Your search keyword '"Naaman, Ron"' showing total 16 results

1. Bacterial extracellular electron transfer components are spin selective.

Author

Niman CM, Sukenik N, Dang T, Nwachukwu J, Thirumurthy MA, Jones AK, Naaman R, Santra K, Das TK, Paltiel Y, Baczewski LT, and El-Naggar MY

Subjects

Electron Transport, Oxidation-Reduction, Metals, Bacteria metabolism, Bacterial Proteins metabolism, Bacterial Outer Membrane Proteins metabolism, Electrons, Periplasm metabolism

Abstract

Metal-reducing bacteria have adapted the ability to respire extracellular solid surfaces instead of soluble oxidants. This process requires an electron transport pathway that spans from the inner membrane, across the periplasm, through the outer membrane, and to an external surface. Multiheme cytochromes are the primary machinery for moving electrons through this pathway. Recent studies show that the chiral-induced spin selectivity (CISS) effect is observable in some of these proteins extracted from the model metal-reducing bacteria, Shewanella oneidensis MR-1. It was hypothesized that the CISS effect facilitates efficient electron transport in these proteins by coupling electron velocity to spin, thus reducing the probability of backscattering. However, these studies focused exclusively on the cell surface electron conduits, and thus, CISS has not been investigated in upstream electron transfer components such as the membrane-associated MtrA, or periplasmic proteins such as small tetraheme cytochrome (STC). By using conductive probe atomic force microscopy measurements of protein monolayers adsorbed onto ferromagnetic substrates, we show that electron transport is spin selective in both MtrA and STC. Moreover, we have determined the spin polarization of MtrA to be ∼77% and STC to be ∼35%. This disparity in spin polarizations could indicate that spin selectivity is length dependent in heme proteins, given that MtrA is approximately two times longer than STC. Most significantly, our study indicates that spin-dependent interactions affect the entire extracellular electron transport pathway., (© 2023 Author(s). All article content, except where otherwise noted, is licensed under a Creative Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/).)

Published

2023

2. Chirality enhances oxygen reduction.

Author

Sang Y, Tassinari F, Santra K, Zhang W, Fontanesi C, Bloom BP, Waldeck DH, Fransson J, and Naaman R

Subjects

Catalysis, Electrodes, Electron Transport, Oxidation-Reduction, Electrons, Oxygen chemistry

Abstract

Controlled reduction of oxygen is important for developing clean energy technologies, such as fuel cells, and is vital to the existence of aerobic organisms. The process starts with oxygen in a triplet ground state and ends with products that are all in singlet states. Hence, spin constraints in the oxygen reduction must be considered. Here, we show that the electron transfer efficiency from chiral electrodes to oxygen (oxygen reduction reaction) is enhanced over that from achiral electrodes. We demonstrate lower overpotentials and higher current densities for chiral catalysts versus achiral ones. This finding holds even for electrodes composed of heavy metals with large spin-orbit coupling. The effect results from the spin selectivity conferred on the electron current by the chiral assemblies, the chiral-induced spin selectivity effect.

Published

2022

3. Chiral Induced Spin Selectivity and Its Implications for Biological Functions.

Author

Naaman R, Paltiel Y, and Waldeck DH

Subjects

Electron Transport, Oxidation-Reduction, Stereoisomerism, Electrons

Abstract

Chirality in life has been preserved throughout evolution. It has been assumed that the main function of chirality is its contribution to structural properties. In the past two decades, however, it has been established that chiral molecules possess unique electronic properties. Electrons that pass through chiral molecules, or even charge displacements within a chiral molecule, do so in a manner that depends on the electron's spin and the molecule's enantiomeric form. This effect, referred to as chiral induced spin selectivity (CISS), has several important implications for the properties of biosystems. Among these implications, CISS facilitates long-range electron transfer, enhances bio-affinities and enantioselectivity, and enables efficient and selective multi-electron redox processes. In this article, we review the CISS effect and some of its manifestations in biological systems. We argue that chirality is preserved so persistently in biology not only because of its structural effect, but also because of its important function in spin polarizing electrons.

Published

2022

4. The electron's spin and molecular chirality - how are they related and how do they affect life processes?

Author

Michaeli K, Kantor-Uriel N, Naaman R, and Waldeck DH

Subjects

Animals, Biochemical Phenomena, Humans, Oxidation-Reduction, Photochemical Processes, Quantum Theory, Stereoisomerism, Electron Transport, Electrons, Water chemistry

Abstract

The recently discovered chiral induced spin selectivity (CISS) effect gives rise to a spin selective electron transmission through biomolecules. Here we review the mechanism behind the CISS effect and its implication for processes in Biology. Specifically, three processes are discussed: long-range electron transfer, spin effects on the oxidation of water, and enantioselectivity in bio-recognition events. These phenomena imply that chirality and spin may play several important roles in biology, which have not been considered so far.

Published

2016

5. Spin-Dependent Transport through Chiral Molecules Studied by Spin-Dependent Electrochemistry.

Author

Mondal PC, Fontanesi C, Waldeck DH, and Naaman R

Subjects

Bacteriorhodopsins chemistry, Cadmium chemistry, Cysteine chemistry, Cytochromes c chemistry, Electrochemical Techniques, Electrodes, Gold chemistry, Magnetic Phenomena, Nanoparticles, Nickel chemistry, Oligopeptides chemistry, Oxidation-Reduction, Selenium chemistry, Stereoisomerism, Tolonium Chloride chemistry, Electrons

Abstract

Molecular spintronics (spin + electronics), which aims to exploit both the spin degree of freedom and the electron charge in molecular devices, has recently received massive attention. Our recent experiments on molecular spintronics employ chiral molecules which have the unexpected property of acting as spin filters, by way of an effect we call "chiral-induced spin selectivity" (CISS). In this Account, we discuss new types of spin-dependent electrochemistry measurements and their use to probe the spin-dependent charge transport properties of nonmagnetic chiral conductive polymers and biomolecules, such as oligopeptides, L/D cysteine, cytochrome c, bacteriorhodopsin (bR), and oligopeptide-CdSe nanoparticles (NPs) hybrid structures. Spin-dependent electrochemical measurements were carried out by employing ferromagnetic electrodes modified with chiral molecules used as the working electrode. Redox probes were used either in solution or when directly attached to the ferromagnetic electrodes. During the electrochemical measurements, the ferromagnetic electrode was magnetized either with its magnetic moment pointing "UP" or "DOWN" using a permanent magnet (H = 0.5 T), placed underneath the chemically modified ferromagnetic electrodes. The spin polarization of the current was found to be in the range of 5-30%, even in the case of small chiral molecules. Chiral films of the l- and d-cysteine tethered with a redox-active dye, toludin blue O, show spin polarizarion that depends on the chirality. Because the nickel electrodes are susceptible to corrosion, we explored the effect of coating them with a thin gold overlayer. The effect of the gold layer on the spin polarization of the electrons ejected from the electrode was investigated. In addition, the role of the structure of the protein on the spin selective transport was also studied as a function of bias voltage and the effect of protein denaturation was revealed. In addition to "dark" measurements, we also describe photoelectrochemical measurements in which light is used to affect the spin selective electron transport through the chiral molecules. We describe how the excitation of a chromophore (such as CdSe nanoparticles), which is attached to a chiral working electrode, can flip the preferred spin orientation of the photocurrent, when measured under the identical conditions. Thus, chirality-induced spin polarization, when combined with light and magnetic field effects, opens new avenues for the study of the spin transport properties of chiral molecules and biomolecules and for creating new types of spintronic devices in which light and molecular chirality provide new functions and properties.

Published

2016

6. Spin selective electron transmission through monolayers of chiral molecules.

Author

Naaman R and Vager Z

Subjects

DNA chemistry, Magnetics, Peptides chemistry, Electrons, Stereoisomerism

Abstract

Self-assembled monolayers (SAMs) of organic dipolar molecules have new electronic and magnetic properties that result from their organization, despite the relatively weak interaction among the molecules themselves. Here we review the origin of this cooperative effect and summarize results obtained on spin selective electron transmission through such monolayers that are made from chiral molecules. We show that SAMs containing chiral dipolar molecules behave like magnetic layers which may serve as spin filters, even without applying an external magnetic field to the layer.

Published

2011

7. Cooperative effect in the electronic properties of human telomere sequence.

Author

Markus TZ, Daube SS, and Naaman R

Subjects

Adenine, Base Sequence, DNA chemistry, DNA genetics, Humans, Photoelectron Spectroscopy, Electrons, Telomere chemistry, Telomere genetics

Abstract

The contribution of sequence elements of human telomere DNA to the interaction of DNA with electrons has been analyzed. By applying wavelength dependent low-energy photoelectron transmission and two-photon photoemission spectroscopy, we investigated the density of states of DNA oligomers with partial sequence elements of the human telomere assembled as monolayers on gold. The findings demonstrate the role of the resonance states in the DNA in accepting electrons and the effect of the sequence on these states. When guanine (G) bases are clustered together, the resonance negative ion state is stabilized, as compared to oligomers containing the same number of G bases but distributed within the sequence. The electron-capturing probability of the human telomere-like oligomer, a sequence with an additional single adenine (A) base adjacent to the G cluster, is dramatically enhanced compared to the other oligomers studied, most likely due to the enhancement of the density of states near the highest occupied molecular orbital.

Published

2010

8. Chiral control of electron transmission through molecules.

Author

Skourtis SS, Beratan DN, Naaman R, Nitzan A, and Waldeck DH

Subjects

DNA chemistry, Electric Conductivity, Nanoparticles chemistry, Peptides chemistry, Electrons, Models, Chemical

Abstract

Electron transmission through chiral molecules induced by circularly polarized light can be very different for mirror-image structures, a peculiar fact given that the electronic energy spectra of the systems are identical. We propose that this asymmetry--as large as 10% for resonant transport--arises from different dynamical responses of the mirrored structures to coherent excitation. This behavior is described in the context of a general novel phenomenon of current transfer (transfer of charge with its momentum information) and accounts for the observed asymmetry and its dependence on structure.

Published

2008

9. Direct measurement of electrical transport through single DNA molecules of complex sequence.

Author

Cohen H, Nogues C, Naaman R, and Porath D

Subjects

Base Sequence, Electric Conductivity, Microscopy, Atomic Force, Nanostructures, DNA chemistry, DNA genetics, Electrons

Abstract

Seemingly contradicting results raised a debate over the ability of DNA to transport charge and the nature of the conduction mechanisms through it. We developed an experimental approach for measuring current through DNA molecules, chemically connected on both ends to a metal substrate and to a gold nanoparticle, by using a conductive atomic force microscope. Many samples could be made because of the experimental approach adopted here, which enabled us to obtain reproducible results with various samples, conditions, and measurement methods. We present multi-leveled evidence for charge transport through 26-bp-long dsDNA of a complex sequence, characterized by S-shaped current-voltage curves that show currents >220 nA at 2 V. This significant observation implies that a coherent or band transport mechanism takes over for bias potentials leading to high currents (>1 nA).

Published

2005

10. Cold denaturation induces inversion of dipole and spin transfer in chiral peptide monolayers.

Author

Eckshtain-Levi, Meital, Capua, Eyal, Refaely-Abramson, Sivan, Sarkar, Soumyajit, Gavrilov, Yulian, Mathew, Shinto P, Paltiel, Yossi, Levy, Yaakov, Kronik, Leeor, and Naaman, Ron

Subjects

Aminoisobutyric Acids, Alanine, Oligopeptides, Protein Structure, Secondary, Protein Denaturation, Electron Transport, Electrons, Cold Temperature, Molecular Dynamics Simulation, Protein Structure, Secondary

Abstract

Chirality-induced spin selectivity is a recently-discovered effect, which results in spin selectivity for electrons transmitted through chiral peptide monolayers. Here, we use this spin selectivity to probe the organization of self-assembled α-helix peptide monolayers and examine the relation between structural and spin transfer phenomena. We show that the α-helix structure of oligopeptides based on alanine and aminoisobutyric acid is transformed to a more linear one upon cooling. This process is similar to the known cold denaturation in peptides, but here the self-assembled monolayer plays the role of the solvent. The structural change results in a flip in the direction of the electrical dipole moment of the adsorbed molecules. The dipole flip is accompanied by a concomitant change in the spin that is preferred in electron transfer through the molecules, observed via a new solid-state hybrid organic-inorganic device that is based on the Hall effect, but operates with no external magnetic field or magnetic material.

Published

2016

11. The Electron Spin as a Chiral Reagent.

Author

Metzger, Tzuriel S., Mishra, Suryakant, Bloom, Brian P., Goren, Naama, Neubauer, Avner, Shmul, Guy, Wei, Jimeng, Yochelis, Shira, Tassinari, Francesco, Fontanesi, Claudio, Waldeck, David H., Paltiel, Yossi, and Naaman, Ron

Subjects

ELECTRON spin, CHEMICAL reagents, ELECTRON spin states, HANDEDNESS, CHEMISTRY, CHIRALITY of nuclear particles, ELECTRONS

Abstract

We show that enantioselective reactions can be induced by the electron spin itself and that it is possible to replace a conventional enantiopure chemical reagent by spin‐polarized electrons that provide the chiral bias for enantioselective reactions. Three examples of enantioselective chemistry resulting from electron‐spin polarization are presented. One demonstrates the enantioselective association of a chiral molecule with an achiral self‐assembled monolayer film that is spin‐polarized, while the other two show that the chiral bias provided by the electron helicity can drive both reduction and oxidation in enantiospecific electrochemical reactions. In each case, the enantioselectivity does not result from enantiospecific interactions of the molecule with the ferromagnetic electrode but from the polarized spin that crosses the interface between the substrate and the molecule. Furthermore, the direction of the electron‐spin polarization defines the handedness of the enantioselectivity. This work demonstrates a new mechanism for realizing enantioselective chemistry. [ABSTRACT FROM AUTHOR]

Published

2020

12. Chirality - Beyond the Structural Effects.

Author

Naaman, Ron

Subjects

*WATER electrolysis, *SPINTRONICS, *ENANTIOMERS, *PHOTOELECTROCHEMICAL cells, *ELECTRONS

Abstract

Usually, when one refers to chirality, one focuses on the structural properties of the molecules. This review focuses on the interesting electronic properties of these molecules, and specifically, on the interrelation between the spin of the electrons transmitted through molecules and the chiral structure of these molecules. This relation is expressed in the chiral-induced spin selectivity (CISS) effect, which is described, including some of its implications. Specifically, several applications are described, in spintronics, in spin-specific reactivity, and in spin-controlled multiple-electron oxidation processes. In the latter, experimental results are described that demonstrate that by coating the anode of a photoelectrochemical cell with chiral molecules, the overpotential of the water-splitting process can be reduced. [ABSTRACT FROM AUTHOR]

Published

2016

13. Spintronics and Chirality: Spin Selectivity in Electron Transport Through Chiral Molecules.

Author

Naaman, Ron and Waldeck, David H.

Subjects

*SPINTRONICS, *CHIRALITY, *MICROELECTRONICS, *ELECTRONS, *INFORMATION technology, *COMPUTER storage devices, *EQUIPMENT & supplies

Abstract

Recent experiments have demonstrated that the electron transmission yield through chiral molecules depends on the electron spin orientation. This phenomenon has been termed the chiral-induced spin selectivity (CISS) effect, and it provides a challenge to theory and promise for organic molecule-based spintronic devices. This article reviews recent developments in our understanding of CISS. Different theoretical models have been used to describe the effect; however, they all presume an unusually large spin-orbit coupling in chiral molecules for the effect to display the magnitudes seen in experiments. A simplified model for an electron's transport through a chiral potential suggests that these large couplings can be manifested. Techniques for measuring spin-selective electron transport through molecules are overviewed, and some examples of recent experiments are described. Finally, we present results obtained by studying several systems, and we describe the possible application of the CISS effect for memory devices. [ABSTRACT FROM AUTHOR]

Published

2015

14. Interface Magnetism.

Author

Kopnov, Gregory, Vager, Zeev, and Naaman, Ron

Subjects

MAGNETISM, ELECTRONS, SILICON, SAPPHIRES, DIAMAGNETIC materials

Published

2007

15. Electron Capturing by DNA.

Author

Ray, Supratim G., Daube, Shirley S., Cohen, Hagai, and Naaman, Ron

Subjects

ELECTRONS, DNA, OLIGOMERS, BINDING energy, PHOTONS, PHOTOELECTRONS

Abstract

Many of the mutagenic or lethal effects of ionization radiation can be attributed to damage caused to the DNA by low-energy electrons. In order to gain insight on the parameters affecting this process, we measured the low-energy electron (< 2 eV) transmission yield through self-assembled monolayers of short DNAoligomers. The electrons that are not transmitted are captured by the layer. Hence, the transmission reflects the capturing efficiency of the electrons by the layer. The dependence of the capturing probability on the base sequence was studied as well as the state of the captured electrons. In addition, two-photon photoelectron (TPPE) spectroscopy studies were performed that established the binding energy of electrons on the DNA.We found that the capturing probability scales with the number of G bases in the single-stranded oligomers and depends on their clustering level. Using TPPE spectroscopy, we found that once captured, the electrons do not reside on the bases. Rather, the state of the captured electrons is insensitive to the oligomer's sequence. A model is proposed for the special role of guanine, based on its low oxidation potential.Double-stranded DNA does not capture electrons as efficiently as single-stranded oligomers; however, once captured, the electrons are more strongly bound than to the single strands. [ABSTRACT FROM AUTHOR]

Published

2007

16. Vibrational induced photodetachment of electrons from small clusters.

Author

Bar-on, A. and Naaman, Ron

Subjects

*VIBRATION (Mechanics), *PHOTODETACHMENT threshold spectroscopy, *ELECTRONS, *COMPLEX ions

Abstract

Presents a study which investigated vibrational induced photodetachment of electrons from small clusters. Method of the study; Results and discussion.

Published

1989