Peter Hamm scite author profile

2D infrared (IR) spectroscopy is a cutting-edge technique, with applications in subjects as diverse as the energy sciences, biophysics and physical chemistry. This book introduces the essential concepts of 2D IR spectroscopy step-by-step to build an intuitive and in-depth understanding of the method. This unique book introduces the mathematical formalism in a simple manner, examines the design considerations for implementing the methods in the laboratory, and contains working computer code to simulate 2D IR spectra and exercises to illustrate involved concepts. Readers will learn how to accurately interpret 2D IR spectra, design their own spectrometer and invent their own pulse sequences. It is an excellent starting point for graduate students and researchers new to this exciting field. Computer codes and answers to the exercises can be downloaded from the authors' website, available at www.cambridge.org/9781107000056.

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Structure of the Amide I Band of Peptides Measured by Femtosecond Nonlinear-Infrared Spectroscopy

Hamm

1998

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Femtosecond infrared (IR) pump probe and dynamic hole burning experiments were used to examine the ultrafast response of the modes in the 1600-1700 cm -1 region (the so-called amide I modes) of N-methylacetamide (NMA) and three small globular peptides, apamin, scyllatoxin, and bovine pancreatic trypsin inhibitor (BPTI). A value of 16 cm -1 was found for the anharmonicity of the amide I vibration. Vibrational relaxation of the amide I modes of all investigated peptides occurs in ca. 1.2 ps. An even faster value of 450 fs is obtained for NMA, a model for the peptide unit. The vibrational relaxation is dominated by intramolecular energy redistribution (IVR) and reflects an intrinsic property of the peptide group in any environment. Dynamic hole burning experiments with a narrow band pump pulse which selectively excites only a subset of the amide I eigenstates reveal that energy migration between different amide I states is slow compared with vibrational relaxation. Two-dimensional pump-probe (2D-IR) spectra that display the spectral response of the amide I band as a function of the frequency of the narrow band pump pulse show that the amide I states are nevertheless delocalized along the peptide backbone. A simple excitonic coupling model describes the nonlinear pump-probe spectrum, and it reproduces the experimental 2D-IR spectra. It is estimated that the accessible peptide excitons are delocalized over a length of ca. 8 Å.

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Structure Determination of Trialanine in Water Using Polarization Sensitive Two-Dimensional Vibrational Spectroscopy

2000

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Using polarization sensitive two-dimensional (2D) vibrational spectroscopy on the amide I mode, the central backbone structure of trialanine in aqueous solution is investigated. We exploit the polarization sensitivity of the 2D pump−probe signal to reveal the cross-peak structure hidden under the strong diagonal peaks. The dihedral angles φ and ψ characterizing the peptide backbone structure are derived directly from the cross-peak intensity and anisotropy, demonstrating the potential of 2D spectroscopy as a tool for peptide structure elucidation.

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Vibrational cooling after ultrafast photoisomerization of azobenzene measured by femtosecond infrared spectroscopy

1997

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The vibrational cooling of azobenzene after photoisomerization is investigated by time resolved IR spectroscopy with femtosecond time resolution. Transient difference spectra were obtained in a frequency range where phenyl ring modes and the central N=N-stretching mode absorbs. The experimental data are discussed in terms of a simple theoretical model which was derived in order to account for the off-diagonal anharmonicity between the investigated high-frequency modes and the bath of the remaining low-frequency modes in a polyatomic molecule. It is shown that these off-diagonal anharmonic constants dominate the observed transient absorbance changes while the anharmonicity of the high-frequency modes themselves (diagonal anharmonicity) causes only minor effects. Based on the transient IR spectra, the energy flow in the azobenzene molecule can be described as follows: After an initial ultrafast intramolecular energy redistribution process, the decay of the related intramolecular temperature occurs via intermolecular energy transfer to the solvent on a time scale of ca. 20 ps.

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The two-dimensional IR nonlinear spectroscopy of a cyclic penta-peptide in relation to its three-dimensional structure

Hamm

Lim

DeGrado

et al. 1999

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

353

434

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A form of two-dimensional (2D) vibrational spectroscopy, which uses two ultrafast IR laser pulses, is used to examine the structure of a cyclic penta-peptide in solution. Spectrally resolved cross peaks occur in the off-diagonal region of the 2D IR spectrum of the amide I region, analogous to those in 2D NMR spectroscopy. These cross peaks measure the coupling between the different amide groups in the structure. Their intensities and polarizations relate directly to the three-dimensional structure of the peptide. With the help of a model coupling Hamiltonian, supplemented by density functional calculations, the spectra of this penta-peptide can be regenerated from the known solution phase structure. This 2D-IR measurement, with an intrinsic time resolution of less than 1 ps, could be used in all time regimes of interest in biology.The three-dimensional (3D) structure of peptides and proteins and their fluctuations are essential properties responsible for the extremely high specificity of biological reactions. Progress in understanding biological processes such as enzyme reactions originates from the detailed knowledge of the secondary, tertiary, and quarternary structures of the participating biomolecules. Two major spectroscopic techniques are responsible for this development: x-ray scattering, which maps out the electron density of the molecule, and two-dimensional (2D)-NMR spectroscopy (1-3), which can measure the distances between pairs of protons. The next step must be the determination of structures in motion over a wide range of time scales. We believe that multidimensional IR spectroscopy can address this new challenge.The IR spectra of the amide transitions provide information about secondary structural motifs of proteins and peptides. The so-called amide I band, which consists of mostly the stretching motion of the peptide backbone CϭO groups, is a strong IR absorber, which is spectrally isolated from other vibrational modes such as those from amino acid side groups. The amide I states can be viewed as vibrational excitons (4, 5) with the individual peptide groups considered as separated but coupled units. The coupling could be either through-space, such as multipole or even dipole-dipole interaction as proposed by Krimm and Bandekar (4), or through-bond, involving charge shifts and kinematic coupling via the C ␣ atoms of the backbone. The states, which have one excitation present in the whole assembly, can be interrogated by conventional (linear) IR absorption spectroscopy, but the information obtained is insufficient to determine the coupling Hamiltonian, from which a structure might be deduced. More information is available from nonlinear third-order spectroscopic techniques (6) such as the 2D experiment presented here. In a separated system picture both the one-exciton and two-exciton states contribute to the nonlinear IR signal in such a way that all couplings between the separate amide units are available, and in principle a 3D structure of the peptide can be deduced.The success of NMR sp...

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Peter Hamm

Concepts and Methods of 2D Infrared Spectroscopy

Structure of the Amide I Band of Peptides Measured by Femtosecond Nonlinear-Infrared Spectroscopy

Structure Determination of Trialanine in Water Using Polarization Sensitive Two-Dimensional Vibrational Spectroscopy

Vibrational cooling after ultrafast photoisomerization of azobenzene measured by femtosecond infrared spectroscopy

The two-dimensional IR nonlinear spectroscopy of a cyclic penta-peptide in relation to its three-dimensional structure

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