High Magnetic Fields in Chemistry

Steiner, Ulrich; Gilch, Peter

doi:10.1142/9789812774873_0010

Cited by 4 publications

(3 citation statements)

References 26 publications

(28 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…According to the spin conservation rule, the kind of product depends on the state of atoms (excited singlet or triplet) at the moment of the reaction. [5] Microwave magnetic fields can lead to resonant transitions between triplet states of molecules, affecting the reaction kinetics that proceeds via triplet formation. In general, magnetic fields can influence on spin-dependent chemical reactions.…”

Section: Spin Chemistrymentioning

confidence: 99%

Effects and Mechanisms of Interaction of Electromagnetic Fields on Cells

Rios¹

2020

Preprint

View full text Add to dashboard Cite

Modern life implies a constant exposure of living organisms to electromagnetic fields generated by human made technology. The question of whether or not electromagnetic fields in the non-ionizing frequency range can affect cellular functions, increasing the risk of cancer or another pathologies is currently a subject of interest for scientific community of several disciplines of physics, biology, chemistry and medicine. The first part of this short review presents briefly the possible mechanism of interaction of electromagnetic fields in cellular level based in theoretical models and experimental results. The second part refers to experimental observations published by several authors about the potential cytotoxic and genotoxic effects of electromagnetic fields. Results of researches are no yet conclusive enough to accept or reject the genotoxic, carcinogenic or cytotoxic potential of these fields. Up to date the International Agency for Research on Cancer (IARC) has classified the X, gamma and ultraviolet radiation as carcinogenic and the fields generated by radio frequencies as possibly carcinogenic.

show abstract

Section: Spin Chemistrymentioning

confidence: 99%

Effects and Mechanisms of Interaction of Electromagnetic Fields on Cells

Rios¹

2020

Preprint

View full text Add to dashboard Cite

show abstract

“…These spin chemistry effects (23) can occur in a wide range of applied fields, depending on the thermodynamic or quantum mechanical mechanism involved. The smallness of the Zeeman splitting magnetic energy can require rather large magnetic fields (of the order of 10 T) to impact the reaction (24). The hyperfine field, typically of the order of 0.1 T, can also significantly modify the lifetime of radical species, in the so-called "normal magnetic field effect," extensively studied for photosynthesis.…”

Section: Significancementioning

confidence: 99%

The magnetoelectrochemical switch

Popa¹,

Kemp

Majjad

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

View full text Add to dashboard Cite

In the field of spintronics, the archetype solid-state two-terminal device is the spin valve, where the resistance is controlled by the magnetization configuration. We show here how this concept of spin-dependent switch can be extended to magnetic electrodes in solution, by magnetic control of their chemical environment. Appropriate nanoscale design allows a huge enhancement of the magnetic force field experienced by paramagnetic molecular species in solutions, which changes between repulsive and attractive on changing the electrodes' magnetic orientations. Specifically, the field gradient force created within a sub-100-nm-sized nanogap separating two magnetic electrodes can be reversed by changing the orientation of the electrodes' magnetization relative to the current flowing between the electrodes. This can result in a breaking or making of an electric nanocontact, with a change of resistance by a factor of up to 10 3 . The results reveal how an external field can impact chemical equilibrium in the vicinity of nanoscale magnetic circuits.magnetohydrodynamics | supramolecular chemistry | electrochemistry S pintronics (1, 2) is a mature research field in solid-state physics, with important electronic device applications. Spindependent transport studies in a liquid environment are much scarcer, and still rely on solid-state spintronics devices concepts. For example, giant magnetoresistance or tunnel magnetoresistance spin valves (3) are used for detecting the stray magnetic field (4) of nearby micrometer-sized (bioactive) magnetic beads (5). The objects studied are significantly larger than the molecular scale, owing to the predominant concentration gradient and Brownian forces exceeding by orders of magnitudes the magnetic force experienced by paramagnetic molecules (6). However, miniaturization of ferromagnetic elements below the micrometer range provides opportunities for enhancing the magnetic force field, making the detection of single spin possible (7). We propose here to use such a nanoscale enhancement strategy to investigate how the realization of very large magnetic field gradients can impact the properties of paramagnetic molecules, in particular by modifying their chemical equilibrium. An external magnetic field controls the magnetization direction of ferromagnetic immersed electrodes, with a related large change of the magnetic forces in their vicinity. This modifies accordingly the chemical stability of the solution, in the interesting case where paramagnetic molecules are essential to the construction of a conductive molecular-sized system. The resulting metallic nanobridge therefore exhibits electrical properties tunable through a change of magnetic orientations of the electrodes. While it relies on a totally different physical origin, this is the chemical analog of a solid-state spin valve device.We illustrate this concept by presenting magnetoresistance (MR) results for a Ni-based nanobrige separating two nearby Ni electrodes immersed in an electrochemical solution. The experiments are based up...

show abstract

“…As for ET systems in general, the energetics and the distance between the donor (D) and acceptor (A) components are cardinal quantities determining the kinetics of the system. − Spin processes may be a further factor influencing ET kinetics. In contrast to hyperfine induced spin conversion prevailing in organic systems (>1 ns), − in compounds containing transition metals, spin processes can have an impact on picosecond ET dynamics, as shown in an exemplary way for oxazine 1/ferrocene. − These ultrafast spin processes may play a role in biological systems involving radical pair (RP)-type intermediates, where one part is a paramagnetic metal ion, as in a vitamin B 12 analogue. , …”

Section: Introductionmentioning

confidence: 99%

Magnetic Field and Temperature Dependencies Shed Light on the Recombination Kinetics of a Transition Metal Donor/Acceptor System

et al. 2005

Self Cite

View full text Add to dashboard Cite

Abstract:The radical pair recombination of an intramolecular electron-transfer system containing a transition metal moiety has been addressed by femtosecond spectroscopy. The radical pair is formed by ultrafast electron transfer (90 fs) from a ferrocene residue to a photoexcited Nile blue moiety. Its recombination proceeds on the picosecond time scale in a multiexponential fashion. The kinetic pattern is a manifestation of spin processes competing with electron transfer. Magnetic field effects on these kinetics allow one to disentangle the two contr butions. Their temperature dependencies yield the activation parameters of the two processes. The discussion focuses on the mechanism of electron spin relaxation. Strong evidence for the Orbach/Kivelson mechanism will be given.

show abstract

High Magnetic Fields in Chemistry

Cited by 4 publications

References 26 publications

Effects and Mechanisms of Interaction of Electromagnetic Fields on Cells

Effects and Mechanisms of Interaction of Electromagnetic Fields on Cells

The magnetoelectrochemical switch

Magnetic Field and Temperature Dependencies Shed Light on the Recombination Kinetics of a Transition Metal Donor/Acceptor System

Contact Info

Product

Resources

About