Clifford Goodman

Bio: Clifford Goodman is an academic researcher. The author has an hindex of 1, co-authored 1 publications receiving 431 citations.

Interfacial Microstructure and Properties of Carbon Fiber Composites Modified with Graphene Oxide

Abstract: The performance of carbon fiber-reinforced composites is dependent to a great extent on the properties of fiber–matrix interface. To improve the interfacial properties in carbon fiber/epoxy composites, we directly introduced graphene oxide (GO) sheets dispersed in the fiber sizing onto the surface of individual carbon fibers. The applied graphite oxide, which could be exfoliated to single-layer GO sheets, was verified by atomic force microscope (AFM). The surface topography of modified carbon fibers and the distribution of GO sheets in the interfacial region of carbon fibers were detected by scanning electron microscopy (SEM). The interfacial properties between carbon fiber and matrix were investigated by microbond test and three-point short beam shear test. The tensile properties of unidirectional (UD) composites were investigated in accordance with ASTM standards. The results of the tests reveal an improved interfacial and tensile properties in GO-modified carbon fiber composites. Furthermore, significa...

Magnesia-Based Cements: A Journey of 150 Years, and Cements for the Future?

Abstract: This review examines the detailed chemical insights that have been generated through 150 years of work worldwide on magnesium-based inorganic cements, with a focus on both scientific and patent literature. Magnesium carbonate, phosphate, silicate-hydrate, and oxysalt (both chloride and sulfate) cements are all assessed. Many such cements are ideally suited to specialist applications in precast construction, road repair, and other fields including nuclear waste immobilization. The majority of MgO-based cements are more costly to produce than Portland cement because of the relatively high cost of reactive sources of MgO and do not have a sufficiently high internal pH to passivate mild steel reinforcing bars. This precludes MgO-based cements from providing a large-scale replacement for Portland cement in the production of steel-reinforced concretes for civil engineering applications, despite the potential for CO2 emissions reductions offered by some such systems. Nonetheless, in uses that do not require steel reinforcement, and in locations where the MgO can be sourced at a competitive price, a detailed understanding of these systems enables their specification, design, and selection as advanced engineering materials with a strongly defined chemical basis.

Stiffness at small strain: research and practice

Abstract: This paper provides the background to the 50th Rankine Lecture. It considers the growth in emphasis of the prediction of ground displacements during design in the past two decades of the 20th century, as a result of the lessons learnt from field observations. The historical development of the theory of elasticity is then described, as are the constitutive frameworks within which it has been proposed that geotechnical predictions of deformation should be carried out. Factors affecting the stiffness of soils and weak rocks are reviewed, and the results of a numerical experiment, assessing the impact of a number of stiffness parameters on the displacements around a retaining structure, are described. Some field and laboratory methods of obtaining stiffness parameters are considered and critically discussed, and the paper concludes with a suggested strategy for the measurement and integration of stiffness data, and the developments necessary to improve the existing state of the art.

Lipids in freshwater ecosystems

Abstract: 1. Determination of Total Lipid, Lipid Classes, and Fatty Acids in Aquatic Samples.- 1.1. Introduction.- 1.2. Results and Discussion.- 1.2.1. Sampling and Storage.- 1.2.2. Lipid Extraction.- 1.2.3. Determination of Total Lipid.- 1.2.4. Determination of Lipid Classes.- 1.2.5. Determination of Fatty Acids and Carbon Number Profiles.- 1.3. Conclusion.- References.- 2. Fatty Acids as Trophic and Chemical Markers in Freshwater Ecosystems.- 2.1. Introduction.- 2.2. Nomenclature.- 2.3. Characteristics of Fatty Acid Markers for Trophic Studies.- 2.4. Primary Sources and Trophic Transfer of Fatty Acids.- 2.4.1. Fatty Acid Composition of Algae and Cyanobacteria.- 2.4.2. Fatty Acids as Trophic Markers of Algae and Cyanobacteria.- 2.4.3. Fatty Acid Composition of Bacteria.- 2.4.4. Fatty Acids as Trophic Markers of Bacteria.- 2.4.5. Fatty Acid Markers from Allochthonous Sources.- 2.4.6. Fatty Acids as Trophic Markers in Vertebrates.- 2.5. Research Needs.- 2.6. Conclusions.- References.- 3. Irradiance and Lipid Production in Natural Algal Populations.- 3.1. Introduction.- 3.2. Metabolism and Reallocation.- 3.2.1. Lipids in Relation to Other Macromolecular Classes.- 3.2.2. Diel Versus Light-Phase Allocation and Synthesis.- 3.2.3. Budgets for Overnight Activity.- 3.2.4. Reallocation Among Lipid Classes.- 3.3. Irradiance and Lipid Synthesis.- 3.3.1. Photosynthetic Parameters.- 3.3.2. Light Saturation Parameter, Ik.- 3.3.3. Production Efficiency Parameter, ?.- 3.3.4. Areal Lipid Production.- 3.3.5. Implications of the Irradiance Response.- 3.4. Conclusions.- 3.5. Research Directions.- References.- 4. Lipids in Freshwater Zooplankton: Selected Ecological and Physiological Aspects.- 4.1. Introduction.- 4.2. Usefulness of Areal Energy Reserve Estimates.- 4.3. Time Course of Lipid Deposition/Loss.- 4.4. Lipids as Indices of Stress.- 4.4.1. Ratio of Storage to Membrane Lipids.- 4.4.2. Maternal Lipid Investment.- 4.4.3. Visible Lipid Energy Stores.- 4.4.4. Fatty Acid Composition and Abundance.- 4.5. Ultraviolet Radiation and Zooplankton Lipids.- 4.6. Research Needs and Suggested Future Directions.- 4.6.1. Geographical Disparities.- 4.6.2. Physicochemical Disparities.- 4.6.3. Essential Fatty Acids.- 4.6.4. Effects of Temperature Changes.- 4.6.5. Diapause.- 4.6.6. Lipids as Allelopathic Compounds and Chemical Feeding Deterrents.- 4.7. Conclusions.- References.- 5. Lipid Dietary Dependencies in Zooplankton.- 5.1. Introduction.- 5.2. Methods.- 5.2.1. Microparticle Preparation.- 5.2.2. Dietary Supplement Experiments.- 5.2.3. Characterization of the Natural Algal Diet.- 5.2.4. Algal Counting and Autoradiography.- 5.3. Results.- 5.3.1. Supplement Experiments with Natural Populations.- 5.3.2. Lake Waynewood Experiment: October 1989.- 5.3.2.1. Algal Diet.- 5.3.2.2. Response byDaphnia.- 5.4. Discussion.- References.- 6. Seasonal Dynamics of Lipids in Freshwater Benthic Invertebrates.- 6.1. Introduction.- 6.2. Results and Discussion.- 6.2.1. Slope and Profundal Zones.- 6.2.1.1. Crustacea: Amphipoda.- 6.2.1.2. Mysidacea.- 6.2.2. Shelf and Nearshore Zones.- 6.2.2.1. Crustacea: Amphipoda.- 6.2.2.2. Annelida: Oligochaeta.- 6.2.2.3. Insecta.- 6.2.2.4. Mollusca: Bivalvia.- 6.3. Research Needs.- 6.4. Conclusions.- References.- 7. Ecological Role of Lipids in the Health and Success of Fish Populations.- 7.1. Introduction.- 7.2. Results and Discussion.- 7.2.1. Overwinter Starvation and Survival.- 7.2.2. Energy Allocation Strategies.- 7.2.3. Reproductive Development and Early Life History.- 7.2.4. Lipids and Environmental Stress.- 7.2.4.1. Contaminant Effects.- 7.2.4.2. Thermal Effects.- 7.2.4.3. Other Stressors.- References.- 8. Lipids and Essential Fatty Acids in Aquatic Food Webs: What Can Freshwater Ecologists Learn from Mariculture?.- 8.1. Introduction.- 8.2. Results and Discussion.- 8.2.1. Some Important Lipids and Fatty Acids.- 8.2.1.1. Essential Fatty Acids.- 8.2.1.2. Lipid Classes.- 8.2.2. Methodological Considerations.- 8.2.3. Physiological Requirements of Marine Animals.- 8.2.3.1. General Evaluation of EFA Requirements.- 8.2.3.2. Anabolic Processes and Growth.- 8.2.3.3. Membrane Transport and Metabolism.- 8.2.3.4. Regulation of Metabolism.- 8.2.3.5. General Considerations and Concluding Remarks.- 8.2.4. Methods for Evaluation of EFA Requirements.- 8.2.5. Symptoms of EFA Deficiency.- 8.2.6. Fatty Acid Transport and Metabolism in Food Webs.- 8.2.6.1. Algae.- 8.2.6.1.1. Lipids of Algae.- 8.2.6.1.2. Essential Fatty Acids of Algae.- 8.2.6.1.3. Conclusion.- 8.2.6.2. Zooplankton.- 8.2.6.2.1. Lipid Content and Lipid Composition.- 8.2.6.2.2. Fatty Acids of TAG-Zooplankton.- 8.2.6.3. Fish.- 8.2.6.3.1. Lipid.- 8.2.6.3.2. Fatty Acid Composition.- 8.2.6.4. General Conclusions.- 8.2.7. Relevance of Mariculture Research.- 8.2.8. Evaluation of Ecological Effects of Essential Fatty Acids.- 8.3. Concluding Remarks.- References.- 9. Influence of Lipids on the Bioaccumulation and Trophic Transfer of Organic Contaminants in Aquatic Organisms.- 9.1. Introduction.- 9.1.1. Sources of Contaminant Gain and Loss in Aquatic Systems.- 9.1.2. Organism Adiposity and Internal Distribution of Contaminants.- 9.1.3. Nonlipid Factors Affecting Internal Distributions.- 9.2. Prediction of Bioconcentration and Bioaccumulation.- 9.2.1. Bioconcentration.- 9.2.2. Bioaccumulation.- 9.3. Factors Affecting Prediction.- 9.3.1. Methods for Measuring Lipid Content.- 9.3.2. Lipid Composition and Bioaccumulation.- 9.4. Mimicking Bioconcentration with Semipermeable Membrane Devices.- 9.5. Toxicity and the Role of Lipid.- 9.5.1. Release of Sequestered Contaminant During Metabolism.- 9.5.2. Lipids and Membrane Narcosis.- 9.5.3. Effect of Toxins on Lipid Metabolism and Function.- 9.6. Relevance of Food Chain Transfer to Bioaccumulation.- 9.6.1. Relevance of Trophic Transfer to Bioaccumulation...- 9.6.2. Role of Lipids in Food Chain Accumulation.- 9.6.2.1. Fugacity Model.- 9.6.2.2. Mechanism for Trophic Transfer.- 9.6.3. Factors Affecting Trophic Transfer.- 9.6.3.1. Assimilation Efficiency.- 9.6.3.2. Miscellaneous Factors Affecting Assimilation.- 9.7. Biomagnification and Organism Lipids.- 9.7.1. Is Biomagnification Real?.- 9.7.2. A Lipid-Based Model for Biomagnification.- 9.7.3. Current Issues in Biomagnification and Relationship to Lipids.- 9.8. Lipids and Transgenerational Transfer of Contaminants.- 9.9. Conclusions.- References.- 10. Lipids in Water-Surface Microlayers and Foams.- 10.1. Introduction.- 10.2. Basic Physicochemistry of Surface Microlayers.- 10.3. Basic Structure of Foams.- 10.4. Sampling Techniques.- 10.5. Physicochemical Processes at the Surface Microlayers.- 10.6. Lipids in the Water-Surface Microlayers and Foams.- 10.6.1. Total Lipids and Major Lipid Classes.- 10.6.2. Fatty Acids.- 10.7. Research Needs.- 10.8. Final Remarks.- References.- 11. Comparison of Lipids in Marine and Freshwater Organisms.- 11.1. Introduction.- 11.2. Discussion.- 11.2.1. Lipid Classes.- 11.2.2. Sterols and Cholesterol.- 11.2.3. Wax Esters and Triacylglycerols.- 11.2.4. Fatty Acids.- 11.2.5. Furan and Some Other Unusual Fatty Acids.- 11.2.6. Ether Lipids.- 11.2.7. Prostanoids.- 11.3. Conclusions.- References.

High Shear Strain of Olivine Aggregates: Rheological and Seismic Consequences

Abstract: High-pressure and high-temperature torsion experiments on olivine aggregates in dislocation creep show about 15 to 20% strain weakening before steady-state behavior, characterized by subgrain-rotation recrystallization and a strong lattice preferred orientation. Such weakening may provide a way to focus flow in the upper mantle without a change in deformation mechanism. Flow laws derived from low strain data may not be appropriate for use in modeling high strain regions. In such areas, seismic wave propagation will be anisotropic with an axis of approximate rotational symmetry about the shear direction. In contrast to current thinking, the anisotropy will not indicate the orientation of the shear plane in highly strained, recrystallized olivine-rich rocks.