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Linear Dichroism and Circular Dichroism

Name: Linear Dichroism and Circular Dichroism
Author: Bengt Nordén, Alison Rodger, Tim Dafforn

A Textbook on Polarized-Light Spectroscopy

Bengt Nordén, Alison Rodger, Tim Dafforn

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304 pages
English
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eBook - ePub

Linear Dichroism and Circular Dichroism

A Textbook on Polarized-Light Spectroscopy

Bengt Nordén, Alison Rodger, Tim Dafforn

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This book provides an introduction to optical anisotropy (linear dichroism, LD) and optical activity (circular dichroism, CD) as techniques for the study of structures and interactions of molecules in solution. The book covers the use of these techniques for both small and large molecular systems with particular emphasis being placed on proteins and nucleic acids. CD is a well-established technique and this book aims to explain how it can be used simply and effectively for new entrants to the field as well as covering more advanced techniques for experts. LD is often seen as a rather exotic method intended only for experienced spectroscopists. This book demonstrates that it is an approach with real utility that may be used by both students and scientists from graduate level onwards to give simple answers, which are not available from any other technique, to structural and kinetic questions. Much of the emphasis is on flow orientation of samples in solution phase. The book first describes the techniques and the information they can provide; it then goes on to give specific details on how to actually implement them, including a wide range of examples showing how LD and CD can help with * protein and nucleic acid secondary structure elucidation; * analysis of the formation and rearrangements of fibrous proteins and membrane proteins; * identification of the absolute configuration of small molecules; * determination of the orientation of small molecules in anisotropic media; * assignment of transition moment polarizations; * investigation of binding strengths and geometries of ligand-macromolecule complexes; * 3-D structure determination from LD, molecular replacement and MD modeling. The advantages of combined LD/CD studies are also outlined with examples of DNA/drug complexes and protein insertion into membranes. Taken together the book represents a comprehensive text on the theory and application of LD and CD in the chemical and biological sciences.

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Informations

Éditeur

Royal Society of Chemistry

Année

2019

ISBN

9781788018210

Édition

Sujet

Scienze fisiche

Sous-sujet

Spettroscopia e analisi dello spettro

1 Linear and circular dichroism spectroscopy: basic principles

1.1 Introduction

1.2 Electromagnetic radiation and spectroscopy

1.3 Normal absorption spectroscopy

1.4 Linear dichroism

1.5 Circular dichroism

Measurement of linear or circular dichroism involves shining two polarizations of respectively linearly or circularly polarized light onto a sample. Any resultant difference in absorption of the light polarizations gives information about the environment and the structures of the molecules contained in the sample. This chapter contains an introduction to both linear and circular dichroism.

1.1 Introduction

The aim of this book is to show how linear dichroism and circular dichroism spectroscopies can be used to provide information about molecular structure and about interactions between molecules.

The somewhat odd word ‘dichroism’ is derived from the Greek διχρωμα meaning ‘two colours’² since for some samples two colours are seen when they are viewed from two different directions. Dichroism was first observed for crystals: when light that has passed through a polarizer shines on a dichroic crystal, the colour you will see depends on the orientation of the crystal relative to the polarizer.

Amethyst is an example of a dichroic crystal. It is a form of crystalline quartz with transition metal ‘impurities’ which shows distinct dichroism, e.g., bluish violet and reddish violet for the ordinary and extraordinary rays, respectively.¹

Figure 1.1 Schematic illustration of LD and CD.

Chiral is derived from a Greek word ξειρ meaning hand (hence the alternate term ‘handedness’). Two molecules that are non-identical mirror images of each other are often referred to as enantiomers.

Superposed technically means: to place one geometric figure over another so that all like parts coincide. The more commonly used ‘superimposed’ does not require the coincidence of all like parts.

Although polarized light has not yet been defined in this book, it is still appropriate to begin with the definitions of linear and circular dichroism (Figure 1.1). Linear dichroism (LD) is the difference in absorption, A, of light linearly polarized parallel (//) and perpendicular (⊥) to an orientation axis:

(1.1)

LD is used with systems that are either intrinsically oriented or are oriented during the experiment. Circular dichroism (CD) is the difference in absorption of left and right circularly polarized light:

(1.2)

CD is particularly useful for studying solutions of chiral molecules, by which we mean ones that cannot be superposed on their mirror images.²

The justification for our interest in LD and CD is that both oriented systems and chiral systems are intrinsic features of the world in which we live. Oriented molecular systems are key components of biological cells as well as leading to macroscopic effects such as crystals, liquid crystals, membranes, and muscles; and all biological systems and many non-living ones are chiral. Sometimes the oriented system is itself built up of chiral molecules and the whole system may exhibit a macroscopic handedness.

This book is designed like a ramp with the text getting gradually more advanced: one starts to read at the beginning and continues until sufficient information has been covered for the purpose at hand. Chapter 1 contains all that is necessary to understand the basic concepts of LD and CD spectroscopies; Chapter 2 continues with what is required to enable the techniques to be implemented in the laboratory. Subsequent chapters are presented with increasingly detailed levels of interpretation and analysis of data. The emphasis of Chapters 3-6 is on the analysis of experimental data, and in the final chapters the theoretical foundations are laid. A selection of general references may be found in references ^3-16.

1.2 Electromagnetic radiation and spectroscopy

Electromagnetic radiation

Electromagnetic radiation, as its name implies, has an electric field, E, and a magnetic field, B; these oscillate at right-angles to one another and to the propagation direction. It may be described by a transverse wave whose polarization is defined by the direction of its electric field (Figure 1.2). Electromagnetic radiation also has particle character. It is impossible to really understand wave-particle duality, we just have to accept the dual character of light. If we do an experiment that would probe wave-like behaviour, it is apparent that light has it, and if we look for particle character we find that too. Thus we refer to the wavelength, λ, (or frequency, ν) of radiation, but acknowledge that if a molecule absorbs radiation energy it is as discrete units or particles called photons.

Figure 1.2 (a) Linearly and (b) circularly polarized electromagnetic radiation. Arrows denote direction of E. The hand on the right indicates the relative orientations of E, B, and k with the so-called ‘right-hand rule’. E, B and k (the direction of propagation of the radiation) are related by equations derived by James Clerk Maxwell in 1864. B = (1/c) k × E with c the velocity of light and × denoting the vector cross product (see §11.1 for a brief discussion of vector products).

Vectors, denoted throughout by bold letters, are a convenient way of summarizing information about physical phenomena that have magnitude (the vector’s length) and a direction in space (indicated by where the arrow points). See §11.1.

Electromagnetic radiation is referred to as light if the energy range of interest is near the visible or easily accessible ultraviolet (UV) wavelength range (~ 170-800 nm).

Two types of polarized light are mentioned above: linear and circular. In a linearly polarized light beam all photons have their electric field, E, oscillating in the same plane, whereas in a circularly polarized light beam the electric field vector retains constant magnitude in time but traces out a helix about the propagation direction. Following the optics convention, we take the end of the electric field vector of right circularly polarized light to form a right-handed helix in space at any instant of time. At each point in space or time, the magnetic field, B, is perpendicular to the electric field such that k, E, and B form a right-handed system as illustrated in Figure 1.2.

If we view right circularly polarized light sitting at a fixed point in space looking towards the light source, down the direction of propagation k, then the electric field vector traces out a clockwise circle.

While linearly polarized (plane-polarized) light is characterized by the electric field vector oscillating in a plane, circularly polarized light is a form of polarization in which the field vector describes a cork-screw motion, completing one turn of a helix after having travelled a distance equal to the wavelength of light. The two forms of light polarizations obviously have quite different ‘textural’ features, one looking symmetric, the other looking asymmetric, like a screw. This textural difference illustrates the basis for quite different applications of the two forms of dichroism in the study of molecular structure: linear dichroism using linearly polarized light probes macroscopically oriented molecules, whereas circu...