Your search keyword '"Rachelle Ihly"' showing total 33 results

1. Switchable photovoltaic windows enabled by reversible photothermal complex dissociation from methylammonium lead iodide

Author

Lance M. Wheeler, David T. Moore, Rachelle Ihly, Noah J. Stanton, Elisa M. Miller, Robert C. Tenent, Jeffrey L. Blackburn, and Nathan R. Neale

Subjects

Science

Abstract

Conventional smart windows with tunable transparency are based on electrochromic systems that consumes energy. Here Wheeler et al. demonstrate a halide perovskite based photo-switchable window that dynamically responds to sunlight and change colors via reversible phase transitions.

Published

2017

2. Optically Generated Free-Carrier Collection from an All Single-Walled Carbon Nanotube Active Layer

Author

Jeffrey L. Blackburn, Lenore Kubie, Henry Wladkowski, William Rice, Kevin J. Watkins, Rachelle Ihly, and Bruce A. Parkinson

Subjects

Materials science, 02 engineering and technology, Carbon nanotube, 010402 general chemistry, 01 natural sciences, law.invention, Condensed Matter::Materials Science, law, Physics::Atomic and Molecular Clusters, General Materials Science, Physical and Theoretical Chemistry, Absorption (electromagnetic radiation), Ohmic contact, Photocurrent, Range (particle radiation), Condensed Matter::Other, business.industry, Relaxation (NMR), Condensed Matter::Mesoscopic Systems and Quantum Hall Effect, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Active layer, Semiconductor, Optoelectronics, 0210 nano-technology, business

Abstract

Semiconducting single-walled carbon nanotubes' (SWCNTs) broad absorption range and all-carbon composition make them attractive materials for light harvesting. We report photoinduced charge transfer from both multichiral and single-chirality SWCNT films into atomically flat SnO2 and TiO2 crystals. Higher-energy second excitonic SWCNT transitions produce more photocurrent, demonstrating carrier injection rates are competitive with fast hot-exciton relaxation processes. A logarithmic relationship exists between photoinduced electron-transfer driving force and photocarrier collection efficiency, becoming more efficient with smaller diameter SWCNTs. Photocurrents are generated from both conventional sensitization and in the opposite direction with the semiconductor under accumulation and acting as an ohmic contact with only the p-type nanotubes. Finally, we demonstrate that SWCNT surfactant choice and concentration play a large role in photon conversion efficiency and present methods of maximizing photocurrent yields.

Published

2018

3. Diameter-Dependent Optical Absorption and Excitation Energy Transfer from Encapsulated Dye Molecules toward Single-Walled Carbon Nanotubes

Author

Wim Wenseleers, Andrew J. Ferguson, Dylan H. Arias, Stein van Bezouw, Jochen Campo, Joeri Defillet, Justin C. Johnson, Sofie Cambré, Rachelle Ihly, and Jeffrey L. Blackburn

Subjects

spectroscopy, Materials science, Absorption spectroscopy, Stacking, General Physics and Astronomy, 02 engineering and technology, Carbon nanotube, 010402 general chemistry, Photochemistry, 01 natural sciences, 7. Clean energy, Article, law.invention, symbols.namesake, law, Ultrafast laser spectroscopy, Molecule, General Materials Science, Spectroscopy, energy transfer, carbon nanotubes, Physics, General Engineering, exciton dynamics, solar photoconversion, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Chemistry, symbols, encapsulation, 0210 nano-technology, Engineering sciences. Technology, Excitation, Raman scattering

Abstract

The hollow cores and well-defined diameters of single-walled carbon nanotubes (SWCNTs) allow for creation of one-dimensional hybrid structures by encapsulation of various molecules. Absorption and near-infrared photoluminescence-excitation (PLE) spectroscopy reveal that the absorption spectrum of encapsulated 1,3-bis[4-(dimethylamino)phenyl]-squaraine dye molecules inside SWCNTs is modulated by the SWCNT diameter, as observed through excitation energy transfer (EET) from the encapsulated molecules to the SWCNTs, implying a strongly diameter dependent stacking of the molecules inside the SWCNTs. Transient absorption spectroscopy, simultaneously probing the encapsulated dyes and the host SWCNTs, demonstrates this EET, which can be used as a route to diameter-dependent photosensitization, to be fast (sub-picosecond). A wide series of SWCNT samples is systematically characterized by absorption, PLE, and resonant Raman scattering (RRS), also identifying the critical diameter for squaraine filling. In addition, we find that SWCNT filling does not limit the selectivity of subsequent separation protocols (including polyfluorene polymers for isolating only semiconducting SWCNTs and aqueous two-phase separation for enrichment of specific SWCNT chiralities). The design of these functional hybrid systems, with tunable dye absorption, fast and efficient EET, and the ability to remove all metallic SWCNTs by subsequent separation, demonstrates potential for implementation in photoconversion devices.

Published

2018

4. Solution-phase p-type doping of highly enriched semiconducting single-walled carbon nanotubes for thermoelectric thin films

Author

Andrew J. Ferguson, Brenna Norton-Baker, Noah J. Stanton, Rachelle Ihly, and Jeffrey L. Blackburn

Subjects

Materials science, Physics and Astronomy (miscellaneous), Dopant, business.industry, Doping, Fermi level, Carbon nanotube, Thermoelectric materials, law.invention, symbols.namesake, law, Thermoelectric effect, symbols, Optoelectronics, Charge carrier, Thin film, business

Abstract

Single-walled carbon nanotubes (SWCNTs) are attractive materials for next-generation energy-harvesting technologies, including thermoelectric generators, due to their tunable opto-electronic properties and high charge carrier mobilities. Controlling the Fermi level within these unique 1D nanomaterials is often afforded by charge transfer interactions between SWCNTs and electron or hole accepting species. Conventional methods to dope SWCNT networks typically involve the diffusion of molecular redox dopant species into solid-state thin films, but solution-phase doping could potentially provide routes and/or benefits for charge carrier transport, scalability, and stability. Here, we develop a methodology for solution-phase doping of polymer-wrapped, highly enriched semiconducting SWCNTs using a p-type charge transfer dopant, F4TCNQ. This allows doped SWCNT inks to be cast into thin films without the need for additional post-deposition doping treatments. We demonstrate that the introduction of the dopant at varying stages of the SWCNT dispersion process impacts the ultimate thermoelectric performance and observe that the dopant alters the polymer selectivity for semiconducting vs metallic SWCNTs. In contrast to dense semiconducting polymer films, where solution-phase doping typically leads to disrupted morphologies and poorer TE performance than solid-state doping, thin films of solution-doped s-SWCNTs perform similarly to their solid-state doped counterparts. Interestingly, our results also suggest that solution-phase F4TCNQ doping leads to fully ionized and dimerized F4TCNQ anions in solid-state films that are not observed in films doped with F4TCNQ after deposition. Our results provide a framework for the application of solution-phase doping to a broad array of high-performance SWCNT-based thermoelectric materials and devices that may require high-throughput deposition techniques.

Published

2021

5. Low-Temperature Single Carbon Nanotube Spectroscopy of sp3 Quantum Defects

Author

Yue Luo, Kamran Shayan, Xiaowei He, Rachelle Ihly, Xuedan Ma, Stefan Strauf, Brendan J. Gifford, Sergei Tretiak, Han Htoon, Jeffrey L. Blackburn, Svetlana Kilina, Nicolai F. Hartmann, and Stephen K. Doorn

Subjects

Nanotube, Materials science, Photoluminescence, General Engineering, General Physics and Astronomy, Nanotechnology, 02 engineering and technology, Electronic structure, Carbon nanotube, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Molecular physics, Spectral line, 0104 chemical sciences, law.invention, Polyfluorene, chemistry.chemical_compound, chemistry, law, General Materials Science, Chemical binding, 0210 nano-technology, Spectroscopy

Abstract

Aiming to unravel the relationship between chemical configuration and electronic structure of sp3 defects of aryl-functionalized (6,5) single-walled carbon nanotubes (SWCNTs), we perform low-temperature single nanotube photoluminescence (PL) spectroscopy studies and correlate our observations with quantum chemistry simulations. We observe sharp emission peaks from individual defect sites that are spread over an extremely broad, 1000–1350 nm, spectral range. Our simulations allow us to attribute this spectral diversity to the occurrence of six chemically and energetically distinct defect states resulting from topological variation in the chemical binding configuration of the monovalent aryl groups. Both PL emission efficiency and spectral line width of the defect states are strongly influenced by the local dielectric environment. Wrapping the SWCNT with a polyfluorene polymer provides the best isolation from the environment and yields the brightest emission with near-resolution limited spectral line width ...

Published

2017

6. Tunable room-temperature single-photon emission at telecom wavelengths from sp3 defects in carbon nanotubes

Author

Nicolai F. Hartmann, Weilu Gao, Xuedan Ma, Takeshi Tanaka, Han Htoon, Younghee Kim, Hiromichi Kataura, Xiaowei He, Yohei Yomogida, Junichiro Kono, Rachelle Ihly, Atsushi Hirano, Jeffrey L. Blackburn, and Stephen K. Doorn

Subjects

Nanotube, Materials science, business.industry, C band, Exciton, Physics::Optics, 02 engineering and technology, Carbon nanotube, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Atomic and Molecular Physics, and Optics, 0104 chemical sciences, Electronic, Optical and Magnetic Materials, law.invention, Optical properties of carbon nanotubes, Condensed Matter::Materials Science, Wavelength, law, 0210 nano-technology, Telecommunications, business, Quantum, Excitation

Abstract

Generating quantum light emitters that operate at room temperature and at telecom wavelengths remains a significant materials challenge. To achieve this goal requires light sources that emit in the near-infrared wavelength region and that, ideally, are tunable to allow desired output wavelengths to be accessed in a controllable manner. Here, we show that exciton localization at covalently introduced aryl sp3 defect sites in single-walled carbon nanotubes provides a route to room-temperature single-photon emission with ultrahigh single-photon purity (99%) and enhanced emission stability approaching the shot-noise limit. Moreover, we demonstrate that the inherent optical tunability of single-walled carbon nanotubes, present in their structural diversity, allows us to generate room-temperature single-photon emission spanning the entire telecom band. Single-photon emission deep into the centre of the telecom C band (1.55 µm) is achieved at the largest nanotube diameters we explore (0.936 nm). Single-photon emission with 99% purity is generated from sp3 defects in carbon nanotubes (CNTs) by optical excitation at room temperature. By increasing the CNT diameter from 0.76 nm to 0.94 nm, the emission wavelength can be changed from 1,100 nm to 1,600 nm.

Published

2017

7. Large n- and p-type thermoelectric power factors from doped semiconducting single-walled carbon nanotube thin films

Author

Rachelle Ihly, Christopher N. Folmar, Christopher S. Fewox, Andrew J. Ferguson, Zbyslaw R. Owczarczyk, Bradley A. MacLeod, Barry L. Zink, Katherine E. Hurst, Katherine Holman Hughes, Devin Wesenberg, Jeffrey L. Blackburn, Isaac E. Gould, and Noah J. Stanton

Subjects

Renewable Energy, Sustainability and the Environment, business.industry, Doping, Nanotechnology, 02 engineering and technology, Carbon nanotube, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Pollution, 0104 chemical sciences, law.invention, Organic semiconductor, Thermoelectric generator, Semiconductor, Nuclear Energy and Engineering, law, Seebeck coefficient, Thermoelectric effect, Environmental Chemistry, Thin film, 0210 nano-technology, business

Abstract

Lightweight, robust, and flexible single-walled carbon nanotube (SWCNT) materials can be processed inexpensively using solution-based techniques, similar to other organic semiconductors. In contrast to many semiconducting polymers, semiconducting SWCNTs (s-SWCNTs) represent unique one-dimensional organic semiconductors with chemical and physical properties that facilitate equivalent transport of electrons and holes. These factors have driven increasing attention to employing s-SWCNTs for electronic and energy harvesting applications, including thermoelectric (TE) generators. Here we demonstrate a combination of ink chemistry, solid-state polymer removal, and charge-transfer doping strategies that enable unprecedented n-type and p-type TE power factors, in the range of 700 μW m−1 K−2 at 298 K for the same solution-processed highly enriched thin films containing 100% s-SWCNTs. We also demonstrate that the thermal conductivity appears to decrease with decreasing s-SWCNT diameter, leading to a peak material zT ≈ 0.12 for s-SWCNTs with diameters in the range of 1.0 nm. Our results indicate that the TE performance of s-SWCNT-only material systems is approaching that of traditional inorganic semiconductors, paving the way for these materials to be used as the primary components for efficient, all-organic TE generators.

Published

2017

8. Photoluminescence Imaging of Polyfluorene Surface Structures on Semiconducting Carbon Nanotubes: Implications for Thin Film Exciton Transport

Author

Anne-Marie Dowgiallo, Nicolai F. Hartmann, Jeffrey L. Blackburn, Stephen K. Doorn, Rachelle Ihly, and Rajib Pramanik

Subjects

Nanotube, Materials science, Photoluminescence, Exciton, General Physics and Astronomy, 02 engineering and technology, Carbon nanotube, 010402 general chemistry, 01 natural sciences, law.invention, Polyfluorene, chemistry.chemical_compound, law, Photovoltaics, General Materials Science, Thin film, chemistry.chemical_classification, business.industry, General Engineering, Polymer, 021001 nanoscience & nanotechnology, 0104 chemical sciences, chemistry, Optoelectronics, 0210 nano-technology, business

Abstract

Single-walled carbon nanotubes (SWCNTs) have potential to act as light-harvesting elements in thin film photovoltaic devices, but performance is in part limited by the efficiency of exciton diffusion processes within the films. Factors contributing to exciton transport can include film morphology encompassing nanotube orientation, connectivity, and interaction geometry. Such factors are often defined by nanotube surface structures that are not yet well understood. Here, we present the results of a combined pump-probe and photoluminescence imaging study of polyfluorene (PFO)-wrapped (6,5) and (7,5) SWCNTs that provide additional insight into the role played by polymer structures in defining exciton transport. Pump-probe measurements suggest exciton transport occurs over larger length scales in films composed of PFO-wrapped (7,5) SWCNTs, compared to those prepared from PFO-bpy-wrapped (6,5) SWCNTs. To explore the role the difference in polymer structure may play as a possible origin of differing transport behaviors, we performed a photoluminescence imaging study of individual polymer-wrapped (6,5) and (7,5) SWCNTs. The PFO-bpy-wrapped (6,5) SWCNTs showed more uniform intensity distributions along their lengths, in contrast to the PFO-wrapped (7,5) SWCNTs, which showed irregular, discontinuous intensity distributions. These differences likely originate from differences in surface coverage and suggest the PFO wrapping on (7,5) nanotubes produces a more open surface structure than is available with the PFO-bpy wrapping of (6,5) nanotubes. The open structure likely leads to improved intertube coupling that enhances exciton transport within the (7,5) films, consistent with the results of our pump-probe measurements.

Published

2016

9. Effect of nanotube coupling on exciton transport in polymer-free monochiral semiconducting carbon nanotube networks

Author

Justin C. Johnson, Andrew J. Ferguson, Dylan H. Arias, Rachelle Ihly, Stephanie M. Hart, Jeffrey L. Blackburn, Dana B. Sulas-Kern, Ji Hao, and Hyun Suk Kang

Subjects

chemistry.chemical_classification, Nanotube, Materials science, Exciton, 02 engineering and technology, Carbon nanotube, Polymer, Trapping, Condensed Matter::Mesoscopic Systems and Quantum Hall Effect, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, law.invention, Coupling (electronics), Condensed Matter::Materials Science, Delocalized electron, chemistry, Chemical physics, law, General Materials Science, Thin film, 0210 nano-technology

Abstract

Semiconducting single-walled carbon nanotubes (s-SWCNTs) are attractive light-harvesting components for solar photoconversion schemes and architectures, and selective polymer extraction has emerged as a powerful route to obtain highly pure s-SWCNT samples for electronic applications. Here we demonstrate a novel method for producing electronically coupled thin films of near-monochiral s-SWCNTs without wrapping polymer. Detailed steady-state and transient optical studies on such samples provide new insights into the role of the wrapping polymer on controlling intra-bundle nanotube–nanotube interactions and exciton energy transfer within and between bundles. Complete removal of polymer from the networks results in rapid exciton trapping within nanotube bundles, limiting long-range exciton transport. The results suggest that intertube electronic coupling and associated exciton delocalization across multiple tubes can limit diffusive exciton transport. The complex relationship observed here between exciton delocalization, trapping, and long-range transport, helps to inform the design, preparation, and implementation of carbon nanotube networks as active elements for optical and electronic applications.

Published

2019

10. Polymer-Free Carbon Nanotube Thermoelectrics with Improved Charge Carrier Transport and Power Factor

Author

Isaac E. Gould, A. D. Avery, Brenna Norton-Baker, Zbyslaw R. Owczarczyk, Andrew J. Ferguson, Rachelle Ihly, and Jeffrey L. Blackburn

Subjects

chemistry.chemical_classification, Nanotube, Materials science, Renewable Energy, Sustainability and the Environment, Energy Engineering and Power Technology, Nanotechnology, 02 engineering and technology, Polymer, Carbon nanotube, 010402 general chemistry, 021001 nanoscience & nanotechnology, Thermoelectric materials, 01 natural sciences, 0104 chemical sciences, law.invention, Fuel Technology, chemistry, Chemistry (miscellaneous), law, Seebeck coefficient, Thermoelectric effect, Materials Chemistry, Charge carrier, Thin film, 0210 nano-technology

Abstract

Semiconducting single-walled carbon nanotubes (s-SWCNTs) have recently attracted attention for their promise as active components in a variety of optical and electronic applications, including thermoelectricity generation. Here we demonstrate that removing the wrapping polymer from the highly enriched s-SWCNT network leads to substantial improvements in charge carrier transport and thermoelectric power factor. These improvements arise primarily from an increase in charge carrier mobility within the s-SWCNT networks because of removal of the insulating polymer and control of the level of nanotube bundling in the network, which enables higher thin-film conductivity for a given carrier density. Ultimately, these studies demonstrate that highly enriched s-SWCNT thin films, in the complete absence of any accompanying semiconducting polymer, can attain thermoelectric power factors in the range of ∼400 μW m–1 K–2, which is on par with that of some of the best single-component organic thermoelectrics demonstrated...

Published

2016

11. Efficient charge extraction and slow recombination in organic–inorganic perovskites capped with semiconducting single-walled carbon nanotubes

Author

Joseph J. Berry, Noah J. Stanton, Anne-Marie Dowgiallo, Jeffrey L. Blackburn, Philip Schulz, Mengjin Yang, Rachelle Ihly, Obadiah G. Reid, Andrew J. Ferguson, and Kai Zhu

Subjects

Materials science, Nanotechnology, 02 engineering and technology, Carbon nanotube, Electron, 010402 general chemistry, 01 natural sciences, law.invention, Condensed Matter::Materials Science, chemistry.chemical_compound, law, Photovoltaics, Environmental Chemistry, Thin film, Perovskite (structure), Renewable Energy, Sustainability and the Environment, business.industry, 021001 nanoscience & nanotechnology, Pollution, 0104 chemical sciences, Nuclear Energy and Engineering, chemistry, Titanium dioxide, Optoelectronics, Charge carrier, 0210 nano-technology, business, Layer (electronics)

Abstract

Metal-halide based perovskite solar cells have rapidly emerged as a promising alternative to traditional inorganic and thin-film photovoltaics. Although charge transport layers are used on either side of perovskite absorber layers to extract photogenerated electrons and holes, the time scales for charge extraction and recombination are poorly understood. Ideal charge transport layers should facilitate large discrepancies between charge extraction and recombination rates. Here, we demonstrate that highly enriched semiconducting single-walled carbon nanotube (SWCNT) films enable rapid (sub-picosecond) hole extraction from a prototypical perovskite absorber layer and extremely slow back-transfer and recombination (hundreds of microseconds). The energetically narrow and distinct spectroscopic signatures for charges within these SWCNT thin films enables the unambiguous temporal tracking of each charge carrier with time-resolved spectroscopies covering many decades of time. The efficient hole extraction by the SWCNT layer also improves electron extraction by the compact titanium dioxide electron transport layer, which should reduce charge accumulation at each critical interface. Finally, we demonstrate that the use of thin interface layers of semiconducting single-walled carbon nanotubes between the perovskite absorber layer and a prototypical hole transport layer improves device efficiency and stability, and reduces hysteresis.

Published

2016

12. Efficiency of Charge-Transfer Doping in Organic Semiconductors Probed with Quantitative Microwave and Direct-Current Conductance

Author

Rachelle Ihly, Obadiah G. Reid, Andrew J. Ferguson, Sanjini U. Nanayakkara, and Jeffrey L. Blackburn

Subjects

education.field_of_study, Materials science, Dopant, Population, Doping, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Organic semiconductor, Condensed Matter::Materials Science, Delocalized electron, Chemical physics, Electrical resistivity and conductivity, General Materials Science, Charge carrier, Electric potential, Physical and Theoretical Chemistry, 0210 nano-technology, education

Abstract

Although molecular charge-transfer doping is widely used to manipulate carrier density in organic semiconductors, only a small fraction of charge carriers typically escape the Coulomb potential of dopant counterions to contribute to electrical conductivity. Here, we utilize microwave and direct-current (DC) measurements of electrical conductivity to demonstrate that a high percentage of charge carriers in redox-doped semiconducting single-walled carbon nanotube (s-SWCNT) networks is delocalized as a free carrier density in the π-electron system (estimated as46% at high doping densities). The microwave and four-point probe conductivities of hole-doped s-SWCNT films quantitatively match over almost 4 orders of magnitude in conductance, indicating that both measurements are dominated by the same population of delocalized carriers. We address the relevance of this surprising one-to-one correspondence by discussing the degree to which local environmental parameters (e.g., tube-tube junctions, Coulombic stabilization, and local bonding environment) may impact the relative magnitudes of each transport measurement.

Published

2018

13. Switchable photovoltaic windows enabled by reversible photothermal complex dissociation from methylammonium lead iodide

Author

David T. Moore, Noah J. Stanton, Lance M. Wheeler, Elisa M. Miller, Nathan R. Neale, Rachelle Ihly, Jeffrey L. Blackburn, and Robert C. Tenent

Subjects

Materials science, Science, General Physics and Astronomy, Halide, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Article, General Biochemistry, Genetics and Molecular Biology, Dissociation (chemistry), Transmittance, Energy transformation, lcsh:Science, Multidisciplinary, business.industry, Photovoltaic system, General Chemistry, Energy consumption, Photothermal therapy, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Optoelectronics, lcsh:Q, 0210 nano-technology, business, Visible spectrum

Abstract

Materials with switchable absorption properties have been widely used for smart window applications to reduce energy consumption and enhance occupant comfort in buildings. In this work, we combine the benefits of smart windows with energy conversion by producing a photovoltaic device with a switchable absorber layer that dynamically responds to sunlight. Upon illumination, photothermal heating switches the absorber layer—composed of a metal halide perovskite-methylamine complex—from a transparent state (68% visible transmittance) to an absorbing, photovoltaic colored state (less than 3% visible transmittance) due to dissociation of methylamine. After cooling, the methylamine complex is re-formed, returning the absorber layer to the transparent state in which the device acts as a window to visible light. The thermodynamics of switching and performance of the device are described. This work validates a photovoltaic window technology that circumvents the fundamental tradeoff between efficient solar conversion and high visible light transmittance that limits conventional semitransparent PV window designs., Conventional smart windows with tunable transparency are based on electrochromic systems that consumes energy. Here Wheeler et al. demonstrate a halide perovskite based photo-switchable window that dynamically responds to sunlight and change colors via reversible phase transitions.

Published

2017

14. Low-Temperature Single Carbon Nanotube Spectroscopy of sp

Author

Xiaowei, He, Brendan J, Gifford, Nicolai F, Hartmann, Rachelle, Ihly, Xuedan, Ma, Svetlana V, Kilina, Yue, Luo, Kamran, Shayan, Stefan, Strauf, Jeffrey L, Blackburn, Sergei, Tretiak, Stephen K, Doorn, and Han, Htoon

Abstract

Aiming to unravel the relationship between chemical configuration and electronic structure of sp

Published

2017

15. PbSe Quantum Dot Field-Effect Transistors with Air-Stable Electron Mobilities above 7 cm2 V–1 s–1

Author

John C. Hemminger, Markelle Gibbs, Yao Liu, Matt Law, Craig L. Perkins, Nathan Crawford, Yu Liu, Jason Tolentino, and Rachelle Ihly

Subjects

Materials science, Transistors, Electronic, Passivation, Bioengineering, Electron, chemistry.chemical_compound, Atomic layer deposition, Quantum Dots, General Materials Science, Particle Size, Selenium Compounds, Lead selenide, Surface states, business.industry, Air, Mechanical Engineering, Equipment Design, General Chemistry, Condensed Matter Physics, Amorphous solid, Lead, chemistry, Quantum dot, Optoelectronics, Field-effect transistor, business

Abstract

PbSe quantum dot (QD) field effect transistors (FETs) with air-stable electron mobilities above 7 cm(2) V(-1) s(-1) are made by infilling sulfide-capped QD films with amorphous alumina using low-temperature atomic layer deposition (ALD). This high mobility is achieved by combining strong electronic coupling (from the ultrasmall sulfide ligands) with passivation of surface states by the ALD coating. A series of control experiments rule out alternative explanations. Partial infilling tunes the electrical characteristics of the FETs.

Published

2013

16. Tailored semiconducting carbon nanotube networks with enhanced thermoelectric properties

Author

Ben H. Zhou, Kevin S. Mistry, Elisa M. Miller, Rachelle Ihly, Barry L. Zink, Jeffrey L. Blackburn, Devin Wesenberg, A. D. Avery, Jounghee Lee, Sarah Lucienne Guillot, Yong-Hyun Kim, Eui Sup Lee, and Andrew J. Ferguson

Subjects

Materials science, Renewable Energy, Sustainability and the Environment, business.industry, Energy Engineering and Power Technology, Nanotechnology, 02 engineering and technology, Carbon nanotube, 010402 general chemistry, 021001 nanoscience & nanotechnology, Solar energy, Thermoelectric materials, 01 natural sciences, 0104 chemical sciences, Electronic, Optical and Magnetic Materials, law.invention, Fuel Technology, Thermal conductivity, law, Thermoelectric effect, Thin film, 0210 nano-technology, business, Electronic materials

Abstract

Organic thermoelectric materials are emerging as low-cost, versatile alternatives to more established inorganic ones. Avery et al. report carbon nanotube-based materials with selected properties that exhibit enhanced thermoelectric performance.

Published

2016

17. The Photothermal Stability of PbS Quantum Dot Solids

Author

Yao Liu, Markelle Gibbs, Jason Tolentino, Matt Law, and Rachelle Ihly

Subjects

Materials science, Absorption spectroscopy, business.industry, technology, industry, and agriculture, General Engineering, food and beverages, General Physics and Astronomy, Photothermal therapy, medicine.disease_cause, Amorphous solid, Atomic layer deposition, Nanocrystal, Quantum dot, Transmission electron microscopy, medicine, Optoelectronics, General Materials Science, business, Ultraviolet

Abstract

We combine optical absorption spectroscopy, ex situ transmission electron microscopy (TEM) imaging, and variable-temperature measurements to study the effect of ultraviolet (UV) light and heat treatments on ethanedithiol-treated PbS quantum dot (QD) films as a function of ambient atmosphere, temperature, and QD size. Film aging occurs mainly by oxidation or ripening and sintering depending on QD size and the presence of oxygen. We can stop QD oxidation and greatly suppress ripening by infilling the films with amorphous Al(2)O(3) using room-temperature atomic layer deposition (ALD).

Published

2011

18. (Invited) Improved Charge and Exciton Transport in Polymer-Removed SWCNT Thin Films: Implications for Photovoltaic and Thermoelectric Energy Harvesting

Author

Andrew John Ferguson, Jeffrey L. Blackburn, Stephanie Hart, Hyun Suk Kang, Rachelle Ihly, Bradley A. MacLeod, and Noah H. Stanton

Abstract

The chemical and physical structure of semiconducting single-walled carbon nanotubes (SWCNTs) results in optical and electronic properties of promise for a wide variety of applications. Until quite recently the presence of metallic SWCNT impurities has hampered efforts to gain a deeper understanding of their true potential, with the additional complication that most commercially available materials contain tens of different chiral species. Significant effort has been devoted to elegant enrichment strategies aimed at extracting tailored semiconducting SWCNT species from the raw soot, from the use of subtly tunable surfactant interactions to the exploitation of specific DNA sequences. However, conjugated polymers, typically based on the fluorene moiety, appear to show the greatest promise with regards to their high selectivity and viability for scalable manufacturing approaches. Unfortunately, the van de Waals forces between the pi-electron systems of the polymer and SWCNT that enable the selective extraction of semiconducting SWCNTs with high purity also make removal of the polymer difficult. Since these polymers typically have a wide bandgap they act as an insulating coating on the surface of the individual SWCNTs within functional networks, inhibiting the transport of energy in the form of excitons and/or charge carriers. Here we demonstrate approaches aimed at replacing the strongly-bound polymers with variants that can be removed using simple solution-based chemical strategies, resulting in networks with vastly improved energy transport properties. We show that removal of the polymer results in a significant enhancement of the charge carrier mobility and electrical conductivity in the SWCNT networks, allowing optimization of the thermoelectric properties for both p-type and n-type transport. Finally, we extend the approach to samples strongly enriched in a single chiral SWCNT species, which allows us to employ transient spectroscopic techniques to probe enhanced exciton transport through the SWCNT network with high spectral fidelity. Our studies highlight a methodology by which high-performance SWCNT thin films can be prepared that could realize their potential for electronic and optoelectronic applications.

Published

2018

19. (Invited) Diameter-Dependent Optical Absorption and Energy Transfer from Encapsulated Dye Molecules to Single Wall Carbon Nanotubes

Author

Wim Wenseleers, Stein Van Bezouw, Jochen Campo, Sofie Cambré, Joeri Defillet, Dylan Arias, Rachelle Ihly, Andrew John Ferguson, Justin C. Johnson, and Jeffrey L. Blackburn

Abstract

The hollow core and well-defined diameters of single-walled carbon nanotubes (SWCNTs) allow for creation of unique one-dimensional hybrid structures by encapsulation of various molecules. For instance, we previously demonstrated that in this way dipolar dye molecules can be naturally aligned in an ideal head-to-tail arrangement to create assemblies with a giant total nonlinear optical response.[1] Here, we show that the optical properties of dye molecules encapsulated in SWCNTs can be strongly modulated by the SWCNT diameter, indicating very specific diameter-dependent stacking and interactions of the molecules. The filling is thoroughly characterized by optical absorption, resonant Raman, and two-dimensional infrared photoluminescence excitation (PLE) spectroscopy. Energy transfer probed by PLE spectroscopy shows the absorption spectrum of the dyes to be strongly diameter-dependent, and transient absorption spectroscopy, simultaneously probing the encapsulated dyes and the host SWCNTs, demonstrates sub-picosecond EET from encapsulated molecules to the host SWCNTs. The design of these functional hybrid systems, with tuneable dye absorption, EET depending on the SWCNT diameter and the ability to remove all metallic SWCNTs by subsequent separation, demonstrates potential for implementation in dedicated photo-conversion devices. [1] S. Cambré, J. Campo et al., Nature Nanotechnol. 10, 248 (2015).

Published

2018

20. Tuning the driving force for exciton dissociation in single-walled carbon nanotube heterojunctions

Author

Kevin S. Mistry, Rachelle Ihly, Jeffrey L. Blackburn, Bryon W. Larson, Tyler T. Clikeman, Steven H. Strauss, Garry Rumbles, Obadiah G. Reid, Andrew J. Ferguson, and Olga V. Boltalina

Subjects

Fullerene, Chemistry, General Chemical Engineering, Selective chemistry of single-walled nanotubes, Nanotechnology, 02 engineering and technology, General Chemistry, Carbon nanotube, 010402 general chemistry, 021001 nanoscience & nanotechnology, Solar fuel, 01 natural sciences, Acceptor, Photoinduced electron transfer, 0104 chemical sciences, law.invention, Optical properties of carbon nanotubes, Condensed Matter::Materials Science, Electron transfer, law, Chemical physics, Physics::Chemical Physics, 0210 nano-technology

Abstract

Understanding the kinetics and energetics of interfacial electron transfer in molecular systems is crucial for the development of a broad array of technologies, including photovoltaics, solar fuel systems and energy storage. The Marcus formulation for electron transfer relates the thermodynamic driving force and reorganization energy for charge transfer between a given donor/acceptor pair to the kinetics and yield of electron transfer. Here we investigated the influence of the thermodynamic driving force for photoinduced electron transfer (PET) between single-walled carbon nanotubes (SWCNTs) and fullerene derivatives by employing time-resolved microwave conductivity as a sensitive probe of interfacial exciton dissociation. For the first time, we observed the Marcus inverted region (in which driving force exceeds reorganization energy) and quantified the reorganization energy for PET for a model SWCNT/acceptor system. The small reorganization energies (about 130 meV, most of which probably arises from the fullerene acceptors) are beneficial in minimizing energy loss in photoconversion schemes.

Published

2015

21. Isolation of1 nm Diameter Single-Wall Carbon Nanotube Species Using Aqueous Two-Phase Extraction

Author

Erik H. Haroz, Stephen K. Doorn, Stephanie Lam, Angela R. Hight Walker, Ming Zheng, Jeffrey A. Fagan, Hui Gui, Jeffrey R. Simpson, Rachelle Ihly, and Jeffrey L. Blackburn

Subjects

Range (particle radiation), Aqueous solution, Materials science, Extraction (chemistry), General Engineering, General Physics and Astronomy, Carbon nanotube, law.invention, Metal, Electric arc, Chemical engineering, Pulmonary surfactant, law, Phase (matter), visual_art, visual_art.visual_art_medium, General Materials Science, Composite material

Abstract

In this contribution we demonstrate the effective separation of single-wall carbon nanotube (SWCNT) species with diameters larger than 1 nm through multistage aqueous two-phase extraction (ATPE), including isolation at the near-monochiral species level up to at least the diameter range of SWCNTs synthesized by electric arc synthesis (1.3-1.6 nm). We also demonstrate that refined species are readily obtained from both the metallic and semiconducting subpopulations of SWCNTs and that this methodology is effective for multiple SWCNT raw materials. Using these data, we report an empirical function for the necessary surfactant concentrations in the ATPE method for separating different SWCNTs into either the lower or upper phase as a function of SWCNT diameter. This empirical correlation enables predictive separation design and identifies a subset of SWCNTs that behave unusually as compared to other species. These results not only dramatically increase the range of SWCNT diameters to which species selective separation can be achieved but also demonstrate that aqueous two-phase separations can be designed across experimentally accessible ranges of surfactant concentrations to controllably separate SWCNT populations of very small (∼0.62 nm) to very large diameters (1.7 nm). Together, the results reported here indicate that total separation of all SWCNT species is likely feasible by the ATPE method, especially given future development of multistage automated extraction techniques.

Published

2015

22. Diameter-Dependent Excitation Energy Transfer for Enhanced Semiconducting Single-Walled Carbon Nanotube Solar Photoconversion

Author

Rachelle Ihly, Stein van Bezouw, Dylan Arias, Sofie Cambre, Jochen Campo, Andrew John Ferguson, Justin C. Johnson, Wim Wenseleers, and Jeffrey L. Blackburn

Abstract

Tremendous progress and innovation has ushered the incorporation of semiconducting single-walled carbon nanotubes (s-SWCNTs) as active components into organic/inorganic/hybrid solar cells and thermoelectrics. For solar photoconversion, strong and tunable absorption is necessitated, suggesting that s-SWCNTs can play a role as light-harvesting components, however the narrow and distinct excitonic optical transitions found in s-SWCNT systems limit broad-band absorption. As such, we introduce encapsulation of small molecules within the endohedral volume of s-SWCNTs as a route to increase and extend light absorption in regions outside s-SWCNT excitonic transitions. Creation of this self-assembled supra-molecular system can strongly modify the opto-electronic properties of both the s-SWCNT and encapsulated molecule. We investigate excitation energy transfer occurring from encapsulated dye molecules to s-SWCNTs, which results in luminescent SWCNT excitons. We exploit the high-throughput and chiral selectivity of polyfluorene wrapping methods to generate dispersions of s-SWCNTs with dye encapsulation. We demonstrate that the selectivity of the polyfluorene polymer for semiconducting chiral distributions is not affected by the presence of encapsulated molecules. Tracking the excited state transient absorption signatures of excitation energy transfer provides detailed information regarding dynamics of both the encapsulated dye and s-SWCNTs. We observe sub-picosecond excitation energy transfer of excitons generated in dye molecules to the surrounding s-SWCNTs. Photoluminescence excitation maps reveal that the absorption of encapsulated dye molecules depends sensitively on the diameter of the s-SWCNT in which they are encapsulated. We consider a simple molecular exciton model to describe aggregate formation within the s-SWCNT endohedral volume, which reveals that the dye molecules adopt unique aggregate structures that are defined both by a competition between intermolecular interactions between the dye molecules and confinement effects due to the s-SWCNT diameter. Small molecule encapsulation in s-SWCNTs serves as a strong platform to control intermolecular interactions in small molecule systems through confinement, which opens up the possibility of enhancing photo-induced extraction of energy and charge in s-SWCNTs solar photoconversion systems.

Published

2017

23. (Invited) Less Is More: Thermoelectric Performance Enhancements in Polymer-Free Semiconducting Single-Walled Carbon Nanotube Networks

Author

Andrew John Ferguson, Brenna Norton-Baker, Rachelle Ihly, Isaac E. Gould, Noah J. Stanton, Bradley A. MacLeod, Azure D. Avery, Zbyslaw R. Owczarczyk, and Jeffrey L. Blackburn

Abstract

There is a growing interest in the use of carbon nanostructures for a variety of electronic and optoelectronic technologies, including energy harvesting applications such as photovoltaics (PV) and thermoelectrics (TE). We will present a series of studies aimed at improving the TE performance of semiconducting single-walled carbon nanotube (s-SWCNT) thin film networks. The optical and electrical performance of SWCNT ensembles is often limited by the presence of metallic single-walled carbon nanotube (m-SWCNT). We will demonstrate a polymer-based purification strategy that effectively eliminates these, and other impurities, from the raw material, leaving s-SWCNTs in extremely high purity. Modification of this extraction process produces s-SWCNT thin film networks where the polymer can be completely removed, resulting in close tube-tube contacts in a dense s-SWCNT network. Removal of the polymer in the solid state, rather than in solution, also minimizes nanotube bundling during network formation. By controlling the bundle size and extent of polymer remaining in the s-SWCNT network we demonstrate TE power factors that almost double the performance of s-SWCNT networks previously demonstrated. We trace the improved performance to an enhanced electrical conductivity, resulting from improved doping and strongly enhanced charge carrier mobility, and analyze our data within the framework of a recently developed thermoelectric transport model. Finally, we demonstrate that the removal of the polymer from the s-SWCNT network has negligible impact on the thermal conductivity, which appears to be limited by dopant-induced phonon scattering processes. These observations demonstrate the ability to exert exquisite control of the thermoelectric performance by controlling the composition of the s-SWCNT network and tuning the carrier density (i.e., Fermi energy), and touts SWCNTs as an avenue for realizing thermally stable room temperature thermoelectric devices fashioned from inexpensive and abundant organic constituents.

Published

2017

24. (Invited) Effects of Residual Wrapping Polymer on Charge and Exciton Transport in Semiconducting SWCNT Thin Films

Author

Jeffrey L. Blackburn, Brenna Norton-Baker, Isaac E. Gould, Bradley A. MacLeod, Zbyslaw R. Owczarczyk, Noah J. Stanton, Rachelle Ihly, Stephen K. Doorn, and Andrew John Ferguson

Abstract

The optical and electrical properties of single-walled carbon nanotubes (SWCNTs) make them attractive for a number of energy conversion devices, including thin-film photovoltaics and thermoelectrics. Both fundamental studies and device efficiencies have benefited from the ability to selectively extract semiconducting SWCNTs (s-SWCNTs) with high yield, purity, and throughput with pi-congujated semiconducting polymers such as polyfluorenes. However, it has proven to be challenging to quantitatively remove these polymers after selective extraction of s-SWCNTs, so thin films prepared from polyfluorene-based dispersions typically have significant amounts of residual polymer. Since charge and exciton transport within s-SWCNT thin films can be sensitive to the degree of inter-nanotube electronic coupling, the ultimate effects of this residual polymer on transport are unclear although they are likely to be deleterious. A number of polymers have recently emerged that can be decomposed into monomers after selective extraction of s-SWCNTs, enabling thin s-SWCNT film fabrication in the complete absence of residual wrapping polymer. In this presentation, I will discuss our recent results demonstrating large improvements to transport for films that are prepared with a removable polymer. These improvements translate directly into improved performance for a variety of thin-film devices based on s-SWCNTs.

Published

2017

25. Imaging interfacial layers and internal fields in nanocrystalline junctions

Author

Jianbing Zhang, Joseph M. Luther, Sanjini U. Nanayakkara, Rachelle Ihly, Matt Law, and Jianbo Gao

Subjects

Materials science, business.industry, Heterojunction, Nanotechnology, Conductive atomic force microscopy, Hybrid solar cell, Quantum dot solar cell, Polymer solar cell, law.invention, Multiple exciton generation, Quantum dot, law, Solar cell, Optoelectronics, business

Abstract

Nanotechnology will likely play a large role in developing future-generation solar photoconversion concepts. Thus, improved resolution or new techniques with the ability to characterize electronic properties of exceptionally small features could greatly aid device design. For example, photovoltaic devices with conductive films of colloidally synthesized PbSe quantum dots (QDs) possess external quantum efficiencies in the blue region of the solar spectrum greater than 100% due to multiple exciton generation (MEG) (where a high-energy photon can produce multiple electron-hole pairs) (1). This greatly motivates continued research on this type of solar cell that has the potential to achieve >40% power conversion efficiency (2). The state-of-the-art (highest overall efficiency) optimized structure for lead chalcogenide QD solar cells uses a variety of interfacial layers that play an important role in the device functionality. The p-n heterojunction (3) model is often used to describe the operation of QD solar cells despite the complex electronic structure of a disordered array of QDs acting as a macroscopic thin-film semiconductor (4). Advancements in device efficiency could follow better understanding of energetics along interfaces, throughout coupled films, and within individual nanostructures. Atomic force microscopy (AFM) techniques offer exceptional spatial resolution that can resolve such properties within devices and individual structures. Scanning Kelvin probe microscopy (SKPM) is one such technique that can accomplish these goals. We have correlated the contact potential difference between a conductive AFM tip and the layers within an operating colloidal QD solar cell with device cross-section exposed. SKPM can also be used on isolated nanostructures to visualize regions of localized band bending and space charge.

Published

2014

26. (Invited) Photoinduced Electron Transfer Processes of Trifluorinated Molecules Dispersed in Conjugated Polymer Films and at Interfaces with Swcnts

Author

Garry Rumbles, Jeffrey L. Blackburn, Rachelle Ihly, Obadiah Reid, Jaehong Park, Steven H. Strauss, Olga V. Boltalina, and David C Coffey

Abstract

The use of a Marcus formulation to describe photo-induced electron transfer processes in the complex blends of conjugated polymers and fullerenes associated with organic photovoltaics is rare. The conventional approach considers the polymer and fullerene to form a type II band offset similar to a picture for two inorganic semiconductors. A motivation for this presentation is to ask whether this simple model is correct and only the energetics need be considered when examining the driving force for the photo-induced electron transfer process. Or whether a re-organization energy is also required to describe the effect and therefore an optimum driving force is required to realize high charge separation yields. This presentation will describe two studies using a series of trifluoromethylfullerenes (TMFs) dispersed at low concentration in a conjugated polymer film or in a bilayer forming an interface with a layer of chiral-pure single-walled carbon nanotubes (SWCNTs). The fullerene series provides exquisite control over a wide range of reduction potentials of the fullerene, and can thus influence the driving force for photo-induced electron transfer studies. In both experiments, the use of the electrodeless technique of flash photolysis, time-resolved microwave conductivity (fp-TRMC) which provides a sensitive probe of the yield and kinetics of charges generated in both systems.

Published

2016

27. (Invited) Thermoelectric Properties of Semiconducting Single-Walled Carbon Nanotube Networks

Author

Andrew John Ferguson, Azure D. Avery, Brenna Norton-Baker, Ben Zhou, Jounghee Lee, Eui-Sup Lee, Elisa M. Miller, Rachelle Ihly, Devin Wesenberg, Kevin S. Mistry, Sarah Lucienne Guillot, Barry L. Zink, Yong-Hyun Kim, and Jeffrey L. Blackburn

Abstract

Nanostructured organic semiconductors (OSCs), including single-walled carbon nanotubes (SWCNTs), offer a number of intriguing technological characteristics for thermoelectric applications, such as earth-abundant raw materials, low-cost deposition, and flexible form factors. We will initially present a series of experiments focused on understanding the thermoelectric performance of enriched semiconducting SWCNT networks dispersed in a wide bandgap semiconducting polymer matrix, followed by more recent work aimed at understanding the role that the semiconducting polymer plays in the observed transport properties. Rational choice of the starting SWCNT material and the semiconducting polymer allows us to sensitively tune the s-SWCNT diameter and band gap distributions within the composites. Consistent with theoretical calculations that consider the density of electronic states in individual s-SWCNTs, we observe a distinct dependence of the thermopower and thermoelectric power factor on the bandgap (or diameter) of the carbon nanotubes. We have measured large thermopower values (as high as ~2,500 µV/K for s-SWCNT networks with very low electrical conductivity) and impressive thermoelectric power factor as large as ~350 µW/m·K2. By varying the carrier density injected into the s-SWCNT networks by a stable charge-transfer dopant, we are able to probe the relationship between the electrical conductivity and Seebeck coefficient (thermopower) in the s-SWCNT networks as a function of the carrier density and position of the Fermi energy. For carbon nanotubes prepared by high-pressure carbon monoxide (HiPCO) conversion, as we tune the carrier density, we are able to maintain a thermopower above 100 µV/K over almost the entire range of hole densities, corresponding to conductivities up to 40,000 S/m, resulting in a thermoelectric power factor of >300 µW/m·K2. These studies suggest that the low dimensionality of the SWCNTs has a stronger impact on the electrical conductivity than the thermopower, implying that they are less strongly coupled in these systems than is observed for compound inorganic semiconductors. By modifying an approach that allows us to strip the dispersing polymer from the s-SWCNTs we were able to demonstrate that the polymer appears to play no role in modifying the barriers to electrical transport present at tube-tube junctions, and simply controls the extent of nanotube bundling and thereby the surface area available to the charge-transfer dopant. This study also indicates that densification of the s-SWCNT network results in a two-fold enhancement of the thermoelectric power factor, suggesting that careful control of the amount and nature of the matrix material is required for high-performance s-SWCNT thermoelectric materials. Finally, we present a data from sensitive transport measurement technique, based on a microfabricated silicon nitride thermal isolation platform, to probe transport in the s-SWCNT networks, showing that the thermoelectric figure of merit (zT) is positively correlated with the measurement temperature, increasing by a factor of ~2.5 from 300 K to 350 K. These observations demonstrate the ability to exert exquisite control of the thermoelectric performance by controlling the composition of the s-SWCNT network and tuning the carrier density (i.e., Fermi energy), and touts SWCNTs as an avenue for realizing thermally stable room temperature thermoelectric devices fashioned from inexpensive and abundant organic constituents.

Published

2016

28. Studies of Fundamental Charge Transfer Processes in Organic Radical-Containing Polymer Films Using Spectroelectrochemical Techniques

Author

Barbara Katherine Hughes, Wade A. Braunecker, Justin C. Johnson, Rachelle Ihly, and Thomas Gennett

Abstract

The electrochemical redox reaction of stable organic polymer materials with unpaired electrons is a relatively new and exciting area of battery research. Specifically, stable nitroxyl radical-containing polymers have displayed excellent characteristics as the cathode-active material and have presented themselves as a low-cost and environmentally friendly alternative to the current Li-ion battery technologies. However, with the advancement of organic-radical battery technology there is a lack of fundamental understanding of the dynamics of charge transfer processes, electronic and ionic, within organic radical-containing polymers. In order to elucidate these mechanisms further, we have conducted extensive spectroscopic and spectroelectrochemical investigations of macromolecular systems containing nitroxide radicals. We have employed spectroelectrochemical experiments for our study of stable radical polymer systems whereby, kinetic information was determined, specifically rates of charge transfer and ion diffusion within our polymer systems. A key factor determining the success of such experiments is that the material of interest exhibits a strong absorption coefficient and allows for measurement in the concentration regime conducive for electrochemical studies (typically up to 10 mM). For this reason, of the available stable nitroxyl radical systems, we have chosen first to study the oxidation of a nitronyl nitroxide derivative. To simulate an electrode architecture, spectroelectrochemical studies were performed in the solid state, and the efficacy of charge transfer was investigated as a function of film thickness, counter-ion size, and radical polymer composition in “neat” polymer films. The addition of semiconducting carbon nanotubes at various loadings was also explored as changes to film conductivity has significant implications for rates of ion transport.

Published

2016

29. (Invited) Charge Separation and Recombination at Single-Walled Carbon Nanotube Photovoltaic Interfaces

Author

Jeffrey L. Blackburn, Andrew John Ferguson, Obadiah Reid, Rachelle Ihly, Anne-Marie Dowgiallo, Philip Schulz, Mengjin Yang, Kai Zhu, and Joseph Berry

Subjects

Condensed Matter::Materials Science, Physics::Atomic and Molecular Clusters

Abstract

Single-wall carbon nanotubes (SWCNTs) have several fundamental properties that make them attractive for photovoltaics, including high electron and hole mobilities, size-tunable ionization potentials and electron affinities in an energy range relevant to many PV devices, and strong optical transitions in the visible and near-infrared spectral regions. These properties have motivated the use of thin SWCNT films for both charge extraction in PV electrodes and charge generation in PV active layers. In both of these applications, the time scales and mechanisms for interfacial charge separation and recombination play crucial roles in determining the resulting photovoltaic efficiencies. In this presentation, I will discuss time-resolved spectroscopic studies of charge separation and recombination across PV-relevant interfaces with SWCNTs. I will discuss two model interfaces – (1) SWCNT/perovskite interfaces, where the SWCNTs are used to extract holes from the perovskite active layer, and (2) SWCNT/fullerene interfaces, where charges are generated via interfacial dissociation of SWCNT excitons. Following the evolution of excitons and charges with multiple techniques provides a platform for understanding the time scales and quantum yields for interfacial charge transfer, recombination rates and mechanisms, and the dependence of charge transfer rates and yields on interfacial energetics. These time-resolved measurements are correlated with device results to provide a window into the connection between interfacial energetics/kinetics and device function.

Published

2016

30. Dependence of carrier mobility on nanocrystal size and ligand length in PbSe nanocrystal solids

Author

James Puthussery, Matt Law, Yao Liu, Rachelle Ihly, Markelle Gibbs, Steven J. Gaik, and Hugh W. Hillhouse

Subjects

Electron mobility, Materials science, business.industry, Mechanical Engineering, Bioengineering, Nanotechnology, General Chemistry, Electron, Orders of magnitude (numbers), Condensed Matter Physics, Electron transport chain, Molecular physics, Nanostructures, Electron Transport, Semiconductor, Nanocrystal, Lead, Semiconductors, Quantum dot, Materials Testing, General Materials Science, Particle size, Particle Size, business, Selenium Compounds

Abstract

We measure the room-temperature electron and hole field-effect mobilities (micro(FE)) of a series of alkanedithiol-treated PbSe nanocrystal (NC) films as a function of NC size and the length of the alkane chain. We find that carrier mobilities decrease exponentially with increasing ligand length according to the scaling parameter beta = 1.08-1.10 A(-1), as expected for hopping transport in granular conductors with alkane tunnel barriers. An electronic coupling energy as large as 8 meV is calculated from the mobility data. Mobilities increase by 1-2 orders of magnitude with increasing NC diameter (up to 0.07 and 0.03 cm(2) V(-1) s(-1) for electrons and holes, respectively); the electron mobility peaks at a NC size of approximately 6 nm and then decreases for larger NCs, whereas the hole mobility shows a monotonic increase. The size-mobility trends seem to be driven primarily by the smaller number of hops required for transport through arrays of larger NCs but may also reflect a systematic decrease in the depth of trap states with decreasing NC band gap. We find that carrier mobility is independent of the polydispersity of the NC samples, which can be understood if percolation networks of the larger-diameter, smaller-band-gap NCs carry most of the current in these NC solids. Our results establish a baseline for mobility trends in PbSe NC solids, with implications for fabricating high-mobility NC-based optoelectronic devices.

Published

2010

31. Probing the complete folding trajectory of a DNA hairpin using dual beam fluorescence fluctuation spectroscopy

Author

Jaemyeong Jung, Rachelle Ihly, Alan Van Orden, Eric Scott, and Ming Yu

Subjects

Kinetics, Time constant, DNA, Fluorescence, Surfaces, Coatings and Films, Folding (chemistry), chemistry.chemical_compound, Crystallography, Spectrometry, Fluorescence, chemistry, Chemical physics, Metastability, Materials Chemistry, Nucleic Acid Conformation, Transition Temperature, A-DNA, Physical and Theoretical Chemistry, Spectroscopy

Abstract

The conformational fluctuations of dye-quencher labeled DNA hairpin molecules in aqueous solution were investigated using dual probe beam fluorescence fluctuation spectroscopy. The measurements revealed the flow and diffusion times of the DNA molecules through two spatially offset optical probe regions, the absolute and relative concentrations of each conformational substate of the DNA, and the kinetics of the DNA hairpin folding and unfolding reactions in the 1 micros to 10 ms time range. A DNA hairpin containing a 21-nucleotide polythymine loop and a 4-base pair stem exhibited double exponential relaxation kinetics, with time constants of 84 and 393 micros. This confirms that folding and melting of the DNA hairpin structure is not a two state process but proceeds by way of metastable intermediate states. The fast time constant corresponds to formation and unfolding of an intermediate, and the slow time constant is due to formation and disruption of the fully base-paired stem. This is consistent with a previous study of a similar DNA hairpin with a 5-base pair stem, in which the fast reaction was attributed to the fluctuations of an intermediate DNA conformation [J. Am. Chem. Soc. 2006, 128, 1240-1249]. In that case, reactions involving the native conformation could not be observed directly due to the limited observation time range of the fluorescence correlation spectroscopy experiment. The intermediate states of the DNA hairpins are suggested to be due to a collapsed ensemble of folded hairpins containing various partially folded or misfolded conformations.

Published

2007

32. (Invited) Charge Separation and Recombination at Semiconducting Single-Walled Carbon Nanotube Interfaces

Author

Jeffrey L. Blackburn, Anne-Marie Dowgiallo, Kevin Mistry, Rachelle Ihly, Andrew Ferguson, and Nikos Kopidakis

Subjects

Condensed Matter::Materials Science

Abstract

The time scales and mechanisms for interfacial charge separation and recombination play crucial roles in determining efficiencies of excitonic photovoltaics. Semiconducting SWCNTs are robust light absorbers that have garnered increasing attention as the electron-donating or electron-accepting components in excitonic solar cells. In particular, near-infrared photons are harvested efficiently by semiconducting single-walled carbon nanotubes (SWCNTs) paired with appropriate electron acceptors, such as fullerenes (e.g. C60). While the reported AM1.5 power conversion efficiencies of such devices are steadily increasing, significant improvements remain to be made if a better fundamental understanding is reached for the kinetics and thermodynamics of exciton dissociation and charge recombination. In this presentation, I will discuss a number of time-resolved spectroscopic studies on donor:acceptor heterojunctions that incorporate semiconducting SWCNTs with widely varying band gaps and frontier orbital energies. Following the evolution of excitons and charges with multiple techniques provides a platform for understanding the time scales and quantum yields for interfacial charge transfer, recombination rates and mechanisms, and the dependence of charge transfer rates and yields on interfacial energetics.

Published

2015

33. Probing the Complete Folding Trajectory of a DNA Hairpin Using Dual Beam Fluorescence Fluctuation Spectroscopy.

Author

Jaemyeong Jung, Rachelle Ihly, Eric Scott, Ming Yu, and Alan Van Orden

Subjects

*NUCLEIC acids, *GENES, *DNA, *MOLECULAR genetics

Abstract

The conformational fluctuations of dye-quencher labeled DNA hairpin molecules in aqueous solution were investigated using dual probe beam fluorescence fluctuation spectroscopy. The measurements revealed the flow and diffusion times of the DNA molecules through two spatially offset optical probe regions, the absolute and relative concentrations of each conformational substate of the DNA, and the kinetics of the DNA hairpin folding and unfolding reactions in the 1 s to 10 ms time range. A DNA hairpin containing a 21-nucleotide polythymine loop and a 4-base pair stem exhibited double exponential relaxation kinetics, with time constants of 84 and 393 s. This confirms that folding and melting of the DNA hairpin structure is not a two state process but proceeds by way of metastable intermediate states. The fast time constant corresponds to formation and unfolding of an intermediate, and the slow time constant is due to formation and disruption of the fully base-paired stem. This is consistent with a previous study of a similar DNA hairpin with a 5-base pair stem, in which the fast reaction was attributed to the fluctuations of an intermediate DNA conformation J. Am. Chem. Soc.2006,128, 1240−1249. In that case, reactions involving the native conformation could not be observed directly due to the limited observation time range of the fluorescence correlation spectroscopy experiment. The intermediate states of the DNA hairpins are suggested to be due to a collapsed ensemble of folded hairpins containing various partially folded or misfolded conformations. [ABSTRACT FROM AUTHOR]

Published

2008