Enhanced extreme ultraviolet high-harmonic generation from chromium-doped magnesium oxide

V. E. Nefedova; S. Froehlich; F. Navarrete; N. Tancogne-Dejean; D. Franz; A. Hamdou; S. Kaassamani; D. Gauthier; R. Nicolas; C. Jargot; M. Hanna; P. Georges; M. F. Ciappina; U. Thumm; W. Boutu; H. Merdji

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Enhanced extreme ultraviolet high-harmonic generation from chromium-doped magnesium oxide

机译：增强铬掺杂氧化镁的极端紫外线发电

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High-order harmonic generation (HHG) from crystals is emerging as a new ultrashort source of coherent extreme ultraviolet (XUV) light. Doping the crystal structure can offer a new way to control the source properties. Here,we present a study of HHG enhancement in the XUV spectral region from an ionic crystal,using dopant-induced vacancy defects,driven by a laser centered at a wavelength of 1.55 ^m. Our numerical simulations based on solutions of the semiconductor Bloch equations and density-functional theory are supported by our experimental observations and demonstrate an increase in the XUV high harmonic yield from doped bulk magnesium oxide (MgO) compared to undoped MgO,even at a low defect concentration. The anisotropy of the harmonic emission as a function of the laser polarization shows that the pristine crystal's symmetry is preserved. Our study paves the way toward the control of HHG in solids with complex defects caused by transition-metal doping.

机译：来自晶体的高阶谐波生成（HHG）是作为相干极端紫外（XUV）光的新超级源。掺杂晶体结构可以提供一种控制源属性的新方法。这里，我们使用掺杂剂诱导的空位缺陷的来自离子晶体的XUV光谱区中的HHG增强研究，其由处于1.55米的波长的激光驱动。我们的实验观察支持基于半导体Bloch方程和密度功能理论的数值模拟，并证明与未掺杂的MgO相比，与未掺杂的MgO相比，与未掺杂的MgO相比，与未掺杂的MgO相比，XUV高谐波产量增加，即使在低缺陷专注。作为激光偏振的函数的谐波发射的各向异性表明了原始晶体的对称性被保留。我们的研究铺平了通过过渡金属掺杂引起的复杂缺陷的固体控制HHG的方法。

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来源
《Applied Physics Letters》 |2021年第20期|201103.1-201103.8|共8页
作者
V. E. Nefedova; S. Froehlich; F. Navarrete; N. Tancogne-Dejean; D. Franz; A. Hamdou; S. Kaassamani; D. Gauthier; R. Nicolas; C. Jargot; M. Hanna; P. Georges; M. F. Ciappina; U. Thumm; W. Boutu; H. Merdji;
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作者单位

Ultrafast Nanophotonics Croup LIDYL CEA-CNRS-Universite Paris-Saclay 91191 Cif-sur-Yvette France;

Ultrafast Nanophotonics Croup LIDYL CEA-CNRS-Universite Paris-Saclay 91191 Cif-sur-Yvette France;

Department of Physics Kansas State University Manhattan Kansas 66506 USA Institute of Physics University of Rostock 18051 Rostock Germany;

Max Planck Institute for the Structure and Dynamics of Matter and Center for Free-Electron Laser Science Luruper Chaussee 149 22761 Hamburg Germany;

Ultrafast Nanophotonics Croup LIDYL CEA-CNRS-Universite Paris-Saclay 91191 Cif-sur-Yvette France;

Ultrafast Nanophotonics Croup LIDYL CEA-CNRS-Universite Paris-Saclay 91191 Cif-sur-Yvette France;

Ultrafast Nanophotonics Croup LIDYL CEA-CNRS-Universite Paris-Saclay 91191 Cif-sur-Yvette France;

Ultrafast Nanophotonics Croup LIDYL CEA-CNRS-Universite Paris-Saclay 91191 Cif-sur-Yvette France;

Ultrafast Nanophotonics Croup LIDYL CEA-CNRS-Universite Paris-Saclay 91191 Cif-sur-Yvette France Department of Natural Sciences Lebanese American University 1102 Beirut Lebanon;

Universite Paris-Saclay Institut d'Optique Graduate School CNRS Laboratoire Charles Fabry 91127 Palaiseau France Fastlite Sophia Antipolis 06600 Antibes France;

Universite Paris-Saclay Institut d'Optique Graduate School CNRS Laboratoire Charles Fabry 91127 Palaiseau France;

Universite Paris-Saclay Institut d'Optique Graduate School CNRS Laboratoire Charles Fabry 91127 Palaiseau France;

ICFO-lnstitut de Ciences Fotoniques The Barcelona Institute of Science and Technology Avenue Carl Fried rich Gauss 3 08860 Castelldefels (Barcelona) Spain Physics Program Guangdong Technion-lsrael Institute of Technology Shantou Guangdong 515063 China Technion-lsrael Institute of Technology Haifa 32000 Israel;

Department of Physics Kansas State University Manhattan Kansas 66506 USA;

Ultrafast Nanophotonics Croup LIDYL CEA-CNRS-Universite Paris-Saclay 91191 Cif-sur-Yvette France;

Ultrafast Nanophotonics Croup LIDYL CEA-CNRS-Universite Paris-Saclay 91191 Cif-sur-Yvette France;

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收录信息美国《科学引文索引》(SCI);美国《工程索引》(EI);美国《生物学医学文摘》(MEDLINE);
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2. Cavity-enhanced noncollinear high-harmonic generation for extreme ultraviolet frequency combs [J] . Jian Wu, Heping Zeng Optics Letters . 2007,第22期

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3. High-harmonic generation sources enable extreme ultraviolet lensless imaging [J] . SALLY JOHNSON Laser Focus World: The Magazine for the Photonics & Optoelectronics Industry . 2020,第4期

机译：高谐波产生源使极端紫外线透镜成像
4. Green enhancement cavity for frequency comb generation in the extreme ultraviolet [C] . Bernhardt Birgitta, Ozawa Akira, Pupeza Ioachim, 2011 Conference on lasers and electro-optics . 2011

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5. Intense capillary discharge plasma extreme-ultraviolet sources for extreme-ultraviolet lithography and other extreme-ultraviolet imaging applications. [D] . Klosner, Marc Alexander. 1998

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6. Enhanced Carbon monoxide-sensing properties of Chromium-doped ZnO nanostructures [O] . I. Y. Habib, Aimi Asilah Tajuddin, Hafiz Armi Noor, -1

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7. Enhanced extreme ultraviolet high-harmonic generation from chromium-doped magnesium oxide [O] . V. E. Nefedova, S. Fröhlich, F. Navarrete, 2021

机译：增强铬掺杂氧化镁的极端紫外线发电
8. Resonantly Enhanced Vacuum-Ultraviolet Generation and Multiphoton Ionization in Carbon Monoxide Gas [R] . Glownia, J. H., Sander, R. K. 1982

机译：一氧化碳气体中共振增强的真空紫外发生和多光子电离

Enhanced extreme ultraviolet high-harmonic generation from chromium-doped magnesium oxide

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