AXSIS: Exploring the frontiers in attosecond X-ray science, imaging and spectroscopy

F. X. Kärtner; F. Ahr; A. L. Calendron; H. Çankaya; S. Carbajo; G. Chang; G. Cirmi; K. Dörner; U. Dorda; A. Fallahi; A. Hartin; M. Hemmer; R. Hobbs; Y. Hua; W. R. Huang; R. Letrun; N. Matlis; V. Mazalova; O. D. Mücke; E. Nanni; W. Putnam; K. Ravi; F. Reichert; I. Sarrou; X. Wu; A. Yahaghi; H. Ye; L. Zapata; D. Zhang; C. Zhou; R. J D Miller; K. K. Berggren; H. Graafsma; A. Meents; R. W. Assmann; H. N. Chapman; Petra Fromme

doi:10.1016/j.nima.2016.02.080

AXSIS: Exploring the frontiers in attosecond X-ray science, imaging and spectroscopy

F. X. Kärtner, F. Ahr, A. L. Calendron, H. Çankaya, S. Carbajo, G. Chang, G. Cirmi, K. Dörner, U. Dorda, A. Fallahi, A. Hartin, M. Hemmer, R. Hobbs, Y. Hua, W. R. Huang, R. Letrun, N. Matlis, V. Mazalova, O. D. Mücke, E. NanniW. Putnam, K. Ravi, F. Reichert, I. Sarrou, X. Wu, A. Yahaghi, H. Ye, L. Zapata, D. Zhang, C. Zhou, R. J D Miller, K. K. Berggren, H. Graafsma, A. Meents, R. W. Assmann, H. N. Chapman, Petra Fromme

Research output: Contribution to journal › Article › peer-review

101 Scopus citations

Abstract

X-ray crystallography is one of the main methods to determine atomic-resolution 3D images of the whole spectrum of molecules ranging from small inorganic clusters to large protein complexes consisting of hundred-thousands of atoms that constitute the macromolecular machinery of life. Life is not static, and unravelling the structure and dynamics of the most important reactions in chemistry and biology is essential to uncover their mechanism. Many of these reactions, including photosynthesis which drives our biosphere, are light induced and occur on ultrafast timescales. These have been studied with high time resolution primarily by optical spectroscopy, enabled by ultrafast laser technology, but they reduce the vast complexity of the process to a few reaction coordinates. In the AXSIS project at CFEL in Hamburg, funded by the European Research Council, we develop the new method of attosecond serial X-ray crystallography and spectroscopy, to give a full description of ultrafast processes atomically resolved in real space and on the electronic energy landscape, from co-measurement of X-ray and optical spectra, and X-ray diffraction. This technique will revolutionize our understanding of structure and function at the atomic and molecular level and thereby unravel fundamental processes in chemistry and biology like energy conversion processes. For that purpose, we develop a compact, fully coherent, THz-driven attosecond X-ray source based on coherent inverse Compton scattering off a free-electron crystal, to outrun radiation damage effects due to the necessary high X-ray irradiance required to acquire diffraction signals. This highly synergistic project starts from a completely clean slate rather than conforming to the specifications of a large free-electron laser (FEL) user facility, to optimize the entire instrumentation towards fundamental measurements of the mechanism of light absorption and excitation energy transfer. A multidisciplinary team formed by laser-, accelerator,- X-ray scientists as well as spectroscopists and biochemists optimizes X-ray pulse parameters, in tandem with sample delivery, crystal size, and advanced X-ray detectors. Ultimately, the new capability, attosecond serial X-ray crystallography and spectroscopy, will be applied to one of the most important problems in structural biology, which is to elucidate the dynamics of light reactions, electron transfer and protein structure in photosynthesis.

Original language	English (US)
Pages (from-to)	24-29
Number of pages	6
Journal	Nuclear Instruments and Methods in Physics Research, Section A: Accelerators, Spectrometers, Detectors and Associated Equipment
Volume	829
DOIs	https://doi.org/10.1016/j.nima.2016.02.080
State	Published - Sep 1 2016

Keywords

Attosecond X-ray source
Optical undulator
Terahertz accelerator
X-ray imaging
X-ray spectroscopy

ASJC Scopus subject areas

Nuclear and High Energy Physics
Instrumentation

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10.1016/j.nima.2016.02.080

Cite this

Kärtner, F. X., Ahr, F., Calendron, A. L., Çankaya, H., Carbajo, S., Chang, G., Cirmi, G., Dörner, K., Dorda, U., Fallahi, A., Hartin, A., Hemmer, M., Hobbs, R., Hua, Y., Huang, W. R., Letrun, R., Matlis, N., Mazalova, V., Mücke, O. D., ... Fromme, P. (2016). AXSIS: Exploring the frontiers in attosecond X-ray science, imaging and spectroscopy. Nuclear Instruments and Methods in Physics Research, Section A: Accelerators, Spectrometers, Detectors and Associated Equipment, 829, 24-29. https://doi.org/10.1016/j.nima.2016.02.080

AXSIS: Exploring the frontiers in attosecond X-ray science, imaging and spectroscopy. / Kärtner, F. X.; Ahr, F.; Calendron, A. L. et al.
In: Nuclear Instruments and Methods in Physics Research, Section A: Accelerators, Spectrometers, Detectors and Associated Equipment, Vol. 829, 01.09.2016, p. 24-29.

Research output: Contribution to journal › Article › peer-review

Kärtner, FX, Ahr, F, Calendron, AL, Çankaya, H, Carbajo, S, Chang, G, Cirmi, G, Dörner, K, Dorda, U, Fallahi, A, Hartin, A, Hemmer, M, Hobbs, R, Hua, Y, Huang, WR, Letrun, R, Matlis, N, Mazalova, V, Mücke, OD, Nanni, E, Putnam, W, Ravi, K, Reichert, F, Sarrou, I, Wu, X, Yahaghi, A, Ye, H, Zapata, L, Zhang, D, Zhou, C, Miller, RJD, Berggren, KK, Graafsma, H, Meents, A, Assmann, RW, Chapman, HN & Fromme, P 2016, 'AXSIS: Exploring the frontiers in attosecond X-ray science, imaging and spectroscopy', Nuclear Instruments and Methods in Physics Research, Section A: Accelerators, Spectrometers, Detectors and Associated Equipment, vol. 829, pp. 24-29. https://doi.org/10.1016/j.nima.2016.02.080

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abstract = "X-ray crystallography is one of the main methods to determine atomic-resolution 3D images of the whole spectrum of molecules ranging from small inorganic clusters to large protein complexes consisting of hundred-thousands of atoms that constitute the macromolecular machinery of life. Life is not static, and unravelling the structure and dynamics of the most important reactions in chemistry and biology is essential to uncover their mechanism. Many of these reactions, including photosynthesis which drives our biosphere, are light induced and occur on ultrafast timescales. These have been studied with high time resolution primarily by optical spectroscopy, enabled by ultrafast laser technology, but they reduce the vast complexity of the process to a few reaction coordinates. In the AXSIS project at CFEL in Hamburg, funded by the European Research Council, we develop the new method of attosecond serial X-ray crystallography and spectroscopy, to give a full description of ultrafast processes atomically resolved in real space and on the electronic energy landscape, from co-measurement of X-ray and optical spectra, and X-ray diffraction. This technique will revolutionize our understanding of structure and function at the atomic and molecular level and thereby unravel fundamental processes in chemistry and biology like energy conversion processes. For that purpose, we develop a compact, fully coherent, THz-driven attosecond X-ray source based on coherent inverse Compton scattering off a free-electron crystal, to outrun radiation damage effects due to the necessary high X-ray irradiance required to acquire diffraction signals. This highly synergistic project starts from a completely clean slate rather than conforming to the specifications of a large free-electron laser (FEL) user facility, to optimize the entire instrumentation towards fundamental measurements of the mechanism of light absorption and excitation energy transfer. A multidisciplinary team formed by laser-, accelerator,- X-ray scientists as well as spectroscopists and biochemists optimizes X-ray pulse parameters, in tandem with sample delivery, crystal size, and advanced X-ray detectors. Ultimately, the new capability, attosecond serial X-ray crystallography and spectroscopy, will be applied to one of the most important problems in structural biology, which is to elucidate the dynamics of light reactions, electron transfer and protein structure in photosynthesis.",

keywords = "Attosecond X-ray source, Optical undulator, Terahertz accelerator, X-ray imaging, X-ray spectroscopy",

author = "K{\"a}rtner, {F. X.} and F. Ahr and Calendron, {A. L.} and H. {\c C}ankaya and S. Carbajo and G. Chang and G. Cirmi and K. D{\"o}rner and U. Dorda and A. Fallahi and A. Hartin and M. Hemmer and R. Hobbs and Y. Hua and Huang, {W. R.} and R. Letrun and N. Matlis and V. Mazalova and M{\"u}cke, {O. D.} and E. Nanni and W. Putnam and K. Ravi and F. Reichert and I. Sarrou and X. Wu and A. Yahaghi and H. Ye and L. Zapata and D. Zhang and C. Zhou and Miller, {R. J D} and Berggren, {K. K.} and H. Graafsma and A. Meents and Assmann, {R. W.} and Chapman, {H. N.} and Petra Fromme",

note = "Funding Information: This work has been supported by the European Research Council under the European Union Seventh Framework Program ( FP/2007-2013 )/ERC Grant Agreement no. 609920, the excellence cluster ׳ The Hamburg Centre for Ultrafast Imaging - Structure, Dynamics and Control of Matter at the Atomic Scale under Grant agreement no. EXC 1074, Air Force Office of Scientific Research through contract FA9550-12-1-0499 . Drs. Wu and Yahaghi, as well as R. Huang acknowledge support by Research Fellowships from the Alexander von Humboldt Foundation and a NDSEG Graduate Research Fellowship, respectively. Publisher Copyright: {\textcopyright} 2016 The Authors",

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doi = "10.1016/j.nima.2016.02.080",

language = "English (US)",

volume = "829",

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T2 - Exploring the frontiers in attosecond X-ray science, imaging and spectroscopy

AU - Kärtner, F. X.

AU - Ahr, F.

AU - Calendron, A. L.

AU - Çankaya, H.

AU - Carbajo, S.

AU - Chang, G.

AU - Cirmi, G.

AU - Dörner, K.

AU - Dorda, U.

AU - Fallahi, A.

AU - Hartin, A.

AU - Hemmer, M.

AU - Hobbs, R.

AU - Hua, Y.

AU - Huang, W. R.

AU - Letrun, R.

AU - Matlis, N.

AU - Mazalova, V.

AU - Mücke, O. D.

AU - Nanni, E.

AU - Putnam, W.

AU - Ravi, K.

AU - Reichert, F.

AU - Sarrou, I.

AU - Wu, X.

AU - Yahaghi, A.

AU - Ye, H.

AU - Zapata, L.

AU - Zhang, D.

AU - Zhou, C.

AU - Miller, R. J D

AU - Berggren, K. K.

AU - Graafsma, H.

AU - Meents, A.

AU - Assmann, R. W.

AU - Chapman, H. N.

AU - Fromme, Petra

N1 - Funding Information: This work has been supported by the European Research Council under the European Union Seventh Framework Program ( FP/2007-2013 )/ERC Grant Agreement no. 609920, the excellence cluster ׳ The Hamburg Centre for Ultrafast Imaging - Structure, Dynamics and Control of Matter at the Atomic Scale under Grant agreement no. EXC 1074, Air Force Office of Scientific Research through contract FA9550-12-1-0499 . Drs. Wu and Yahaghi, as well as R. Huang acknowledge support by Research Fellowships from the Alexander von Humboldt Foundation and a NDSEG Graduate Research Fellowship, respectively. Publisher Copyright: © 2016 The Authors

PY - 2016/9/1

Y1 - 2016/9/1

N2 - X-ray crystallography is one of the main methods to determine atomic-resolution 3D images of the whole spectrum of molecules ranging from small inorganic clusters to large protein complexes consisting of hundred-thousands of atoms that constitute the macromolecular machinery of life. Life is not static, and unravelling the structure and dynamics of the most important reactions in chemistry and biology is essential to uncover their mechanism. Many of these reactions, including photosynthesis which drives our biosphere, are light induced and occur on ultrafast timescales. These have been studied with high time resolution primarily by optical spectroscopy, enabled by ultrafast laser technology, but they reduce the vast complexity of the process to a few reaction coordinates. In the AXSIS project at CFEL in Hamburg, funded by the European Research Council, we develop the new method of attosecond serial X-ray crystallography and spectroscopy, to give a full description of ultrafast processes atomically resolved in real space and on the electronic energy landscape, from co-measurement of X-ray and optical spectra, and X-ray diffraction. This technique will revolutionize our understanding of structure and function at the atomic and molecular level and thereby unravel fundamental processes in chemistry and biology like energy conversion processes. For that purpose, we develop a compact, fully coherent, THz-driven attosecond X-ray source based on coherent inverse Compton scattering off a free-electron crystal, to outrun radiation damage effects due to the necessary high X-ray irradiance required to acquire diffraction signals. This highly synergistic project starts from a completely clean slate rather than conforming to the specifications of a large free-electron laser (FEL) user facility, to optimize the entire instrumentation towards fundamental measurements of the mechanism of light absorption and excitation energy transfer. A multidisciplinary team formed by laser-, accelerator,- X-ray scientists as well as spectroscopists and biochemists optimizes X-ray pulse parameters, in tandem with sample delivery, crystal size, and advanced X-ray detectors. Ultimately, the new capability, attosecond serial X-ray crystallography and spectroscopy, will be applied to one of the most important problems in structural biology, which is to elucidate the dynamics of light reactions, electron transfer and protein structure in photosynthesis.

AB - X-ray crystallography is one of the main methods to determine atomic-resolution 3D images of the whole spectrum of molecules ranging from small inorganic clusters to large protein complexes consisting of hundred-thousands of atoms that constitute the macromolecular machinery of life. Life is not static, and unravelling the structure and dynamics of the most important reactions in chemistry and biology is essential to uncover their mechanism. Many of these reactions, including photosynthesis which drives our biosphere, are light induced and occur on ultrafast timescales. These have been studied with high time resolution primarily by optical spectroscopy, enabled by ultrafast laser technology, but they reduce the vast complexity of the process to a few reaction coordinates. In the AXSIS project at CFEL in Hamburg, funded by the European Research Council, we develop the new method of attosecond serial X-ray crystallography and spectroscopy, to give a full description of ultrafast processes atomically resolved in real space and on the electronic energy landscape, from co-measurement of X-ray and optical spectra, and X-ray diffraction. This technique will revolutionize our understanding of structure and function at the atomic and molecular level and thereby unravel fundamental processes in chemistry and biology like energy conversion processes. For that purpose, we develop a compact, fully coherent, THz-driven attosecond X-ray source based on coherent inverse Compton scattering off a free-electron crystal, to outrun radiation damage effects due to the necessary high X-ray irradiance required to acquire diffraction signals. This highly synergistic project starts from a completely clean slate rather than conforming to the specifications of a large free-electron laser (FEL) user facility, to optimize the entire instrumentation towards fundamental measurements of the mechanism of light absorption and excitation energy transfer. A multidisciplinary team formed by laser-, accelerator,- X-ray scientists as well as spectroscopists and biochemists optimizes X-ray pulse parameters, in tandem with sample delivery, crystal size, and advanced X-ray detectors. Ultimately, the new capability, attosecond serial X-ray crystallography and spectroscopy, will be applied to one of the most important problems in structural biology, which is to elucidate the dynamics of light reactions, electron transfer and protein structure in photosynthesis.

KW - Attosecond X-ray source

KW - Optical undulator

KW - Terahertz accelerator

KW - X-ray imaging

KW - X-ray spectroscopy

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ER -

AXSIS: Exploring the frontiers in attosecond X-ray science, imaging and spectroscopy

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