Adhesion Studies of Polymers: (I) Autohesion of Ethylene/1-Octene Copolymers; (II) Method Development and Adhesive Characterization of Pressure Sensitive Adhesive in Paper Laminates for Postage Stamps

Yang, Hailing

08 May 2006

Autohesion is defined as the resistance to separation of two bonded identical films that have been joined together for a period of time under a given temperature and pressure. Studies on the autohesion phenomenon can provide fundamental insights into the physical processes of adhesive bond and failure, as well as the practical engineering issues such as crack healing, elastomer tack, polymer fusion, self-healing, and polymer welding. In the first part of this dissertation work, four ethylene/1-octene (EO) copolymers were used in the present study consisting of molecules with linear polyethylene backbone to which hexyl groups are attached at random intervals. These copolymers have similar number-average molecular weight (Mn) and polydispersity, but different 1-octene content. These hexyl groups act as the short branches and hinder the crystallization, reduce density to some extent in the solid state, lower the melting temperature, and decrease the stiffness of the bulk materials. A full understanding of the autohesion behavior of the ethylene/1-octene copolymers involves investigations at three different length scales: 1) the molecular scale which controls the interfacial structure; 2) the mesoscopic or microscopic scale which can provide information on the formation of interfaces and on how the energy is dissipated during a fracture process; and 3) the macroscopic scale at which the mechanical properties such as fracture energy can be obtained for a particular test geometry. In the present study, the effects of the branch content on the formation and fracture of the interface of these ethylene/1-octene assemblies were evaluated at the bonding temperatures (Tb) and bonding times (tb). The correlation among these three length scales was also investigated and modeled. The adhesion strength of these symmetric interfaces of EO copolymers was investigated by T-peel fracture tests. The fracture of the interface is an irreversible entropy creating process which involved a substantial amount of energy dissipation. The results of such mechanical tests with respect to the bonding temperature (Tb), bonding time (tb) and peel rate indicated this energy dissipation is the result of a complicated interplay between the ability of the interface to transfer stress and its plastic and viscoelastic deformation properties. When Tb is much higher than the characteristic temperature (Tc), the interfaces were completely healed and cohesive failure was observed in T-peel tests. In this case, the fracture strength decreased with increasing branch content. In contrast, when Tb is very close to Tc, the fracture strength showed an increase with the branch content with either interfacial failure or cohesive failure being observed depending on the branch content and Tb. At higher peel rates, it is observed that higher peel energies are required to fracture the surfaces. Transmission electron microscopy (TEM) showed that the interfacial/interphase structure changed from amorphous to crystalline with an increase in the Tb. The results from the bonding time effect studies showed that the peel energy is proportional to tb1/2 regardless of Tb. But the branch content and the Tb play an important role on the seal rate. Thus, higher seal rate was found for higher Tb and higher branch content. These results also suggest that the autohesion of ethylene/1-octene copolymers are strongly associated with the interactions of melted chains. The chain compositions of these Zeigler-Natta EO copolymers are highly heterogeneous with the branches concentrated in the lower molecular weight portion. Long linear chain segments could form large, well-ordered crystals that provide strong anchors for the tie molecules and therefore determine the density of inter-crystalline links. Short chains with lots of branches could behave as protrusions along the chain to obstruct chain disentanglement and limit a chain from sliding through a crystal. Due to these reasons, the short chains with branches would contribute much less than the long linear chains to the full peel strength after complete sealing. However, higher peel strengths could be obtained only at the higher temperatures or longer bonding times at which the long linear chains begin to melt and diffuse across the interface. On the other hand, the higher branch content samples have the lower crystallinity and could obtain the higher chain mobility at the lower bonding temperatures and with shorter bonding times. Therefore, higher seal strength was observed for the higher branch content samples at lower Tb. Following T-peel fracture tests of ethylene/1-octene copolymer assemblies which showed interfacial failures, the fractured surfaces were investigated by using Atomic Force Microscopy (AFM) and characterized by fractal analysis together with the original films. The AFM images showed strong dependence on the peel rate and branch content. Quantitatively, the fractal analyses demonstrated fractal characteristics at the different finite scales. Two regimes showing fractal features were identified for each surface. In regime I (low magnifications) the fracture test did not change the fractal dimensions much. But there were significant changes in regime II before welding and after T-peel fracture tests. The length scale that separated these two regimes is very close to the size of lamellar structures. The characteristic sizes at which the fractal characteristics emerge were shown to appear at larger scales for surfaces fractured at higher peel rates. This suggests that the appearance of fractal behavior at larger scales requires higher fracture energies. The characteristic sizes and fractal dimensions were shown to depend on the molecular structure. Because the fractal analysis suggests at least some crystalline lamellae on the surfaces still existed during T-peel fracture tests, a "Stitch-welding" has been therefore proposed as the autohesion mechanism in which only chains in the amorphous portions could inter-diffuse. In the second part of this dissertation work, a multi-layer lap-shear geometry has been designed and proven as a reliable testing method in evaluation of the dynamical mechanical properties of polyacrylic pressure sensitive adhesive (PSA) in paper lamination for postage stamp applications. In-situ testing of four different PSA stamp laminates constructed by laminating water-based polyacrylic PSAs to the stamp face papers were carried out using a dynamic mechanical analyzer (DMA) in the temperature range from -50 to 60 oC at frequencies 0.1, 1, 10, and 100 Hz. This geometry requires the tension mode on the DMA, but the results which were recorded as tensile properties were converted to shearing properties of the PSA layers in the laminate. The effect of the thickness (layers of laminates) on the dynamical mechanical properties has been studied and the results suggested that a multi-layer geometry with 5-10 layers could be an appropriate structure to produce enhanced responses. Therefore, the geometry with 8-layer laminates was used for frequency sweep/isothermal temperature and frequency sweep/temperature step tests. The results showed three relaxation responses that is, glassy, transition, and flow regions with respect to the frequencies and temperatures. These results also implied the viscoelastic characteristics of these PSA products. The tensile properties of the face papers were also tested using the same parameters as those of the multi-layer geometry. Significant differences were found between the shearing behaviors of the multi-layer geometry and the tensile behaviors of the elastic face paper. This suggests that the tensile deformation of the face paper in the multi-layer geometry could be ignored and the elastic paper did not contribute to the shearing properties of the PSA layers. Time-temperature superposition curves have been produced with reference temperature set at 23 oC, which can be used to predict the long term and short term performances of these samples at this temperature. This method can be utilized as a standard testing method on the PSA adhesives in the laminate form. In addition to the dynamic mechanical properties, it can also be developed to be a general standard method on testing the rheological properties of adhesives, polymer melts and other viscous materials. / Ph. D.

Autohesion

Postage Stamp

Viscoelsticity

Fractals Analysis

Pressure-Sensitive Adhesive

LLDPE

Fracture

Multilayer Lap-shear

Ethylene/1-Octene Copolymers

Time-Temperature Superposition

Analysis of PAH and PCB Emissions from the Combustion of dRDF and the Nondestructive Analysis of Stamp Adhesives

Poslusny, Matthew

05 1900

This work includes two unrelated areas of research. The first portion of this work involved combusting densified refuse derived fuel (dRDF) with coal and studying the effect that Ca(0H)2 binder had on reducing polycyclic aromatic hydrocarbon (PAH) and polychlorinated biphenyl (PCB) emissions. The second area of work was directed at developing nondestructive infrared techniques in order to aid in the analysis of postage stamp adhesives. With Americans generating 150-200 million tons a year of Municipal Solid Waste (MSW) and disposing of nearly ninety percent of it in landfills, it is easy to understand why American landfills are approaching capacity. One alternative to landfilling is to process the MSW into RDF. There are technical and environmental problems associated with RDF. This work provides some answers concerning the amount of PAH and PCB emissions generated via the combustion of RDF with coal. It was found that the Ca(OH)2 binder greatly reduced both the PAH and the PCB emissions. In fact, PAH emissions at the ten-percent level were reduced more by using the binder than by the pollution control equipment. If the Ca(0H)2 binder can reduce not only PAH and PCB emissions, but also other noxious emissions, such as acid gases or dioxin, RDF technology could soon be the answer to the current landfill problems. The second portion of this work focused on developing a method to analyze stamp adhesives nondestructively. Using this method, it was fairly easy to differentiate among the three different types of adhesives that have been used by the United States Postal Service: gum arabic, dextrin, and polyvinyl alcohol. Differences caused by changes in chemicals added to the adhesives were also detected. Also, forgeries were detected with as much success, if not more, than by conventional methods. This work also led to the construction of equipment that allows large samples to be analyzed by reflectance infrared methods.

densified refuse derived fuel

adhesives

chemistry

polycyclic aromatic hydrocarbon

polychlorinated biphenyl

Refuse as fuel -- Environmental aspects.

Polycyclic aromatic hydrocarbons.

Polychlorinated biphenyls.

Adhesives -- Analysis.

History Will Be My Judge: A Cultural Examination of America's Racial Tensions Presented Through the Symbolization of Booker T. Washington

Keturah C Nix (8088539)

06 December 2019

<i> History Will Be My Judge: A Cultural Examination of America's Racial Tensions Presented Through the Symbolization of Booker T. Washington</i> is an interdisciplinary study about the emergence of Booker T. Washington as a black cultural hero. By the turn of the twentieth century, Washington had become the most prominent African American educator, economic reformer, entrepreneur, and race leader in the United States. He is most recognized as the founder of Tuskegee Institute (now University) and his highly acclaimed autobiography, <i>Up From Slavery</i>, which recounts his life growing up enslaved to becoming an international icon. Since his death in 1915, several monuments, memorials, landmarks, and commemorative tributes have been established in his honor. During the 1940s, Washington became the first African American pictured on the United States postage stamp and minted silver half-dollar. Additionally, he was spotlighted in a series of media campaigns called "Famous American Firsts," and was the first African American inducted into the Hall of Fame for Great Americans. Moreover, amidst the presidential transition between Barack Obama and Donald Trump, black popular media has alluded to Washington's economic philosophy through music videos, documentaries, and television programs. I argue that each of these posthumous commemorations belong to larger social justice movements, namely, the Civil Rights movement and Black Lives Matter movement. Throughout these eras, Washington's legacy has served to counter white supremacy and symbolize the rise of integration, the black middle class, economic justice, black self-made, black education, and the legacy of slavery.<div> The purpose of this study is to examine how during periods of racial unrest, African Americans leverage Booker T. Washington's image to counter racist stereotypes and reaffirm black citizenship. The primary framework applied in this study is William L. Van Deburg's theory of the <i>black cultural hero. </i>Two emergent theories from this research are my developing frameworks called <i>Black Hustle Theory</i> and <i>nostalgic tension</i>. Using literary and visual analysis, I assess historical archives from popular press, black literature, American memorabilia, and black popular culture to examine Washington's commemorative legacy through a black radical lens. Specifically, I explore how the following four people have connected Washington's legacy to the Civil Rights movement and Black Lives Matter movement: Major Richard Robert Wright, Sr., founder of Savannah State University; Langston Hughes, famed Harlem Renaissance poet and author; Stanley Nelson, award-winning producer; and, Beyonce Knowles-Carter, singer and pop mogul. I put Washington's legacy in conversation with each of these cultural producers to simulate a call-and-response between his lifework and the generations after him.<br><div><br></div></div>

History

Race and Ethnic Relations

Booker T. Washington

Langston Hughes

Beyonce Knowles-Carter

Major Richard Robert Wright, Sr.

Tuskegee

Civil Rights Movement

Lemonade

Black Lives Matter

Tell Them We Are Rising

HBCU

black popular culture

commemoration

white supremacy

W.E.B. Du Bois

Stanley Nelson

black cultural hero

race

racism

Frederick Douglass

Black Hustle Theory

nostalgic tension

Up From Slavery

postage stamp

self-made

slavery

economic justice