Cómo citar
Diaz Gómez, V., Munévar Espitia, E., & Leyva Rojas, J. (2021). Resultados preliminares de un acelerador lineal compacto para un haz de iones. Conocimiento Global, 6(1), 266-290. https://doi.org/10.70165/cglobal.v6i1.217
Resumen
Durante más de tres décadas, las simulaciones computacionales de extracción por haz de iones se han utilizado en sistemas de aceleración de iones. Este artículo describe una simulación en MATLAB R2020a de un sistema de extracción de iones de siete electrodos. El propósito de este trabajo es determinar si ciertos parámetros del sistema de extracción, como el menisco del plasma y la interfaz del haz, pueden modelarse con precisión y, por lo tanto, usarse para predecir con éxito la trayectoria iónica y la forma del haz en un amplio rango. Se analizan varias configuraciones de electrodos en columnas de acelerador y se selecciona una para describirla de manera más detallada en este trabajo.
Citas
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Herranz J. L., Herraiz E., Vicente S., España J., Cal-Gonzalez J. L., and Udías J. M. (2008). Hadrontherapy. First Complutense Meeting for the Dissemination of Nuclear and Particle Physics.
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Leung K. N., Lee Y., Verbeke J. M., Vujic J., Williams M. D., Wu L. K., and Zahir N. (1998). A Sealed-Accelerator-Tube Neutron Generator for Boron Neutron Capture Therapy Application (Ph. D. Thesis). Lawrence Berkeley National Laboratory University of California Berkeley USA. CA 94720. Nuclear Engineering Department. La jolla, CA.
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Niño E. D. (2011). Surface modification of an AISI SAE 1045 steel through the implantation of nitrogen and titanium ions. ITECKNE Vol. 8 Número 1 • ISSN 1692 - 1798
Passariello G, and Mora F. (1995). Medical Images: acquisition, analysis, processing and interpretation. Universidad Simón Bolívar. Equinox, Editions of the Simón Bolívar University; printed in venezuela 1ra. edicion.
Perez M. R., Hernández H. A., and Güiza G. N. (2011). Application for processing metallographic images from PME3. Universidad Distrital Francisco José de Caldas, Bogotá D. C., Colombia. Revista Visión Electrónica Vol. 5 No. 2.
Raudales I. R. (2014). DIAGNOSTIC IMAGES: CONCEPTS AND GENERALITIES Rev. Fac. Cienc. Med.
Santamaría R. A. (2014). Feasibility study for the construction and operation of a particle accelerator in Spain. Superior technical school of engineering (ICAI), Madrid.
Saenz J. G., Camargo L. H., and Camargo E. (2014). Color descriptors for cytology smear images analysis. Research Group Engineering and Nanotechnology for Life (INVID). Universidad Distrital Francisco José de Caldas, Bogotá D. C. DIGITI Research Group, Universidad Distrital Francisco José de Caldas, Bogotá D. C. Vol. 8 No. 2 July-December, Bogotá (Colombia).
Smith A. R. (2019). Proton Therapy. Department of Radiation Oncology, The University of Texas M. D. Anderson Cancer Center, 1515 Holcombe Boulevard, Houston, Texas 77030 Med Phys. 2009 Jan 26 [Accessed 2019 Apr 20]; 36 (2): 556-68.
Verbeke J. M. (2000). Development of High-Intensity D-D and D-T Neutron Sources and Neutron Filters for Medical and Industrial Applications (Ph. D. Thesis). Engineering - Nuclear Engineering. University of California, Berkeley
World Health Organization, February 1, (2018). [Online]. Available: http://www.who.int/es/newsroom/fact-sheets/detail/cancer.
Cañas D. L. (2020). Study of the viability of CBCT images for treatment planning (Master Thesis). Ponticia Universidad Javeriana, Faculty of Sciences, Department of Physics, Bogotá D.C, Colombia.
Cifuentes J. A. (2019). Preliminary Evaluation of D Acceleration in a Compact High Flow D-D Neutron Generator (Master Thesis). Ponticia Universidad Javeriana, Faculty of Sciences, Department of Physics, Bogotá D.C, Colombia.
Chu P. K., and Cheung N. W. (1998). Microcavity engineering by plasma immersion ion implantation, Materials Chemistry and Physics. Volume 57, Number 1, Pages 1-16.
Eastman G. W., Wald C., and Crossin J. (2005). Getting started in clinical radiology, from image to diagnosis. Germany.
EducationalApplets:https://www.falstad.com/vector2de,https://www.falstad.com/vector3de.
Escobar A., and Calderón, L. A. (2009). THREE-DIMENSIONAL LOWER LIMB MODEL BASED ON MAGNETIC RESONANCE IMAGES. Universidad Distrital Francisco José de Caldas. Revista Visión Electrónica Vol. 3 No. 1.
Esquivel L., García Y. F., and González Y. J. (2018). A look at the means for diagnostic imaging from medical education. 10 (1): ISSN 2077-2874 RNPS 2234 Santa Clara Jan.-Mar. EDUMECENTRO.
Fajardo M. (2016). The scientific-technical revolution and its impact on the medical sciences. M. Hernández Pino. Havana: Virtual University of Health.
Forero J., Bohórquez C., and Ruiz V. H. (2013). AUTOMATED MEASUREMENT OF TURNED PARTS USING ARTIFICIAL VISION. Revista Visión Electrónica Year 7 No. 2 pp. 36 - 4.
Garza J. G., and Juárez P. (2014). Cáncer. Autonomous University of Nuevo León. Centro, Monterrey, Nuevo León, México, C.P. 64000 First edition, 2014.ISBN: 978-607-27-0215-8
Hermida E. B. (2003). Influence of ionic implantation on film traction from al 8006. SAM 2000 Conference - IV Latin American Colloquium on Fracture and Fatigue, August 2000, 885-891. Buenos Aires.
Herranz J. L., Herraiz E., Vicente S., España J., Cal-Gonzalez J. L., and Udías J. M. (2008). Hadrontherapy. First Complutense Meeting for the Dissemination of Nuclear and Particle Physics.
Holzer B. J. (2016). Introduction to Particle Accelerators and their Limitations. Published by CERN in the Proceedings of the CAS-CERN Accelerator School: Plasma Wake Acceleration, Geneva, Switzerland, edited by B. Holzer.
Leung K. N., Lee Y., Verbeke J. M., Vujic J., Williams M. D., Wu L. K., and Zahir N. (1998). A Sealed-Accelerator-Tube Neutron Generator for Boron Neutron Capture Therapy Application (Ph. D. Thesis). Lawrence Berkeley National Laboratory University of California Berkeley USA. CA 94720. Nuclear Engineering Department. La jolla, CA.
Lozares S., Mañeru F., and Pellejero S. (2009). Heavy particle radiation therapy. Radiophysics and Radiological Protection Service. Navarra Hospital. Pamplona. An. Sist. Sanit. Navar. Vol. 32, Suplemento 2.
Moreno H. J., Dougar-Jabon V. D., and Tsygankov P. A. (2016). ION IMPLANTATION. Universidad Francisco de Paula Santander, A.A. 1055 Cúcuta, Colombia, Universidad Industrial de Santander, A.A. 678 Bucaramanga, Colombia, Moscow Bauman State Technical University, Moscow, Russia.
Moranchel I. L., Mand aurelos P. I. (2019). Proton Therapy: state of the art and clinical applications. Revista oficial de la sociedad española de enfermería oncológica. ENFERM ONCOL VOL.21. N.2.
Muthukumaran V., Selladurai V., Nandhakumar S., and Senthilkumar M. (2010). Experimental investigation on corrosion and hardness of ion implanted AISI 316L stainless steel. Materials & design technology. Department of Mechanical Engineering, Kumaraguru College of Technology, India, Volume 31, pages 2813-2817.
Niño E. D. (2011). Surface modification of an AISI SAE 1045 steel through the implantation of nitrogen and titanium ions. ITECKNE Vol. 8 Número 1 • ISSN 1692 - 1798
Passariello G, and Mora F. (1995). Medical Images: acquisition, analysis, processing and interpretation. Universidad Simón Bolívar. Equinox, Editions of the Simón Bolívar University; printed in venezuela 1ra. edicion.
Perez M. R., Hernández H. A., and Güiza G. N. (2011). Application for processing metallographic images from PME3. Universidad Distrital Francisco José de Caldas, Bogotá D. C., Colombia. Revista Visión Electrónica Vol. 5 No. 2.
Raudales I. R. (2014). DIAGNOSTIC IMAGES: CONCEPTS AND GENERALITIES Rev. Fac. Cienc. Med.
Santamaría R. A. (2014). Feasibility study for the construction and operation of a particle accelerator in Spain. Superior technical school of engineering (ICAI), Madrid.
Saenz J. G., Camargo L. H., and Camargo E. (2014). Color descriptors for cytology smear images analysis. Research Group Engineering and Nanotechnology for Life (INVID). Universidad Distrital Francisco José de Caldas, Bogotá D. C. DIGITI Research Group, Universidad Distrital Francisco José de Caldas, Bogotá D. C. Vol. 8 No. 2 July-December, Bogotá (Colombia).
Smith A. R. (2019). Proton Therapy. Department of Radiation Oncology, The University of Texas M. D. Anderson Cancer Center, 1515 Holcombe Boulevard, Houston, Texas 77030 Med Phys. 2009 Jan 26 [Accessed 2019 Apr 20]; 36 (2): 556-68.
Verbeke J. M. (2000). Development of High-Intensity D-D and D-T Neutron Sources and Neutron Filters for Medical and Industrial Applications (Ph. D. Thesis). Engineering - Nuclear Engineering. University of California, Berkeley
World Health Organization, February 1, (2018). [Online]. Available: http://www.who.int/es/newsroom/fact-sheets/detail/cancer.
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