A Rapid Photopatterning Method for Selective Plating of 2D and 3D Microcircuitry on Polyetherimide

In this work, a method for the rapid synthesis of metallic microtracks on polyetherimide is presented. The method relies on the photosynthesis of silver nanoparticles on the surface of the polymer substrates from photosensitive silver chloride (AgCl), which is synthesized directly on the polyetherimide surface. The study reveals that the use of AgCl as a photosensitive intermediate accelerates the reactions leading to the formation of silver nanoparticles by up to two orders of magnitude faster than other photodecomposition schemes. The patterning can be conducted under blue light, with notable advantages over UV exposure. Polymers of significant interest to the microelectronics and 3D printing industries can be directly patterned by light using this photography‐inspired technique at throughputs high enough to be commercially advantageous. Light exposures as short as a few seconds are sufficient to allow the direct metallization of the illuminated polyetherimide surface. The results show that the silver required for the seed layer is minimal, and the later copper electroless plating results in the selective growth of conductive tracks for circuitry on the light‐patterned areas, both on flexible films and 3D printed surfaces.     

Does early responsive parenting have a special importance for children's development or is consistency across early childhood necessary?

The role of early versus ongoing maternal responsiveness in predicting cognitive and social development was examined in home visits for mothers, full-term children (n?=?103), and medically low-risk (n?=?102) and high-risk (n?=?77) preterm children at 5 ages. There were 4 maternal clusters based on warm and contingent responsiveness behaviors observed early (at 6, 12, and 24 months) and late (at 3 and 4 years): high early, high late; high early, low late; low early, moderate late; and low early, low late. Children, especially preterm children, showed faster cognitive growth when mothers were consistently responsive. Social growth was similar in the consistently responsive (high-high) and the early-responsive inconsistent (high-low) clusters, but greater deceleration at 4 years among children with mothers in the inconsistent cluster refuted the notion of a unique role for early responsiveness. The importance of consistent responsiveness, defined by an affective-emotional construct, was evident even when a broader constellation of parenting behaviors was considered. (PsycINFO Database Record (c) 2010 APA, all rights reserved)     

Defect microstructure in heavy-ion-bombarded (0 0 0 1) ZnO

Radiation defects in oxides are complex and remain poorly understood. Here, we use transmission electron microscopy to study ZnO crystals bombarded at room temperature with heavy ions (500 keV Xe). Results reveal that the damage evolution proceeds via the formation of a band of cavities centered on ～7 nm from the sample surface. With further irradiation, a layered structure is formed, with alternating near-stoichiometric and Zn-rich layers. The anomalous intermediate peak and step in ion channeling spectra are attributed to a Zn-rich defect band and an interface between stoichiometric and Zn-rich layers, respectively. To explain these observations, we propose a damage build-up scenario involving vacancy clustering, loss of O from the surface, and peculiarities of point-defect transport through a Zn-rich defect band toward the surface.     

The production of amorphous regions in carbon nanotubes by 140 keV He ion irradiation

The production of amorphous regions in carbon nanotubes irradiated with 140 keV He ions was studied using Raman spectroscopy and transmission electron microscopy (TEM). Intensity ratios of Raman D to G bands (I_D/I_G) initially increase and then decrease as a function of ion fluence at all investigated irradiation temperatures (room temperature, 200 and 400 °C). The critical ion fluences corresponding to the maximum in I_D/I_G ratios increase with increasing irradiation temperature because of the enhanced defect annealing. The displacement per atom (dpa) values, consistent with a maximum in I_D/I_G ratios, are determined to be 0.15 dpa at room temperature and 200 °C, and 0.3 dpa at 400 °C. TEM examination of all irradiated specimens supports Raman results indicating that the maximum in I_D/I_G correlates to the formation of amorphous regions. The study shows that after formation of amorphous regions at high fluences, I_D/I_G ratio can be no longer used to measure amorphous/graphitic content in CNTs.     

Understanding the phase equilibrium and irradiation effects in Fe–Zr diffusion couples

We have studied the radiation effects in Fe–Zr diffusion couples, formed by thermal annealing of a mechanically bonded binary system at 850 °C for 15 days. After irradiation with 3.5 MeV Fe ions at 600 °C, a cross sectional specimen was prepared by using a focused-ion-beam-based lift out technique and was characterized using scanning/transmission electron microscopy, selected-area diffraction and X-ray energy dispersive spectroscopy analyses. Comparison studies were performed in localized regions within and beyond the ion projected range and the following observations were obtained: (1) the interaction layer consists of FeZr₃, FeZr₂, Fe₂Zr, and Fe₂₃Zr₆; (2) large Fe₂₃Zr₆ particles with smaller core particles of Zr-rich Fe₂Zr are found within the α-Fe matrix; (3) Zr diffusion is significantly enhanced in the ion bombarded region, leading to the formation of an Fe–Zr compound; (4) grains located within the interaction layer are much smaller in the ion bombarded region and are associated with new crystal growth and nanocrystal formation; and (5) large α-Fe particles form on the surface of the Fe side, but the particles are limited to the region close to the interaction layer. These studies reveal the complexity of the interaction phase formation in an Fe–Zr binary system and the accelerated microstructural changes under irradiation.     

Mesenchymal Stem Cell-Based Therapy for Rheumatoid Arthritis

Mesenchymal stem cells (MSCs) have great potential to differentiate into various types of cells, including but not limited to, adipocytes, chondrocytes and osteoblasts. In addition to their progenitor characteristics, MSCs hold unique immunomodulatory properties that provide new opportunities in the treatment of autoimmune diseases, and can serve as a promising tool in stem cell-based therapy. Rheumatoid arthritis (RA) is a chronic systemic autoimmune disorder that deteriorates quality and function of the synovium membrane, resulting in chronic inflammation, pain and progressive cartilage and bone destruction. The mechanism of RA pathogenesis is associated with dysregulation of innate and adaptive immunity. Current conventional treatments by steroid drugs, antirheumatic drugs and biological agents are being applied in clinical practice. However, long-term use of these drugs causes side effects, and some RA patients may acquire resistance to these drugs. In this regard, recently investigated MSC-based therapy is considered as a promising approach in RA treatment. In this study, we review conventional and modern treatment approaches, such as MSC-based therapy through the understanding of the link between MSCs and the innate and adaptive immune systems. Moreover, we discuss recent achievements in preclinical and clinical studies as well as various strategies for the enhancement of MSC immunoregulatory properties.     

Defect formation and annealing kinetics in ion irradiated carbon nanotube buckypapers

We studied the frequency shifts in G, D and D^* Raman modes in freestanding multiwall carbon nanotube buckypapers. Upon ion irradiation by 140 keV He⁺ or 3 MeV H⁺ ions, the intensity ratio of D–G modes linearly increases with fluence before amorphization. The ratio is used to quantitatively measure the level of disorder in the buckypaper. The study shows that, upon post-irradiation annealing, defect removal requires little energy addition in lightly damaged buckypaper, which is evidenced by an activation energy of 0.36 eV. Once amorphized, defect removal becomes very difficult. The D–G intensity ratio has no reduction in heavily damage sample after annealing up to 850 °C.     

Towards Bridging the Experimental Length-Scale Gap for Tensile Tests on Structural Materials: Lessons Learned from an Initial Assessment of Microtensile Tests and the Path Forward

JOM - Microtensile testing of structural materials offers several advantages over conventional mesoscale tests, including the ability to target specific areas of interest and directly correlate the...