Resolution TEM Research Articles

Distortions correction in HR-(S)TEM and low resolution TEM images: Absolute size, strain and polarization measurements

Distortions correction in HR-(S)TEM and low resolution TEM images: Absolute size, strain and polarization measurements

Voxel dose-limited resolution for thick beam-sensitive specimens imaged in a TEM or STEM

The resolution limit imposed by radiation damage is quantified in terms of a voxel dose-limited resolution (DLR), applicable to small features within a thick specimen. An analytical formula for this DLR is derived and applied to bright-field mass-thickness contrast from organic (polymer or biological) specimens of thickness between 400 nm and 20 µm. For a permissible dose of 330 MGy (typical of frozen-hydrated tissue), the TEM or STEM image resolution is determined by radiation damage rather than by lens aberrations or beam-broadening effects, which can be restricted by use of a small angle-limiting aperture. DLR is improved by a up to factor of 2 by increasing the primary-electron energy from 300 keV to 3 MeV, or by up to a factor of 3 by heavy-metal staining. For stained samples, a higher electron fluence allows better resolution but the improvement is modest because the voxel DLR is proportional to the 1/4 power of electron dose. The relevance of voxel and columnar DLR is discussed, for both thick and thin samples.

NanoMi: An open source electron microscope hardware and software platform

We outline a public license (open source) electron microscopy platform, referred to as NanoMi. NanoMi offers a modular, flexible electron microscope platform that can be utilized for a variety of applications, such as microscopy education and development of proof-of-principle experiments, and can be used to complement an existing experimental apparatus. All components are ultra-high vacuum compatible and the electron optics elements are independent from the vacuum envelope. The individual optical components are mounted on a 127 mm (5-inch) diameter half-pipe, allowing customizing of electron optics for a variety of purposes. The target capabilities include SEM, TEM, scanning TEM (STEM), and electron diffraction (ED) at up to 50 keV incident electron energy. The intended image resolution in SEM, TEM and STEM modes is ≈ 10 nm. We describe the existing components and the interfaces among components that ensure their compatibility and interchangeability. The paper provides a resource for those who consider building or utilizing their own NanoMi.

Microreactor-Based TG-TEM Synchronous Analysis.

It is challenging to measure the heating-induced mass change of the material during its morphological/structural evolution process. Herein, a silicon microreactor is developed for thermogravimetric-transmission electron microscopy synchronous analysis (TG-TEM synchronous analysis). A self-heating resonant microcantilever for mass-change detection and a dummy microcantilever with electron-beam transparent SiNx windows for in situ TEM imaging are integrated back-to-back inside the microreactor. The TEM resolution of the microreactor reaches the Ångström level in an air atmosphere of 100 mbar, and the TGA function is realized by the heatable resonant microcantilever. The TG-TEM synchronous analysis has been successfully used to characterize two Ni(OH)2 samples. During the in situ TEM observing process, the desorption of the intercalated H2O molecules and dehydration of the lattice OH groups in the amorphous Ni(OH)2·xH2O nanosheets can be clearly distinguished from the microcantilever-based TGA. For single-crystal Ni(OH)2 nanosheets, the TG-TEM synchronous analysis can distinguish the desorption of physiosorbed water, the condensation of surface OH groups, and the dehydration of lattice OH groups. The amorphous Ni(OH)2 nanosheets transformed to polycrystalline NiO completed at 290 °C, and the decomposition from the single-crystalline Ni(OH)2 nanoplates to NiO at 315 °C is also clearly recognized. The proposed microreactor-based TG-TEM synchronous analysis provides an interrelated characterization platform to obtain more comprehensive information on materials.

Radiation induced hardening of beryllium during low temperature He implantation

• Helium implantation resulted in significant hardness increase of beryllium. • Dislocation loops and helium bubbles are responsible for hardening. • Low purity grade has higher irradiation induced hardening after 200°C implantation. • Crystallography leads to significant scatter in indentation hardness. • Softer grains exhibited higher irradiation induced hardening. The effect of ion irradiation on evolution of microstructure and hardening of beryllium with different impurity levels was investigated using TEM and nanoindentation. High purity S-65 grade and less-pure S-200-F grade were implanted by helium ions at temperatures of 50°C and 200°C. 11 different energies were used, so as to create a quasi-homogeneous 3 µm irradiated layer with average radiation damage of 0.1 dpa and average He content of 2000 appm. Nanoindentation experiments demonstrated that before irradiation, the S-200-F and S-65 grades have an average hardness of 3.7±0.8 GPa and 3.4±0.8 GPa correspondently. After implantation the hardness of both grades increased by about 60% for the 200°C irradiation and 100% for the 50°C irradiation. The crystallographic analysis of indented grains demonstrated that in the as-received materials the hardness is about 2.5 times higher when the indentation direction is close to the [0001] c-axis of beryllium compared to indentation perpendicular to [0001]. Hardness anisotropy significantly decreased after irradiation: the “soft orientation” was most sensitive to irradiation-induced hardening, with hardness increasing by about 140% after irradiation at 50°C and 100% after irradiation at 200°C, compared to about 15 - 20% for the “hard” orientation at both irradiation temperatures. The higher purity grade had smaller increase of the “soft orientation” hardness: 2.5±0.3 GPa for the S-65 and 2.9±0.2 GPa for the S-200-F. At both temperatures in both grades, under TEM investigation the radiation damage appears as “black dots” which are likely to be small dislocation loops with the number density of ~ 10 22 m −3 . No bubbles were observed by TEM inside grains and at grain boundaries. Analysis of the possible hardening contribution demonstrated that the observed “black dots” could be responsible for up to half of the measured hardening, while the rest of the hardening should originate from helium bubbles with the size below the TEM resolution (at or below 1.5 nm).

Synthesis of ZrO2-Shelled SnO2 Nanowires for NO2 Gas Sensing

Introduction NO2 gas, with its highly toxic nature, is mainly produced from automobile exhaust or the burning of fossil fuels [1]. This gas could lead to damage in the respiratory system when inhaled [2]. Moreover, when exposed to high concentration, could lead to cancer or related disease.One unique type of nanowires is core-shell (C-S) nanowires, where nanowires are covered by a thin shell. In this study, SnO2 nanowires covered by ZrO2 shell has been explored.The oxygen ions in ZrO2 are actively transported after it reaches 600°C limiting the application field. SnO2 has often been applied for gas sensing due to its physiochemical stability and high mobility of charge carriers. SnO2-ZrO2 C-S NWs are expected to show a prominent result in respect of sensor temperature and sensor response. This study has been published on Sensors and Actuators B: Chemical 319 (2020) 128309. Method SnO2 NWs were fabricated using the vapor-liquid-solid (VLS) method. Metallic Sn powders in alumina tube were placed into a furnace and were thermally evaporated at 900°C for 15 min. Evaporated Sn reacts with oxygen from the air, finally, SnO2 NWs are synthesized.ZrO2 was coated on SnO2 NWs by a thermal ALD system (Lucida D100, NCD Technology, Korea). The precursor and reactant for the ALD process were tris(dimethylamino) cyclopentadienyl zirconium (Cp-Zr) and ozone (O3), respectively. Cp-Zr was heated to 90°C in a canister, and Ar gas was used as a bubbler. The pressure and temperature of the ALD process were kept at 0.5 Torr and 300°C, respectively [3,4].A bi-layer electrode (200-nm thick Au and 50-nm thick Ti) was sputter-deposited on the samples for making of the gas sensors. The sensors were placed inside a gas chamber in a tubular furnace. The gas concentrations were controlled by mass flow controllers with air as a background gas. The total flow rate was fixed to 500 sccm during all measurements. Result and Conclusions Fig. 1(A,B), (C,D), (E,F) and (G,H) show TEM and high resolution TEM (HR-TEM) images of SnO2-ZrO2 C-S NWs with 50, 100, 150, 200 ALD cycles respectively. Owing to the very thin nature of the shell, the lattice fringes from the underlying SnO2 core were able to be observed.Fig. 2A and B show EDAX data of SnO2-ZrO2 C-S NWs after 50 cycles for core and shell parts, respectively. For evaluation of the presence of Zr in the core and shell regions, the ratio of Zr/(Zr+Sn) was used. The ratio of Zr/(Zr+Sn) in the core region was 0.08 and that of the shell region was 0.98. This demonstrates the successful deposition of Zr in the shell region. The same trend can be seen for other C-S NWs. Therefore, it can be concluded that ZrO2 is mainly concentrated in the outer regions, whereas the SnO2 is concentrated in the core region, regardless of ALD cycle time. The value of Zr/(Zr+Sn) in the core region becomes higher at higher ALD cycles, as the ZrO2 shell gets thicker, whereas the SnO2 core is constant.Fig. 3 depicts the response to 10 ppm NO2 gas versus temperature for pristine and C-S gas sensors. At low temperatures, the response is low and after reaching a peak at a particular temperature, the response decreases. The highest response for pristine SnO2 gas sensor occurred at 250°C, which was 20.9. For C-S NW gas sensors with a ZrO2 shell deposited at 50, 100, 150, and 200 cycles, the maximum responses were 14.9, 16.2, 24.7, and 14.2, respectively. The sensor with ZrO2 shell being deposited with 150 ALD cycles exhibited the highest gas response. All C-S gas sensors except that deposited with 100 ALD cycles showed their optimal sensing temperature at 150°C. However, for the sensor with ZrO2 shell deposited with 100 ALD cycles, the optimal sensing temperature was 100°C.The selectivity of SnO2-ZrO2 (150 cycles) C-S NW to 10 ppm of various gases at 150°C is presented in Fig. 4. The response to NO2 (24.7) was much higher than that of the other gases.To conclude, the optimal sensing temperature was varied from 100°C for the sensor with a ZrO2 shell deposited with 100 cycles to 250°C for pristine SnO2 gas sensor. Also, NO2 gas sensing results demonstrated a dependence of response to the thickness of the ZrO2 shell. The optimal sensor with a ZrO2 shell thickness of 24.1 nm (150 ALD cycles) revealed a high response to NO2 gas and also a good selectivity to NO2 gas.

Microstructural evolution of three potential fusion candidate steels under ion-irradiation

The present paper studies the gas bubble distribution in triple beam irradiated (Fe+, He+, H+) EUROFER97, ODS-EUROFER and a 13%Cr ODS-steel. All materials were irradiated at 350 °C, 450 °C and 550 °C up to a displacement damage of 40 dpa, a helium concentration of ∼12.5 appm He/dpa and a final hydrogen content of ∼50 appm H/dpa, respectively.While most of the bubbles, with diameters up to 107 nm, in the 13%Cr ODS-steel were found to be attached to the ODS-particles at all temperatures, they showed a homogenous distribution in EUROFER97 at 350 °C. At 450 °C however, many small clusters with mainly facetted cavities were observed, whereas at 550 °C most of the bubbles were localized at microstructural sinks like grain boundaries, dislocations or precipitates. The largest bubble found in EUROFER97 had a diameter of ∼19 nm.In both materials, the largest bubbles were located in the area where, according to SRIM calculations, superposition of maximum displacement damage and highest gas concentration occurred. This observation suggests that synergetic effects between helium and hydrogen strongly influenced the bubble growth but not the bubble nucleation.Despite exhaustive analysis, no bubbles could be identified in any of the three ODS-EUROFER lamellae. Apparently, bubbles have formed only below the TEM resolution limit or the helium was evenly distributed within the grains or at the particle-matrix interface.In addition, electron energy loss spectroscopy (EELS) was used to confirm the existence of helium and hydrogen inside closed gas bubbles.

Effect of hydriding induced defects on the small-scale plasticity mechanisms in nanocrystalline palladium thin films

Nanoindentation tests performed on nanocrystalline palladium films subjected to hydriding/dehydriding cycles demonstrate a significant softening when compared to the as-received material. The origin of this softening is unraveled by combining in situ TEM nanomechanical testing with automated crystal orientation mapping in TEM and high resolution TEM. The softening is attributed to the presence of a high density of stacking faults and of Shockley partial dislocations after hydrogen loading. The hydrogen induced defects affect the elementary plasticity mechanisms and the mechanical response by acting as preferential sites for twinning/detwinning during deformation. These results are analyzed and compared to previous experimental and simulation works in the literature. This study provides new insights into the effect of hydrogen on the atomistic deformation and cracking mechanisms as well as on the mechanical properties of nanocrystalline thin films and membranes.

Pollen wall ontogeny in Polemonium caeruleum (Polemoniaceae) and suggested underlying mechanisms of development.

By a detailed ontogenetic study of Polemonium caeruleum pollen, tracing each stage of development at high TEM resolution, we aim to understand the establishment of the pollen wall and to unravel the mechanisms underlying sporoderm development. The main steps of exine ontogeny in Polemonium caeruleum, observed in the microspore periplasmic space, are spherical units, gradually transforming into columns, then to rod-like units (procolumellae), the appearance of the initial tectum, growth of columellae in height and tectum in thickness and initial sporopollenin accumulation on them, the appearance of the endexine lamellae and of dark-contrasted particles on the tectum, the appearance of a sponge-like layer and of the intine in aperture sites, the appearance of the foot layer on the base of the sponge-like layer and of spinules on the tectum, and massive sporopollenin accumulation. This sequence of developmental events fits well to the sequence of self-assembling micellar mesophases. This gives (together with earlier findings and experimental exine simulations) strong evidence that genome and self-assembly probably share control of exine formation. It is highly probable that self-assembly is an intrinsic instrument of evolution.

Investigation of the localization phenomenon in quaternary BInGaAs/GaAs for optoelectronic applications

In this paper, single quantum well (SQW) structure of BxInyGa1-x-yAs/GaAs lattice-matched to GaAs has been grown by metal organic vapor phase epitaxy (MOVPE). The sample was characterized morphologically and structurally using the atomic force microscopy AFM, transmission electron microscopy TEM and high resolution X-ray diffraction HRXRD measurements. The optical study was investigated by photoluminescence (PL) spectroscopy as a function of temperature. The PL peak energy, the full width at half maximum (FWHM) and the PL intensity, versus temperature, exhibit anomalous behaviors such as S-shaped and N-shaped. They were attributed to the creation of a fluctuation potential in the band edge of the host material from the non-uniform distribution of boron atoms in the structure induced exciton localization. We investigate the localization phenomenon by excitation density variation. Then, a quasi-steady state rate-equation model for temperature dependent luminescence spectra of localized-state material system (LSE) was presented to quantitatively reinterpret the band gap emission process. The novel analytical models, compared with the classical ones, were used to fit the PL peak energy evolution. Good agreement between experimental and theoretical results has been observed using the modified Pässler model. Modeling results will be discussed based on specified parameters. These results can improve the fundamental properties of quaternary based on light-emitting and optoelectronic devices.

FEI Titan G3 50-300 PICO

The FEI Titan G3 50-300 PICO is a unique fourth generation transmission electron microscope which has been specifically designed for the investigation of a wide range of solid state phenomena taking place on the atomic scale and thus necessitating true atomic resolution analysis capabilities. For these purposes, the FEI Titan G3 50-300 PICO is equipped with a Schottky type high-brightness electron gun (FEI X-FEG), a monochromator unit, and a Cs probe corrector (CEOS DCOR), a Cs-Cc achro-aplanat image corrector (CEOS CCOR+), a double biprism, a post-column energy filter system (Gatan Quantum 966 ERS) as well as a 16 megapixel CCD system (Gatan UltraScan 4000 UHS). Characterised by a TEM and STEM resolution well below 50 pm at 200 kV, the instrument is one of the few chromatically-corrected high resolution transmission electron microscopes in the world. Typical examples of use and technical specifications for the instrument are given below.

Investigation of Li ion and Multivalent Battery Systems Using In situ TEM and High Resolution EELS

Investigation of Li ion and Multivalent Battery Systems Using In situ TEM and High Resolution EELS

Effect of mechanical milling of elemental powders on interface formation in TiN–Ni cermets prepared by pulsed current sintering

Interfaces of TiN–Ni cermets prepared by mechanical milling (MM) of TiN and Ni powders and the pulsed current sintering (PCS) method were investigated using TEM and high resolution TEM. The MM is an effective method for the formation of the TiN/Ni interface. Coherent TiN/Ni interfaces were observed in the sintered sample. The orientation relationship of the coherent interface was (111)TiN/(111)Ni. This coherent interface was formed by the Ni lattice expansion due to the introduction of the dislocations. Therefore, the Ni energy state in the cermet was metastable. The MM can excite the Ni energy state to a higher state rather than the metastable state in the cermet, and subsequent PCS leads to the Ni metastable state by relaxation of the exited energy; presuming that this process requires the lower activation energy compared with the amount that the Ni energy is excited to the metastable state from the stable (non-milled) state.

(Invited) Plasmonic Composites of Semiconducting Polymers for Optoelectronic Applications

Downscaling metallic fillers in polymer composites to nanometers opens a new field of applications as, for example, in photochemical catalysis, optical sensing or nonvolatile rewritable memories. Combination of plasmonic properties of NPs with semiconducting properties of p-conjugated polymers brings a new functionality for advanced optoelectronic applications due to the synergy effect of surface plasmons and delocalized p-electrons in the polymer backbone. It can be used e.g. for better harvesting of absorbed light for photovoltaic energy conversion by the enhancement of charge transfer near the NP surface.1 Various procedures of plasmonic composites preparation will be shown on the example of poly(3-alkylthiophene), P3AT and the electrical and optical properties of these composites will be discussed.By mixing negatively charged Ag or Au NPs with cationic derivatives of P3AT in a composition ratio near to the charge balance between NPs and cationic chains aggregates were formed, in which interparticle distances of NPs enable strong interactions of their plasmons, as it was demonstrated by their optical extinction and high SERS activity, which is even preserved in dry thin solid films prepared from such sol. The surface plasmon resonance of metal nanoparticles contributed markedly to the overall extinction of the composite showing a red shift of optical absorption with increasing number of layers due to an increased electronic coupling of plasmons. For understanding phenomena that accompany the effect of plasmonic nanoparticles on the optoelectronic behavior of the composites we prepared a more defined system consisting of a metal NPs layer prepared by physical vapor deposition onto surface of spin-cast thin films of poly(3-hexylthiophene). Gold or silver deposited in a very thin layer formed a nanoparticles-like island structure with the morphology depending on the effective thickness of the deposited layer and on its subsequent thermal treatment. Particularly, we focused on the changes of the electrical conductivity of the polymer/NPs composite system measured during temperature cycling (annealing), and on its relation to morphology of the same composite structures monitored by TEM and extra-high resolution SEM microscopy. Comparison to the analogous polystyrene/AuNP layers was made in order to distinguish the role of the polymer support on the morphology and electrical properties of the nanoparticles assembly. The electrical conductivity and optical properties were found to be strongly related to the morphology of the Au NP surface layer, reflecting the thermodynamical behavior of the polymer during thermal annealing, namely the glass transition and melting of the polymer structure. A stabilizing effect of the thiophene-gold interaction on the nanoparticles morphology was observed. By embedding the Au or Ag NPs, having strong optical extinction in the wavelength interval from 450 nm to 570 nm, in the active layer of P3HT-fullerene bulk heterojunction solar cell, we changed the photovoltaic spectrum of incident photon to collected charge ratio. Besides that, it was shown that in the cells with Au NPs the power conversion efficiency under white light illumination was improved by about 25%. By careful control of the nanoparticles formation we were able to exclude the effects of variation of the plasmonic resonance frequency and possible effects of incident light scattering that would increase the interaction pathway of light within the active polymer. We attributed the observed increase in photovoltaic conversion efficiency to a strong local field enhancement around metal nanoparticles that locally increases optical absorption in a surrounding semiconducting polymer. Figure 1 shows the influence of the Ag and Au NPs on the IPCE and volt-amp characteristics of P3HT/PCBM solar cells. In the case of Au nanoparticles, a clear increase in the power conversion efficiency under white light illumination was detected. The observed increase in the photovoltaic conversion efficiency was attributed to a strong local optical field enhancement around metal nanoparticles that locally increases light absorption in the surrounding semiconducting polymer. The maximum of this optical absorption was found at the position of the respective plasmon resonance peak. It indicates that the enhancement of the solar cells efficiency occurred due to the localized surface plasmon phenomena.2 Acknowledgement: This work was funded by the Czech Science Foundation under the project No. P108/12/1143 and the Ministry of Education, Youths and Sports of the Czech Republic (COST LD 14011).

Statistical analysis of gold nanoparticle-induced oxidative stress and apoptosis in myoblast (C2C12) cells

Nanoscale gold particles (Au-NPs) with a diameter below 20nm are notably important candidates for various important applications because of their extraordinary quantum size effects. Their high surface area-to-volume ratio facilitates their very high reactivities; therefore, they can be utilised in different ways in biomedical applications. For example, these nanoparticles can penetrate into cells and bind with proteins or DNA and are therefore potential nanostructures employed for sensing and detecting various biological identities. In the present work, we synthesised Au-NPs via a colloidal process using chloroauric acid (HAuCl4·4H2O) and trisodium citrate dihydrate (N3C6H5O7) as a reducing agent. The shape evolution and the structural properties of these NPs were investigated in detail using TEM and high resolution HR-TEM investigations. Different doses of Au NPs have been applied to treat C2C12 myoblast cells in a 24-h incubation period, and a dose-dependent study has also been performed. The cells were cultivated in DMEM with FBS and antibiotics (strepto-penicillin) at 37°C in a 5% humidified environment of CO2 and 95% air. Cell viability analysis using MTT assays revealed that increased concentration of Au NPs (100–1000ng/mL) resulted in a decreased density of cells. The amount of reactive oxygen species (ROS) in C2C12 cells analysed with Au-NPs (in a dose-dependent manner), and the RT-PCR data demonstrated the up-regulation of caspase-3 and caspase-7 genes in C2C12 cells after treatment with Au-NPs. These results have been confirmed by detailed confocal microscopy (CLSM) studies. In addition, the quantitative analysis of the Au-NPs was also confirmed by statistical analytical parameters, such as precision, accuracy, linearity, limits of detection (LOD) and limit of quantitation (LOQ), quantitative recoveries and relative standard deviation (RSD), and the analyses again exhibited a significant and large effect of Au NPs on C2C12 cells.

Cyclic Plastic Response and Damage in Materials for High Temperature Applications*

The characteristic changes of the cyclic plastic stress-strain response of stainless steel and superalloys derived from the analysis of hysteresis loop at different temperatures are reported. The evolution of the surface relief in strain controlled cycling is documented using high resolution SEM and TEM. The mechanisms leading to cyclic strain localization, formation of surface relief, fatigue crack initiation and early crack growth are discussed. The study of the low cycle fatigue behavior of these materials was concentrated mostly to the analysis of the stress-strain response, internal structures, fatigue life and crack growth (1-3). In recent years, considerable attention has been attracted to the study of the early damage mechanisms in crystalline materials, starting with the cyclic slip localization and resulting finally in the initiation of fatigue cracks and their early growth (4, 5). In this contribution, the methods allowing to study the sources of cyclic stress and early fatigue damage at room and elevated temperatures are presented and used to reveal details of the mechanisms of cyclic plastic straining and fatigue damage evolution in austenitic steels and nickel superalloys. 1. Cyclic Plastic Stress-Strain Response. Cyclic plasticity of materials is usually studied in strain- controlled cycling with constant strain rate, since stress response of the material depends not only on temperature but also on the strain rate. In a standard low cycle fatigue experiment, several specimens are cycled in a symmetrical cycle with constant total or plastic strain amplitudes, and their stress response is recorded and evaluated. Hysteresis loops can be stored in computer memory, and stress, strain and plastic strain amplitudes are evaluated during the fatigue life. The plot of the stress amplitudes vs. number of loading cycles represents the fatigue hardening/softening curves. The plot of the saturated stress amplitude (or stress amplitude at half-life) vs. strain or plastic strain amplitude represents the cyclic stress-strain curve. In order to find the sources of the cyclic stress, more detailed analysis is necessary. Hysteresis loop and the analysis of its shape using the generalized statistical theory (6) can yield information on the sources of the cyclic

Towards High Resolution in TEM and STEM: What are the Limitations and Achievements

Towards High Resolution in TEM and STEM: What are the Limitations and Achievements

Synthesis of air stable silver nanoparticles and their application as conductive ink on paper based flexible electronics

Air stable silver nanoparticles (NPs) at a high concentration (up to 0·2M) were synthesised by the reduction in Ag+ ions with glucose in cetyltrimethylammonium bromide (CTAB) solutions, for preparing nano-Ag ink applicable for direct writing on photo paper using a gel ink pen. The reaction was performed at room temperature, and the input of extra inert gas was not necessary. The UV/vis spectrum exhibited an absorption band at 413 nm, revealing the formation of Ag NPs. By the analysis of X-ray diffraction (XRD), the resultant particles were confirmed to be pure Ag with a face centred cubic structure. From the (high resolution) TEM analysis, it was found that the mean diameter of Ag NPs was 16·5 nm, and the morphology of the particles exhibited highly crystalline nature. In addition, the excess of CTAB was effective in reducing the aggregation and size of the Ag NPs and in improving their air stability. The reduced size and enhanced air stability of the Ag NPs resulted in an improved particle density upon sintering, which was mainly responsible for the increased conductivity of the Ag patterns. The resistivity of Ag patterns sintered at 160°C for 2 h was 6·8±0·8 μΩ cm, 4·2 times the bulk resistivity. A sample paper based electrode and circuits were successfully made, and all of them exhibited excellent flexibility and good conductivity, which can be used as part of some flexible electronic devices, such as triboelectronic generator, solar cells and radio frequency identification antenna, etc.

Effect of Cold Rolling on Microstructure and Mechanical Properties of an Al-Mg-Sc-Zr Alloy

The microstructural evolution and mechanical properties of an Al-5.4Mg-0.4Mn-0.2Sc-0.09Zr alloy subjected to cold rolling with a total strain up to ~1.6 was studied using high resolution EBSD analysis and TEM. It was shown that cold rolling induces elongation of initial grains and the formation of deformation bands along rolling direction in addition to dramatic increase in density of lattice dislocations. Two types of deformation bands evolve. Deformation bands initially bounded by low-angle boundaries (LABs) with misorientation higher than 2o and spacing ranging from 0.8 to 4 μm gradually transform to lamellas delimited by high-angle boundaries (HABs). Thin deformation bands delimited by LABs with misorientation of 2o or less evolve within these coarse bands. First type of deformation bands is subdivided due to mutual intersection with second order deformation bands or shear bands to elongated crystallite evolving to micron scale grains with strain. The thin deformation bands may be also subdivided to nanoscale crystallites. It was shown that the formation of well-defined deformation bands yield very high anisotropy in strength and ductility, while a strong increase in lattice dislocation density with strain diminishes this anisotropy.

Evolution of a martensitic structure in a Cu–Al alloy during processing by high-pressure torsion

A Cu-11.8 wt% Al alloy was quenched in iced water from a high temperature (850 °C) to introduce a martensitic phase and then the alloy was processed using quasi-constrained high-pressure torsion (HPT). The micro-hardness and the microstructures of the unprocessed and severely deformed materials were investigated using a wide range of experimental techniques (X-ray diffraction, optical microscopy, scanning electron microscopy, transmission electron microscopy, and high- resolution TEM). During HPT, a stress-induced martensite–martensite transformation occurs and an \( \alpha^{\prime}_{1} \) martensite phase is formed. In the deformed material, there are nanoscale deformation bands having high densities of defects and twins in the \( \alpha^{\prime}_{1} \) martensite. It was observed that a high density of dislocations became pinned and accumulated in the vicinity of twin boundaries, thereby demonstrating a strong interaction between twin boundaries and dislocations during the HPT process.