The correct term is "precess," and they do it only if excited. When sitting in a static B0 field, the spins are simply aligned or anti-aligned with B0 (in the simple classical picture).anorred said:I'm pretty sure I get the basics of NMR, but I'm trying to learn, so please be patient.
From what I understand, when an individual is placed in an MRI machine, the nuclei of atoms in his or her body with an odd number of protons align with the B0 field. My understanding is that these nuclei "spin" at a speed that is related to how strong the B0 field is.
Please use the term "oscillatory" or "rotating", because the word "fluctuations" typically refers to random variations.anorred said:If the fluctuating B1 field
No, again spin is an intrinsic property of the nucleus. You mean that the B1 frequency matches the Larmor or precession frequency.anorred said:matches this spin speed,
precessanorred said:the magnetic poles of a small percent of these atoms spins
Yes, only the CP component matching the precession sense will couple to the spin system.anorred said:at an increasing angle away from the axis parallel to the B0 field. I didn't know the B1 field NEEDS to be circularly polarized, but that makes sense.
They don't snap, but rather relax exponentiallyanorred said:Once the B1 field is turned off, the nuclei of the atoms snap back
not exactly, they don't release anything. They induce in the pickup coil an oscillating EMF at the Larmor frequency that is exponentially damped according to the relaxation rates.anorred said:and release a pulsating field relating to how they "relax."
As I mentioned, the transit or excitation time is proportional to the strength of the applied B1 field. 1 ms is a typical value used in MRI. Relaxation times depend entirely on the material being examined. In MRI, hydrogen atoms (protons), primarily in water, are imaged. Purified water has a relaxation time of many seconds, and cerebral spinal fluid is also very long. Water in bones is surrounded by a solid matrix with strong dissipation mechanisms, so relaxation is very short. I forget actual values but you can look them up easily.anorred said:Electrons are the target particle in ESR and not NMR.. so I guess I was generalizing when I mentioned electrons.
Do I understand it alright or am I completely off?
My question is how fast a typical "transit time" is compared to the "returning" time. I'm not a physicist, but I'm an inventor and I only want to fill my head with the basics so sorry if I sound dumb! I'm new to this.
MRI excitation time refers to the time it takes for the hydrogen atoms in the body to be aligned in a specific direction by a magnetic field. This is a necessary step in the MRI process to produce images. On the other hand, relaxation time refers to the time it takes for the hydrogen atoms to return to their original alignment after being excited. This process is what creates the actual signal used to create the MRI image.
MRI excitation time is important because it determines the contrast and resolution of the resulting image. A longer excitation time can result in a higher signal-to-noise ratio and clearer images, while a shorter excitation time can lead to lower quality images with less contrast.
MRI excitation time is primarily controlled by adjusting the strength and duration of the magnetic field used in the MRI scanner. The strength of the magnetic field determines the amount of energy needed to excite the hydrogen atoms, while the duration of the field determines how long the atoms remain excited before returning to their original alignment.
There are several factors that can affect MRI relaxation time, including the type of tissue being imaged, the strength of the magnetic field, and the presence of any contrast agents. Additionally, certain diseases or conditions can also affect relaxation time, leading to changes in the resulting image.
Yes, MRI excitation time and relaxation time can be adjusted to improve image quality. For example, longer excitation times can result in clearer images, while shorter relaxation times can help to reduce motion artifacts. Additionally, the use of contrast agents can also help to improve image quality by altering relaxation times and enhancing contrast between different tissues.