Assembly of an Ionic-Complementary Peptide on Surfaces and its Potential Applications

Yang, Hong

25 September 2007

Self-assembling peptides have emerged as new nanobiomaterials and received considerable attention in the areas of nanoscience and biomedical engineering. In this category are ionic-complementary peptides, which contain a repeating charge distribution and alternating hydrophobic and hydrophilic residues in the amino acid sequence, leading to the unusual combination of amphiphilicity and ionic complementarity. Although their self-assembled nanostructures have been successfully applied as scaffoldings for tissue engineering, novel materials for regenerative medicine and nanocarriers for drug and gene/siRNA delivery, aspects of the assembly process remain unclear. Since many of these applications involve peptide-modified interfaces and surfaces, a better understanding and control of the peptide assembly on a surface are very crucial for future development of peptide-based applications in nano-biotechnology. This thesis contains two major parts: (i) fundamental study of the assembly of a model ionic-complementary peptide EAK16-II on surfaces and (ii) potential applications of such a peptide in surface modification and nanofabrication. In the fundamental study, EAK16-II assembly on negatively charged mica was first investigated via in-situ Atomic Force Microscopy (AFM). It was found that EAK16-II nanofiber growth on mica is surface-assisted and follows a nucleation and growth mechanism involving two steps: (i) adsorption of nanofibers and fiber clusters (from the bulk solution) on the surface to serve as the seeds and (ii) fiber elongation from the active ends of the seeds. Such a process can be controlled by adjusting the solution pH since it modulates the adsorption of the seeds and the growth rates. Unlike what is observed on mica, EAK16-II formed well-ordered nanofiber patterns with preferential orientations at angles of 60° or 120° to each other on hydrophobic highly ordered pyrolytic graphite (HOPG) surfaces, resembling the crystallographic structure of the graphite. Nanofiber formation on HOPG is also surface-assisted and adopts a nucleation and growth mechanism that can be affected by solution pH. The pH-dependent adsorption of peptides to HOPG is attributed to the resulting changes in peptide hydrophobicity. It was also found that EAK16-II assembly can be induced by the mechanical force of a tapping AFM tip. It occurs when the tip cuts the adsorbed EAK16-II nanofibers into segments that then serve as seeds for new nanofiber growth. This finding allows one to locally grow nanofibers at specific regions of the surface. The tip cutting has been combined with the effect that solution pH has on peptide assembly to develop a new AFM lithography method to fabricate local patterned peptide nanostructures on HOPG. To study the use of EAK16-II for surface modification applications, the wettability and stability of the peptide-modified surfaces were characterized. EAK16-II-modified mica becomes slightly hydrophobic as the water contact angle increases from <10° to 20.3 ± 2.9°. However, the hydrophobicity of the HOPG surface is significantly reduced, as reflected in a contact angle change from 71.2 ± 11.1° to 39.4 ± 4.3°. The EAK16-II-modified mica surface is stable in acidic solution, while the modified HOPG surface is stable in both acidic and alkaline solutions. The peptide-modified HOPG shows potential as a biocompatible electrode for (bio)molecular sensing. The ability of EAK16-II to form nanofibers on surfaces has also promoted research on peptide-based metallic nanowire fabrication. Our approach is to provide EAK16-II with metal ion binding ability by adding a GGH motif to the C-terminus. This new peptide EAK16(II)GGH has been found to form one-dimensional nanofibers while binding to Cu2+ ions. The dimensions of the nanofibers were significantly affected by the nature of the anions (SO42-, Cl- and NO3-) in the copper salt solution. This work demonstrates the potential usage of EAK16-II for nanowire fabrication.

Self-assembling peptide

Surface-assisted assembly

Surface modification

AFM tip nanolithography

Metallic nanowire fabrication

Chemical Engineering

The Design Of A Nanolithographic Process

Johannes, Matthew Steven

02 July 2007

This research delineates the design of a nanolithographic process for nanometer scale surface patterning. The process involves the combination of serial atomic force microscope (AFM) based nanolithography with the parallel patterning capabilities of soft lithography. The union of these two techniques provides for a unique approach to nanoscale patterning that establishes a research knowledge base and tools for future research and prototyping.To successfully design this process a number of separate research investigations were undertaken. A custom 3-axis AFM with feedback control on three positioning axes of nanometer precision was designed in order to execute nanolithographic research. This AFM system integrates a computer aided design/computer aided manufacturing (CAD/CAM) environment to allow for the direct synthesis of nanostructures and patterns using a virtual design interface. This AFM instrument was leveraged primarily to study anodization nanolithography (ANL), a nanoscale patterning technique used to generate local surface oxide layers on metals and semiconductors. Defining research focused on the automated generation of complex oxide nanoscale patterns as directed by CAD/CAM design as well as the implementation of tip-sample current feedback control during ANL to increase oxide uniformity. Concurrently, research was conducted concerning soft lithography, primarily in microcontact printing (µCP), and pertinent experimental and analytic techniques and procedures were investigated.Due to the masking abilities of the resulting oxide patterns from ANL, the results of AFM based patterning experiments are coupled with micromachining techniques to create higher aspect ratio structures at the nanoscale. These relief structures are used as master pattern molds for polymeric stamp formation to reproduce the original in a parallel fashion using µCP stamp formation and patterning. This new method of master fabrication provides for a useful alternative to conventional techniques for soft lithographic stamp formation and patterning. / Dissertation

Engineering, Mechanical

Engineering, Materials Science

Atomic force microscope

Soft Lithography

Anodization

Microcontact Printing

Nanolithography

Nanotechnology

Inkless Soft Lithography: Utilizing Immobilized Enzymes and Small Molecules to Pattern Self-Assembled Monolayers Via Catalytic Microcontact Printing

Vogen, Briana Noelle

January 2010

<p>During the past two decades, soft lithographic techniques that circumvent the limitations of photolithography have emerged as important tools for the transfer of patterns with sub-micron dimensions. Among these techniques, microcontact printing (uCP) has shown special promise. In uCP, an elastomeric stamp is first inked with surface-reactive molecules and placed in contact with an ink-reactive surface, resulting in pattern transfer in the form of self-assembled monolayers in regions of conformal contact. The resolution in uCP is ultimately limited to the diffusion of ink and the elastomechanical properties of the bulk stamping material. </p> <p>One way to improve resolution is to eliminate diffusion by using inkless methods for pattern transfer. Inkless catalytic-uCP uses a chemical reaction between a stamp-immobilized catalyst and surface bearing cognate substrate to transfer pattern in the areas of conformal contact. By using pre-assembled cognate surfaces, the approach extends the range of surfaces readily amenable to patterning while obviating diffusive resolution limits imposed by traditional uCP. </p> <p>In this thesis, we report two methods using inkless catalytic uCP: biocatalytic-uCP utilizes an immobilized enzyme as a catalyst whereas catalytic-uCP utilizes an immobilized small molecule as a catalyst, such as an acid or base. Both catalytic techniques demonstrate pattern transfer at the microscale while using unconventional, acrylate-based stamp materials. Previous results produced with catalytic-uCP have shown pattern transfer with sub-50 nm edge resolution. In this demonstration of catalytic-uCP, we use the technique to demonstrate a bi-layered patterning technique for H-terminated silicon, the foremost material in semi-conductor fabrication. This technique simultaneously protects the underlying silicon surface from degradation while a highly-reactive organic overlayer remains patternable by acidic-functionalized PU stamps. Lines bearing widths as small as 150 nm were reproduced on the reactive SAM overlayer, which would not be possible without circumvention of diffusion. Before and after patterning, no oxidation of the underlying silicon was observed, preserving desired electronic properties throughout the whole process. This bi-patterning technique could be extended to other technologically-relevant surfaces for further application in organic-based electronic devices and other related technologies.</p> / Dissertation

Chemistry, Organic

Engineering, Materials Science

inkless lithography

inkless soft lithography

microcontact printing

microlithography

nanolithography

soft lithography

High Aspect-Ratio Nanoscale Etching in Silicon using Electron Beam Lithography and Deep Reactive Ion Etching (DRIE) Technique

Perng, John Kangchun

05 July 2006

This thesis reports the characterization and development of nanolithography using Electron Beam Lithography system and nanoscale plasma etching. The standard Bosch process and a modified three-pulse Bosch process were developed in STS ICP and Plasma ICP system separately. The limit of the Bosch process at the nanoscale regime was investigated and documented. Furthermore, the effect of different control parameters on the process were studied and summarized in this report. 28nm-wide trench with aspect-ratio of 25 (smallest trench), and 50nm-wide trench with aspect ratio of 37 (highest aspect-ratio) have been demonstrated using the modified three-pulse process. Capacitive resonators, SiBAR and IBAR devices have been fabricated using the process developed in this work. IBARs (15MHz) with ultra-high Q (210,000) have been reported.

Plasma etching

Sensors

RF

Resonators

Nanolithography

MEMS

Microelectromechanical systems

Plasma etching

Nanotechnology

Lithography, Electron beam

Micro/nanopatterning approaches for molecular manipulation

Liu, Zhan

11 November 2010

Nanotechnology has a steadily increasing impact on worldwide research and business activities. This work explores advanced micro/nano patterning approaches for molecular manipulation. The objectives are to (1) build a proper bridge from a few microns to the 100-10 nm range and below as well as to (2) combine “top-down” precise design with the “bottom-up” size scale to create designed surfaces, areas and volumes that can interact with molecules in a designed way. Three studies were designed and studied accordingly. The first investigation demonstrates that “top-down” Inclined Nanoimprinting Lithography (INIL) is able to produce three-dimensional (3-D) nanopatterns of varying heights in a single step. INIL reduces pattern's feature size from microns to nanometers. The degree of resulting nanopattern's asymmetry can be controlled by the magnitude of the inclination angle. Various 3-D nanostructures are successfully demonstrated including nanolines, nanocircles and nanosquares. The underlying INIL mechanism is investigated, which is primarily due to the induced shear force when the inclination angle is not zero. This leads to the anisotropic dewetting of polymer fluid and consequently asymmetric 3D nanopatterns of varying heights. INIL removes the need of preparation of expensive 3D nanotemplates or multiple template-to-substrate alignments. In addition, such 3-D structures are successfully transferred to silicon, silicone rubber and metal gold. INIL enables 3D nano-scale devices including angle-resolved photonic and plasmonic crystals. The second investigation demonstrates the success of “bottom-up” molecular imprinting of X-ray contrast agent iodixanol in polymer matrix. The synthetic tailor-made molecularly imprinted polymers (MIPs) are poly(4-vinylpyridine-co-ethylene glycol dimethacrylate) which possess specific binding sites induced by the template molecules of X-ray contrast agent iodixanol. It leads the feature size reduction from macromolecules to molecular scale. The properly imprinted binding sites also leads MIPs to have improved absorption capacity and efficiency for X-ray contrast agent iodixanol relative to non-imprinted polymers. The best binding capacity achieved from the optimized MIPs was 284 mg/g in aqueous solution, 8.8 times higher than that of the non-imprinted polymers. The best binding capacity obtained in sheep plasma was 232 mg/g, 4.5 times higher than the non-imprinted polymers. The factors that may affect the binding performance of MIPs in aqueous media are studied. The optimized MIPs are encouraging for biomedical implementations including dialysis and nanosensors. The third investigation of nanolithography-based molecular manipulation (NMM) explores a hybrid approach by combining “top-down” electron-beam lithography (EBL) with “bottom-up” surface initiated polymerization (SIP). It reduces the nanopattern's feature size to sub-10 nm and simultaneously tunes its surface chemistry through functional polymer brushes. The process has reduced process complexity and cost. The demonstrated prototype molecular manipulation templates have 3D surface nanostructures with sub-10 nm feature size and anisotropic surface functionalities. They mimic biocatalyst enzymes to “bottom-up” assemble nanoparticle targets at specific locations producing 3D nanostructures in a designated way. Various 3D synthetic nanostructures have been demonstrated including polystyrene “nanomushrooms” “nanospikes”, “nanofibers” and polystyrene-iron oxide “nanoflowers”. Potential applications of these synthetic 3D nanostructures can be improved therapeutic agents. This hybrid strategy realizes the integration of “top-down” design with “bottom-up” molecular scale to create designed nanopatterned surfaces that can interact with molecules in a designated way.

Nanoimprinting

Molecular imprinting

Molecular manipulation

Nanofabrication

Nanostructures

Nanolithography

Nanostructures

Microlithography

Molecular imprinting

Development of solution-processed methods for graphene synthesis and device fabrication

Chu, Hua-Wei

19 May 2011

Various solution-processed methods have been employed in this work. For the synthesis of graphene, a chemical exfoliation method has been used to generate large graphene flakes in the solution phase. In addition, chemical or electro polymerization has been used for synthesizing polyanthracene, which tends to form graphene nanoribbon through cyclodehydrogenation. For the device fabrication, graphene oxide (GO) thin films were deposited from solution phase on the vapor-silanzed aminosilane surface to make semiconducting active layer or conducting electrodes. Gold nanoparticles (AuNPs) were selectively self-assembled from solution phase to pattern nanowires.

Graphene OFET

APTES

Thermochemical nanolithography

Gold nanoparticles

Graphene oxide

Graphene nanoribbon

Graphene

Nanostructured materials

Graphite

Carbon Nanotubes Interactions: Theory and Applications

Popescu, Adrian

01 January 2011

A theoretical framework describing the carbon nanotubes interaction, involving two distinct approaches, is presented. Based on the results obtained practical applications using carbon nanotubes are further proposed. First a classical approach is employed for different geometrical configurations, such as parallel or concentric carbon nanotubes. For all the cases analytical expressions for the systems potential energies are derived. The results obtained using the classical approach are used to propose a few practical applications. These applications include a non-contact device for profiling surfaces and a custom telescopic double wall carbon nanotube for nanolithography applications. It is expected that such devices can be effectively used with major advantages. Next the interaction between nanotubes is considered using a quantum electrodynamics approach suitable for dispersing and absorbing media. Each carbon nanotube is characterized by its individual full dielectric response. The method also allows taking into account the full carbon nanotube cylindrical geometry by imposing the appropriate boundary conditions at the nanotubes surfaces. It is found that at small nanotube separations, similar to their equilibrium distances, the interaction is dominated by the collective excitations in the electron energy loss spectra originating from interband transitions. Furthermore, it is shown that the collective surface excitations and their chirality dependent characteristics play a profound role in the interaction strength in double wall carbon nanotube systems. The obtained results are in good agreement with experimental measurements on determining the chirality of individual double wall carbon nanotubes

chirality

collective excitations

nanolithography

quantum electrodynamics

surface profiling

American Studies

Arts and Humanities

Physics

Structure formation and dynamics in molecularly thin smectic liquid crystal films

Schulz, Benjamin

29 April 2013

No description available.

530

Physik (PPN621336750)

smectic liquid crystals

ultrathin films

free-standing films

single molecule diffusion

nanolithography

Closed-loop nanopatterning and characterization of polymers with scanning probes

Saygin, Verda

24 May 2023

There is a need to discover advanced materials to address the pressing challenges facing humanity, however there are far too many combinations of material composition and processing conditions to explore using conventional experimentation. One powerful approach for accelerating the rate at which materials are explored is by miniaturizing the scale at which experiments take place. Reducing the size of samples has been tremendously productive in biomedicine and drug discovery through standardized formats such as microwell plates, and while these formats may not be the most appropriate for studying polymeric materials, they do highlight the advantages of studying materials in ultra-miniaturized volumes. However, precise and controlled methods for handling diverse samples at the sub-femtoliter-scale have not been demonstrated. In this thesis, we establish that scanning probes can be used as a technique for realizing and interrogating sub-femtoliter scale polymer samples. To do this, we develop and apply methods for patterning materials with control over their size and composition and then use these methods to study material systems of interest. First, we develop a closed-loop method for patterning liquid samples using scanning probes by utilizing tipless cantilevers capable of holding a discrete liquid drop together with an inertial mass sensing scheme to measure the amount of liquid loaded on the probe. Using these innovations, we perform patterning with better than 1% mass accuracy on the pL-scale. While dispensing fluid with tipless cantilevers is successful for patterning pL-scale features and can be considered a candidate for robust nanoscale manipulation of liquids for high-throughput sample preparation, the minimum amount of liquid that can be transferred using this method is limited by number of factors. Thus, in the second section of this thesis, we explore ultrafast cantilevers that feature spherical tips and find them capable of patterning aL-scale features with in situ feedback. The development of methods of interrogating polymers at the pL-scale led us to explore how the mechanical properties of photocurable polymers depend on processing conditions. Specifically, we investigate the degree to which oxygen inhibits photocrosslinking during vat polymerization and how this effect influences the mechanical properties of the final material. We explore this through a series of macroscopic compression studies and AFM-based indentation studies of the cured polymers. Ultimately, the mechanical properties of these systems are compared to pL-scale features patterned using scanning probe lithography and we find that not only does oxygen prevent full crosslinking when it is present during the post-print curing, but the presence of oxygen during printing itself irreversibly softens the material. In addition to developing new methods for realizing ultra-miniaturized samples for study, the novel scanning probe methods in this work have led to new paradigms for rapidly evaluating complex interactions between material systems. In particular, we present a novel method to quantitatively investigate the interaction between the metal-organic frameworks (MOFs) and polymers by attaching a single MOF particle to a cantilever and studying the interaction force between this MOF and model polymer surfaces. Using this approach, we find direct evidence supporting the intercalation of polymer chains into the pores of MOFs. This work lays the foundation for directly characterizing the facet-specific interactions between MOFs and polymers in a high-throughput manner sufficient to fuel a data-driven accelerated material discovery pipeline. Collectively, the focus of this thesis is the development and utilization of novel scanning probe methods to collect data on extremely small systems and advance our understanding of important classes of materials. We expect this thesis to provide the foundation needed to transform scanning probe systems into instruments for performing reliable nanochemistry by combining controlled and quantitative sample preparation at the nanoscale and high-throughput characterization of materials. To conclude, we present an outlook about the necessary technological advancements and promising directions for materials innovations that stem from this work.

Mechanical engineering

Atomic force microscopy

Dip-pen nanolithography

Inertial mass sensing

Nanoindentation

Nanopatterning

Scanning probe lithography

Electric Charging and Nanostructure Formation in Polymeric Films using Combined Amplitude-Modulated Atomic Force Microscopy Assisted Electrostaitc Nanolithography and Electric Force Microscopy

Reagan, Michael A.

23 December 2009

No description available.

Physics

Polymers

nanolithography

physics

polymer

atomic force microscope

electric force microscope