Magnetic resonance force microscopy — the quest for a molecular structure microscope

The magnetic resonance force microscope (MRFM) provides a route to achieving scanned probe magnetic resonance imaging with extremely high spatial resolution. Achieving this capability will require understanding the force exerted on a microscopic magnetic probe by a spatially extended sample over whi

## Ž . The Magnetic Resonance Force Microscope MRFM presents the opportunity for a magnetic resonance imaging probe with ultra-high, potentially atomic-scale, resolution. The successful application of this technique in detection of nuclear Ž . magnetic, electron-spin and ferromagnetic resonance FM

The combination of ultrasound with atomic force microscopy (AFM) opens the high lateral resolution of scanning probe techniques in the nanometer range to ultrasonics. One possible method is to observe the resonance frequencies of the AFM sensors under different tip-sample interaction conditions. AFM

Biomolecular force fields for use in molecular dynamics (MD) simulations of proteins, DNA, or membranes are generally parametrized against ab initio quantum-chemical and experimental data for small molecules. The application of a force field in a simulation of a biomolecular system, such as a protei

The effects of imbibed pyridine on the molecular structure of a high-volatile bituminous vitrinite have been studied at room temperature by proton nuclear magnetic resonance pulse techniques. Both the free induction decay and nominal solid echo signals, recorded before and after addition of fully-de