Temperature effects in ion-electron emission of graphite quasicrystal

Analysis of the comparative influence of complete amorphization of a polycrystalline graphite surface layer and radiation-induced disordering of highly oriented pyrolytic graphite UPV-1T on the character of temperature dependences of the ion-electron emission yield under high-dose (10¹⁸–10¹⁹ ion/cm²) 30 keV Ar⁺ ion irradiation has been carried out.     

高电荷态离子与Si(110)晶面碰撞的沟道效应研究

不同电荷态低速离子(Ar^q+,Pb^q+)轰击Si(110)晶面,测量不同入射角情况下的次级粒子的产额. 通过比较溅射产额与入射角的关系,证实沟道效应的存在. 高电荷态离子与Si相互作用产生的沟道效应说明溅射产额主要是由动能碰撞引起的. 在小角入射条件下,高电荷态离子能够增大溅射产额. 当高电荷态离子以40°—50°入射时,存在势能越高溅射产额越大的势能效应. 关键词： 高电荷态离子 溅射 沟道效应     

Sputtering yields for light ions as a function of angle of incidence

The sputtering yield of Ni, Mo, and Au have been measured at oblique angles of incidence for H⁺-, D⁺-, and⁴He⁺-ion irradiation in the energy region from 1 to 8 keV. The yields were determined from the weight loss of the targets. For Ni and Mo the dependence of the sputtering yield on the angle of incidence was found to be much stronger for H⁺- and D⁺-ion than for⁴He⁺-ion irradiation. In all cases the maximum in the yield was found at angles of incidence ϑ≧80°, where ϑ is the angle measured from the surface normal. Furthermore the ratio of the maximum yield to the yeild at normal incidence increases with increasing surface binding energy of the target material as well as with increasing ion energy in the energy region inveestigated. The results are discussed qualitatively in view of a model for the sputtering mechanism for light ions.     

A nonlinear thermal spike model for pyrolytic graphite under irradiation with 86Kr and 209Bi high-energy heavy ions

The temperature dependences of the specific heat capacity and thermal conductivity are introduced for a highly oriented pyrolytic graphite; i.e., the nonlinear model of a thermal spike is considered and a comparative analysis of the obtained results and those for the linear model of a thermal spike is performed. The temperature effects observed in the highly oriented pyrolytic graphite with a change in the electron-phonon interaction coefficient g are investigated in detail. It is shown that, under irradiation of the highly oriented pyrolytic graphite by bismuth ions with an energy of 710 MeV, the temperature on the surface of the target within the framework of the nonlinear model can exceed the sublimation temperature, whereas the temperature on the surface of the target under irradiation by krypton ions with an energy of 253 MeV does not exceed the sublimation temperature. The characteristic range of variations in the electron-phonon interaction coefficient g is evaluated. For values of g in this range, the thermal spike model explains the experimental data on the presence of structures in the form of hillocks with craters at their centers on the surface of the highly oriented pyrolytic graphite exposed to irradiation by ²⁰⁹Bi ions and on the absence of such structures in the case of irradiation by ⁸⁶Kr ions.     

Effect of temperature on the physical sputtering of highly oriented pyrolytic graphite

The results of experimentally investigating the sputtering and erosion of the basal plane of highly oriented pyrographite UPV-1T under irradiation with 30-keV Ar⁺ in the range from room temperature to 400°C are presented. It has been found that ion-induced surface-relief evolution at higher temperatures results in a two-fold increase in the sputtering yield (Y = 2) in comparison with sputtering of a surface with a nanosized relief at temperatures less than that of the texture transition T _t ≈ 150°C. Sputtering simulation using the OKSANA code for a surface with a sinusoidal nanorelief, which reflects the instability of the basal plane of UPV-1T under ion irradiation, permits to estimate the ratio of the amplitude to the relief period at T < T _t.     

Relation between surface structures and sputtering ratios of copper single crystals

Polished (100) Cu crystals have been bombarded at target temperatures of 204 K, 294 K and 456 K by 10 and 20 keV Ne⁺ ions up to a total dose of 1.7 × 10¹⁹ ions/cm². The plane of incidence was chosen to be a {100} plane perpendicular to the surface. Measurements have been performed for incident angles between 36° and 44° with respect to the surface normal. In this angular interval the sputtering ratio and the surface structure have been studied by weightloss and replica electron microscope techniques respectively. At target temperatures of 204 K and 294 K an anomaly was observed in the curve of the sputtering ratio versus angle of incidence. A small peak appears where the curve slopes towards the 〈110〉 minimum. The position and height of the peak is a function of target temperature and ion energy.

This sputtering submaximum is accompanied by the formation of {100} orientated furrows perpendicular to the ion beam. The nucleation of this relief is tentatively discussed in terms of local deviations from perfection of the surface, which might be due to a singularity in the production of focusing collisions influencing the damage structure. The growth of the furrows and the submaximum in the sputtering ratio are discussed in terms of the angle between the ion beam and the characteristic {110} side of the furrows.

These sputtering and faceting phenomena have not been observed at 20 keV Ar⁺ ion bombardment nor generally under bombardment at a target temperature of 456 K.     

The effect of radiation damage on microstructure and ion electron emission of pyrolytic graphites

The influence of radiation damage on the microstructure of pyrolytic graphites was analyzed. The correlation between the temperature dependences of ion-induced electron emission and structural modification of UPV-1 pyrolytic graphite and highly oriented UPV-1T pyrolytic graphite under neutron and high-fluence (10¹⁷–10¹⁹ cm⁻²) (30 keV) Ar⁺ irradiation was experimentally studied and discussed.     

Study of carbon material surface layers modified by nitrogen and argon ion irradiation

We present the results of the study of the elemental composition and defects of the electronic structure of the surface layer modified by high-dose irradiation (10¹⁸–10¹⁹ ion/cm²) of highly oriented pyrolytic graphite (UPV-1T) by 30-keV N ₂ ⁺ and Ar⁺ ions in the temperature range from 180 to 400°C. The EPR spectra observed during irradiation with argon ions at high temperatures and with nitrogen ions at temperatures near the liquid-nitrogen temperature T = 77 K exhibit anomalously narrow lines which probably result from the exchange interaction inside paramagnetic clusters of displaced carbon atoms. During nitrogen ion irradiation at room and higher temperatures, paramagnetic defects typical of many carbon materials (single EPR lines with g = 2.0027–2.0029) and belonging to carbon atoms bound to one or three nitrogen atoms were detected.     

Nuclear electric quadrupole interaction of 182Re (64h) and 183Re recoil-implanted into graphite

Abstract

The technique of static low-temperature nuclear orientation has been used to investigate the nuclear electric quadrupole interaction of implanted ¹⁸²Re (64h) and ¹⁸³Re in thin foils of highly oriented pyrolytic graphite (HOPG) at temperatures down to 5 mK. The isotopes were recoil-implanted at a temperature of 700°C in order to limit the amount of lattice damage. The fraction of nuclei experiencing a large electric field gradient was considerably improved after two successive annealing sessions at 1200°C, from 1.0(0.6)% before annealing to 4.5(0.8)% after 6h and to 11.3(2.0)% after 162 h annealing. The electric field gradient for Re in HOPG is deduced to be V_zz = +5.4(2.6)·10²²V/m².     

石墨薄片弯曲度的高分辨率电子显微镜研究

报道了一种用高序石墨在乙醇、水或乙醇 水混合溶液中超声波处理产生的碳样品．高分辨率电子显微镜揭示出大量具有总角度为θ₀（±30℃）倍数的弯曲石墨片存在．显微镜检查表明，弯曲是通过原子晶格平面的偏转而成的．基于石墨的对称轴结构和在sp²石墨网络中类-sp³线缺陷的形成，讨论了石墨片弯曲的可能解释. 关键词：     

Sputtering of solids by heavy ions and temperature effects in electronic and lattice subsystems

The results of sputtering coefficient measurements for pure metals, alloys, amorphous alloys, semiconductors, and highly oriented pyrolytic graphite under irradiation by high energy ions are considered. The possible mechanisms of strong sputtering of materials with high defect concentrations are discussed. The three-dimensional thermal spike model (“hot ion track”) with the temperature dependence of thermodynamic parameters (specific heat thermal conductivity) is formulated for single-layer mono-and polycrystals and multilayer systems (materials). The results of a numerical solution to the introduced system of partial differential equations are considered for the lattice and electronic subsystem temperatures around and along the fast heavy ion trajectory as a function of the time t, as well as radial r and longitudinal z coordinates, taking into account possible phase transitions such as melting and evaporation. The results obtained are discussed.     

Electron capture and loss in the scattering of H+ from HOPG graphite

In this paper we report measurements of the positive (H⁺) and negative (H^?) ion fractions after H⁺ scattering from a highly oriented pyrolytic graphite (HOPG) surface. The experimental results show that for a fixed (large) exit angle the negative fraction is almost independent of the primary ion energy, while the positive fraction increases steadily. For a fixed incident energy, the H⁺ and H^? fractions show a complementary behavior with exit angle. A dynamical quantum mechanical calculation, based on the localized and extended features of the atom–surface interaction, allows us to understand many of the features of the experimental results.     

Study of the orientation of HNO3 molecules intercalated in graphite using nuclear techniques

Nuclear resonance scattering of photons from ¹⁵N has been used to study the orientation of the HNO₃ intercalant molecule with respect to the graphite planes. In the second-stage compound C₁₀(HNO₃) and the temperature range T = 15°K ? 300°, no orientational phase transition was observed and the NO₃ molecular plane was found to be oriented at an angle θ ∽ 82 ± 8° with respect to the graphite planes.     

Effect of the ion current density on the temperature dependences of ion-induced electron emission from carbon-based materials

The effect of ion current density j on the temperature dependences of the ion-induced electron emission yield γ(T) of carbon-based materials (polycrystalline graphite MPG-8, highly oriented pyrolytic graphite UPV-1T, and some glassy carbons) under irradiation by atomic and molecular nitrogen ions with energies of several tens of keV has been experimentally studied. The most significant effect of the density j on the dependences γ(T) is observed for low-temperature glassy carbons.     

Vacancy-type defect distributions near argon sputtered Al(100) surface studied by variable-energy positrons and molecular dynamics simulations

A beam of variable-energy positrons, whose back-diffusion probability is measured as a function of positron implantation energy, is applied to studies of depth distribution of sputtering damage in aluminum. The defects are produced by argon ion bombardment of an Al(110) surface in ultra-high vacuum. We have varied the Ar⁺ energy, incident angle and dose, as well as sputtering and annealing temperatures. The extracted defect profiles have typically a narrow peak at the surface with a width of 10–20 A and a broader tail extending down to 50–100 Å. The shape of the defect profile varies only slightly with the sputtering energy and angle. Defect production at less than 1 keV Ar⁺ energies is typically 1–5 vacancies per incident ion. The defect profiles become fluence-independent at about 2 × 10¹⁶ Ar⁺ cm⁻². The defect density at the outer atomic layers saturates at high argon fluences to a few at%, depending on sputtering conditions. The sputtering temperature (below or above the vacancy migration stage at 250 K) has little effect on vacancy profiles. Defects anneal out gradually between 100 °C and 400 °C. Sputtering damage was also evaluated with the molecular dynamics technique. The shape and depth scale of the simulated collision cascades are in agreement with the experimentally extracted quantities.     

μ- spin rotation studies on graphite and its second-stage rubidium intercalation compound. Evidence for a paramagnetic chemical shift

The precession frequencies of negative-muon spin rotation in highly oriented pyrolytic graphite and its second stage Rb compound were measured at room temperature. The results showed that a μ^- C-C bond is formed from sp² hybrid orbitals involving the partially filled p_z orbital and that intercalation influences the σ as well as the π bonds.     

A comparison of the magnetic properties of proton- and iron-implanted graphite

In this work we have investigated the changes of the magnetic properties of highly oriented pyrolytic graphite samples after irradiation either with ~3×10¹⁴ protons or 3.5×10¹³ ... 3.5×10¹⁴ iron ions with energies in the MeV range. Our results show that iron and proton irradiations can produce similar paramagnetic contributions depending on the implantation temperature. However, only protons induce a ferromagnetic effect.     

Characterization of fluorinated multiwalled carbon nanotubes by x-ray absorption spectroscopy

The C 1s and F 1s x-ray absorption spectra of fluorinated multiwalled carbon nanotubes with different fluorine contents and reference compounds (highly oriented pyrolytic graphite crystals and “white” graphite fluoride) were measured using the equipment of the Russian-German beamline at the BESSY II storage ring with a high energy resolution. The spectra obtained were analyzed with the aim of characterizing multiwalled carbon nanotubes and their products formed upon treatment of the nanotubes with fluorine at a temperature of 420°C. It was established that, within the probing depth (～15 nm) of carbon nanotubes, the process of fluorination occurs uniformly and does not depend on the fluorine concentration. The interaction of fluorine atoms with multiwalled carbon nanotubes in this case proceeds through the covalent attachment of fluorine atoms to graphene layers of the graphite skeleton and is accompanied by a change in the hybridization of the 2s and 2p valence electron states of the carbon atom from the trigonal (sp ²) to tetrahedral (sp ³) hybridization.     

Surface reactivity of oxygen on cleaved and sputtered graphite

The characterization of reactions which occur during the oxidation of highly oriented pyrolytic graphite (HOPG) was performed using high-resolution electron energy loss spectroscopy (HREELS) temperature programmed desorption (TPD), and scanning tunneling microscopy (STM). The results of this investigation provide spectroscopic evidence for the presence of semi-quinone functionalities on sputtered and oxidized HOPG STM images are presented to quantify the increase in defect sites after oxygen ion sputtering, and to correlate defect site density with reactivity.     

Angular distribution and differential sputtering yields for low-energy light-ion irradiation of polycrystalline nickel and tungsten

Angular differential and total sputtering yields of polycrystalline nickel and tungsten have been measured for 1 and 4 keV H⁺ and 4 keV He⁺ ion bombardment at incidence angles between 0° and 80°. The differential sputtering yields (dY/dΩ) were determined with the aid of the collector technique, whereas the total yieldY was determined from the weight loss of the target during irradiation. Asymmetric angular distributions are observed at oblique angles of incidence, the emission maximum being shifted in forward direction (with respect to the incident ions). Even more pronounced than the change in shape of the emission distribution is an increase in the differential yield:dY/dΩ rises with increasing incidence angle over the whole range of ejection angles, the increase being most prominent in the direction of primary recoil emission. This effect is therefore ascribed to emission of surface atoms in direct projectile-surface atom collisions. On short term leave from Institut für Plasmaphysik der Kernforschungsanlage Jülich GmbH, D-5170, Jülich, Fed. Rep. Germany.