employed to compensate errors, can be used to exclude fields from interacting with certain spins.
February 23, 2025 at 7:18 AM
3. Pulse sequences
High-field methods can be used in alternative ways. For example composite pulses, usually employed to compensate errors, can be used to exclude fields from interacting with certain spins.
High-field methods can be used in alternative ways. For example composite pulses, usually employed to compensate errors, can be used to exclude fields from interacting with certain spins.
2. Applications in Chemistry and Physics
Throughout its history, ZULF NMR has been used to study magnetically inhomogeneous materials. You can read about latest applications from batteries, to surface science, to chirality.
Throughout its history, ZULF NMR has been used to study magnetically inhomogeneous materials. You can read about latest applications from batteries, to surface science, to chirality.
February 23, 2025 at 7:18 AM
2. Applications in Chemistry and Physics
Throughout its history, ZULF NMR has been used to study magnetically inhomogeneous materials. You can read about latest applications from batteries, to surface science, to chirality.
Throughout its history, ZULF NMR has been used to study magnetically inhomogeneous materials. You can read about latest applications from batteries, to surface science, to chirality.
1. Theory
Given the right frame of reference, ZULF NMR is simple to understand.
Here's a 3D representation of zero-quantum NMR signals evolving in time across magnetic fields from "zero" to "high".
Given the right frame of reference, ZULF NMR is simple to understand.
Here's a 3D representation of zero-quantum NMR signals evolving in time across magnetic fields from "zero" to "high".
February 23, 2025 at 7:18 AM
1. Theory
Given the right frame of reference, ZULF NMR is simple to understand.
Here's a 3D representation of zero-quantum NMR signals evolving in time across magnetic fields from "zero" to "high".
Given the right frame of reference, ZULF NMR is simple to understand.
Here's a 3D representation of zero-quantum NMR signals evolving in time across magnetic fields from "zero" to "high".