Determination of Hydrogen Density by Swift Heavy Ions

Xu, Guoqing; Barriga-Carrasco, Manuel D.; Blažević, A.; Borovkov, B.; Casas, David; Cistakov, K.; Gavrilin, R. O.; Iberler, M.; Jacoby, J.; Loisch, Gregor; Morales, Roberto; Mader, Roger A.; Qin, Si‐xue; Rienecker, T.; Rosmej, O.; Savin, S.; Schönlein, A.; Weyrich, K.; Wiechula, J.; Wieser, J.; Xiao, Guoqing; Zhao, Yongtao

doi:10.1103/physrevlett.119.204801

Cited by 25 publications

(5 citation statements)

References 28 publications

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“…The differences in the average ionization and the ion abundances obtained from the different atomic kinetics models for some ranges of plasma conditions will influence the theoretical calculations of the projectile energy loss in the plasma, Eqs. ( 6) and (7). To analyze this, we have studied the influence of the atomic kinetics model in the calculation of the total stopping number, L…”

Section: -4mentioning

confidence: 99%

“…The understanding of the interactions of swift charged particles with plasmas is fundamental to determine the energy deposition of the beam inside the plasma. [4][5][6][7] Therefore, a full theoretical method is needed to calculate correctly this energy deposition of projectile ions in any kind of laboratory plasmas. The energy loss of ions in local thermal equilibrium (LTE) plasmas has been widely studied.…”

Section: Introductionmentioning

confidence: 99%

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Energy loss of Fe ions in He plasmas at different thermodynamic states

et al. 2018

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In this work, we analyze the thermodynamic states of the helium plasma and their influence on the stopping power calculations which are needed for obtaining the energy loss of the iron beams traversing them. The analysis is made in ranges of plasma free electron densities (10 15 -10 19 cm À3 ) and temperatures (1-10 eV) of experiments with iron beams at 6 and 4.3 MeV/u energies. For this purpose, we use Saha-Boltzmann equations for local thermal equilibrium (LTE) and a collisionalradiative model for non-local thermal equilibrium (NLTE) in steady-state situation implemented in a computer code. For the highest temperatures and free electron densities, LTE and NLTE models provide quite similar results for the average ionization and ion abundances. When the opacity effects are taken into account in the NLTE simulations, the optically thick simulations provide fairly similar results to those of the LTE model. The plasma thermodynamic states have a direct impact on the calculation of the energy loss. The differences on the plasma stopping power between considering it in LTE or in NLTE may entail a 10% of the total stopping for the experiments analyzed in the electron density region of 10 18 -10 19 cm À3 . These differences can be around 27% for plasmas with smaller electron density of 10 17 cm À3 and around 42% for plasmas with an electron density of 10 15 cm À3 . New experiments would be appreciated to be made in a future to corroborate the latest calculations.

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Section: -4mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Energy loss of Fe ions in He plasmas at different thermodynamic states

et al. 2018

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“…Ion stopping power in high density plasmas plays a crucial role in the development of inertial confinement fusion (ICF), and an accurate description of the ion energy deposition in the ignition and combustion phases of the deuterium-tritium fuel is very important. The energy deposition of ions in high density plasmas is currently investigated with special interest in low and medium energy projectiles [5,6], i.e. in the energy range where a higher stopping power appears.…”

Section: Introductionmentioning

confidence: 99%

Contrasting ion stopping models at medium energies in partially ionized plasmas

Vázquez-Moyano

Barriga-Carrasco

2021

Eur. Phys. J. Plus

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In this paper, we present a comparison between our stopping power model and other models from bibliography at medium projectile energies for partially ionized plasmas, containing dominant concentrations of ions with A > 2. Our stopping power model takes into account free and bound electron stopping power contributions while the other models only consider free electron contributions. Other perturbative and nonperturbative free electron stopping power models are discussed for typical plasma parameters finding differences of up to 320%. Our model results are the lowest ones, obtaining values by 50% lower than other perturbative models depending on the plasma ionization considered. The stopping power of the target in plasma state compared to the target in solid state is between 50% higher, in case of our model, that seems more appropriate, and 530%, in case of the SSM model, that seems very overestimated. These large differences clearly show the need to compare the results from the models with experimental results in plasmas to determine which stopping model is more appropriate.

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“…Zhang等 [9] 利用光纤干涉方法诊断了紧凑环中的 He等离子体的自由电子密度; 然而, 上述光学类诊断技术仅针对等离子体中的自由电子成分, 瞬态光谱仅能反应自由电子信息; 汤姆孙散射方法中的散射过程主要来自自由电子, 以及束缚电子密度对等离子体折射率的贡献很小, 现有的激光干涉法等均无法诊断部分电离等离子体中束缚电子密度信息 [7][8][9] . Xu等 [10] 利用德国GSI的UNILAC束线提供的3.65 MeV/u 48 Ca 10+ 离子束与角箍缩放电形式产生的氢等离子体靶作用, 实验测量了出射离子电荷态分布与离子的能损; 结合角箍缩等离子体特征光谱诊断结果, 分析了H β 线的Stark展宽, 取得了该等离子体的电子温度与自由电子密度等信息, 最后利用Bethe公式对重离子束在等离子体中的能损进行计算, 考虑到该等离子体靶空间的高均匀性以及在该能区下的离子的阻止本领数值基本不变, 因此离子能损函数可简化为 [11] ∆E ∝ Z 2 eff [( dE dx 究工作, 取得大量的可靠数据 [11] .…”

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Diagnosis of bound electron density by measuring energy loss of proton beam in partially ionized plasma target

Chen,

Wang,

Zhou

et al. 2024

Acta Phys. Sin.

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Partially ionized plasma contains the bound electrons aspect which have an impact on the instability of the plasma, among other things. The evolution process of bound electron density cannot be obtained from the popular method applying for diagnosis of the free electron density aspect, in which the existing optical diagnostics fail. In this paper, we introduce a high-precision experiment: the energy loss of a 100 keV proton beam penetrating through the partially ionized hydrogen plasma target was measured based on the platform of ion beam - plasma interaction at the Institute of Modern Physics, Chinese Academy of Sciences. The bound electron density is figured out according to the energy loss model of Bethe theory, the free electron density information obtained by laser interferometry diagnosis and the electron tempercture measureed by spectrum (Te=0.68 eV; nfe =2.41×1017 cm-2). It is found that the bound electron density decreases with the plasma lifetime. The diagnosis of bound electron density by measuring energy loss of ion beam has the advantages of on-line, in-situ and high resolution, and provides a new way to solve the problem of the bound electron density in partially ionized plasma. A COMSOL simulation reveals that the high-temperature free electrons quickly spray out of the plasma area through a mechanical diaphragm, thus the total number of free electrons decreases. In order to maintain a relatively high degree of ionization in this plasma, in principle, more and more bound electrons are ionized to be free electrons, correspondingly the density of bound electrons decreases. The simulation result agrees well with our experimental data. Based on this finding, more detailed plasma target parameter is provied, which is helpful to deepen the understanding of the interaction process between ion beam and plasma. In future, more research work about lowly energy highly charged ions-plasma interaction will be introduced.

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Determination of Hydrogen Density by Swift Heavy Ions

Cited by 25 publications

References 28 publications

Energy loss of Fe ions in He plasmas at different thermodynamic states

Energy loss of Fe ions in He plasmas at different thermodynamic states

Contrasting ion stopping models at medium energies in partially ionized plasmas

Diagnosis of bound electron density by measuring energy loss of proton beam in partially ionized plasma target

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