Cryogenic anion photoelectron spectroscopy apparatus with filament ionizer using velocity map imaging

The new design of the spectroscopy apparatus for cryogenic anion photoelectron spectroscopy consists of velocity map imaging (VMI) and filament ionization source as described in Figure.1. Quadrupole mass filter delivers mass-selected ions into a copper quadrupole ion trap (QIT) that is cryogenicall...

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Main Authors:	An, Sejun, Kim, Dabin, Kim, Sang Kyu
Other Authors:	Asian Spectroscopy Conference 2020
Format:	Conference or Workshop Item
Language:	English
Published:	2020
Subjects:	Science::Chemistry Anion Photoelectron Spectroscopy Velocity Map Imaging
Online Access:	https://hdl.handle.net/10356/144315
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Institution:	Nanyang Technological University
Language:	English

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spelling	sg-ntu-dr.10356-1443152020-10-29T20:11:57Z Cryogenic anion photoelectron spectroscopy apparatus with filament ionizer using velocity map imaging An, Sejun Kim, Dabin Kim, Sang Kyu Asian Spectroscopy Conference 2020 Institute of Advanced Studies Science::Chemistry Anion Photoelectron Spectroscopy Velocity Map Imaging The new design of the spectroscopy apparatus for cryogenic anion photoelectron spectroscopy consists of velocity map imaging (VMI) and filament ionization source as described in Figure.1. Quadrupole mass filter delivers mass-selected ions into a copper quadrupole ion trap (QIT) that is cryogenically cooled by a closed-cycle cryostat. Especially, copper QIT has a better ability to decrease the temperature of ions trapped compared to normal QIT made from stainless steel.[3] The improved cooling efficiency of copper QIT makes ions not to excite to vibrational state, so it enables us to observe vibration-controlled reaction dynamics. A cryogenically cooled ion packet is extracted from QIT and travels in the Wiley-McLaren time of flight (TOF) region. Both deflectors and einzel lenses fix the turned beam before entering the VMI region. Also, SIMION simulation provides proper electrostatic ion optics and predicts the ion pathway. Based on the simulation, we optimized this described design for increasing the number of focused ions in the interaction region. By using the above system, we obtained a mass spectrum confirming that the TOF system operates well to perform a further experiment. Published version 2020-10-28T03:32:42Z 2020-10-28T03:32:42Z 2020 Conference Paper An, S., Kim, D., & Kim, S. K. (2020). Cryogenic anion photoelectron spectroscopy apparatus with filament ionizer using velocity map imaging. Proc. Of the 7th Asian Spectroscopy Conference (ASC 2020). doi:10.32655/ASC_8-10_Dec2020.54 https://hdl.handle.net/10356/144315 10.32655/ASC_8-10_Dec2020.54 en © 2020 Nanyang Technological University. application/pdf
institution	Nanyang Technological University
building	NTU Library
continent	Asia
country	Singapore Singapore
content_provider	NTU Library
collection	DR-NTU
language	English
topic	Science::Chemistry Anion Photoelectron Spectroscopy Velocity Map Imaging
spellingShingle	Science::Chemistry Anion Photoelectron Spectroscopy Velocity Map Imaging An, Sejun Kim, Dabin Kim, Sang Kyu Cryogenic anion photoelectron spectroscopy apparatus with filament ionizer using velocity map imaging
description	The new design of the spectroscopy apparatus for cryogenic anion photoelectron spectroscopy consists of velocity map imaging (VMI) and filament ionization source as described in Figure.1. Quadrupole mass filter delivers mass-selected ions into a copper quadrupole ion trap (QIT) that is cryogenically cooled by a closed-cycle cryostat. Especially, copper QIT has a better ability to decrease the temperature of ions trapped compared to normal QIT made from stainless steel.[3] The improved cooling efficiency of copper QIT makes ions not to excite to vibrational state, so it enables us to observe vibration-controlled reaction dynamics. A cryogenically cooled ion packet is extracted from QIT and travels in the Wiley-McLaren time of flight (TOF) region. Both deflectors and einzel lenses fix the turned beam before entering the VMI region. Also, SIMION simulation provides proper electrostatic ion optics and predicts the ion pathway. Based on the simulation, we optimized this described design for increasing the number of focused ions in the interaction region. By using the above system, we obtained a mass spectrum confirming that the TOF system operates well to perform a further experiment.
author2	Asian Spectroscopy Conference 2020
author_facet	Asian Spectroscopy Conference 2020 An, Sejun Kim, Dabin Kim, Sang Kyu
format	Conference or Workshop Item
author	An, Sejun Kim, Dabin Kim, Sang Kyu
author_sort	An, Sejun
title	Cryogenic anion photoelectron spectroscopy apparatus with filament ionizer using velocity map imaging
title_short	Cryogenic anion photoelectron spectroscopy apparatus with filament ionizer using velocity map imaging
title_full	Cryogenic anion photoelectron spectroscopy apparatus with filament ionizer using velocity map imaging
title_fullStr	Cryogenic anion photoelectron spectroscopy apparatus with filament ionizer using velocity map imaging
title_full_unstemmed	Cryogenic anion photoelectron spectroscopy apparatus with filament ionizer using velocity map imaging
title_sort	cryogenic anion photoelectron spectroscopy apparatus with filament ionizer using velocity map imaging
publishDate	2020
url	https://hdl.handle.net/10356/144315
_version_	1683494060366495744

Cryogenic anion photoelectron spectroscopy apparatus with filament ionizer using velocity map imaging

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