An Introduction to Chirality at the Nanoscale

Barron, Laurence D.

doi:10.1002/9783527625345.ch1

Cited by 35 publications

(31 citation statements)

References 86 publications

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“…They have been extensively investigated and applied for many years in organic, inorganic and biochemistry [10][11][12] and, more recently, supramolecular chemistry and chiral nanoscience [13][14][15], with concomitant advances in computational methods [16][17][18][19]. It had long been appreciated that extending natural optical activity into the vibrational spectrum could provide more detailed and reliable stereochemical information because a vibrational spectrum contains many more bands sensitive to the details of the molecular structure (3N À 6 fundamentals, where N is the number of atoms) [2].…”

Section: Introductionmentioning

confidence: 99%

Vibrational optical activity

Barron

Buckingham

2010

Chemical Physics Letters

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148

169

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Section: Introductionmentioning

confidence: 99%

Vibrational optical activity

Barron

Buckingham

2010

Chemical Physics Letters

Self Cite

148

169

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“…Alternatively, ad-hoc probe-tips for PiMFM or PiCFM can be fabricated separately and then "picked-up" and attached to the cantilever. Lanthanides and DNA have the capability to interact and contribute to optical magnetism and chirality [2,5,6,[59][60][61][62][63][64][65], therefore nanostructures incorporating these materials can serve as ideal probe-tips for optical magnetism or chirality detection purposes. Following this approach, a challenge is in firmly attaching such particles to the ideal position on the cantilever in a stable way.…”

Section: Challenges Visions and Roadmaps Forwardmentioning

confidence: 99%

“…Among the elusive material properties, we are particularly interested in photo-induced magnetism and chirality [1,2], due to their promising and fascinating implications, to name just a few: nanoscale magnetic imaging, magnetic tweezers and force microscopy, chirality detection, chiral force microscopy, magnetic spectroscopy, and spintronics, which have applications in material science, chemistry, and biology. However, both optical magnetism and chirality, which are related to the material's magnetic properties at optical frequencies, are typically weak and difficult to detect by conventional microscopy techniques that are typically based on the electric dipole response of the sample [2][3][4][5][6]. Moreover, the attempted nanoscale detection of such magnetic and chiral properties by conventional optical microscopy is especially difficult due to the diffraction limit.…”

Section: Introductionmentioning

confidence: 99%

In pursuit of photo-induced magnetic and chiral microscopy

Zeng

Kamandi

Darvishzadeh-Varcheie

et al. 2018

EPJ Appl. Metamat.

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Light-matter interactions enable the perception of specimen properties such as its shape and dimensions by measuring the subtle differences carried by an illuminating beam after interacting with the sample. However, major obstacles arise when the relevant properties of the specimen are weakly coupled to the incident beam, for example when measuring optical magnetism and chirality. To address this challenge we propose the idea of detecting such weakly-coupled properties of matter through the photo-induced force, aiming at developing photo-induced magnetic or chiral force microscopy. Here we review our pursuit consisting of the following steps: (1) Development of a theoretical blueprint of a magnetic nanoprobe to detect a magnetic dipole oscillating at an optical frequency when illuminated by an azimuthally polarized beam via the photo-induced magnetic force; (2) Conducting an experimental study using an azimuthally polarized beam to probe the near fields and axial magnetism of a Si disk magnetic nanoprobe, based on photo-induced force microscopy; (3) Extending the concept of force microscopy to probe chirality at the nanoscale, enabling enantiomeric detection of chiral molecules. Finally, we discuss difficulties and how they could be overcome, as well as our plans for future work.

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“…Such a σ-dipole consists of parallel electric and magnetic dipole moments of equal amplitudes and a relative phase of ±π/2, leading to a well-defined helicity of ±1 in the far field [10,11]. Furthermore, the σ-dipole is conceptually similar to the coupled dipole moments observed for the fundamental mode of a chiral nanostructure [12][13][14][15]. There, the occurence of a σ-dipole component is directly linked to the chiral geometry of the system.…”

Section: Introductionmentioning

confidence: 97%

Exciting a chiral dipole moment in an achiral nanostructure

Eismann¹,

Neugebauer²,

Banzer³

2018

Optica

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We discuss the excitation of a chiral dipolar mode in an achiral silicon nanoparticle. In particular, we make use of the electric and magnetic polarizabilities of the silicon nanoparticle to construct this chiral electromagnetic mode which is conceptually similar to the fundamental modes of 3D chiral nanostructures or molecules. We describe the chosen tailored excitation with a beam carrying neither spin nor orbital angular momentum and investigate the emission characteristics of the chiral dipolar mode in the helicity basis, consisting of parallel electric and magnetic dipole moments, phase shifted by ±π/2. We demonstrate the wavelength dependence and measure the spin and orbital angular momentum in the emission of the excited chiral mode.

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An Introduction to Chirality at the Nanoscale

Cited by 35 publications

References 86 publications

Vibrational optical activity

Vibrational optical activity

In pursuit of photo-induced magnetic and chiral microscopy

Exciting a chiral dipole moment in an achiral nanostructure

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