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1. Electron-Ion Coupling Breaks Energy Symmetry in Organic Electrochemical Transistors

Author

Bongartz, Lukas M., LeCroy, Garrett, Quill, Tyler J., Siemons, Nicholas, Dijk, Gerwin, Marks, Adam, Cheng, Christina, Kleemann, Hans, Leo, Karl, and Salleo, Alberto

Subjects
Condensed Matter - Materials Science, Condensed Matter - Disordered Systems and Neural Networks, Physics - Applied Physics
Abstract

Organic electrochemical transistors are extensively studied for applications ranging from bioelectronics to analog and neuromorphic computing. Despite significant advances, the fundamental interactions between the polymer semiconductor channel and the electrolyte, which critically determine the device performance, remain underexplored. Here, we examine the coupling between the benchmark semiconductor PEDOT:PSS and ionic liquids to explain the bistable and non-volatile behavior observed in OECTs. Using X-ray scattering and spectroscopy techniques, we demonstrate how the electrolyte modifies the channel composition, enhances molecular order, and reshapes the electronic and energetic landscape. Notably, the observed bistability arises from asymmetric and path-dependent energetics during doping and dedoping, resulting in two distinct, stable states, driven by a direct interaction between the electronic and ionic charge carriers. These findings highlight a compelling method to control charge carrier dynamics via the electrolyte, positioning it as a powerful yet underutilized tool for enabling novel device functionalities.

Published
2024

2. Direct X-Ray Measurements of Strain in Monolayer MoS$_{2}$ from Capping Layers and Geometrical Features

Author

Neilson, Kathryn, Jaikissoon, Marc, Zakhidov, Dante, Peña, Tara, Salleo, Alberto, Saraswat, Krishna, and Pop, Eric

Subjects
Condensed Matter - Materials Science
Abstract

Strain induced through fabrication, both by patterning and capping, can be used to change the properties of two-dimensional (2D) materials or other thin films. Here, we explore how capping layers impart strain to monolayer MoS$_{2}$ using direct x-ray diffraction measurements of the lattice. We first observe the impact of naturally-oxidized metal layers ($\sim$1.5 nm Al) and subsequently-deposited Al$_{2}$O$_{3}$ (15 nm to 25 nm thick) on the 2D material, and find that the strain imparted to MoS$_{2}$ is mainly controlled by the interfacial adhesion of the seed layer in addition to the substrate adhesion. Then, using test structures which mimic transistor contacts, we measure enhanced strain from such patterns compared to blanket films. Furthermore, we observe significant tensile strain - up to 2% in monolayer MoS$_{2}$, one of the largest experimental values to date on a rigid substrate - due to highly-stressed blanket metal capping layers. These results provide direct evidence supporting previous reports of strain effects in 2D material devices.

Published
2024

3. Towards Reverse-Engineering the Brain: Brain-Derived Neuromorphic Computing Approach with Photonic, Electronic, and Ionic Dynamicity in 3D integrated circuits

Author

Yoo, S. J. Ben, El-Srouji, Luis, Datta, Suman, Yu, Shimeng, Incorvia, Jean Anne, Salleo, Alberto, Sorger, Volker, Hu, Juejun, Kimerling, Lionel C, Bouchard, Kristofer, Geng, Joy, Chaudhuri, Rishidev, Ranganath, Charan, and O'Reilly, Randall

Subjects
Computer Science - Emerging Technologies, Computer Science - Neural and Evolutionary Computing, Physics - Optics
Abstract

The human brain has immense learning capabilities at extreme energy efficiencies and scale that no artificial system has been able to match. For decades, reverse engineering the brain has been one of the top priorities of science and technology research. Despite numerous efforts, conventional electronics-based methods have failed to match the scalability, energy efficiency, and self-supervised learning capabilities of the human brain. On the other hand, very recent progress in the development of new generations of photonic and electronic memristive materials, device technologies, and 3D electronic-photonic integrated circuits (3D EPIC ) promise to realize new brain-derived neuromorphic systems with comparable connectivity, density, energy-efficiency, and scalability. When combined with bio-realistic learning algorithms and architectures, it may be possible to realize an 'artificial brain' prototype with general self-learning capabilities. This paper argues the possibility of reverse-engineering the brain through architecting a prototype of a brain-derived neuromorphic computing system consisting of artificial electronic, ionic, photonic materials, devices, and circuits with dynamicity resembling the bio-plausible molecular, neuro/synaptic, neuro-circuit, and multi-structural hierarchical macro-circuits of the brain based on well-tested computational models. We further argue the importance of bio-plausible local learning algorithms applicable to the neuromorphic computing system that capture the flexible and adaptive unsupervised and self-supervised learning mechanisms central to human intelligence. Most importantly, we emphasize that the unique capabilities in brain-derived neuromorphic computing prototype systems will enable us to understand links between specific neuronal and network-level properties with system-level functioning and behavior., Comment: 15 pages, 12 figures

Published
2024

6. An ordered, self-assembled nanocomposite with efficient electronic and ionic transport

Author

Quill, Tyler J, LeCroy, Garrett, Halat, David M, Sheelamanthula, Rajendar, Marks, Adam, Grundy, Lorena S, McCulloch, Iain, Reimer, Jeffrey A, Balsara, Nitash P, Giovannitti, Alexander, Salleo, Alberto, and Takacs, Christopher J

Subjects
Engineering, Macromolecular and Materials Chemistry, Materials Engineering, Chemical Sciences, Nanoscience & Nanotechnology
Abstract

Mixed conductors-materials that can efficiently conduct both ionic and electronic species-are an important class of functional solids. Here we demonstrate an organic nanocomposite that spontaneously forms when mixing an organic semiconductor with an ionic liquid and exhibits efficient room-temperature mixed conduction. We use a polymer known to form a semicrystalline microstructure to template ion intercalation into the side-chain domains of the crystallites, which leaves electronic transport pathways intact. Thus, the resulting material is ordered, exhibiting alternating layers of rigid semiconducting sheets and soft ion-conducting layers. This unique dual-network microstructure leads to a dynamic ionic/electronic nanocomposite with liquid-like ionic transport and highly mobile electronic charges. Using a combination of operando X-ray scattering and in situ spectroscopy, we confirm the ordered structure of the nanocomposite and uncover the mechanisms that give rise to efficient electron transport. These results provide fundamental insights into charge transport in organic semiconductors, as well as suggesting a pathway towards future improvements in these nanocomposites.

Published
2023

7. Closing the loop between microstructure and charge transport in conjugated polymers by combining microscopy and simulation.

Author

Balhorn, Luke, MacPherson, Quinn, Bustillo, Karen, Takacs, Christopher, Spakowitz, Andrew, and Salleo, Alberto

Subjects
charge mobility, computational model, electron microscopy, organic electronics, Polymers, Semiconductors, Microscopy, Computer Simulation, Models, Molecular
Abstract

A grand challenge in materials science is to identify the impact of molecular composition and structure across a range of length scales on macroscopic properties. We demonstrate a unified experimental-theoretical framework that coordinates experimental measurements of mesoscale structure with molecular-level physical modeling to bridge multiple scales of physical behavior. Here we apply this framework to understand charge transport in a semiconducting polymer. Spatially-resolved nanodiffraction in a transmission electron microscope is combined with a self-consistent framework of the polymer chain statistics to yield a detailed picture of the polymer microstructure ranging from the molecular to device relevant scale. Using these data as inputs for charge transport calculations, the combined multiscale approach highlights the underrepresented role of defects in existing transport models. Short-range transport is shown to be more chaotic than is often pictured, with the drift velocity accounting for a small portion of overall charge motion. Local transport is sensitive to the alignment and geometry of polymer chains. At longer length scales, large domains and gradual grain boundaries funnel charges preferentially to certain regions, creating inhomogeneous charge distributions. While alignment generally improves mobility, these funneling effects negatively impact mobility. The microstructure is modified in silico to explore possible design rules, showing chain stiffness and alignment to be beneficial while local homogeneity has no positive effect. This combined approach creates a flexible and extensible pipeline for analyzing multiscale functional properties and a general strategy for extending the accesible length scales of experimental and theoretical probes by harnessing their combined strengths.

Published
2022

8. Impact of Side Chain Hydrophilicity on Packing, Swelling and Ion Interactions in Oxy-bithiophene Semiconductors

Author

Siemons, Nicholas, Pearce, Drew, Cendra, Camila, Yu, Hang, Tuladhar, Sachetan M., Hallani, Rawad K., Sheelamanthula, Rajendar, LeCroy, Garrett S., Siemons, Lucas, White, Andrew J. P., Mcculloch, Iain, Salleo, Alberto, Frost, Jarvist M., Giovannitti, Alexander, and Nelson, Jenny

Subjects
Condensed Matter - Soft Condensed Matter
Abstract

Exchanging hydrophobic alkyl-based side chains to hydrophilic glycol-based side chains is a widely adopted method for improving mixed-transport device performance, despite the impact on solid state packing and polymer-electrolyte interactions being poorly understood. Presented here is a Molecular Dynamics (MD) force field for modelling alkoxylated and glycolated polythiophenes. The force field is validated against known packing motifs for their monomer crystals. MD simulations, coupled with X-ray Diffraction (XRD), show that alkoxylated polythiophenes will pack with a `tilted stack' and straight interdigitating side chains, whilst their glycolated counterpart will pack with a `deflected stack' and an s-bend side chain configuration. MD simulations reveal water penetration pathways into the alkoxylated and glycolated crystals - through the {\pi}-stack and through the lamellar stack respectively. Finally, the two distinct ways tri-ethylene glycol polymers can bind to cations are revealed, showing the formation of a meta-stable single bound state, or an energetically deep double bound state, both with a strong side chain length dependance. The minimum energy pathways for the formation of the chelates are identified, showing the physical process through which cations can bind to one or two side chains of a glycolated polythiophene, with consequences for ion transport in bithiophene semiconductors., Comment: 10 pages, 4 figures

Published
2022
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10. 2022 Roadmap on Neuromorphic Computing and Engineering

Author

Christensen, Dennis V., Dittmann, Regina, Linares-Barranco, Bernabé, Sebastian, Abu, Gallo, Manuel Le, Redaelli, Andrea, Slesazeck, Stefan, Mikolajick, Thomas, Spiga, Sabina, Menzel, Stephan, Valov, Ilia, Milano, Gianluca, Ricciardi, Carlo, Liang, Shi-Jun, Miao, Feng, Lanza, Mario, Quill, Tyler J., Keene, Scott T., Salleo, Alberto, Grollier, Julie, Marković, Danijela, Mizrahi, Alice, Yao, Peng, Yang, J. Joshua, Indiveri, Giacomo, Strachan, John Paul, Datta, Suman, Vianello, Elisa, Valentian, Alexandre, Feldmann, Johannes, Li, Xuan, Pernice, Wolfram H. P., Bhaskaran, Harish, Furber, Steve, Neftci, Emre, Scherr, Franz, Maass, Wolfgang, Ramaswamy, Srikanth, Tapson, Jonathan, Panda, Priyadarshini, Kim, Youngeun, Tanaka, Gouhei, Thorpe, Simon, Bartolozzi, Chiara, Cleland, Thomas A., Posch, Christoph, Liu, Shih-Chii, Panuccio, Gabriella, Mahmud, Mufti, Mazumder, Arnab Neelim, Hosseini, Morteza, Mohsenin, Tinoosh, Donati, Elisa, Tolu, Silvia, Galeazzi, Roberto, Christensen, Martin Ejsing, Holm, Sune, Ielmini, Daniele, and Pryds, N.

Subjects
Computer Science - Emerging Technologies, Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Materials Science
Abstract

Modern computation based on the von Neumann architecture is today a mature cutting-edge science. In the Von Neumann architecture, processing and memory units are implemented as separate blocks interchanging data intensively and continuously. This data transfer is responsible for a large part of the power consumption. The next generation computer technology is expected to solve problems at the exascale with 1018 calculations each second. Even though these future computers will be incredibly powerful, if they are based on von Neumann type architectures, they will consume between 20 and 30 megawatts of power and will not have intrinsic physically built-in capabilities to learn or deal with complex data as our brain does. These needs can be addressed by neuromorphic computing systems which are inspired by the biological concepts of the human brain. This new generation of computers has the potential to be used for the storage and processing of large amounts of digital information with much lower power consumption than conventional processors. Among their potential future applications, an important niche is moving the control from data centers to edge devices. The aim of this Roadmap is to present a snapshot of the present state of neuromorphic technology and provide an opinion on the challenges and opportunities that the future holds in the major areas of neuromorphic technology, namely materials, devices, neuromorphic circuits, neuromorphic algorithms, applications, and ethics. The Roadmap is a collection of perspectives where leading researchers in the neuromorphic community provide their own view about the current state and the future challenges. We hope that this Roadmap will be a useful resource to readers outside this field, for those who are just entering the field, and for those who are well established in the neuromorphic community. https://doi.org/10.1088/2634-4386/ac4a83

Published
2021
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11. Unraveling the Unconventional Order of a High-Mobility Indacenodithiophene-Benzothiadiazole Copolymer

Author

Cendra, Camila, Balhorn, Luke, Zhang, Weimin, O'Hara, Kathryn, Bruening, Karsten, Tassone, Christopher J., Steinrück, Hans-Georg, Liang, Mengning, Toney, Michael F., McCulloch, Iain, Chabinyc, Michael L., Salleo, Alberto, and Takacs, Christopher J.

Subjects
Condensed Matter - Materials Science
Abstract

A new class of donor-acceptor (D-A) copolymers found to produce high charge carrier mobilities competitive with amorphous silicon ($> 1 cm^{2}V^{-1}s^{-1}$) exhibits the puzzling microstructure of substantial local order, however lacking long-range order and crystallinity previously deemed necessary for achieving high mobility. Here, we demonstrate the application of low-dose transmission electron microscopy to image and quantify the nanoscale and mesoscale organization of an archetypal D-A copolymer across areas comparable to electronic devices (~ $9 {\mu}m^{2}$). The local structure is spatially resolved by mapping the backbone (001) spacing reflection, revealing nanocrystallites of aligned polymer chains over nearly the entire film. Analysis of the nanoscale structure of its ordered domains suggests significant short- and medium-range order and preferential grain boundary orientations. Moreover, we provide insights into the rich, interconnected mesoscale organization of this new family of D-A copolymers by analysis of the local orientational spatial autocorrelations., Comment: 31 pages, 5 main figures, 10 supporting figures

Published
2021

12. High-speed ionic synaptic memory based on two-dimensional titanium carbide MXene

Author

Melianas, Armantas, Kang, Min-A, VahidMohammadi, Armin, Tian, Weiqian, Gogotsi, Yury, Salleo, Alberto, and Hamedi, Mahiar Max

Subjects
Physics - Applied Physics, Condensed Matter - Materials Science
Abstract

Synaptic devices with linear high-speed switching can accelerate learning in artificial neural networks (ANNs) embodied in hardware. Conventional resistive memories however suffer from high write noise and asymmetric conductance tuning, preventing parallel programming of ANN arrays as needed to surpass conventional computing efficiency. Electrochemical random-access memories (ECRAMs), where resistive switching occurs by ion insertion into a redox-active channel address these challenges due to their linear switching and low noise. ECRAMs using two-dimensional (2D) materials and metal oxides suffer from slow ion kinetics, whereas organic ECRAMs enable high-speed operation but face significant challenges towards on-chip integration due to poor temperature stability of polymers. Here, we demonstrate ECRAMs using 2D titanium carbide (Ti3C2Tx) MXene that combines the high speed of organics and the integration compatibility of inorganic materials in a single high-performance device. Our ECRAMs combine the speed, linearity, write noise, switching energy and endurance metrics essential for parallel acceleration of ANNs, and importantly, they are stable after heat treatment needed for back-end-of-line integration with Si electronics. The high speed and performance of these ECRAMs introduces MXenes, a large family of 2D carbides and nitrides with more than 30 compositions synthesized to date, as very promising candidates for devices operating at the nexus of electrochemistry and electronics., Comment: Fig. 4 now shows film stability up to 400C (replacing earlier 300C data). Section headings were also added to the main text

Published
2021

14. Dynamic lattice distortions driven by surface trapping in semiconductor nanocrystals

Author

Guzelturk, Burak, Cotts, Benjamin L., Jasrasaria, Dipti, Philbin, John P., Hanifi, David A., Koscher, Brent A., Balan, Arunima D., Curling, Ethan, Zajac, Marc, Park, Suji, Yazdani, Nuri, Nyby, Clara, Kamysbayev, Vladislav, Fischer, Stefan, Nett, Zach, Shen, Xiaozhe, Kozina, Michael E., Lin, Ming-Fu, Reid, Alexander H., Weathersby, Stephen P., Schaller, Richard D., Wood, Vanessa, Wang, Xijie, Dionne, Jennifer A., Talapin, Dmitri V., Alivisatos, A. Paul, Salleo, Alberto, Rabani, Eran, and Lindenberg, Aaron M.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Nonradiative processes limit optoelectronic functionality of nanocrystals and curb their device performance. Nevertheless, the dynamic structural origins of nonradiative relaxations in nanocrystals are not understood. Here, femtosecond electron diffraction measurements corroborated by atomistic simulations uncover transient lattice deformations accompanying radiationless electronic processes in semiconductor nanocrystals. Investigation of the excitation energy dependence shows that hot carriers created by a photon energy considerably larger than the bandgap induce structural distortions at nanocrystal surfaces on few picosecond timescales associated with the localization of trapped holes. On the other hand, carriers created by a photon energy close to the bandgap result in transient lattice heating that occurs on a much longer 200 ps timescale, governed by an Auger heating mechanism. Elucidation of the structural deformations associated with the surface trapping of hot holes provides atomic-scale insights into the mechanisms deteriorating optoelectronic performance and a pathway towards minimizing these losses in nanocrystal devices., Comment: 17 pages, 4 figures

Published
2021
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15. Uncovering the Effects of Metal Contacts on Monolayer MoS2

Author

Schauble, Kirstin, Zakhidov, Dante, Yalon, Eilam, Deshmukh, Sanchit, Grady, Ryan W., Cooley, Kayla A., McClellan, Connor J., Vaziri, Sam, Passarello, Donata, Mohney, Suzanne E., Toney, Michael F., Sood, A. K., Salleo, Alberto, and Pop, Eric

Subjects
Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Metal contacts are a key limiter to the electronic performance of two-dimensional (2D) semiconductor devices. Here we present a comprehensive study of contact interfaces between seven metals (Y, Sc, Ag, Al, Ti, Au, Ni, with work functions from 3.1 to 5.2 eV) and monolayer MoS2 grown by chemical vapor deposition. We evaporate thin metal films onto MoS2 and study the interfaces by Raman spectroscopy, X-ray photoelectron spectroscopy, X-ray diffraction, transmission electron microscopy, and electrical characterization. We uncover that, 1) ultrathin oxidized Al dopes MoS2 n-type (> 2x10^12 1/cm^2) without degrading its mobility, 2) Ag, Au, and Ni deposition causes varying levels of damage to MoS2 (broadening Raman E' peak from <3 1/cm to >6 1/cm), and 3) Ti, Sc, and Y react with MoS2. Reactive metals must be avoided in contacts to monolayer MoS2, but control studies reveal the reaction is mostly limited to the top layer of multilayer films. Finally, we find that 4) thin metals do not significantly strain MoS2, as confirmed by X-ray diffraction. These are important findings for metal contacts to MoS2, and broadly applicable to many other 2D semiconductors.

Published
2020
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17. Reversible Electrochemical Phase Change in Monolayer to Bulk MoTe2 by Ionic Liquid Gating

Author

Zakhidov, Dante, Rehn, Daniel A., Reed, Evan J., and Salleo, Alberto

Subjects
Condensed Matter - Materials Science
Abstract

Transition metal dichalcogenides (TMDs) exist in various crystal structures with semiconducting, semi-metallic, and metallic properties. The dynamic control of these phases is of immediate interest for next generation electronics such as phase change memories. Of the binary Mo and W-based TMDs, MoTe2 is attractive for electronic applications because it has the lowest energy difference (40 meV) between the semiconducting (2H) and semi-metallic (1T') phases, allowing for MoTe2 phase change by electrostatic doping. Here we report phase change between the 2H and 1T' polymorphs of MoTe2 in thicknesses ranging from the monolayer case to effective bulk (73nm) using an ionic liquid electrolyte at room temperature and in air. We find consistent evidence of a partially reversible 2H-1T' transition using in-situ Raman spectroscopy where the phase change occurs in the top-most layers of the MoTe2 flake. We find a thickness-dependent transition voltage where higher voltages are necessary to drive the phase change for thicker flakes. We also show evidence of electrochemical activity during the gating process by observation of Te metal deposition. This finding suggests the formation of Te vacancies which have been reported to lower the energy difference between the 2H and 1T' phase, potentially aiding the phase change process. Our discovery that the phase change can be achieved on the surface layer of bulk materials reveals that this electrochemical mechanism does not require isolation of a single layer and the effect may be more broadly applicable than previously thought., Comment: Paper is 15 pages with 7 figures. SI is 13 pages with 8 figures, 2 tables, and 1 video (not uploaded)

Published
2019

18. Reversible Doping and Photo Patterning of Polymer Nanowires

Author

Bedolla‐Valdez, Zaira I, Xiao, Rui, Cendra, Camila, Fergerson, Alice S, Chen, Zekun, Gonel, Goktug, Salleo, Alberto, Yu, Dong, and Moulé, Adam J

Subjects
Macromolecular and Materials Chemistry, Chemical Sciences, Engineering, Materials Engineering, Nanotechnology, doping, nanowires, organic electronics, photo patterning, polymers, Electrical and Electronic Engineering, Macromolecular and materials chemistry, Materials engineering
Abstract

Recent development of dopant induced solubility control (DISC) patterning of polymer semiconductors has enabled direct-write optical patterning of poly-3-hexylthiophene (P3HT) with diffraction limited resolution. Here, the optical DISC patterning technique to the most simple circuit element, a wire, is applied. Optical patterning of P3HT and P3HT doped with the molecular dopant 2,3,5,6-tetrafluoro-7,7,8,8-tetracyanoquinodimethane (F4TCNQ) wires with dimensions of 20–70 nm thickness, 200–900 nm width, and 40 μm length is demonstrated. In addition, optical patterning of wire patterns like “L” bends and “T” junctions without changing the diameter or thickness of the wires at the junctions is demonstrated. The wires themselves show up to 0.034 S cm-1 conductance when sequentially doped. It is also demonstrated that a P3HT nanowire can be doped, de-doped, and re-doped from solution without changing the dimension of the wire. The combined abilities to optically pattern and reversibly dope a polymer semiconductor represents a full suite of patterning steps equivalent to photolithography for inorganic semiconductors.

Published
2020

19. Nonequilibrium Thermodynamics of Colloidal Gold Nanocrystals Monitored by Ultrafast Electron Diffraction and Optical Scattering Microscopy

Author

Guzelturk, Burak, Utterback, James K, Coropceanu, Igor, Kamysbayev, Vladislav, Janke, Eric M, Zajac, Marc, Yazdani, Nuri, Cotts, Benjamin L, Park, Suji, Sood, Aditya, Lin, Ming-Fu, Reid, Alexander H, Kozina, Michael E, Shen, Xiaozhe, Weathersby, Stephen P, Wood, Vanessa, Salleo, Alberto, Wang, Xijie, Talapin, Dmitri V, Ginsberg, Naomi S, and Lindenberg, Aaron M

Subjects
Physical Sciences, Macromolecular and Materials Chemistry, Chemical Sciences, Physical Chemistry, Affordable and Clean Energy, colloidal nanocrystals, electron-phonon coupling, hot carriers, ligands, ultra fast electron diffraction, thermal transport, time-resolved microscopy, electron−phonon coupling, ultrafast electron diffraction, Nanoscience & Nanotechnology
Abstract

Metal nanocrystals exhibit important optoelectronic and photocatalytic functionalities in response to light. These dynamic energy conversion processes have been commonly studied by transient optical probes to date, but an understanding of the atomistic response following photoexcitation has remained elusive. Here, we use femtosecond resolution electron diffraction to investigate transient lattice responses in optically excited colloidal gold nanocrystals, revealing the effects of nanocrystal size and surface ligands on the electron-phonon coupling and thermal relaxation dynamics. First, we uncover a strong size effect on the electron-phonon coupling, which arises from reduced dielectric screening at the nanocrystal surfaces and prevails independent of the optical excitation mechanism (i.e., inter- and intraband). Second, we find that surface ligands act as a tuning parameter for hot carrier cooling. Particularly, gold nanocrystals with thiol-based ligands show significantly slower carrier cooling as compared to amine-based ligands under intraband optical excitation due to electronic coupling at the nanocrystal/ligand interfaces. Finally, we spatiotemporally resolve thermal transport and heat dissipation in photoexcited nanocrystal films by combining electron diffraction with stroboscopic elastic scattering microscopy. Taken together, we resolve the distinct thermal relaxation time scales ranging from 1 ps to 100 ns associated with the multiple interfaces through which heat flows at the nanoscale. Our findings provide insights into optimization of gold nanocrystals and their thin films for photocatalysis and thermoelectric applications.

Published
2020

20. Excitation Wavelength Dependent Reversible Photoluminescence Peak in Iodide Perovskites

Author

Qarony, Wayesh, Hossain, Mohammad Kamal, Hossain, Mohammad Ismail, Ma, Sainan, Zeng, Longhui, Yu, Kin Man, Knipp, Dietmar, Salleo, Alberto, Sun, Huarui, Yip, Cho Tung, and Tsang, Yuen Hong

Subjects
Physics - Optics, Physics - Applied Physics
Abstract

Halide perovskites have indisputably exceptional optical and electronic properties, which are attractive for next-generation optoelectronic device technologies. We report on a reversible photoluminescence (PL) peak in iodide-based organic-inorganic lead halide perovskite materials under a two-photon absorption (TPA) process, while tuning the excitation wavelength. This phenomenon occurs when the incoming femtosecond (fs) laser photon energy is higher than a threshold energy. Intriguingly, this phenomenon also occurs in other kinds of iodide perovskite materials. Moreover, two more shorter wavelength peaks exhibit and become prominent when the excitation photon energy is being tuned in the high energy wavelength spectrum, while laser power is remained constant. However, the spectral PL energy window between the original material peak and the first high energy peak can vary based on the optoelectronic properties of the prepared films. The same phenomenon of reversible PL peak is also observed in various iodide based organic-inorganic halides as well as all-inorganic perovskite single crystals and polycrystals. We attribute to the reversible PL peak to the photoinduced structural deformation and the associated change in optical bandgap of iodide perovskites under the femtosecond laser excitation. Our findings will introduce a new degree of freedom in future research as well as adding new functionalities to optoelectronic applications in these emerging perovskite materials., Comment: Main manuscript (23 pages and 4 figures) and supplementary (9 pages and 5 figures)

Published
2018

21. Tuning the bandgap of Cs2AgBiBr6 through dilute tin alloying.

Author

Lindquist, Kurt P, Mack, Stephanie A, Slavney, Adam H, Leppert, Linn, Gold-Parker, Aryeh, Stebbins, Jonathan F, Salleo, Alberto, Toney, Michael F, Neaton, Jeffrey B, and Karunadasa, Hemamala I

Subjects
Chemical Sciences
Abstract

The promise of lead halide hybrid perovskites for optoelectronic applications makes finding less-toxic alternatives a priority. The double perovskite Cs2AgBiBr6 (1) represents one such alternative, offering long carrier lifetimes and greater stability under ambient conditions. However, the large and indirect 1.95 eV bandgap hinders its potential as a solar absorber. Here we report that alloying crystals of 1 with up to 1 atom% Sn results in a bandgap reduction of up to ca. 0.5 eV while maintaining low toxicity. Crystals can be alloyed with up to 1 atom% Sn and the predominant substitution pathway appears to be a ∼2 : 1 substitution of Sn2+ and Sn4+ for Ag+ and Bi3+, respectively, with Ag+ vacancies providing charge compensation. Spincoated films of 1 accommodate a higher Sn loading, up to 4 atom% Sn, where we see mostly Sn2+ substitution for both Ag+ and Bi3+. Density functional theory (DFT) calculations ascribe the bandgap redshift to the introduction of Sn impurity bands below the conduction band minimum of the host lattice. Using optical absorption spectroscopy, photothermal deflection spectroscopy, X-ray absorption spectroscopy, 119Sn NMR, redox titration, single-crystal and powder X-ray diffraction, multiple elemental analysis and imaging techniques, and DFT calculations, we provide a detailed analysis of the Sn content and oxidation state, dominant substitution sites, and charge-compensating defects in Sn-alloyed Cs2AgBiBr6 (1:Sn) crystals and films. An understanding of heterovalent alloying in halide double perovskites opens the door to a wider breadth of potential alloying agents for manipulating their band structures in a predictable manner.

Published
2019

22. Tuning the bandgap of Cs 2 AgBiBr 6 through dilute tin alloying

Author

Lindquist, Kurt P, Mack, Stephanie A, Slavney, Adam H, Leppert, Linn, Gold-Parker, Aryeh, Stebbins, Jonathan F, Salleo, Alberto, Toney, Michael F, Neaton, Jeffrey B, and Karunadasa, Hemamala I

Subjects
Macromolecular and Materials Chemistry, Chemical Sciences, Physical Chemistry, Chemical sciences
Abstract

The promise of lead halide hybrid perovskites for optoelectronic applications makes finding less-toxic alternatives a priority. The double perovskite Cs2AgBiBr6 (1) represents one such alternative, offering long carrier lifetimes and greater stability under ambient conditions. However, the large and indirect 1.95 eV bandgap hinders its potential as a solar absorber. Here we report that alloying crystals of 1 with up to 1 atom% Sn results in a bandgap reduction of up to ca. 0.5 eV while maintaining low toxicity. Crystals can be alloyed with up to 1 atom% Sn and the predominant substitution pathway appears to be a ∼2 : 1 substitution of Sn2+ and Sn4+ for Ag+ and Bi3+, respectively, with Ag+ vacancies providing charge compensation. Spincoated films of 1 accommodate a higher Sn loading, up to 4 atom% Sn, where we see mostly Sn2+ substitution for both Ag+ and Bi3+. Density functional theory (DFT) calculations ascribe the bandgap redshift to the introduction of Sn impurity bands below the conduction band minimum of the host lattice. Using optical absorption spectroscopy, photothermal deflection spectroscopy, X-ray absorption spectroscopy, 119Sn NMR, redox titration, single-crystal and powder X-ray diffraction, multiple elemental analysis and imaging techniques, and DFT calculations, we provide a detailed analysis of the Sn content and oxidation state, dominant substitution sites, and charge-compensating defects in Sn-alloyed Cs2AgBiBr6 (1:Sn) crystals and films. An understanding of heterovalent alloying in halide double perovskites opens the door to a wider breadth of potential alloying agents for manipulating their band structures in a predictable manner.

Published
2019

23. Diffraction imaging of nanocrystalline structures in organic semiconductor molecular thin films

Author

Panova, Ouliana, Ophus, Colin, Takacs, Christopher J, Bustillo, Karen C, Balhorn, Luke, Salleo, Alberto, Balsara, Nitash, and Minor, Andrew M

Subjects
Engineering, Macromolecular and Materials Chemistry, Materials Engineering, Chemical Sciences, MSD-Soft Matter EM, MSD-General, Nanoscience & Nanotechnology
Abstract

The properties of organic solids depend on their structure and morphology, yet direct imaging using conventional electron microscopy methods is hampered by the complex internal structure of these materials and their sensitivity to electron beams. Here, we manage to observe the nanocrystalline structure of two organic molecular thin-film systems using transmission electron microscopy by employing a scanning nanodiffraction method that allows for full access to reciprocal space over the size of a spatially localized probe (~2 nm). The morphologies revealed by this technique vary from grains with pronounced segmentation of the structure-characterized by sharp grain boundaries and overlapping domains-to liquid-crystal structures with crystalline orientations varying smoothly over all possible rotations that contain disclinations representing singularities in the director field. The results show how structure-property relationships can be visualized in organic systems using techniques previously only available for hard materials such as metals and ceramics.

Published
2019

24. Redefining near-unity luminescence in quantum dots with photothermal threshold quantum yield

Author

Hanifi, David A, Bronstein, Noah D, Koscher, Brent A, Nett, Zach, Swabeck, Joseph K, Takano, Kaori, Schwartzberg, Adam M, Maserati, Lorenzo, Vandewal, Koen, van de Burgt, Yoeri, Salleo, Alberto, and Alivisatos, A Paul

Subjects
Quantum Physics, Physical Sciences, General Science & Technology
Abstract

A variety of optical applications rely on the absorption and reemission of light. The quantum yield of this process often plays an essential role. When the quantum yield deviates from unity by significantly less than 1%, applications such as luminescent concentrators and optical refrigerators become possible. To evaluate such high performance, we develop a measurement technique for luminescence efficiency with sufficient accuracy below one part per thousand. Photothermal threshold quantum yield is based on the quantization of light to minimize overall measurement uncertainty. This technique is used to guide a procedure capable of making ensembles of near-unity emitting cadmium selenide/cadmium sulfide (CdSe/CdS) core-shell quantum dots. We obtain a photothermal threshold quantum yield luminescence efficiency of 99.6 ± 0.2%, indicating nearly complete suppression of nonradiative decay channels.

Published
2019

25. Additive solution deposition of multi-layered semiconducting polymer films for design of sophisticated device architectures

Author

Murrey, Tucker L, Guo, Kunping, Mulvey, Justin T, Lee, Owen A, Cendra, Camila, Bedolla-Valdez, Zaira I, Salleo, Alberto, Moulin, Jean-Francois, Hong, Kunlun, and Moulé, Adam J

Subjects
Engineering, Macromolecular and Materials Chemistry, Materials Engineering, Chemical Sciences, Physical Chemistry (incl. Structural), Macromolecular and materials chemistry, Physical chemistry, Materials engineering
Abstract

Many organic electronic devices require vertically layered structures to operate. This manuscript demonstrates an additive solution process for depositing multiple layers of semiconducting polymer (SP) films by controlling film solubility with molecular dopants. During multi-layer deposition the bottom layers are exposed to a series of solvent environments that swell the SP films. We use neutron reflectometry (NR) to quantify the film thickness change and solvent content during solvent exposure in a single poly-3-hexylthiophene (P3HT) layer. The film thickness increases by 40-80% with exposure to good solvents. Four layer thin-films composed of alternating protonated and deuterated P3HT layers were additively coated from solution. NR measurements reveal high individual layer purity and that extensive solvent soaking induces no mixing between layers. Finally, two-point conductivity measurements demonstrate that P3HT:P3HT layer interfaces have no effect on vertical conductivity. This facile process enables additive layering of mutually soluble SP films and can be used to design novel electronic device architectures.

Published
2019

26. High-mobility, trap-free charge transport in conjugated polymer diodes

Author

Nikolka, Mark, Broch, Katharina, Armitage, John, Hanifi, David, Nowack, Peer J, Venkateshvaran, Deepak, Sadhanala, Aditya, Saska, Jan, Mascal, Mark, Jung, Seok-Heon, Lee, Jin‐Kyun, McCulloch, Iain, Salleo, Alberto, and Sirringhaus, Henning

Subjects
Engineering, Macromolecular and Materials Chemistry, Materials Engineering, Chemical Sciences
Abstract

Charge transport in conjugated polymer semiconductors has traditionally been thought to be limited to a low-mobility regime by pronounced energetic disorder. Much progress has recently been made in advancing carrier mobilities in field-effect transistors through developing low-disorder conjugated polymers. However, in diodes these polymers have to date not shown much improved mobilities, presumably reflecting the fact that in diodes lower carrier concentrations are available to fill up residual tail states in the density of states. Here, we show that the bulk charge transport in low-disorder polymers is limited by water-induced trap states and that their concentration can be dramatically reduced through incorporating small molecular additives into the polymer film. Upon incorporation of the additives we achieve space-charge limited current characteristics that resemble molecular single crystals such as rubrene with high, trap-free SCLC mobilities up to 0.2 cm2/Vs and a width of the residual tail state distribution comparable to kBT.

Published
2019

29. Improving Quantum Yield of Upconverting Nanoparticles in Aqueous Media via Emission Sensitization

Author

Wisser, Michael D, Fischer, Stefan, Siefe, Chris, Alivisatos, A Paul, Salleo, Alberto, and Dionne, Jennifer A

Subjects
Engineering, Chemical Sciences, Nanotechnology, Bioengineering, Upconversion, radiative rate, dye sensitization, quantum yield, fluorescence lifetimes, nanoparticles, Nanoscience & Nanotechnology
Abstract

We demonstrate a facile method to improve upconversion quantum yields in Yb,Er-based nanoparticles via emission dye-sensitization. Using the commercially available dye ATTO 542, chosen for its high radiative rate and significant spectral overlap with the green emission of Er3+, we decorate the surfaces of sub-25 nm hexagonal-phase Na(Y/Gd/Lu)0.8F4:Yb0.18Er0.02 upconverting nanoparticles with varying dye concentrations. Upconversion photoluminescence and absorption spectroscopy provide experimental confirmation of energy transfer to and emission from the dye molecules. Upconversion quantum yield is observed to increase with dye sensitization, with the highest enhancement measured for the smallest particles investigated (10.9 nm in diameter); specifically, these dye-decorated particles are more than 2× brighter than are unmodified, organic-soluble nanoparticles and more than 10× brighter than are water-soluble nanoparticles. We also observe 3× lifetime reductions with dye adsorption, confirming the quantum yield enhancement to result from the high radiative rate of the dye. The approach detailed in this work is widely implementable, renders the nanoparticles water-soluble, and most significantly improves sub-15 nm nanoparticles, making our method especially attractive for biological imaging applications.

Published
2018

30. Polymorphism controls the degree of charge transfer in a molecularly doped semiconducting polymer

Author

Jacobs, Ian E, Cendra, Camila, Harrelson, Thomas F, Bedolla Valdez, Zaira I, Faller, Roland, Salleo, Alberto, and Moulé, Adam J

Subjects
Engineering, Macromolecular and Materials Chemistry, Materials Engineering, Chemical Sciences, Chemical Engineering, Macromolecular and materials chemistry, Chemical engineering, Materials engineering
Abstract

When an organic semiconductor (OSC) is blended with an electron acceptor molecule that can act as a p-type dopant, there should ideally be complete (integer) transfer of charge from the OSC to the dopant. However, some dopant-OSC blends instead form charge transfer complexes (CTCs), characterized by fractional charge transfer (CT) and strong orbital hybridization between the two molecules. Fractional CT doping does not efficiently generate free charge carriers, but it is unclear what conditions lead to incomplete charge transfer. Here we show that by modifying film processing conditions in the semiconductor-dopant couple poly(3-hexylthiophene):2,3,5,6-tetrafluoro-7,7,8,8,-tetracyanoquinodimethane (P3HT:F4TCNQ), we can selectively obtain nearly pure integer or fractional CT phases. Fractional CT films show electrical conductivities approximately 2 orders of magnitude lower than corresponding integer CT films, and remarkably different optical absorption spectra. Grazing incidence wide-angle X-ray diffraction (GIXD) reveals that fractional CT films display an unusually dense and well-ordered crystal structure. These films show lower paracrystallinity and shorter lamellar and π-stacking distances than undoped films processed under similar conditions. Using plane-wave DFT we obtain a structure with unit cell parameters closely matching those observed by GIXD. This first-ever observation of both fractional and integer CT in a single OSC-dopant system demonstrates the importance of structural effects on OSC doping and opens the door to further studies.

Published
2018

33. The impact of hydrogen peroxide production in OECTs for in vitro applications

Author

Lubrano, C, Bettucci, O, Dijk, G, Salleo, A, Giovannitti, A, Santoro, F, Lubrano, Claudia, Bettucci, Ottavia, Dijk, Gerwin, Salleo, Alberto, Giovannitti, Alexander, Santoro, Francesca, Lubrano, C, Bettucci, O, Dijk, G, Salleo, A, Giovannitti, A, Santoro, F, Lubrano, Claudia, Bettucci, Ottavia, Dijk, Gerwin, Salleo, Alberto, Giovannitti, Alexander, and Santoro, Francesca

Abstract

Organic electrochemical transistors (OECTs) have shown great potential in bioelectronics to transduce small biological signals for applications such as the electrical recording of excitable cells and assessing cell barrier properties. It is imperative that operating the OECT as a biosensor does not affect the biological system. However, bias voltages applied to channel materials such as the conducting polymer (CP) PEDOT:PSS have been shown to induce the formation of hydrogen peroxide (H2O2) which can disrupt the physiology of cells. In this work, we evaluated the impact of H2O2 formation during OECT operation by comparing an oxygen-sensitive CP (PEDOT:PSS) and an oxygen-stable CP (p(gPyDPP-MeOT2)). While both CPs show high biocompatibility in their non-biased, resting state, we observed large differences during the operation of the electrochemical device. OECTs with PEDOT:PSS produce H2O2 where the H2O2 concentration in the electrolyte depends on the channel area and the time of operation. In comparison, OECTs using the oxygen-stable DPP-based polymer showed no sign of H2O2 formation. Further investigation also revealed how the proliferation rate of neuronal cells directly interfaced with such OECTs was affected by the concentration of H2O2. Our work demonstrated the limitations of oxygen-sensitive OECT channel materials for bioelectronic applications and provides guidance for material design strategies to develop safe bioelectronic devices for real-life applications.

Published
2024

38. Enhancing Quantum Yield via Local Symmetry Distortion in Lanthanide-Based Upconverting Nanoparticles

Author

Wisser, Michael D, Fischer, Stefan, Maurer, Peter C, Bronstein, Noah D, Chu, Steven, Alivisatos, A Paul, Salleo, Alberto, and Dionne, Jennifer A

Subjects
Atomic, Molecular and Optical Physics, Physical Sciences, Nanotechnology, Bioengineering, Affordable and Clean Energy, upconversion, lanthanides, quantum yield, radiative rate, optical selection rules, crystal symmetry, Optical Physics, Quantum Physics, Electrical and Electronic Engineering, Atomic, molecular and optical physics
Abstract

Lanthanide-based upconverting nanoparticles exhibit significant promise for solar energy generation, biological imaging, and security technologies but have not seen widespread adoption due to the prohibitively low efficiencies of current materials. Weak transition dipole moments between 4f orbitals hinder both photon absorption and emission. Here, we introduce a novel way to increase the radiative transition rates in Yb,Er-based upconverting nanoparticles based on local symmetry distortion. Beginning from a host matrix of the well-studied hexagonal (β)-phase NaYF4, we incrementally remove Y3+ ions and cosubstitute for them a 1:1 mixture of Gd3+ and Lu3+. These two ions act to expand and contract the lattice, respectively, inducing local-level distortion while maintaining the average host structure. We synthesize a range of β-NaY0.8-2xGdxLuxF4:Yb0.18Er0.02 nanoparticles and experimentally confirm that particle size, phase, global structure, and Yb3+ and Er3+ concentrations remain constant as x is varied. Upconversion quantum yield is probed as the degree of cosubstitution is varied from x = 0 to x = 0.24. We achieve a maximum quantum yield value of 0.074% under 63 W/cm2 of excitation power density, representing a 1.6× enhancement over the unmodified particles and the highest measured value for near-infrared-to-visible upconversion in sub-25 nm unshelled nanoparticles. We also investigate upconversion emission at the single-particle level and report record improvements in emission intensity for sub-50 nm particles. Radiative rate enhancements are confirmed by measuring excited-state lifetimes. The approach described herein can be used in combination with more established methods of efficiency improvement, such as adding passivating shells or coupling to plasmonic nanoattenas, to further boost the upconversion quantum yield.

Published
2016

39. Roadmap on optical energy conversion

Author

Boriskina, Svetlana V, Green, Martin A, Catchpole, Kylie, Yablonovitch, Eli, Beard, Matthew C, Okada, Yoshitaka, Lany, Stephan, Gershon, Talia, Zakutayev, Andriy, Tahersima, Mohammad H, Sorger, Volker J, Naughton, Michael J, Kempa, Krzysztof, Dagenais, Mario, Yao, Yuan, Xu, Lu, Sheng, Xing, Bronstein, Noah D, Rogers, John A, Alivisatos, A Paul, Nuzzo, Ralph G, Gordon, Jeffrey M, Wu, Di M, Wisser, Michael D, Salleo, Alberto, Dionne, Jennifer, Bermel, Peter, Greffet, Jean-Jacques, Celanovic, Ivan, Soljacic, Marin, Manor, Assaf, Rotschild, Carmel, Raman, Aaswath, Zhu, Linxiao, Fan, Shanhui, and Chen, Gang

Subjects
Engineering, Electrical Engineering, Atomic, Molecular and Optical Physics, Physical Sciences, optical energy conversion, light harvesting, solar technology, photovoltaics, solar cell
Abstract

For decades, progress in the field of optical (including solar) energy conversion was dominated by advances in the conventional concentrating optics and materials design. In recent years, however, conceptual and technological breakthroughs in the fields of nanophotonics and plasmonics combined with a better understanding of the thermodynamics of the photon energy-conversion processes reshaped the landscape of energy-conversion schemes and devices. Nanostructured devices and materials that make use of size quantization effects to manipulate photon density of states offer a way to overcome the conventional light absorption limits. Novel optical spectrum splitting and photon-recycling schemes reduce the entropy production in the optical energy-conversion platforms and boost their efficiencies. Optical design concepts are rapidly expanding into the infrared energy band, offering new approaches to harvest waste heat, to reduce the thermal emission losses, and to achieve noncontact radiative cooling of solar cells as well as of optical and electronic circuitries. Light-matter interaction enabled by nanophotonics and plasmonics underlie the performance of the third- and fourth-generation energy-conversion devices, including up- and down-conversion of photon energy, near-field radiative energy transfer, and hot electron generation and harvesting. Finally, the increased market penetration of alternative solar energy-conversion technologies amplifies the role of cost-driven and environmental considerations. This roadmap on optical energy conversion provides a snapshot of the state of the art in optical energy conversion, remaining challenges, and most promising approaches to address these challenges. Leading experts authored 19 focused short sections of the roadmap where they share their vision on a specific aspect of this burgeoning research field. The roadmap opens up with a tutorial section, which introduces major concepts and terminology. It is our hope that the roadmap will serve as an important resource for the scientific community, new generations of researchers, funding agencies, industry experts, and investors.

Published
2016

43. Multi-phase semicrystalline microstructures drive exciton dissociation in neat plastic semiconductors

Author

Paquin, Francis, Rivnay, Jonathan, Salleo, Alberto, Stingelin, Natalie, and Silva, Carlos

Subjects
Condensed Matter - Materials Science, Physics - Chemical Physics
Abstract

The optoelectronic properties of macromolecular semiconductors depend fundamentally on their solid-state microstructure. For example, the molecular-weight distribution influences polymeric- semiconductor properties via diverse microstructures; polymers of low weight-average molecular weight (Mw) form unconnected, extended-chain crystals, usually of a paraffinic structure. Because of the non-entangled nature of the relatively short-chain macromolecules, this leads to a polycrystalline, one-phase morphology. In contrast, with high-Mw materials, where average chain lengths are longer than the length between entanglements, two-phase morphologies, comprised of crystalline moieties embedded in largely unordered (amorphous) regions, are obtained. We investigate charge photogeneration processes in neat regioregular poly(3-hexylthiophene) (P3HT) of varying Mw by means of time-resolved photoluminescence (PL) spectroscopy. At 10 K, PL originating from recombination of long-lived charge pairs decays over microsecond timescales. Both the amplitude and decay rate distribution depend strongly on Mw. In films with dominant one-phase chain-extended microstructures, the delayed PL is suppressed as a result of a diminished yield of photoinduced charges, and its decay is significantly faster than in two-phase microstructures. However, independent of Mw, charge recombination regenerates singlet excitons in torsionally disordered chains forming more strongly coupled photophysical aggregates than those in the steady-state ensemble, with delayed PL lineshape reminiscent of that in paraffinic morphologies at steady state. We conclude that highly delocalized excitons in disordered regions between crystalline and amorphous phases dissociate extrinsically with yield and spatial distribution that depend intimately upon microstructure., Comment: 19 pages, 4 figures

Published
2013
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44. Altered heparan sulfate metabolism during development triggers dopamine-dependent autistic-behaviours in models of lysosomal storage disorders

Author

De Risi, Maria, Tufano, Michele, Alvino, Filomena Grazia, Ferraro, Maria Grazia, Torromino, Giulia, Gigante, Ylenia, Monfregola, Jlenia, Marrocco, Elena, Pulcrano, Salvatore, Tunisi, Lea, Lubrano, Claudia, Papy-Garcia, Dulce, Tuchman, Yaakov, Salleo, Alberto, Santoro, Francesca, Bellenchi, Gian Carlo, Cristino, Luigia, Ballabio, Andrea, Fraldi, Alessandro, and De Leonibus, Elvira

Published
2021
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45. Electrolyte-gated transistors for enhanced performance bioelectronics

Author

Torricelli, Fabrizio, Adrahtas, Demetra Z., Bao, Zhenan, Berggren, Magnus, Biscarini, Fabio, Bonfiglio, Annalisa, Bortolotti, Carlo A., Frisbie, C. Daniel, Macchia, Eleonora, Malliaras, George G., McCulloch, Iain, Moser, Maximilian, Nguyen, Thuc-Quyen, Owens, Róisín M., Salleo, Alberto, Spanu, Andrea, and Torsi, Luisa

Published
2021
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47. Modeling Space-Charge Limited Currents in Organic Semiconductors: Extracting Trap Density and Mobility

Author

Dacuña, Javier and Salleo, Alberto

Subjects
Condensed Matter - Materials Science
Abstract

We have developed and applied a mobility edge model that takes into account drift and diffusion currents to characterize the space charge limited current in organic semiconductors. The numerical solution of the drift-diffusion equation allows the utilization of asymmetric contacts to describe the built-in potential within the device. The model has been applied to extract information of the distribution of traps from experimental current-voltage measurements of a rubrene single crystal from Krellner et al. [Phys. Rev. B, 75(24), 245115] showing excellent agreement across several orders of magnitude of current. Although the two contacts are made of the same metal, an energy offset of 580 meV between them, ascribed to differences in the deposition techniques (lamination vs. evaporation) was essential to correctly interpret the shape of the current-voltage characteristics at low voltage. A band mobility 0.13 cm2/Vs for holes was estimated, which is consistent with transport along the long axis of the orthorhombic unit cell. The total density of traps deeper than 0.1 eV was 2.2\times1016 cm-3. The sensitivity analysis and error estimation in the obtained parameters shows that it is not possible to accurately resolve the shape of the trap distribution for energies deeper than 0.3 eV or shallower than 0.1 eV above the valence band edge. The total number of traps deeper than 0.3 eV however can be estimated. Contact asymmetry and the diffusion component of the current play an important role in the description of the device at low bias, and are required to obtain reliable information about the distribution of deep traps.

Published
2011
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48. Structural origin of gap states in semicrystalline polymers and the implications for charge transport

Author

Rivnay, Jonathan, Noriega, Rodrigo, Northrup, John E., Kline, R. Joseph, Toney, Michael F., and Salleo, Alberto

Subjects
Condensed Matter - Materials Science, Condensed Matter - Soft Condensed Matter
Abstract

We quantify the degree of disorder in the {\pi}-{\pi} stacking direction of crystallites of a high performing semicrystalline semiconducting polymer with advanced X-ray lineshape analysis. Using first principles calculations, we obtain the density of states of a system of {\pi}-{\pi} stacked polymer chains with increasing amounts of paracrystalline disorder. We find that for an aligned film of PBTTT the paracrystalline disorder is 7.3%. This type of disorder induces a tail of trap states with a breadth of ~100 meV as determined through calculation. This finding agrees with previous device modeling and provides physical justification for the mobility edge model., Comment: Text and figures are unchanged in the new version of the file. The only modification is the addition of a funding source to the acknowledgments

Published
2010
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49. Enhancing Fullerene‐Based Solar Cell Lifetimes by Addition of a Fullerene Dumbbell

Author

Schroeder, Bob C, Li, Zhe, Brady, Michael A, Faria, Gregório Couto, Ashraf, Raja Shahid, Takacs, Christopher J, Cowart, John S, Duong, Duc T, Chiu, Kar Ho, Tan, Ching‐Hong, Cabral, João T, Salleo, Alberto, Chabinyc, Michael L, Durrant, James R, and McCulloch, Iain

Subjects
fullerenes, lifetime, organic solar cells, photovoltaics, stability, Chemical Sciences, Organic Chemistry
Abstract

Cost-effective, solution-processable organic photovoltaics (OPV) present an interesting alternative to inorganic silicon-based solar cells. However, one of the major remaining challenges of OPV devices is their lack of long-term operational stability, especially at elevated temperatures. The synthesis of a fullerene dumbbell and its use as an additive in the active layer of a PCDTBT:PCBM-based OPV device is reported. The addition of only 20 % of this novel fullerene not only leads to improved device efficiencies, but more importantly also to a dramatic increase in morphological stability under simulated operating conditions. Dynamic secondary ion mass spectrometry (DSIMS) and TEM are used, amongst other techniques, to elucidate the origins of the improved morphological stability.

Published
2014

50. Tuning the Mobility of Indacenodithiophene-Based Conjugated Polymers via Coplanar Backbone Engineering

Author

Ji, Xiaozhou, primary, Cheng, Hao-Wen, additional, Schuster, Nathaniel J., additional, LeCroy, Garrett S., additional, Zhang, Song, additional, Wu, Yilei, additional, Michalek, Lukas, additional, Nguyen, Bao-Nguyen T., additional, Chiong, Jerika A., additional, Schrock, Max, additional, Tomo, Yoko, additional, Rech, Jeromy, additional, Salleo, Alberto, additional, Gam, Sangah, additional, Lee, Gae Hwang, additional, Tok, Jeffrey B.-H., additional, and Bao, Zhenan, additional

Published
2023
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