Experimental and theoretical study of the energy loss of C and O in Zn

Cantero, E. D.; Montanari, C. C.; Behar, M.; Fadanelli, R. C.; Lantschner, G. H.; Miraglia, J. E.; Arista, N. R.

doi:10.1103/physreva.84.014902

Cited by 10 publications

(9 citation statements)

References 21 publications

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“…5 valence electrons (SLPA ii for the bound and EFSR-TCS iii for the valence electrons), and good agreement was found between theory and experiment. Recently, they extended their work to C and O ions 19 . But here, the perturbative SLPA calculation for inner shells that had been satisfactory for ions from H to B, was found too high; however, using the non-perturbative CasP iv theory due to Schiwietz and Grande 20 for the inner shells yielded approximate agreement v (see Fig.…”

Section: Measurements and Theoriesmentioning

confidence: 99%

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New results about stopping power for positive ions: Experiment and theory

Paul¹

2013

AIP Conference Proceedings

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Section: Measurements and Theoriesmentioning

confidence: 99%

“…The stopping power of Zn for O ions, as measured by Cantero et al19 ., compared to different theoretical formulations from the same paper, and to CasP and SRIM.They used different descriptions for inner shell and…”

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confidence: 99%

New results about stopping power for positive ions: Experiment and theory

Paul¹

2013

AIP Conference Proceedings

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“…Recent studies on the slowing-down of energetic ions in matter have addressed a wide variety of topics. Arranged roughly in the order of increasing projectile energy or velocity, noteworthy examples include the following: the correlation between electronic stopping and ion induced electron emission [1,2,3], the role of s and d electrons in electronic stopping of slow protons and deuterons [1,4,5,6,7], systematic differences in electronic stopping of low-energy H + and He + ions [6,8], the importance of exact knowledge of nuclear stopping (screening length) in low-energy ion scattering [9], the applicability of the reciprocity approach [10] for predicting ranges of slow heavy ions in compounds [11,12,13], modelling of range distributions in crystalline silicon [14], and measurements and interpretation of electronic stopping of low-and medium-mass ions in solids at energies around the Bragg peak and below [15,16,17]. However, reasonably accurate knowledge of electronic stopping cross sections S e is still available merely for a very limited number of projectile-target combinations, often within narrow ranges of energy.…”

Section: Introductionmentioning

confidence: 99%

Highly accurate nuclear and electronic stopping cross sections derived using Monte Carlo simulations to reproduce measured range data

Wittmaack

Mutzke

2017

Journal of Applied Physics

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We have examined and confirmed the previously unexplored concept of using measured projected ranges of ions implanted in solids to derive a quantitative description of nuclear interaction and electronic stopping. The idea was to perform Monte Carlo calculations of range distributions and to search for those input parameters that generate, over a wide band of energies, the best possible agreement with accurate experimental range data. The projectile-target combination studied was 11 B in Si, in which case 98 data contained in 12 sets reported by 10 different groups were compiled between 1 keV and 8 MeV. Detailed examination revealed set-wise systematic errors up to ± 8%. Their removal resulted in a refined data base with 93 ranges featuring only statistical uncertainties (mean standard deviation 1.8%; five outliers not considered any further). Ultimately, the Monte Carlo calculations reproduced the 93 refined ranges very well, with a mean ratio of 1.002 ± 1.7%. The input parameters required to achieve this very high level of agreement were identified to be as follows. Nuclear interaction is best described by the Kr-C potential, but only when used in obligatory combination with the Lindhard-Scharff (LS) screening length. Up to 300 keV the electronic stopping cross section is proportional to the projectile velocity, i.e., LS-type, S e = kS e,LS , with k = 1.46 ± 0.01. At higher energies S e falls progressively short of kS e,LS. Around the Bragg peak, i.e., between 0.8 and 10 MeV, S e is described by an adjustable function with fit parameters selected to tailor the peak shape properly (flat-topped region between 1.5 and 5 MeV). The reliability of our results is confirmed by showing that calculated and measured isotope effects for ranges of 10 B and 11 B in Si agree within experimental uncertainty (± 0.25%). Furthermore, the range-based S e,R (E) reported here predicts the scarce experimental data derived from energy loss in projectile transmission through thin Si foils to within 2% or better. By contrast, S e (E) data available from different types of stopping power tables must be rated inaccurate, the deviations from S e,R (E) ranging between-40% and + 14%.

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“…Two completely independent versions and able to fully describe the energy loss in perturbative approaches are known as Mermin Energy-Loss Function -Generalized Oscillator Strength (MELF-GOS) [89,90] and Shell Local Plasma Approximation (SLPA) [12,91].…”

Section: Linear and Non-linear Approachesmentioning

confidence: 99%

“…Even though more than a century of extensive investigation has passed, the process of energy loss 3 still configures an active field in modern science and technological applications. Precise and quantitative measurements with ion beams are required in material science and engineering [9,10,11,12], medical physics (radiotherapy) [13], ion implantation and modification of materials [14], and also in practically all Ion Beam Analysis (IBA) techniques [15,16,17,18,19,20]. Current research may be divided in two main categories: i) measuring accurate and reliable stopping power data, and ii) improving fundamental physics models, in other words: stopping power is a prerequisite for precise validation of theoretical models.…”

Section: Chapter 1 Introductionmentioning

confidence: 99%

Energy loss of light ions (H+ and He+) in matter: high accuracy measurements and comparison with the FEG model

Moro¹

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The phenomenon of energy loss that occurs when an ion interacts with matter, also called stopping power, has been investigated for more than a century, and has provided findings of interest. However, reliable procedures for obtaining accurate experimental measurements and a fully theoretical comprehension of the process are tasks still in high demand by the scientific community. Moreover, stopping power data are prerequisites in several applications in modern science, such as engineering, ion implantation and modification of materials, damage to electronics devices (e.g. space radiation), medical physics (e.g. proton therapy), among others. In this thesis we i) develop a rigorous experimental protocol to measure stopping power with high precision, and ii) investigate 1 the collapse of the free electron gas (FEG) model in energy loss of light ions (protons) at a low energy range in transition and rare-earth metals. In the first part, we present an approach to obtain, with high accuracy, the stopping cross sections in the pure materials Al and Mo for protons in the energy range of [0.9 − 3.6] MeV by means of the transmission method. The traceability of the sources of uncertainties are fully evaluated and the final accuracy of the results is 0.63 % (0.32 % rand. and 0.54 % syst.) for Al, and 1.5 % (0.44 % rand. and 1.4 % syst.) for Mo, with both results primarily limited by the quality and homogeneity of the stopping foils. For Al, this high accuracy represents an improvement com-Foremost I want to express my gratitude to my advisor, co-author and friend Prof. Dr. Manfredo H. Tabacniks. His guidance, encouragement over the years, vast scientific knowledge and notable vision in many other areas (e.g. ethics and interaction with participants) have always inspired me to reach interesting findings in physics and in life, always expanding my mind. Without his support, the accomplishments here presented would never have been possible. Thank you so much.

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Experimental and theoretical study of the energy loss of C and O in Zn

Cited by 10 publications

References 21 publications

New results about stopping power for positive ions: Experiment and theory

New results about stopping power for positive ions: Experiment and theory

Highly accurate nuclear and electronic stopping cross sections derived using Monte Carlo simulations to reproduce measured range data

Energy loss of light ions (H+ and He+) in matter: high accuracy measurements and comparison with the FEG model

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