Spelling suggestions: "subject:"noncovalent functionalization"" "subject:"noncovalente functionalization""
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The synthesis of nitrogen doped carbon spheres and polythiophene/carbon sphere compositesKunjuzwa, Nikiwe 17 March 2010 (has links)
This study reports on the synthesis of N-doped carbon spheres (N-CSs) by a simple synthetic
procedure. A horizontal CVD type reactor was used to synthesize N-CSs from pyridine.
Depending on the dilution of the pyridine with toluene, a nitrogen content of 0.13-5 mol % was
obtained. The use of a vertical CVD reactor gave N-CSs with a N-content of 0.19-3 mol % when
an ammonium solution and acetylene were used as reactants. The diameters of carbon spheres
were found to be in the range of 40 nm to 1000 nm for both CVD reactors. The diameter can be
controlled by varying the flow rate, temperature, time, concentration and the reactor type. The
samples were characterized by TEM, HRTEM, elemental analysis, Raman spectroscopy, TGA,
PXRD and ESR.
We have demonstrated that unsubstituted thiophene can be polymerized by Fe3+-catalyzed
oxidative polymerization. The average particle size was about 50 nm, within a narrow particlesize
distribution. The undoped carbon spheres (CSs) were reacted with thiophene to give
polymer/carbon composites containing polythiophene and carbon nanospheres via chemical
oxidative polymerization reaction. Polythiophene molecules were either chemically bonded or
physically adsorbed to the surface of carbon spheres. The microstructure and properties of the
two types of composites were compared. The thermogravimetric analysis data confirmed that the
presence of CSs in the polymer\carbon composites is responsible for the higher thermal stability
of the composite material in comparison with pristine polythiophene. The FTIR analysis showed
that covalent functionalized nanocomposites exhibit a high intensity of a C-S bond This study reports on the synthesis of N-doped carbon spheres (N-CSs) by a simple synthetic
procedure. A horizontal CVD type reactor was used to synthesize N-CSs from pyridine.
Depending on the dilution of the pyridine with toluene, a nitrogen content of 0.13-5 mol % was
obtained. The use of a vertical CVD reactor gave N-CSs with a N-content of 0.19-3 mol % when
an ammonium solution and acetylene were used as reactants. The diameters of carbon spheres
were found to be in the range of 40 nm to 1000 nm for both CVD reactors. The diameter can be
controlled by varying the flow rate, temperature, time, concentration and the reactor type. The
samples were characterized by TEM, HRTEM, elemental analysis, Raman spectroscopy, TGA,
PXRD and ESR.
We have demonstrated that unsubstituted thiophene can be polymerized by Fe3+-catalyzed
oxidative polymerization. The average particle size was about 50 nm, within a narrow particlesize
distribution. The undoped carbon spheres (CSs) were reacted with thiophene to give
polymer/carbon composites containing polythiophene and carbon nanospheres via chemical
oxidative polymerization reaction. Polythiophene molecules were either chemically bonded or
physically adsorbed to the surface of carbon spheres. The microstructure and properties of the
two types of composites were compared. The thermogravimetric analysis data confirmed that the
presence of CSs in the polymer\carbon composites is responsible for the higher thermal stability
of the composite material in comparison with pristine polythiophene. The FTIR analysis showed
that covalent functionalized nanocomposites exhibit a high intensity of a C-S bondThis study reports on the synthesis of N-doped carbon spheres (N-CSs) by a simple synthetic
procedure. A horizontal CVD type reactor was used to synthesize N-CSs from pyridine.
Depending on the dilution of the pyridine with toluene, a nitrogen content of 0.13-5 mol % was
obtained. The use of a vertical CVD reactor gave N-CSs with a N-content of 0.19-3 mol % when
an ammonium solution and acetylene were used as reactants. The diameters of carbon spheres
were found to be in the range of 40 nm to 1000 nm for both CVD reactors. The diameter can be
controlled by varying the flow rate, temperature, time, concentration and the reactor type. The
samples were characterized by TEM, HRTEM, elemental analysis, Raman spectroscopy, TGA,
PXRD and ESR.
We have demonstrated that unsubstituted thiophene can be polymerized by Fe3+-catalyzed
oxidative polymerization. The average particle size was about 50 nm, within a narrow particlesize
distribution. The undoped carbon spheres (CSs) were reacted with thiophene to give
polymer/carbon composites containing polythiophene and carbon nanospheres via chemical
oxidative polymerization reaction. Polythiophene molecules were either chemically bonded or
physically adsorbed to the surface of carbon spheres. The microstructure and properties of the
two types of composites were compared. The thermogravimetric analysis data confirmed that the
presence of CSs in the polymer\carbon composites is responsible for the higher thermal stability
of the composite material in comparison with pristine polythiophene. The FTIR analysis showed
that covalent functionalized nanocomposites exhibit a high intensity of a C-S bond at 695 cm-1 ,
which is not observed in the noncovalent functionalized nanocomposites
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"Noncovalent Complexation of Single-Wall Carbon Nanotubes with Biopolymers: Dispersion, Purification, and Protein Interactions"DiLillo, Ana M. 24 June 2021 (has links)
No description available.
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Tailoring Nanoscopic and Macroscopic Noncovalent Chemical Patterns on Layered Materials at Sub-10 nm ScalesJae Jin Bang (5929496) 20 December 2018 (has links)
<p></p><p></p><p>The unprecedented
properties of 2D materials such as graphene and MoS2 have been researched
extensively [1,2] for a range of applications including nanoscale electronic and
optoelectronic devices [3–6]. Their unique physical and electronic properties
promise them as the next generation materials for electrodes and other
functional units in nanostructured devices. However, successful incorporation
of 2D materials into devices entails development of high resolution patterning
techniques that are applicable to 2D materials. Patterning at the sub-10 nm
scale is particularly of great interest as the next technology nodes require
patterning of (semi)conductors and insulators at 7 nm and 5 nm scales for
nanoelectronics. It will also benefit organic photovoltaic cells as phase
segregation of p/n-type semiconducting polymers on 2D electrodes at
length scales smaller than the typical exciton diffusion length (10 nm)</p>
<p>is expected to improve
the charge separation efficiency [7].</p><br><p></p><p></p><p>Characterizing locally
modulated properties of non-ovalently functionalized 2D materials requires
high-resolution imaging techniques capable of extracting measurements of
various physical/chemical properties. One such method is scanning probe
microscopy (SPM) [18–21]. In Chapter 1, we present a brief review of SPM
modalities, some of which are used to characterize interfacial properties, such
as conductivity and local contact potential differences that can be modulated
by amphiphilic assemblies [17, 22]. Atomic force microscopy (AFM) is one of
main techniques that we use to determine topography. All imaging in this work
were performed in attractive AC mode [23,24] in order to minimize disruption to
the self-assembly of the amphiphiles by the scanning tip.</p><br><p></p><p></p><p>One challenge of using
SAMs for locally modulated functionalization is that the proximity to the
nonpolar interface can modify the behavior of the functionalities present on
the surface in conjunction with the steric hindrance of 2D molecular
assemblies. For instance, ionizable functional groups, one of the strongest
local modulators of surface chemistry, undergo substantial pKa shifts (in some
cases, > 5 units) at nonpolar interfaces, limiting their ability to ionize.
In order to apply molecular assembly to create 2D chemical patterns, we needed
to design alternative structures that can avoid such penalties against the
intrinsic properties of functionalities present in the assemblies. Among
amphiphiles, we observed that the chiral centers of phospholipids have the
potential of elevating the terminal functional group in the head from the surface
for improved accessibility. We refer to this type of assembly as a ’sitting’
phase. Chapter 2 describes sitting phase assembly of phospholipids; the
projection of the terminal functionality allows it to maintain solution
phase-like behavior while the dual alkyl tails provide additional stabilizing
interactions with the substrates. Given the diversity of phospholipid
architecture [25], the sitting phase assembly suggests the possibility of
greatly diversifying the orthogonality of the chemical patterns, allowing
highly precise control over surface functionalities.</p><br><p></p><p></p><p>While a variety of
methods including drop-casting [26–28] and microcontact printing [29] have been
used previously by others for noncovalent assembly of materials on the surface,
they mostly address patterning scale in the sub-μm range. Here, we utilize
Langmuir-Schaefer(LS) transfer, which has been historically used to transfer
standing phase multilayers [30], and lying-down domains of PCDA at < 100 nm
scales in the interest of molecular electronics [14, 31–33], as our sample
preparation technique. LS transfer is remarkable in that the transferred
molecules relinquish their pre-existing interactions in the standing phase at
air-water interface to undergo ∼ 90◦
rotation and assemble into the striped phase on a substrate. This introduces
the possibility of modulating local transfer rate across the substrate by
manipulating local environment of the molecules. Thus, LS transfer has the
potential to offer spatial control over the noncovalent chemical
functionalization of the 2D substrate, essential in device applications.</p><br><p></p><p></p><p>In Chapter 3 and 4, We
make comparative studies of various experimental factors such as surface pressure,
temperature and molecular interactions that affect the efficiency of LS
conversion. Considering the energetics of the transfer process, we predicted
that the rate of transfer from the air-water interface to the substrate should
be the highest from the regions around defects, which would be the
energetically</p>
<p>least stable regions of
the Langmuir film [34, 35]. In Langmuir films, two phases of lipid
assemblies—liquid expanded (LE) and liquid condensed (LC)—often coexist at the
low surface pressures (< 10 mN/m) used for sample preparation. Hence, we
hypothesized that the microscale structural heterogeneity of Langmuir films
could be translated into microscale patterns in the transferred film on HOPG.
We compare the transfer rates between LE and LC phases and investigate the
impacts of physical conditions during LS transfer such as temperature, packing
density, dipping rate and contact time to conclude that local destabilization
of Langmuir films leads to increased transfer efficiency. (Chapter 3)</p><p><br></p><p></p><p>As in the case of lipid
membranes that reorganize routinely based on the structure of the constituent
molecules [36–38], the structure of Langmuir films is strongly dependent on the
molecular structures of the constituent molecules [39–43]. Accordingly, we
expected the molecular structures/interactions to provide additional control
over the LS transfer process. In Chapter 4, we compare domain morphologies and
the average coverages between three single chain amphiphiles and two
phospholipids, each</p><p></p><p>
</p><p>of which contain
hydrogen bonding motifs of varying strengths. We show that by influencing the
adsorption and diffusion rates, molecular architecture indeed influences LS
conversion efficiency and subsequent assembly on the substrate. The presence of
strong lateral interactions limits transfer and diffusion, forming vacancies in
the transferred films with smaller domain sizes while weaker intermolecular
interactions enabled high transfer efficiencies.</p><p></p><p><br></p><p></p>
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Controlled Interfacial Adsorption of AuNW Along 1-Nm Wide Dipole Arrays on Layered Materials and The Catalysis of Sulfide OxygenationAshlin G Porter (6580085) 12 October 2021 (has links)
<p>Controlling the
surface chemistry of 2D materials is critical for the development of next
generation applications including nanoelectronics and organic photovoltaics
(OPVs). Further, next generation nanoelectronics devices require very specific
2D patterns of conductors and insulators with prescribed connectivity and
repeating patterns less than 10 nm. However, both top-down and bottom-up
approaches currently used lack the ability to pattern materials with sub 10-nm
precision over large scales. Nevertheless, a class of monolayer chemistry
offers a way to solve this problem through controlled long-range ordering with
superior sub-10 nm patterning resolution. Graphene is most often functionalized
noncovalently, which preserves most of its intrinsic properties (<i>i.e.,</i> electronic conductivity) and
allows spatial modulation of the surface. Phospholipids such as
1,2-bis(10,12-tricsadiynoyl)-<i>sn</i>-glycero-3-phosphoethanolamine
(diyne PE) form lying down lamellar phases on graphene where both the
hydrophilic head and hydrophobic tail are exposed to the interface and resemble
a repeating cross section of the cell membrane. Phospholipid is made up of a complex
headgroup structure and strong headgroup dipole which allows for a diverse
range of chemistry and docking of objects to occur at the nonpolar membrane,
these principals are equally as important at the nonpolar interface of 2D
materials. A key component in the development of nanoelectronics is the
integration of inorganic nanocrystals such as nanowires into materials at the
wafer scale. Nanocrystals can be integrated into materials through templated
growth on to surface of interest as well as through assembly processes (i.e.
interfacial adsorption). </p>
<p>In this work, I
have demonstrated that gold nanowires (AuNWs) can be templated on striped
phospholipid monolayers, which have an orientable headgroup dipoles that can
order and straighten flexible 2-nm diameter AuNWs with wire lengths of ~1 µm. While AuNWs in
solution experience bundling effects due to depletion attraction interactions,
wires adsorb to the surface in a well separated fashion with wire-wire
distances (e.g. 14 or 21 nm) matching multiples of the PE template pitch. This
suggests repulsive interactions between wires upon interaction with dipole
arrays on the surface. Although the reaction and templating of AuNWs is
completed in a nonpolar environment (cyclohexane), the ordering of wires varies
based on the hydration of the PE template in the presence of excess oleylamine,
which forms hemicylindrical micelles around the hydrated headgroups protecting
the polar environment. Results suggest that PE template experience
membrane-mimetic dipole orientation behaviors, which in turn influences the
orientation and ordering of objects in a nonpolar environment.</p>
<p>Another
promising material for bottom-up device applications is MoS<sub>2 </sub>substrates
due to their useful electronic properties. However, being able to control the
surface chemistry of different materials, like MoS<sub>2</sub>, is relatively
understudied, resulting in very limited examples of MoS<sub>2 </sub>substrates
used in bottom-up approaches for nanoelectronics devices. Diyne PE templates adsorb
on to MoS<sub>2 </sub>in an edge-on conformation in which the alkyl tails
stack on top of each other increasing the overall stability of the monolayer. A
decrease in lateral spacing results in high local concentrations of orientable
headgroups dipoles along with stacked tails which could affect the interactions
and adsorption of inorganic materials (i.e. AuNW) at the interface. </p>
<p>Here, I show
that both diyne PE/HOPG and diyne PE/MoS<sub>2</sub> substrates can template
AuNW of various lengths with long range ordering over areas up to 100 µm<sup>2</sup>. Wires on
both substrates experience repulsive interactions upon contact with the
headgroup dipole arrays resulting in wire-wire distances greater than the
template pitch (7 nm). As the wire length is shortened the measured distance
between wires become smaller eventually resulting in tight packed ribbon
phases. Wires within these ribbon phases have wire-wire distances equal to the
template. Ribbon phases occur on diyne
PE/HOPG substrates when the wire length is ~50 nm, whereas wire below ~600 nm
produce ribbon phases on diyne PE/MoS<sub>2 </sub>substrates. </p>
<p>Another
important aspect to future scientific development is the catalysis of organic
reactions, specifically oxygenation of organic sulfides. Sulfide oxygenation is
important for applications such as medicinal chemistry, petroleum
desulfurization, and nerve agent detoxification. Both reaction rates and the
use of inexpensive oxidants and catalysts are important for practical
applications. Hydrogen peroxide and <i>tert</i>-butyl
hydroperoxide are ideal oxidants due to being cost efficient and
environmentally friendly. Hydrogen peroxide can be activated through transition
metal base homogeneous catalysts. Some of the most common catalysts are homo-
and hetero-polyoxometalates (POMs) due their chemical robustness. Heptamolybdate
[Mo<sub>7</sub>O<sub>24</sub>]<sup>6-</sup><sub> </sub>is a member of the
isopolymolybdate family and its ammonium salt is commercially available and low
in cost.<sup>22</sup> Heteropolyoxometalates have
been widely studied as a catalyst for oxygenation reactions whereas heptamolybdate
has been rarely studied in oxygenation reactions. </p>
<p> Here
I report sulfide oxygenation activity of both heptamolybdate and its peroxo
derivate [Mo<sub>7</sub>O<sub>22</sub>(O<sub>2</sub>)<sub>2</sub>]<sup>6-</sup>.
Sulfide oxygenation of methyl phenyl sulfide (MPS) by H<sub>2</sub>O<sub>2 </sub>to
sulfoxide and sulfone occurs rapidly with 100 % utility of H<sub>2</sub>O<sub>2</sub>
in the presence of [Mo<sub>7</sub>O<sub>22</sub>(O<sub>2</sub>)<sub>2</sub>]<sup>6-</sup>,
suggesting the peroxo adduct is an efficient catalyst. However, heptamolybdate
is a faster catalyst compared to [Mo<sub>7</sub>O<sub>22</sub>(O<sub>2</sub>)<sub>2</sub>]<sup>6-</sup>
for MPS oxygenation and all other sulfides tested under identical conditions.
Pseudo-first order <i>k</i><sub>cat</sub>
constants from initial rate kinetics show that [Mo<sub>7</sub>O<sub>24</sub>]<sup>6-</sup><sub>
</sub>catalyzes sulfide oxygenation faster. The significant difference in the <i>k</i><sub>cat</sub> suggests differences in
the active catalytic species, which was characterized by both UV-Vis and
electrospray ionization mass spectrometry. ESI-MS suggest that the active
intermediate of [Mo<sub>7</sub>O<sub>24</sub>]<sup>6-</sup><sub> </sub>under
catalytic reaction conditions for sulfide oxygenation by H<sub>2</sub>O<sub>2</sub>
is [Mo<sub>2</sub>O<sub>11</sub>]<sup>2-</sup>. These results show that
heptamolybdate is a highly efficient catalyst for H<sub>2</sub>O<sub>2 </sub>oxygenation
of organic sulfides.</p>
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Controlled Transfer Of Macroscopically Organized Nanoscopically Patterned Sub–10 nm Features onto 2D Crystalline and Amorphous MaterialsTyson C Davis (9121889) 05 August 2020 (has links)
<div>Surface level molecules act as an interface that mediates between the surface and the environment. In this way, interfacial molecules are responsible for conferring characteristics of relevance to many modern material science problems, such as electrical conductivity and wettability. For many applications, such as organic photovoltaics and nanoelectronics, macroscopic placement of chemical patterns at the sub-10 nm must be achieved to advance next generation device applications.</div><div><br></div><div>In the work presented here, we show that sub-10 nm orthogonal features can be prepared by translating the building principles of the lipid bilayer into striped phase lipids on 2D materials (e.g. highly ordered pyrolytic graphite (HOPG), MoS2). Macroscopic patterning of these nanoscopic elements is achieved via Langmuir Schafer deposition of polymerizable diyne amphiphiles. On the Langmuir trough, amphiphiles at the air water interface are ordered into features that can be observed on the macroscale using Brewster angle microscopy. Upon contact of the 2D material with the air-water interface the macroscopic pattern on the trough is transferred to the 2D material creating a macroscopic pattern consisting of sub-10 nm orthogonal chemistries. We also show here how hierarchical ordering can be accomplished via noncovalent microcontact printing of amphiphiles onto 2D materials. Microcontact printing allows a greater measure of control over the placement and clustering of interfacial molecules.</div><div><br></div><div>The alkyl chain/surface enthalpy has a great deal of influence over the ordering of amphiphiles at the sub-nm scale. Here, we examine this influence by depositing diyne amphiphiles onto MoS2 which has a weaker alkyl adsorption enthalpy compared to HOPG. We found that dual-chain amphiphiles deposited on MoS2 adopt a geometry that maximized the molecule-molecule interaction compared to the geometry adopted on HOPG.</div><div><br></div><div>Finally, we show how the hierarchical pattern of diyne amphiphiles can be transferred off of the 2D material onto an amorphous material. This is done by reacting the amorphous material with the conjugated backbone of the diyne moiety through a hydrosilylation reaction to exfoliate the film from the 2D crystalline material. The resulting polymer ‘skin’ has many applications were controlling interfacial properties of an amorphous material is important.</div>
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DEVELOPMENT OF THERMALLY CONTROLLED LANGMUIR–SCHAEFER CONVERSION TECHNIQUES FOR SUB-10-NM HIERARCHICAL PATTERNING ACROSS MACROSCOPIC SURFACE AREASTyler R Hayes (9754796) 14 December 2020 (has links)
<div> As hybrid 2D materials are incorporated into next-generation device designs, it becomes more and more pertinent that methods are being developed which can facilitate large-area structural control of noncovalent monolayers assembled at 2D material interfaces. Noncovalent functionalization is often leveraged to modulate the physical properties of the underlying 2D material without disrupting the extended electronic delocalization networks intrinsic to its basal plane. The bottom-up nanofabrication technique of self-assembly permits sub-10-nm chemical patterning with low operational costs and relatively simple experimental designs.</div><div> The Claridge Group is interested in leveraging the unique chemical orthogonality intrinsic to the cellular membrane as a means of creating sub-10-nm hydrophilic-hydrophobic striped patterns across 2D material interfaces for applications ranging from interfacial wetting to large-area molecular templates to guide heterogeneous nanoparticle assembly. Using Langmuir–Schaefer conversion, standing phases of polymerizable amphiphiles at the air-water interfaces of a Langmuir trough are converted (through rotation) to lying-down phases on 2D material substrates. Using room temperature substrates, transfer of amphiphiles to a lowered substrate results in small domains and incomplete surface coverage.</div><div> Recognizing that heating the substrate during the LS conversion process may lower the energy barriers to molecular reorientation, and promote better molecular domain assembly, we developed a thermally controlled heated transfer stage that can maintain the surface temperature of the substrate throughout the deposition process. We found that heating during transfer results in the assembly of domains with edge lengths routinely an order of magnitude larger than transfer using room temperature substrates that are more stable towards rigorous repeat washing cycles with both polar and nonpolar solvents.</div><div> To promote the effectiveness of the LS conversion technique beyond academic environments for the noncovalent functionalization 2D material substrates for next-generation device designs, we designed and built a thermally controlled rotary stage to address the longstanding scaling demerit of LS conversion. First, we report the development of a flexible HOPG substrate film that can wrap around the perimeter of the heated disk and can be continuously cycled through the Langmuir film. We found that thermally controlled rotary (TCR) LS conversion can achieve nearly complete surface coverage at the slowest translation speed tested (0.14 mm/s). TCR–LS facilitates the assembly of domains nearly 10,000 μm<sup>2</sup> which were subsequently used as molecular templates to guide the assembly of ultranarrow AuNWs from solution in a non-heated rotary transfer step. Together, these findings provide the foundation for the use of roll-to-roll protocols to leverage LS conversion for noncovalent functionalization of 2D materials. A true roll-to-roll thermally controlled LS conversion system may prove to be advantageous and a cost-efficient process in applications that require large areas of functional surface, or benefit from long-range ordering within the functional film.</div>
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