Electron interactions with the heteronuclear carbonyl precursor H₂FeRu₃(CO)₁₃ and comparison with HFeCo₃(CO)₁₂: from fundamental gas phase and surface science studies to focused electron beam induced deposition

Ragesh Kumar T P,
Paul Weirich,
Lukas Hrachowina,
Marc Hanefeld,
Ragnar Bjornsson,
Helgi Rafn Hrodmarsson,
Sven Barth,
D. Howard Fairbrother,
Michael Huth and
Oddur Ingólfsson

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Published 14 Feb 2018

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1. Figure 1: Structural arrangement of HFeCo₃(CO)₁₂ and H₂FeRu₃(CO)₁₃ illustrating differences in symmetry and l...
  
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2. Figure 2: Isotope distribution of a) HFeCo₃(CO)₁₂ and b) H₂FeRu₃(CO)₁₃. Isotope distribution for both compoun...
  
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3. Figure 3: Negative ion yield curves for the formation of a) [Fe(CO)_n]⁻ and b) [Ru(CO)_n]⁻ up on electron attac...
  
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4. Figure 4: Loss of Fe(CO)₂ (panel a), Fe(CO)₃ (panel b), Fe(CO)₄ (panel c) and additional loss of up to 7 COs ...
  
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5. Figure 5: Negative ions formed through loss of Ru(CO)₃ (panel a), Ru(CO)₄ (panel b) and further loss of up to...
  
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6. Figure 6: Calculated spin density of the [H₂FeRu₃(CO)₁₃]⁻ anion; a) in the constrained geometry of neutral H₂...
  
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7. Figure 7: Calculated MO diagrams of H₂FeRu₃(CO)₁₃ and HFeCo₃(CO)₁₂. Red lines represent the unoccupied molecu...
  
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8. Figure 8: Electron impact ionization spectra of H₂FeRu₃(CO)₁₃ recorded at electron energy of 70 eV, upper pan...
  
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9. Figure 9: Evolution of O 1s, Fe 2p and Ru 3d/C 1s XPS regions of a H₂FeRu₃(CO)₁₃ film exposed to electron dos...
  
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10. Figure 10: Change in fractional coverage of oxygen atoms (red stars) and, Ru 3d_5/2 peak position (blue open ci...
  
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11. Figure 11: Mass spectrum of neutral gas phase species desorbed from an H₂FeRu₃(CO)₁₃ film during the course of...
  
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12. Figure 12: Changes in O 1s, Fe 2p and Ru 3d/C 1s XPS regions when an H₂FeRu₃(CO)₁₃ film was exposed to electro...
  
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13. Figure 13: Initial decomposition/deposition of surface adsorbed H₂FeRu₃(CO)₁₃ precursor, mediated by dissociat...
  
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14. Figure 14: Schematic showing the incorporation of partially decarbonylated intermediate of H₂FeRu₃(CO)₁₃ into ...
  
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15. Figure 15: (a) AFM cross sections of deposits shown in the SEM micrograph (b) at the positions indicated by th...
  
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16. Figure 16: Transport measurements of as-grown Fe–Ru deposit and deposits grown under identical conditions afte...
  
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Beilstein J. Nanotechnol. 2018, 9, 555–579, doi:10.3762/bjnano.9.53

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Amplified cross-linking efficiency of self-assembled monolayers through targeted dissociative electron attachment for the production of carbon nanomembranes

Sascha Koch,
Christopher D. Kaiser,
Paul Penner,
Michael Barclay,
Lena Frommeyer,
Daniel Emmrich,
Patrick Stohmann,
Tarek Abu-Husein,
Andreas Terfort,
D. Howard Fairbrother,
Oddur Ingólfsson and
Armin Gölzhäuser

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Published 30 Nov 2017

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1. Figure 1: Negative halogen ion yield curves for dissociative electron attachment to 2′-chloro-1,1′-biphenyl (...
  
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2. Figure 2: XP spectra of the Cl 2p, Br 3p doublets and the I 3d_5/2 peak regions of SAMs made of 2-Cl-BPT 2-Br-...
  
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3. Figure 3: (a) Raw XP spectra of the S 2p region of SAMs made from BPT, 2-Cl-BPT 2-Br-BPT and 2-I-BPT before a...
  
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4. Figure 4: Helium ion microscope (HIM) image of a transferred carbon nanomembrane (CNM) made using 3 min (1.8 ...
  
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Beilstein J. Nanotechnol. 2017, 8, 2562–2571, doi:10.3762/bjnano.8.256

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Comparing postdeposition reactions of electrons and radicals with Pt nanostructures created by focused electron beam induced deposition

Julie A. Spencer,
Michael Barclay,
Miranda J. Gallagher,
Robert Winkler,
Ilyas Unlu,
Yung-Chien Wu,
Harald Plank,
Lisa McElwee-White and
D. Howard Fairbrother

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Published 15 Nov 2017

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1. Figure 1: (a) Representative FEBID deposit created from cis-Pt(CO)₂Cl₂. Representative AES and EDS of “as-dep...
  
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2. Figure 2: (a) SEM image of a deposit created from cis-Pt(CO)₂Cl₂, and (b) corresponding EDS spectrum. (c) SEM...
  
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3. Figure 3: (a) PtCl₂ deposit created from cis-Pt(CO)₂Cl₂; (b) corresponding EDS analysis. (c) SEM image of the...
  
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4. Figure 4: (a) SEM image of a PtCl₂ deposit created from cis-Pt(CO)₂Cl₂, without any EDS analysis and prior to...
  
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5. Figure 5: SEM images of a deposit created from cis-Pt(CO)₂Cl₂: (a) prior to any treatment, and after (b) 48, ...
  
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6. Figure 6: AES for a deposit created from cis-Pt(CO)₂Cl₂ (top spectrum) and then subjected to alternating trea...
  
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7. Figure 7: AFM data for nanostructures created from MeCpPtMe₃ using different total exposure times (TET) (per ...
  
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8. Figure 8: (a) Height of nanostructures created from MeCpPtMe₃ as determined by AFM: as-deposited (black bar) ...
  
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9. Scheme 1: Hess cycle for electron purification of PtCl₂. ∆H = −∆H_f PtCl₂ + Cl₂ bond dissociation enthalpy (BD...
  
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10. Scheme 2: Hess cycle for atomic hydrogen purification of PtCl₂. ∆H = −∆H_f PtCl₂ + H₂ bond dissociation enthal...
  
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Beilstein J. Nanotechnol. 2017, 8, 2410–2424, doi:10.3762/bjnano.8.240

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The role of low-energy electrons in focused electron beam induced deposition: four case studies of representative precursors

Rachel M. Thorman,
Ragesh Kumar T. P.,
D. Howard Fairbrother and
Oddur Ingólfsson

Review
Published 16 Sep 2015

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1. Figure 1: Schematic representation of the FEBID process (reproduced with permission from [2], Copyright (2008) A...
  
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2. Figure 2: Schematic representation of elastic and inelastic scattering of high-energy primary electrons impin...
  
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3. Figure 3: Experimentally measured SE spectra from Ni(111) [6] irradiated by PEs with 400 eV impact energy (black...
  
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4. Figure 4: Simplified two-dimensional potential energy diagram for quasi-diatomic dissociation through electro...
  
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5. Figure 5: Simplified two-dimensional potential energy diagram for a quasi-diatomic dissociation through elect...
  
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6. Figure 6: Simplified two-dimensional potential energy diagram for a quasi-diatomic dissociation through elect...
  
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7. Figure 7: Energy-dependent relative cross sections (ion yields) of negative ion fragments produced by DEA to ...
  
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8. Figure 8: Positive ion mass spectrum of MeCpPtMe₃ recorded with electron energy of 100 eV (reproduced with pe...
  
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9. Figure 9: Positive ion mass spectra of MeCpPtMe₃ in the m/z range of 0–85 (reproduced with permission from Wn...
  
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10. Figure 10: Changes in the C/Pt ratio of a 3.16 nm thick film of MeCpPtMe₃ adsorbed on a gold surface at 180 K ...
  
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11. Figure 11: a) A line of best fit to the cross section for methane desorption from MeCpPtMe₃ adsorbed on a gold...
  
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12. Figure 12: Energy-dependent absolute cross sections for negative ion fragments produced by DEA to Pt(PF₃)₄ (re...
  
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13. Figure 13: Electron ionization FT-ICR mass spectrum of Pt(PF₃)₄ recorded at 20 eV incident electron energy (re...
  
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14. Figure 14: (a) Electron energy loss spectra of Pt(PF₃)₄ recorded at 0° angle with varying residual energies. T...
  
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15. Figure 15: Time-resolved mass spectra of gas phase PF₃ (positive [PF₂]⁺ ions produced by 70 eV electron impact...
  
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16. Figure 16: Electron dose dependence of the fractional coverage of Phosphorous (P/P_D=0), Fluorine (F/F_D=0) and ...
  
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17. Figure 17: Energy-dependent absolute DEA cross sections for Co(CO)₃NO (reproduced with permission from [10], Copyr...
  
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18. Figure 18: Energy dependence of the partial cross sections for positive ion fragments formed from Co(CO)₃NO (r...
  
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19. Figure 19: The partial cross sections for single CO loss through DEA (red solid line), for single CO loss thro...
  
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20. Figure 20: Predicted relative effective damage yield for single CO loss through DEA (red solid line), for sing...
  
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21. Figure 21: Positive ion (DI) mass spectra of (a) gas phase Co(CO)₃NO, (b) volatile species desorbing from a 2....
  
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22. Figure 22: Electron dose dependence of the fractional coverage of carbon, oxygen and nitrogen from Co(CO)₃NO a...
  
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