Advances in nuclear magnetic resonance spectroscopy: case of proton conductive materials

Abstract: Understanding of molecular dynamics in proton conductive materials in solid-state allows creating materials with increased performance and efficiency. For this purpose, the nuclear magnetic resonance (NMR) spectroscopy is a very...

“…Besides being the smallest existing atom, hydrogen can gain or lose one electron, forming the proton or the hydride ion; consequently, proton detection is complex, and the determination of how they are present in the compound's formula is still often unknown [65]. Nowadays, there are diverse techniques that can be used to detect protons, including direct methods (such as neutron scattering [66], nuclear magnetic resonance [67], and gas chromatography [68]) or indirect ones (like thermogravimetry [69]). All of them are supported by an initial hypothesis regarding the formed/evolved species [70].…”

A Review on Low-Temperature Protonic Conductors: Principles and Chemical Sensing Applications

“…Besides being the smallest existing atom, hydrogen can gain or lose one electron, forming the proton or the hydride ion; consequently, proton detection is complex, and the determination of how they are present in the compound's formula is still often unknown [65]. Nowadays, there are diverse techniques that can be used to detect protons, including direct methods (such as neutron scattering [66], nuclear magnetic resonance [67], and gas chromatography [68]) or indirect ones (like thermogravimetry [69]). All of them are supported by an initial hypothesis regarding the formed/evolved species [70].…”

A Review on Low-Temperature Protonic Conductors: Principles and Chemical Sensing Applications

Structural effect on physicochemical properties of ethanolamine carboxylate ionic liquids by experimental and theoretical study