Learning from e-family history : online research behaviour and strategies of family historians and implications for local studies collections

Friday, Kate

January 2012

The massive expansion of electronic resources has been identified as one of the major drivers behind the ‘explosion’ in the popularity of family history, which bring ease, convenience and accessibility to some parts of the research process. Amongst this expanse of easily-accessible raw materials, online local studies materials (recording both historical and contemporary aspects of a community) can add real context and value to researchers’ findings and experience; turning a genealogy into a family history. However, the vast majority of these do not appear visible to online family history researchers. Through three central foci (users, e-family history resources, and Local Studies Collections), this research investigates these resources and collections from the perspective of users, to establish how to make the added value of the local studies collections more visible and encourage increased engagement for those who cannot visit collections in person. Specific evaluative criteria for e-family history resources are presented, contributing to practitioners’ awareness and understanding of their nature; in turn helping maintain their service quality to researchers. Using a hybrid (primarily ethnographic) research approach, the study also examines the online research behaviour of family historians, identifying a taxonomy of actions (seeking of genealogical facts, local or social history; communicating with other researchers or resources; locating resources or instructive information; managing own information), strategies (search modifications and incorporation of background knowledge) and outcomes (outcome; direction (projected and actual)). From these categories, a model of Family Historians’ online information seeking has been developed. Researchers have both informational and affective needs, and are highly emotionally attached to the research process. Users universally used Ancestry, FamilySearch, ScotlandsPeople, and Genes Reunited far more than other sites, seeking out quality informational content and unique records, which must be successful for researchers. Google was a major method of access to these. Very few participants were preaware of ‘e-local studies’ websites, and were surprised by the variations in quality, inconsistencies in terminology and navigation, and invisibility of quality content. Despite a lack of ease of use, the content present on e-local studies sites and their usefulness and value had been demonstrated to researchers. This suggests significant demand for local information of this kind online where it is available and made known.

929.1

Stress Analysis for Chip Scale Packages with Embedded Active Devices under Thermal Cycling

Yeo, Hyunwook

13 June 2014

One of the main challenges in the electronics manufacturing and packaging development is how to integrate more functions inside the same or even smaller size. To meet the demand for higher integration, the interest toward passive and active component embedding has been increasing during the past few years. One of the main reasons for the growing interest toward embedded active components, in addition to demand for higher packaging density, is the need for better electrical performance of the component assemblies. However, it is little known how embedded IC and passives affect the reliability of IC packaging. Solder joints have been used in the electronic industry as both structural and electrical interconnections between electronic packages and printed circuit boards (PCB). When solder joints are under thermal cyclic loading, mismatch in coefficients of thermal expansion (CTE) between the printed circuit boards and the solder balls creates thermal strains and stresses on the joints, which may finally result in cracking. Consequently, the mechanical interconnection is lost, leading to electrical failures (such as hard/intermittent open, parametric failure), which in turn causes malfunction of the circuit or whole system. When a die is embedded into a substrate, Young's modulus of the die is larger than one of the core of the substrate and the CTEs of the die is smaller than those of the substrate. As a result, mismatch in coefficients of thermal expansions (CTE) between the substrate with the embedded device and the solder balls may increase. In the present study, the stress of chip scale packages (CSP) with an embedded die under thermal cycling conditions is evaluated using the finite element method. The viscoplastic model for solders including matrix dislocation mechanism and grain boundary sliding model developed by Yi et al. (2002) is employed.

Chip scale packaging

Electronic packaging

Electronics -- Materials -- Research

Manufacturing

Materials Science and Engineering

Mechanical Engineering

An investigation into the non-adoption of soil-cement bricks by the community of the Kei District

Williams, Nomsa

January 2002

Thesis (M. Dev.) -- University of Limpopo, 2002 / Refer to document

Soil-cement bricks

Rural development

Rural development -- South Africa

Brick houses -- South Africa

Design and characterization of materials with microphase-separated surface patterns for screening osteoblast response to adhesion

Wingkono, Gracy A.

21 August 2009

A study on application of combinatorial methods (CM) and high-throughput methods (HTM) to biomaterials design, characterization, and screening are reported in this thesis - focusing on screening the effects of biomaterial surface features on adherent bone cell cultures. Polymeric biomaterials were prepared on two-dimensional combinatorial libraries that systematically varied the size and shape of chemically-distinct microstructural patterns - generated from blends of biodegradable polyurethanes and polyesters. Characterization and screening were performed with high-throughput optical and fluorescence microscopy. A unique advance of this work is the application of data mining techniques to identify the controlling structural features that affect cell behavior from among the myriad variety of metrics from the microscope images. The results from this study demonstrated the potentials of CM/HTS to be applied to exploratory studies involving complex systems in life sciences. This study accomplishes the goal to demonstrate the efficient screening and exploration of vast and complex dataset, extracting important and meaningful information to narrow down the future path of study in this field. Further study aimed to tuning cellular responses via signals from surface cues will be necessary to examine the causal relationships beyond the observed correlations shown in this exploratory study. It is recommended for further studies to narrow down the range for surface patterning around each of the three 'activation' ranges found in this study: apoptotic, viable, and one unknown state to be studied further. Different cellular-function staining methods will be necessary to be used in cellular imaging techniques in order to explore this unknown state further.

Blend

Polymer

Combinatorial chemistry

High-throughput

Screening

Biocompatible

Biodegradable

Biomaterial

Surface pattern

Biomedical materials

Materials Research

Tissue engineering

Biocompatibility

Annual Report 2012 - Institute of Ion Beam Physics and Materials Research

08 May 2013

In 2012 the HZDR, and in consequence also the Institute of Ion Beam Physics and Materials Research (IIM) including its Ion Beam Center (IBC), has undergone a scientific evaluation. The evaluation committee composed of the Scientific Advisory Board and numerous external experts in our field of research concluded that “the overall quality of the scientific work is excellent”, that “there are an impressive number of young scientists working enthusiastically on a variety of high-level projects” and that “the choice of these projects represents a clear underlying strategy and vision”. We feel honored and are proud that the external view on our scientific achievements is that extraordinary. In view of this outstanding result we would like to express our gratitude to all our staff members for their commitment and efforts! In the past year, we continued our integration into the Helmholtz Association of German Research Centers (HGF) with our Institute mostly active in the research area “Matter”, but also involved in a number of activities in the research area “Energy”. In this respect, many consultations were held with the Helmholtz centers contributing to common research areas to precisely define the role we will play in the newly established HGF program “From Matter to Materials and Life” (see schematic below). Our IBC has been recognized as a large-scale user facility for ion beam analysis and modification of materials, i.e., specializing on materials science. In particular, the IBC plays a prominent role in the recently approved Helmholtz Energy Materials Characterization Platform (HEMCP), which mainly concentrates on the development of dedicated analytical tools for the characterization of materials required for future energy technologies. The successes achieved by the IBC allows us to invest 7200 k€ to further improve and strengthen the ion beam capabilities at the Institute. In addition to this infrastructure-related grant, we were also successful in our funding application for the establishment of the International Helmholtz Research School for Nanoelectronic Networks (IHRS NANONET), aiming at promoting the next generation of leading scientists in the field of nanoelectronics. The IHRS NANONET is coordinated by our Institute and offers a well-structured PhD program to outstanding students of all nationalities with emphasis on interdisciplinary research and comprehensive training in technical and professional skills.

Jahresbericht 2012

Annual Report 2012

ddc:539

Annual Report 2014 - Institute of Ion Beam Physics and Materials Research

23 July 2015

This past year 2014 was the year when we finally completely arrived as a “full member” in the Helmholtz Association. This is related to the successfully passed research evaluation in the framework of the Program Oriented Funding (POF), which will give us a stable and predictable funding for the next five years (2015 – 2019). This is particularly true for our large-scale user facilities, like the Ion Beam Center (IBC) and the electron accelerator ELBE with the free-electron laser. Most of our activities are assigned to the program “From Matter to Materials and Life” within the research area “Matter”, in cooperation with several other German Helmholtz Centers. Our in-house research is performed in three so-called research themes, as depicted in the schematic below. What is missing there for simplicity is a small part of our activities in the program “Nuclear Waste Management and Safety” within the research area “Energy”. Our research and facilities were well appreciated by the evaluation committee, who made the following judgement about the Ion Beam Center: “The Ion Beam Centre (IBC) of HZDR is an internationally leading ion-beam facility (with ion energies ranging from several eV to several tens of MeV). At both the national and international level it is one of the key players and is unique in its kind. The synergy between forefront research and user service has been leading to a very good publication output for both in-house research and user research. … The very broad range of beam energies, the versatility of techniques and applications – both for ion beam modification of materials and for ion-beam analysis – makes the IBC unique in its kind. … The strength of IBC is that its activities are based on a combination of forefront research and user service, which mutually interact in synergy and strengthen one another. In turn, this synergy has been leading to a very good publication output for both in-house research and user research.” In order to make our Annual Report a bit more compact, we have decided to include only four full journal papers this year. This was also triggered by the fact that our publication activities have turned out be become more diverse, in more diverse journals than in the past, and often through longer papers, which would be too long to reprint them here. However, apart from the constantly quantitatively high publication output, we succeeded to publish in excellent journals such as Nature Physics, Nano Letters and Physical Review Letters, in fields as diverse as ion beam physics, magnetism and terahertz spectroscopy. Two of our scientists, Dr. Artur Erbe and Dr. Alexej Pashkin obtained their Habilitation in 2014, both at University of Konstanz. For the first time, we are hosting an Emmy Noether Young Investigator Group funded by the Deutsche Forschungsgemeinschaft (DFG); the group works on the hot topic of magnonics and is headed by Dr. Helmut Schultheiß. Finally we would like to cordially thank all partners, friends, and organizations who supported our progress in 2014. Special thanks are due to the Executive Board of the Helmholtz-Zentrum Dresden-Rossendorf, the Minister of Science and Arts of the Free State of Saxony, and the Minister of Education and Research of the Federal Government of Germany. Numerous partners from universities, industry and research institutes all around the world contributed essentially, and play a crucial role for the further development of the institute. Last but not least, the directors would like to thank again all IIM staff for their efforts and excellent contributions in 2014.

Jahresbericht 2014

Annual Report 2014

ddc:539

Annual Report 2011 - Institute of ion Beam Physics and Materials Research

Cordeiro, A. L., Helm, M.

January 2012

The first year of membership of the Helmholtz-Zentrum Dresden-Rossendorf (HZDR) in the Helmholtz Association of German Research Centers (HGF) was a year of many changes also for the Institute of Ion Beam Physics and Materials Research (IIM). The transition period, however, is not yet over, since the full integration of the Center into the HGF will only be completed in the next period of the so-called program-oriented funding (POF). This funding scheme addresses the six core research fields identified by the Helmholtz Association (Energy; Earth and Environment; Health; Key Technologies; Structure of Matter; Aeronautics, Space and Transport) to deal with the grand challenges faced by society, science and industry. Since the Institute has strong contributions to both core fields “Key Technologies” and “Structure of Matter”, intense discussions were held amongst the leading scientists of the Institute, across the Institutes of the HZDR, and finally with leading scientists of other Helmholtz centers, to determine the most appropriate classification of the Institute’s research. At the end we decided to establish ourselves in Structure of Matter, the core field in which most of the large-scale photon, neutron and ion facilities in Germany are located. As a consequence, the Ion Beam Center (IBC) of the Institute submitted an application to become a HGF recognized large-scale facility, providing more than 50% of its available beam time to external users. This application perfectly reflects the development of the IBC over more than a decade as a European Union funded infrastructure in the framework of the projects “Center for Application of Ion Beams in Materials Research (AIM)” (1998-2000, 2000-2003, 2006-2010) and subsequently as the coordinator of the integrated infrastructure initiative (I3) “Support of Public and Industrial Research using Ion Beam Technology (SPIRIT)” (2009-2013). Another part of the Institute’s activities is dedicated to exploit the infrared/THz free-electron laser at the 40 MeV superconducting electron accelerator ELBE for condensed matter research. This facility is also open to external users and funded by the European Union.

info:eu-repo/classification/ddc/539

ddc:539

Materials selection and evaluation of Cu-W particulate composites for extreme electrical contacts

Watkins, Bobby Gene, II

21 January 2011

Materials for extreme electrical contacts need to have high electrical conductivity coupled with good structural properties. Potential applications include motor contacts, high power switches, and the components of electromagnetic launch (EML) systems. In particular, the lack of durability of these materials in rail components limits practical EML implementation. These rails experience significant amounts of Joule heating, due to extreme current densities, and subsequent thermally-assisted wear. New more durable materials solutions are needed for these components. A systematic materials selection study was executed to identify and compare candidate materials solutions. Several possible candidate non-dominated materials as well as hybrid materials that could potential fill the "white spaces" on the Ashby charts were identified. A couple potential candidate materials were obtained and evaluated. These included copper-tungsten W-Cu, "self-lubricating" graphite-impregnated Cu, and Gr-W-Cu composites with different volume fractions of the constituents. The structure-property relations were determined through mechanical and electrical resistivity testing. A unique test protocol for exposing mechanical test specimens to extreme current densities up to 1.2 GA/m2 was developed and used to evaluate these candidate materials. The systematic design of multi-functional materials for these extreme electrical contacts requires more than an empirical approach. Without a good understanding of both the tribological and structural performance, the optimization of the microstructure will not be quickly realized. By using micromechanics modeling and other materials design modeling tools coupled with systematic mechanical and tribological experiments, the design of materials for these applications can potentially be accelerated. In addition, using these tools, more complex functionally-graded materials tailored to the application can be systematically designed. In this study, physics- and micromechanics-based models were used to correlate properties to the volume fraction of the constituents of the evaluated candidate materials. Properties correlated included density, elastic modulus, hardness, strength, and electrical resistivity of the W-Cu materials.

Electrical conductivity

Hybrid materials design

Tensile property evaluation

Ashby method

Railgun

Effective property modeling

Electric conductivity

Electric conductors

Materials

Materials Analysis

Materials Research

Processing and characterization of carbon black-filled electrically conductive nylon-12 nanocomposites produced by selective laser sintering

Athreya, Siddharth Ram

24 February 2010

Electrically conductive polymer composites are suitable for use in the manufacture of antistatic products and components for electronic interconnects, fuel cells and electromagnetic shielding. The most widely used processing techniques for producing electrically conductive polymer composites place an inherent constraint on the geometry and architecture of the part that can be fabricated. Hence, this thesis investigates selective laser sintering (SLS), a rapid prototyping technique, to fabricate and characterize electrically conductive nanocomposites of Nylon-12 filled with 4% by weight of carbon black. The objective of the dissertation was to study the effects of the SLS process on the microstructure and properties of the nanocomposite. The effect of laser power and the scan speed on the flexural modulus and part density of the nanocomposite was studied. The set of parameters that yielded the maximum flexural modulus and part density were used to fabricate specimens to study the tensile, impact, rheological and viscoelastic properties. The electrical conductivity of the nanocomposite was also investigated. The thermo-mechanical properties and electrical conductivity of the nanocomposites produced by SLS were compared with those produced by extrusion-injection molding. The structure and morphology of the SLS-processed and extrusion-injection molded nanocomposites were characterized using gas pycnometry, gel permeation chromatography, differential scanning calorimetry, electron microscopy, polarized light microscopy and x-ray diffraction. Physical models were developed to explain the effects of the processing technique on the structure and properties of the nanocomposites. Finally, a one-dimensional heat transfer model of the SLS process that accounted for sintering-induced densification and thermal degradation of the polymer was implemented in order to study the variation in part density with respect to the energy density of the laser beam. This dissertation demonstrated that SLS can be successfully used to fabricate electrically conductive polymer nanocomposites with a relatively low percolation threshold. This capability combined with the ability of SLS to fabricate complicated three-dimensional objects without part-specific tooling could open up several new opportunities.

Electrical conductivity

Selective laser sintering

Structure-property relationships

Nylon-12

Carbon black

Thermo-mechanical properties

Laser fusion

Manufacturing processes

Nanocomposites (Materials)

Materials Research

Incorporation of protease-sensitive biomaterial degradation and tensile strain for applications in ligament-bone interface tissue engineering

Yang, Peter J.

02 November 2011

The interface between tendon/ligament and bone tissue is a complex transition of biochemical, cellular, and mechanical properties. Investigating computational and tissue engineering models that imitate aspects of this interface may supply critical design parameters for designing future tissue replacements to promote increased biochemical and mechanical integration between tendon/ligament and bone. Strategies for modeling this tissue have typically focused on the development of heterogeneous structures to create gradients or multiphasic materials that mimic aspects of the transition. However, further work is required to elucidate the role of specific mechanical and material stimuli in recapitulating features of the tendon/ligament-bone insertion. In particular, in constructs that exhibit variation in both mechanical and biochemical properties, the interplay of mechanical, material, and chemical signals can complicate understanding of the particular factors at work in interface formation. Thus, the overall goal of this dissertation was to provide insight into the role of mechanical strain and scaffold degradability on cell behavior within heterogeneous biomaterials. Specifically, a method for determining cell vertical position within a degradable gel through a laminated interface was developed. A computational model was created to examine possible variation in local mechanical strain due to heterogeneity in mechanical properties and different interface geometries. Finally, the influence of biomaterial degradability on changes in encapsulated human mesenchymal stem cell morphology under response to cyclic mechanical strain was explored. Together, these studies provide insight into mechanical and material design considerations when devising tissue engineering strategies to regenerate the tendon/ligament-bone interface.

PEG hydrogels

Soft tissue biomaterials

Tissue engineering

Tendon and ligament

Regenerative medicine

Regeneration (Biology)

Guided tissue regeneration

Biomedical materials

Biomedical materials Research

Colloids