Using Non-Destructive Testing to Predict Bending Modulus of Carbon Infiltrated-Carbon Nanotubes

Fagergren, Fred Stile

01 December 2018

Fabrication of carbon infiltrated carbon nanotubes (CI-CNT) can result in large mechanical property variation, and methods to characterize properties usually involve destructive testing. Finding a non-destructive way to test for stiffness of this material reduces the number of parts that have to be made. It also simplifies testing of complex parts. The stiffness of CI-CNT beams is related to the type of carbon material infiltrated between the carbon nanotubes (CNTs), how it interacts with the CNTs, and how much of it there is. The amount of material can be estimated using the density of the beam, and both the type of material and its interaction with the carbon nanotubes can be approximated through analysis of the Raman spectra taken at the surface. A combination of these two observations can be related to the effective material stiffness. The relationship can be fitted with a power function, with a variance of 1.41 GPa, which is about 11% of the maximum stiffness of the samples tested. This variance is similar to the larger variations in CI-CNT beam stiffnesses found in a single batch of beams.

Raman Spectroscopy

density

Carbon Nanotubes

CI-CNT

Bending Modulus

beam

Mechanical Engineering

Biophysics of Blood Membranes

Himbert, Sebastian

11 1900

Red blood cells (RBCs) are the predominant cell type in blood and have a two-layered outer shell which is composed of a cytoskeleton network tethered to a cytoplasmic membrane. In this thesis, I study the structure and mechanical properties of the RBC’s cytoplasmic membrane (RBCcm) on the nanoscale and utilize this knowledge to functionalize this biological structure on a molecular level. In a first case study, I measure the membrane’s bending rigidity from thermal fluctuations observed in X-ray diffuse scattering (XDS) and Neutron Spin Echo (NSE) experiments, as well as Molecular Dynamics (MD) simulations. I provide evidence of the RBCcm's highly deformable nature with a bending rigidity that is substantially softer as compared to synthetic membranes. The methods are applied to RBCs that were stored for up to 5 weeks. I demonstrate that storage of RBCs leads to an increased fraction of liquid ordered membrane domains and an increased bending rigidity. RBCs are ideal for pharmaceutical applications as they provide access to numerous targets in the body, however lack specificity. Functionalizing the cytoplasmic membrane is thus a prerequisite to use these cells in biotechnology. I develop protocols throughout two studies to tune the membrane's lipid and protein composition. I investigate the impact of synthetic lipid molecules on the membrane's structure and demonstrate that small molecules can be encapsulated into liposomes that are formed from these hybrid membranes. Further, I provide direct evidence that the SARS-CoV 2 spike protein can be anchored into the RBCcm through a detergent mediated insertion protocol. These virus-like particles are observed to trigger seroconversion in mouse models, which demonstrates the potential of functionalized RBC in biotechnology. / Thesis / Doctor of Philosophy (PhD)

Blood

Membrane

Biophysics

Bending Modulus

Red Blood Cell Membrane

Covid 19

Functionalized Membranes

Hybrid Membranes

Effect of surfactant structure on properties of oil/water interfaces : A coarse-grained molecular simulation study.

Rekvig, Live

January 2004

<p>The elastic properties of oil/water/surfactant interfaces play an important role in the phase behaviour of microemulsions and for the stability of macroemulsions. The aim of this thesis is to obtain an understanding of the relationship between the structure of the surfactant molecules, the structure of the interface, and macroscopic interfacial properties. To achieve this aim, we performed molecular simulations of oil/water/surfactant systems. We made a quantitative comparison of various model surfactants to determine how structural changes affect interfacial properties and film rupture. The model consists of water, oil, head, and tail beads, and surfactants are constructed by coupling head and tail beads with harmonic springs. We used a hybrid dissipative particle dynamics-Monte Carlo scheme. The former was used to simulate particle trajectories and the Monte Carlo scheme was used to mimic experimental conditions: bulk-interface phase equilibrium, tensionless interfaces in microemulsions, and the surface force apparatus.</p><p>A detailed comparison of various non-ionic model surfactants showed how structural changes affect interfacial properties:</p><p>Comparison between linear and branched surfactants showed that the efficiency of adsorption is higher for linear surfactants, although branched surfactants are more efficient at a given surface density. Linear surfactants can be more efficient also at the same surface density if the head group is sufficiently soluble in oil, because low head-oil repulsion makes the branched isomers stagger at the interface. The bending rigidity is higher for linear surfactants. Furthermore, branched surfactants make oil droplets coalesce more easily than linear surfactants do, but linear and branched surfactants have roughly the same effect on water droplet coalescence. </p><p>Comparison of linear surfactants with varying chain lengths showed that longer surfactants have a lower surface tension and higher bending rigidity. The increase in rigidity with chain length follows a power law, but the exponent is higher for surfactant monolayers at a fixed density than at a fixed tension. Longer tails and/or denser monolayers influence the stability of water droplets in a positive direction, and the stability of oil droplets in a negative direction. </p><p>Addition of cosurfactant showed that mixed monolayers have a lower bending rigidity than pure monolayers at the same average chain length and tension. Cosurfactants have a negative effect on the stability of water droplets, and a positive effect on the stability of oil droplets.</p> / Paper I reprinted with kind permission of EDP Sciences. Paper III reprinted with kind permission of the American Institute of Physics. Paper IV reprinted with kind permission of the American Physics Society.

Surfactants

amphiphiles

oil/water interfaces

molecular simulations

dissipative particle dynamics

emulsions

emulsion stability

surface tension

bending modulus

Chemistry

Kemi

Chemistry

Kemi

Effect of surfactant structure on properties of oil/water interfaces : A coarse-grained molecular simulation study.

Rekvig, Live

January 2004

The elastic properties of oil/water/surfactant interfaces play an important role in the phase behaviour of microemulsions and for the stability of macroemulsions. The aim of this thesis is to obtain an understanding of the relationship between the structure of the surfactant molecules, the structure of the interface, and macroscopic interfacial properties. To achieve this aim, we performed molecular simulations of oil/water/surfactant systems. We made a quantitative comparison of various model surfactants to determine how structural changes affect interfacial properties and film rupture. The model consists of water, oil, head, and tail beads, and surfactants are constructed by coupling head and tail beads with harmonic springs. We used a hybrid dissipative particle dynamics-Monte Carlo scheme. The former was used to simulate particle trajectories and the Monte Carlo scheme was used to mimic experimental conditions: bulk-interface phase equilibrium, tensionless interfaces in microemulsions, and the surface force apparatus. A detailed comparison of various non-ionic model surfactants showed how structural changes affect interfacial properties: Comparison between linear and branched surfactants showed that the efficiency of adsorption is higher for linear surfactants, although branched surfactants are more efficient at a given surface density. Linear surfactants can be more efficient also at the same surface density if the head group is sufficiently soluble in oil, because low head-oil repulsion makes the branched isomers stagger at the interface. The bending rigidity is higher for linear surfactants. Furthermore, branched surfactants make oil droplets coalesce more easily than linear surfactants do, but linear and branched surfactants have roughly the same effect on water droplet coalescence. Comparison of linear surfactants with varying chain lengths showed that longer surfactants have a lower surface tension and higher bending rigidity. The increase in rigidity with chain length follows a power law, but the exponent is higher for surfactant monolayers at a fixed density than at a fixed tension. Longer tails and/or denser monolayers influence the stability of water droplets in a positive direction, and the stability of oil droplets in a negative direction. Addition of cosurfactant showed that mixed monolayers have a lower bending rigidity than pure monolayers at the same average chain length and tension. Cosurfactants have a negative effect on the stability of water droplets, and a positive effect on the stability of oil droplets. / Paper I reprinted with kind permission of EDP Sciences. Paper III reprinted with kind permission of the American Institute of Physics. Paper IV reprinted with kind permission of the American Physics Society.

Surfactants

amphiphiles

oil/water interfaces

molecular simulations

dissipative particle dynamics

emulsions

emulsion stability

surface tension

bending modulus

Chemistry

Kemi

Chemistry

Kemi

Nondestructive assessment of flexural and tensile properties for southern pine structural lumber

Carmona Uzcategui, Marly Gabriela

09 August 2022

The flexural and tensile properties of visually graded southern yellow pine lumber were modeled. Longitudinal and transverse vibration techniques and proof-loading bending tests were used to assess the flexural and tensile properties of southern pine lumber. The properties evaluated were dynamic modulus of elasticity (dMOE), static modulus of elasticity (Eb), tension modulus of elasticity (Et), and ultimate tensile stress (UTS). The tensile properties were evaluated in the direction parallel to the grain. This study presents the results of tests conducted on No. 2 2 × 6 and 2 × 10 southern pine lumber of two different lengths (14 ft. and 16 ft.). The results of the analysis show that nondestructive testing techniques are excellent to assess Et and Eb. Moderate relationships were found between dMOE and UTS and between Eb and UTS. Improvements in the prediction of UTS were done with the inclusion of additional parameters into the model. The combination of dMOE, density, and frequency domain area (FDA) generated the highest coefficient of determination for UTS. The distributions of flexural and tensile properties were analyzed for the goodness of fit. Normal distribution was found for Eb data whereas the lognormal distribution was the best fit for the tensile properties.

bending modulus of elasticity

tensile properties

longitudinal vibration

transverse vibration

southern pine

structural lumber

Other Forestry and Forest Sciences

Wood Science and Pulp, Paper Technology