Chemical Sciences: A Manual for CSIR-UGC National Eligibility Test for Lectureship and JRF/Magnetic resonance force microscopy
This page was imported and needs to be de-wikified. Books should use wikilinks rather sparsely, and only to reference technical or esoteric terms that are critical to understanding the content. Most if not all wikilinks should simply be removed. Please remove {{dewikify}} after the page is dewikified. |
Magnetic resonance force microscopy (MRFM) is an imaging technique that acquires magnetic resonance images (MRI) at nanometer scales, and possibly at atomic scales in the future. MRFM is potentially able to observe protein structures which cannot be seen using X-ray crystallography and protein nuclear magnetic resonance spectroscopy. Detection of the magnetic spin of a single electron has been demonstrated using this technique. The sensitivity of a current MRFM microscope is 10 billion times better than a medical MRI used in hospitals.
Basic principle
[edit | edit source]The MRFM concept combines the ideas of magnetic resonance imaging (MRI) and atomic force microscopy (AFM). Conventional MRI employs an inductive coil as an antenna to sense resonant nuclear or electronic spins in a magnetic field gradient. MRFM uses a cantilever tipped with a ferromagnetic (iron cobalt) particle to directly detect a modulated spin gradient force between sample spins and the tip. As the ferromagnetic tip moves close to the sample, the atoms’ nuclear spins become attracted to it and generate a small force on the cantilever. The spins are then repeatedly flipped, causing the cantilever to gently sway back and forth in a synchronous motion. That displacement is measured with an interferometer (laser beam) to create a series of 2-D images of the sample, which are combined to generate a 3-D image. The interferometer measures resonant frequency of the cantilever. Smaller ferromagnetic particles and softer cantilevers increase the signal to noise ratio. Unlike the inductive coil approach, MRFM sensitivity scales favorably as device and sample dimensions are reduced.
Because the signal to noise ratio is inversely proportional to the sample size, Brownian motion is the primary source of noise at the scale in which MRFM is useful. Accordingly, MRFM devices are cryogenically cooled. MRFM was specifically devised to determine the structure of proteins in situ.
Milestones
[edit | edit source]The basic principles of MRFM imaging and the theoretical possibility of this technology were first described in 1991[1]. The first MRFM image was obtained in 1993 at the IBM Almaden Research Center with 1-μm vertical resolution and 5-μm lateral resolution using a bulk sample of the paramagnetic substance diphenyipicrylhydrazil[2]. The spatial resolution reached nanometer-scale in 2003.[3] Detection of the magnetic spin of a single electron was achieved in 2004[4]. In 2009 researchers at IBM and Stanford announced that they had achieved resolution of better than 10 nanometers, imaging tobacco mosaic virus particles on a nanometer-thick layer of adsorbed hydrocarbons.[5]
External links
[edit | edit source]- University of Washington Quantum System Engineering and MRFM Home Page, http://courses.washington.edu/goodall/MRFM/.
- Magnetic-Resonance Force Microscopy, http://www.medgadget.com/archives/2005/04/magneticresonan.html.
- Degen CL, Poggio M, Mamin HJ, Rettner CT, Rugar D (12 January 2009). "Nanoscale magnetic resonance imaging". PNAS. We have combined ultrasensitive magnetic resonance force microscopy (MRFM) with 3D image reconstruction to achieve magnetic resonance imaging (MRI) with resolution <10 nm. 106 (5): 1313–7. doi:10.1073/pnas.0812068106. PMC 2628306. PMID 19139397.
{{cite journal}}
: Unknown parameter|laysummary=
ignored (help)CS1 maint: location (link) CS1 maint: multiple names: authors list (link) - "BBC NEWS - Science & Environment - IBM team boosts MRI resolution". 13 January 2009. Retrieved 2009-01-14.
References
[edit | edit source]- ↑ J. A. Sidles (1991). "Noninductive detection of single-proton magnetic resonance". Applied Physics Letters. 58: 2854–6. doi:0.1063/1.104757.
{{cite journal}}
: Check|doi=
value (help) - ↑ O. Zuger and D. Rugar (1993). "First images from a magnetic resonance force microscope". Applied Physics Letters. 63: 2496–8. doi:10.1063/1.110460.
- ↑ S. Chao, W. Dougherty, J. Garbini, J. Sidles (2003). "Nanometer-scale magnetic resonance imaging". Review of Scientific Instruments. 75: 1175–81. doi:10.1063/1.1666983.
{{cite journal}}
: CS1 maint: multiple names: authors list (link) - ↑ D. Rugar, R. Budakian, H. Mamin, B. Chui (2004). "Single spin detection by magnetic resonance force microscopy". Nature. 430 (6997): 329–32. doi:10.1038/nature02658. PMID 15254532.
{{cite journal}}
: CS1 maint: multiple names: authors list (link) - ↑ C. L. Degen, M. Poggio, H. J. Mamin, C. T. Rettner, and D. Rugar (2009). "Nanoscale magnetic resonance imaging". PNAS. 106 (5): 1313. doi:10.1073/pnas.0812068106. PMC 2628306. PMID 19139397.
{{cite journal}}
: CS1 maint: multiple names: authors list (link)