Casino electron simulation

Casino electron simulation

{H1}

Go to:

References

  • Akenine-Möller T. A Fast Triangle-Triangle Intersection Test. Journal of Graphics Tools. ;2(2)[Google Scholar]
  • Babin S, Borisov S, Ivanchikov A, Ruzavin I. Modeling of Linewidth Measurement in SEMs Using Advanced Monte Carlo Software. J. Vac, Sci. Technol B. ;–[Google Scholar]
  • Bronstein IM, Fraiman BS. Vtorichnaya Elektronnaya Emissiya. Moskva: Nauka; [Google Scholar]
  • Demers H, Poirier-Demers N, Drouin D, de Jonge N. Simulating STEM Imaging of Nanoparticles in Micrometers-Thick Substrates. Microscopy and Microanalysis. ;–[Europe PMC free article] [Abstract] [Google Scholar]
  • Ding ZJ, Li HM. Application of Monte Carlo simulation to SEM image contrast of complex structures. Surface And Interface Analysis. ;–[Google Scholar]
  • Drouin D, Couture AR, Joly D, Tastet X, Aimez V, Gauvin R. CASINO V A Fast and Easy-to-use Modeling Tool for Scanning Electron Microscopy and Microanalysis Users. Scanning. ;29(3)– [Abstract] [Google Scholar]
  • El Gomati MM, Walker CGH, Assa'd AMD, Zadrazil M. Theory Experiment Comparison of the Electron Backscattering Factor from Solids at Low Electron Energy (–5, eV) Scanning. ;30(1):2– [Abstract] [Google Scholar]
  • Gauvin R, Michaud P. MC X-Ray, a New Monte Carlo Program for Quantitative X-Ray Microanalysis of Real Materials. Microscopy and Microanalysis. ;15(S2)–[Google Scholar]
  • Gnieser D, Frase CG, Bosse H, Tutsch R. In: MCSEM -- a modular Monte Carlo simulation program for various applications in SEM metrology and SEM photogrammetry. Martina Luysberg KT, Weirich T, editors. Springer Berlin Heidelberg; pp. – [Google Scholar]
  • Goldstein JI, Newbury DE, Echlin P, Joy DC, Romig JAD, Lyman CE, Fiori C, Lifshin E. Scanning Electron Microscopy and X-Ray Microanalysis: A Text for Biologists, Materials Scientists, and Geologists. Plemum Press; [Google Scholar]
  • Hovington P, Drouin D, Gauvin R. CASINO: A new Monte Carlo code in C language for electron beam interaction - Part I: description of the program. Scanning. ;19(1):1–[Google Scholar]
  • Jablonski A, Salvat F, Powell CJ. NIST Electron Elastic-Scattering Cross-Section Database - Version National Institute of Standards and Technology. [Google Scholar]
  • Johnsen K-P, Frase CG, Bosse H, Gnieser D. SEM image modeling using the modular Monte Carlo model MCSEM. Proceedings of SPIE. ;O.[Google Scholar]
  • Joy DC. A Database of Electron-Solid Interactions. Scanning. a;17(4)–[Google Scholar]
  • Joy DC. Monte Carlo Modeling for Electron Microscopy and Microanalysis. New York: Oxford University Press; b. [Google Scholar]
  • Joy DC, Luo S. An empirical stopping power relationship for low-energy electrons. Scanning. ;–[Google Scholar]
  • Kieft E, Bosch E. Refinement of Monte Carlo simulations of electron–specimen interaction in low-voltage SEM. Journal of Physics D: Applied Physics. ;41(21)[Google Scholar]
  • Kotera M, Ijichi R, Fujiwara T, Suga H, Wittry DB. A simulation of electron scattering in metals. Japanese Journal of Applied Physics. ;29(10)–[Google Scholar]
  • Lowney JR. Use of Monte Carlo modeling for interpreting scanning electron microscope linewidth measurements. Scanning. ;5(5)–[Google Scholar]
  • Lowney JR. Monte Carlo simulation of scanning electron microscope signals for lithographic metrology. Scanning. ;18(4)–[Google Scholar]
  • Mark de Berg OC, van Kreveld Marc, Overmars Mark. Computational Geometry. [Google Scholar]
  • Newbury DE, Yakowitz H. Studies of the Distribution of Signals in the SEM/EPMA by Monte Carlo Electron Trajectory Calculations: An Outline. In: Heinrich KFJ, Newbury DE, Yakowitz H, editors. NBS Special Publication. National Bureau of Standards; Oct , pp. 15– [Google Scholar]
  • Reimer L. Scanning Electron Microscopy: Physics of Image Formation and Microanalysis. Springer; [Google Scholar]
  • Ritchie NWM. A new Monte Carlo application for complex sample geometries. Surface and Interface Analysis. ;–[Google Scholar]
  • Salvat F, Fernandez-Varea JM, Sempau J. Facultat de Fisica (ECM) Spain: Universitat de Barcelona, Nuclear Energy Agency; PENELOPE - A Code System for Monte Carlo Simulation of Electron and Photon Transport. [Google Scholar]
  • Salvat F, Jablonski A, Powell CJ. ELSEPA -- Dirac partial-wave calculation of elastic scattering of electrons and positrons by atoms, positive ions and molecules. Computer Physics Communications. ;–[Google Scholar]
  • Villarrubia JS, Ding ZJ. Sensitivity of scanning electron microscope width measurements to model assumptions. Journal of Micro/Nanolithography, MEMS and MOEMS. ;8(3)–[Google Scholar]
  • Villarrubia JS, Ritchie NWM, Lowney JR. Monte Carlo modeling of secondary electron imaging in three dimensions. Proc. of SPIE. ; K [Google Scholar]
  • Yan H, Gomati MME, Prutton M, Wilkinson DK, Chu DP, Dowsett MG. Mc3D: A Three-Dimensional Monte Carlo System Simulation Image Contrast in Surface Analytical Scanning Electron Microscopy I-- Object-Oriented Software Design and Tests. Scanning. ;20(6)–[Google Scholar]
Источник: thisisnl.nl

5574 | 5575 | 5576 | 5577 | 5578 | 5579 | 5580 | 5581 | 5582 | 5583