Your search keyword '"nanotechnology"' showing total 938,647 results

1. Electronic and structural properties of group IV materials and their polytypes.

Author

Ziembicki, Jakub, Scharoch, Paweł, Polak, Maciej P., Wiśniewski, Michał, and Kudrawiec, Robert

Subjects

*ISING model, *ELECTRONIC materials, *OPTOELECTRONIC devices, *SEMICONDUCTOR industry, *NANOTECHNOLOGY

Abstract

Nanotechnology's impact on semiconductor industry advancement, particularly through the engineering of nanostructures like nanowires, opens new possibilities for material functionality due to the tunable physical properties of nanostructures compared to bulk materials. This paper presents a comprehensive study on group IV semiconductors and their binaries across four polytypes: 2H, 3C, 4H, and 6H, focusing on their optoelectronic application potential. Deep understanding of these polytypes is particularly relevant for nanowire-based technologies. Through first principles modeling, we examine the structural and electronic properties of these materials, emphasizing their band structure, stability, and the feasibility for light-emitting applications. We use a generalized Ising model to discuss materials stability and tendency for polytypism. We also determine relative band edge positions and employ a six-band k⋅p model for a detailed understanding of the materials' electronic properties. Due to the comprehensive nature of this study, we provide insight on the chemical trends present in all of the studied properties. Our theoretical predictions align well with the existing experimental data, suggesting new avenues for nanostructure-based device development. The discussion extends to the implications of these findings for the fabrication of optoelectronic devices with the studied IV–IV materials, highlighting the challenges and opportunities for future research in nanowire synthesis and their applications. [ABSTRACT FROM AUTHOR]

Published

2024

2. Design of SRAM cell using an optimized D-latch in quantum-dot cellular automata (QCA) technology.

Author

Rathore, Nitesh Kumar and Singh, Pooran

Subjects

*STATIC random access memory, *NANOTECHNOLOGY, *CELLULAR automata, *RESEARCH personnel, *DIGITAL electronics, *SEMICONDUCTORS

Abstract

A newer nanoscale technology called quantum-dot cellular automata (QCA) has been used by researchers to design digital circuits in place of the more traditional complementary metal–oxide semiconductor (CMOS) technology. This recent development in the technology change is due to the problems faced by CMOS technology in terms of power consumption and physical limitations. The advantages of QCA technology over CMOS technology are high density, low power consumption, high-speed operation, and less footprint area. This research provides a novel circuit for D-latch and static random access memory (SRAM) cells based on QCA technology. Initially, a D-latch circuit is proposed with a layout area of 0.01 μm2, a 0.5 clock cycle delay (latency), and a cell count of 18 QCA cells. Furthermore, an SRAM cell is proposed using the same D-latch circuit, which uses cell counts of 26 QCA cells and contributes to a layout area of 0.02 μm2 with a 0.75 clock cycle delay (latency). It is observed that our proposed circuits have a smaller layout area, fewer QCA cell counts, and a lower clock cycle delay (latency) than existing circuits. [ABSTRACT FROM AUTHOR]

Published

2024

3. Magnetic Order in Nanogranular Iron Germanium (Fe0.53Ge0.47) Films.

Author

Zielinski, Ruthi Linnea, Nguyen, Nhat, Herrington, Bryce, Tarkian, Amir, Taha, Omar Ahmed Hassan Ahmed, Chin, Wai Kiat, Mahmood, Ather, Chen, Xiaoqian, Klewe, Christoph, Shafer, Padraic, Ciston, Jim, Ashby, Paul, Mazzoli, Claudio, and Streubel, Robert

Subjects

Physical Sciences, Condensed Matter Physics, amorphous film, magnetic imaging, magnetic moment, strain, topological magnetism, x-ray photon correlation spectroscopy, Materials Engineering, Nanotechnology, Fluids & Plasmas, Materials engineering, Condensed matter physics

Abstract

We study the effect of strain on the magnetic properties and magnetization configurations in nanogranular FexGe1-x films (x = 0.53 ±0.05) with and without B20 FeGe nanocrystals surrounded by an amorphous structure. Relaxed films on amorphous silicon nitride membranes reveal a disordered skyrmion phase while films near and on top of a rigid substrate favor ferromagnetism and an anisotropic hybridization of Fe d levels and spin-polarized Ge sp band states. The weakly coupled topological states emerge at room temperature and become more abundant at cryogenic temperatures without showing indications of pinning at defects or confinement to individual grains. These results demonstrate the possibility to control magnetic exchange and topological magnetism by strain and inform magnetoelasticity-mediated voltage control of topological phases in amorphous quantum materials.

Published

2024

4. Charge Transfer Kinetics and Thermodynamics Control the Energy Conversion Efficiency of a Gallium Phosphide Solar Hydrogen Photocathode

Author

Becker, Kathleen, Wang, Li, and Osterloh, Frank E

Subjects

Macromolecular and Materials Chemistry, Chemical Sciences, Physical Chemistry, Engineering, Materials Engineering, Nanotechnology, Affordable and Clean Energy, Technology, Chemical sciences

Abstract

P-type gallium phosphide (GaP) photocathodes for hydrogen evolution from water have a theoretical energy conversion efficiency of 12% based on the 2.4 eV optical band gap of the material. The performance of actual GaP photocathodes is much lower, for reasons not entirely clear. Here we use vibrating Kelvin probe surface photovoltage (VKP-SPV), open circuit potential (OCP) measurements, and photoelectrochemical (PEC) experiments to evaluate the kinetic and thermodynamic factors that control energy conversion with GaP photocathodes for the hydrogen evolution reaction (HER). We find that the open circuit photovoltage of the bare GaP-H2O junction is limited by recombination at surface states and that an CdS overlayer increases both photovoltage and photocurrent due to formation of a n-p-junction. An optimized GaP/CdS/Pt photocathode drives hydrogen evolution with a quantum efficiency of 62% at 400 nm and 0.0 V RHE and an open circuit photovoltage of 0.43 V at 250 mW cm-2. The Pt cocatalyst increases the photocurrent due to improve HER kinetics but reduces the photovoltage by promoting recombination. Added hydrogen or oxygen gas raise or lower the photovoltage by modifying the electrostatic barrier (band bending) in GaP. This shows that the GaP/CdS junction is not "buried" but behaves like a Schottky junction whose charge separating properties are controlled by the electrochemical potential of the electrolyte. The dynamic junction properties need to be considered in the design of optimized hydrogen evolution photoelectrodes and photocatalysts. Additionally, the work reveals that PEC or OCP measurements tend to underestimate the photovoltage because they do not account for changes in the electrochemical potential at the electrode-liquid contact. In contrast, the VKP-SPV method provides the open circuit photovoltage value directly. By combining the photovoltage data with OCP data, the minority carrier electrochemical potential at the electrode-liquid contact can be measured in a contactless way. This provides an improved understanding of illuminated photoelectrodes for the production of solar fuels.

Published

2024

5. Infrared nanoimaging and nanospectroscopy of electrochemical energy storage materials and interfaces

Author

Larson, Jonathan M, Dopilka, Andrew, and Kostecki, Robert

Subjects

Engineering, Materials Engineering, Chemical Sciences, Physical Chemistry, Affordable and Clean Energy, Nano-FTIR, s-SNOM, SINS, AFM-IR, Infrared nanospectroscopy, Batteries, Li-ion battery, Energy storage, Electrochemistry, Analytical chemistry, Physical chemistry, Nanotechnology

Abstract

Electrochemical interfaces are central to the function and performance of energy storage devices. Thus, the development of new methods to characterize these interfaces, in conjunction with electrochemical performance, is essential for bridging the existing knowledge gaps and accelerating the development of energy storage technologies. Of particular need is the ability to characterize surfaces or interfaces in a non-destructive way with adequate resolution to discern individual structural and chemical building blocks. To this end, sub-diffraction-limit low-energy infrared optical probes that exploit near-field interactions within atomic force microscopy platforms, such as pseudoheterodyne nanoimaging, photothermal nanoimaging and nanospectroscopy, and nanoscale Fourier transform infrared spectroscopy, are all powerful emerging techniques. These are capable of non-destructive surface probing and imaging at nanometer resolution. This review outlines recent efforts to characterize ex situ,in situ,andoperando electrode materials and electrochemical interfaces in rechargeable batteries with these advanced infrared near-field probes.

Published

2024

6. Giant resistance switch in twisted transition metal dichalcogenide tunnel junctions

Author

Vila, Marc

Subjects

Quantum Physics, Engineering, Physical Sciences, Nanotechnology, Condensed Matter Physics, twisted bilayers, transition metal dichalcogenides, resistance switching, spin-orbit coupling, landauer formula, Macromolecular and Materials Chemistry, Materials Engineering, Materials engineering, Condensed matter physics

Abstract

Resistance switching in multilayer structures are typically based on materials possessing ferroic orders. Here we predict an extremely large resistance switching based on the relative spin-orbit splitting in twisted transition metal dichalcogenide (TMD) monolayers tunnel junctions. Because of the valence band spin splitting which depends on the valley index in the Brillouin zone, the perpendicular electronic transport through the junction depends on the relative reciprocal space overlap of the spin-dependent Fermi surfaces of both layers, which can be tuned by twisting one layer. Our quantum transport calculations reveal a switching resistance larger than 10 6 % when the relative alignment of TMDs goes from 0∘ to 60∘ and when the angle is kept fixed at 60∘ and the Fermi level is varied. By creating vacancies, we evaluate how inter-valley scattering affects the efficiency and find that the resistance switching remains large ( 10 4 % ) for typical values of vacancy concentration. Not only should this resistance switching be observed at room temperature due to the large spin splitting, but our results also show how twist angle engineering and control of van der Waals heterostructures could be used for next-generation memory and electronic applications.

Published

2024

7. Click chemistry-mediated enrichment of circulating tumor cells and tumor-derived extracellular vesicles for dual liquid biopsy in differentiated thyroid cancer

Author

Feng, Bing, Wang, Jing, Zhang, Ryan Y, Wei, Anna Yaxuan, Zhao, Chen, Yen, Ying-Tzu, Ji, You-Ren, Kim, Hyoyong, Ju, Yong, Smalley, Matthew, Zuo, Vivian Xufei, Cheng, Liwen, Phung, Aaron, Zhou, Ziang, Yu, Sitong, DiBernardo, Gabriella, Memarzadeh, Sanaz, Posadas, Edwin M, Chai-Ho, Wanxing, Agopian, Vatche, Lee, Junseok, Yeh, Michael W, Wu, James, Zheng, Guangjuan, Tseng, Hsian-Rong, and Zhu, Yazhen

Subjects

Biomedical and Clinical Sciences, Oncology and Carcinogenesis, Cancer, Clinical Research, Good Health and Well Being, Biomedical Engineering, Nanotechnology, Nanoscience & Nanotechnology, Medical biotechnology, Biomedical engineering

Abstract

Circulating tumor cells (CTCs) and tumor-derived extracellular vesicles (tEVs) are two crucial methodologies of liquid biopsy. Given their distinct size differences and release dynamics, CTCs and tEVs potentially offer synergistic capabilities in the non-invasive detection of differentiated thyroid cancer (DTC), a typically indolent tumor. We present the Combined DTC CTC/tEV Assay, integrating dual liquid biopsy processes: i) DTC CTC enrichment by Click Chips, followed by analysis of seven DTC-specific genes, and ii) DTC tEV enrichment by Click Beads, succeeded by mRNA cargo quantification in DTC tEVs. This method utilizes click chemistry, leveraging a pair of biorthogonal and highly reactive functional motifs (tetrazine, Tz, and trans-cyclooctene, TCO), to overcome the challenges encountered in the conventional immunoaffinity-based enrichment of CTCs and tEVs. The Combined DTC CTC/tEV Assay synergistically combines the diagnostic precision of CTCs with the sensitivity of tEVs, demonstrating superior diagnostic accuracy in DTC detection and boasting an AUROC of 0.99. This outperforms the individual diagnostic performance of using either DTC CTC or DTC tEV alone. This integration enables full utilization of a patient's blood sample, and marks a significant evolution in the development of nanomaterial-based liquid biopsy technologies to address challenging unmet clinical needs in cancer care.

Published

2024

8. Ion transport and ultra-efficient osmotic power generation in boron nitride nanotube porins

Author

Li, Zhongwu, Hall, Alex T, Wang, Yaqing, Li, Yuhao, Byrne, Dana O, Scammell, Lyndsey R, Whitney, R Roy, Allen, Frances I, Cumings, John, and Noy, Aleksandr

Subjects

Medical Physiology, Biomedical and Clinical Sciences, Physical Sciences, Bioengineering, Nanotechnology

Abstract

Nanotube porins form transmembrane nanomaterial-derived scaffolds that mimic the geometry and functionality of biological membrane channels. We report synthesis, transport properties, and osmotic energy harvesting performance of another member of the nanotube porin family: boron nitride nanotube porins (BNNTPs). Cryo-transmission electron microscopy imaging, liposome transport assays, and DNA translocation experiments show that BNNTPs reconstitute into lipid membranes to form functional channels of ~2-nm diameter. Ion transport studies reveal ion conductance characteristics of individual BNNTPs, which show an unusual C1/4 scaling with ion concentration and pronounced pH sensitivity. Reversal potential measurements indicate that BNNTPs have strong cation selectivity at neutral pH, attributable to the high negative charge on the channel. BNNTPs also deliver very large power density up to 12 kW/m2 in the osmotic gradient transport experiments at neutral pH, surpassing that of other BNNT-based devices by two orders of magnitude under similar conditions. Our results suggest that BNNTPs are a promising platform for mass transport and osmotic power generation.

Published

2024

9. Control of threshold voltages in Si/Si0.7Ge0.3 quantum devices via optical illumination

Author

Wolfe, MA, Coe, Brighton X, Edwards, Justin S, Kovach, Tyler J, McJunkin, Thomas, Harpt, Benjamin, Savage, DE, Lagally, MG, McDermott, R, Friesen, Mark, Kolkowitz, Shimon, and Eriksson, MA

Subjects

Quantum Physics, Engineering, Physical Sciences, Nanotechnology, Condensed Matter Physics, Physical sciences

Abstract

Optical illumination of quantum dot qubit devices at cryogenic temperatures, while not well studied, is often used to recover operating conditions after undesired shocking events or charge injection. Here, we demonstrate systematic threshold-voltage shifts in a dopant-free Si/Si0.7Ge0.3 field-effect transistor using a near-infrared (780-nm) laser diode. We find that illumination under an applied gate voltage can be used to set a specific, stable, and reproducible threshold voltage that, over a wide range in gate bias, is equal to that gate bias. Outside this range, the threshold voltage can still be tuned, although the resulting threshold voltage is no longer equal to the applied gate bias during illumination. We present a simple and intuitive model that provides a mechanism for the tunability in the gate bias. The model presented also explains why cryogenic illumination is successful at resetting quantum dot qubit devices after undesired charging events.

Published

2024

10. Solid phase epitaxy of SrRuO3 encapsulated by SrTiO3 membranes

Author

Zhou, Jieyang, Feng, Mingzhen, Shih, Hudson, Takamura, Yayoi, and Hong, Seung Sae

Subjects

Engineering, Materials Engineering, Electrical and Electronic Engineering, Mechanical Engineering, Materials engineering, Nanotechnology, Condensed matter physics

Abstract

Solid phase epitaxy (SPE) has been widely employed for various thin-film materials, making it valuable for industrial applications due to its scalability. In complex oxides, SPE has been limited to a few materials because of the challenges in maintaining stoichiometric control during growth, particularly when volatile phases are present at high temperatures. Here, we investigate the impact of encapsulation layers on the SPE of complex oxides, using SrRuO3 (SRO) as a model system. An amorphous SRO layer was deposited on a SrTiO3 (STO) substrate, followed by the transfer of a single-crystalline STO membrane as an encapsulation layer in order to suppress the evaporation of volatile species (RuO2) during the SPE process. Whereas both encapsulated and unencapsulated SRO layers were successfully crystallized, the unencapsulated films suffered a substantial loss of Ru ions—exceeding 20%—compared to their encapsulated counterparts. This loss of Ru ions led to a loss of metallicity in the unencapsulated SRO layers, whereas the encapsulated layers retained their metallic ferromagnetic properties. This study demonstrates that the encapsulation provided by oxide membranes effectively suppresses stoichiometric loss during SPE, presenting a new strategy in stabilizing a broader class of functional oxides as epitaxial thin films.

Published

2024

11. Roadmap on low-power electronics

Author

Ramesh, Ramamoorthy, Salahuddin, Sayeef, Datta, Suman, Diaz, Carlos H, Nikonov, Dmitri E, Young, Ian A, Ham, Donhee, Chang, Meng-Fan, Khwa, Win-San, Lele, Ashwin Sanjay, Binek, Christian, Huang, Yen-Lin, Sun, Yuan-Chen, Chu, Ying-Hao, Prasad, Bhagwati, Hoffmann, Michael, Hu, Jia-Mian, Yao, Zhi, Bellaiche, Laurent, Wu, Peng, Cai, Jun, Appenzeller, Joerg, Datta, Supriyo, Camsari, Kerem Y, Kwon, Jaesuk, Incorvia, Jean Anne C, Asselberghs, Inge, Ciubotaru, Florin, Couet, Sebastien, Adelmann, Christoph, Zheng, Yi, Lindenberg, Aaron M, Evans, Paul G, Ercius, Peter, and Radu, Iuliana P

Subjects

Engineering, Physical Sciences, Materials Engineering, Nanotechnology, Condensed Matter Physics, Electrical and Electronic Engineering, Mechanical Engineering, Materials engineering, Condensed matter physics

Published

2024

12. A red-light-powered silicon nanowire biophotochemical diode for simultaneous CO2 reduction and glycerol valorization

Author

Kim, Jimin, Lin, Jia-An, Kim, Jinhyun, Roh, Inwhan, Lee, Soohyung, and Yang, Peidong

Subjects

Engineering, Nanotechnology, Affordable and Clean Energy, Inorganic chemistry, Physical chemistry, Chemical engineering

Abstract

A bias-free photochemical diode, in which a p-type photocathode is connected to an n-type photoanode to harness light for driving photoelectrochemical reduction and oxidation pairs, serves as a platform for realizing light-driven fuel generation from CO2. However, the conventional design, in which cathodic CO2 reduction is coupled with the anodic oxygen evolution reaction (OER), requires substantial energy input. Here we present a photochemical diode device that harnesses red light (740 nm) to simultaneously drive biophotocathodic CO2-to-multicarbon conversion and photoanodic glycerol oxidation as an alternative to the OER to overcome the above thermodynamic limitation. The device consists of an efficient CO2-fixing microorganism, Sporomusa ovata, interfaced with a silicon nanowire photocathode and a Pt–Au-loaded silicon nanowire photoanode. This photochemical diode operates bias-free under low-intensity (20 mW cm−2) red light irradiation with ~80% Faradaic efficiency for both the cathodic and anodic products. This work provides an alternative photosynthetic route to mitigate excessive CO2 emissions and efficiently generate value-added chemicals from CO2 and glycerol. (Figure presented.)

Published

2024

13. Moisture self-regulating ionic skins with ultra-long ambient stability for self-healing energy and sensing systems

Author

He, Peisheng, Long, Yu, Fang, Chao, Ahn, Christine Heera, Lee, Ashley, Chen, Chun-Ming, Park, Jong Ha, Wang, Monong, Ghosh, Sujoy Kumar, Qiu, Wenying, Guo, Ruiqi, Xu, Renxiao, Shao, Zhichun, Peng, Yande, Zhang, Likun, Mi, Baoxia, Zhong, Junwen, and Lin, Liwei

Subjects

Engineering, Materials Engineering, Electronics, Sensors and Digital Hardware, Affordable and Clean Energy, Hydrogels, Self-powered sensor, Ionic skins, Ambient stability, Self-healing, Macromolecular and Materials Chemistry, Nanotechnology, Macromolecular and materials chemistry, Materials engineering

Abstract

Dehydration has been a key limiting factor for the operation of conductive hydrogels in practical application. Here, we report self-healable ionic skins that can self-regulate their internal moisture level by capturing extenral moistures via hygroscopic ion-coordinated polymer backbones through antipolyelectrolyte effect. Results show the ionic skin can maintain its mechanical and electrical functions over 16 months in the ambient environment with high stretchability (fracture stretch ∼2216 %) and conductivity (23.5 mS/cm). The moisture self-regulating capability is further demonstrated by repeated exposures to harsh environments such as 200°C heating, freezing, and vacuum drying with recovered conductivity and stretchability. Their reversible ionic and hydrogen bonds also enable self-healing feature as a sample with the fully cut-through damage can restore its conductivity after 24 h at 40 % relative humidity. Utilizing the ionic skin as a building block, self-healing flexible piezoelecret sensors have been constructed to monitor physiological signals. Together with a facile transfer-printing process, a self-powered sensing system with a self-healable supercapacitor and humidity sensor has been successfully demonstrated. These results illustrate broad-ranging possibilities for the ionic skins in applications such as energy storage, wearable sensors, and human-machine interfaces.

Published

2024

14. Hypobaric hypoxia exposure regulates tissue distribution of nanomedicine for enhanced cancer therapy

Author

Tao, Ye and Chen, Zhongping

Subjects

Medical Biotechnology, Biomedical and Clinical Sciences, Digestive Diseases, Rare Diseases, Cancer, Nanotechnology, Liver Disease, Bioengineering, Development of treatments and therapeutic interventions, 5.1 Pharmaceuticals, Medical biotechnology, Oncology and carcinogenesis

Abstract

Background: Effective drug delivery of nanomedicines to targeted sites remains challenging. Given that hypobaric hypoxia and hyperbaric oxygen exposure can significantly change pharmacokinetics of drugs, it is interesting to determine whether they can regulate tissue distribution of nanomedicine, especially in tumor, for enhanced cancer therapy. Results: Hypobaric hypoxia exposure improved the pharmacokinetics of paclitaxel-loaded liposomes and facilitated their distribution in the heart and liver, whereas hyperbaric oxygen exposure did not benefit and even impaired the pharmacokinetics and distribution. Particularly, both hypobaric hypoxia and hyperbaric oxygen exposure could not improve the distribution in subcutaneous tumor. Thus, we constructed orthotopic liver tumor model and discussed whether high distribution of the liposomal nanomedicine in the liver, facilitated by hypobaric hypoxia exposure, could ensure their effective accumulation in liver tumor for enhanced cancer therapy. Conclusions: The liposomal nanomedicine with adjuvant hypobaric hypoxia exposure significantly inhibited the growth of orthotopic liver tumor for prolonged survival time, achieved by hypobaric hypoxia-promoted accumulation at tumor sites of the liver. It might be the first example of the application of adjuvant intermittent hypobaric hypoxia exposure in treating liver cancer.

Published

2024

15. Dynamic Evolution of Copper Nanowires during CO2 Reduction Probed by Operando Electrochemical 4D-STEM and X‑ray Spectroscopy

Author

Yang, Yao, Shi, Chuqiao, Feijóo, Julian, Jin, Jianbo, Chen, Chubai, Han, Yimo, and Yang, Peidong

Subjects

Chemical Sciences, Physical Chemistry, Engineering, Materials Engineering, Nanotechnology, Bioengineering, Affordable and Clean Energy, General Chemistry, Chemical sciences

Abstract

Nanowires have emerged as an important family of one-dimensional (1D) nanomaterials owing to their exceptional optical, electrical, and chemical properties. In particular, Cu nanowires (NWs) show promising applications in catalyzing the challenging electrochemical CO2 reduction reaction (CO2RR) to valuable chemical fuels. Despite early reports showing morphological changes of Cu NWs after CO2RR processes, their structural evolution and the resulting exact nature of active Cu sites remain largely elusive, which calls for the development of multimodal operando time-resolved nm-scale methods. Here, we report that well-defined 1D copper nanowires, with a diameter of around 30 nm, have a metallic 5-fold twinned Cu core and around 4 nm Cu2O shell. Operando electrochemical liquid-cell scanning transmission electron microscopy (EC-STEM) showed that as-synthesized Cu@Cu2O NWs experienced electroreduction of surface Cu2O to disordered (spongy) metallic Cu shell (Cu@CuS NWs) under CO2RR relevant conditions. Cu@CuS NWs further underwent a CO-driven Cu migration leading to a complete evolution to polycrystalline metallic Cu nanograins. Operando electrochemical four-dimensional (4D) STEM in liquid, assisted by machine learning, interrogates the complex structures of Cu nanograin boundaries. Correlative operando synchrotron-based high-energy-resolution X-ray absorption spectroscopy unambiguously probes the electroreduction of Cu@Cu2O to fully metallic Cu nanograins followed by partial reoxidation of surface Cu during postelectrolysis air exposure. This study shows that Cu nanowires evolve into completely different metallic Cu nanograin structures supporting the operando (operating) active sites for the CO2RR.

Published

2024

16. Discovery of a Peptoid-Based Nanoparticle Platform for Therapeutic mRNA Delivery via Diverse Library Clustering and Structural Parametrization

Author

Webster, Elizabeth R, Peck, Nicole E, Echeverri, Juan Diego, Gholizadeh, Shima, Tang, Wei-Lun, Woo, Rinette, Sharma, Anushtha, Liu, Weiqun, Rae, Chris S, Sallets, Adrienne, Adusumilli, Gowrisudha, Gunasekaran, Kannan, Haabeth, Ole AW, Leong, Meredith, Zuckermann, Ronald N, Deutsch, Samuel, and McKinlay, Colin J

Subjects

Medical Biotechnology, Biomedical and Clinical Sciences, Gene Therapy, Bioengineering, Nanotechnology, Biotechnology, Genetics, 5.1 Pharmaceuticals, Peptoids, Nanoparticles, Animals, Mice, RNA, Messenger, Humans, Respiratory Syncytial Viruses, Lipids, peptoid, mRNA delivery, lipid nanoparticle, design of experiments, nucleic acid delivery, high-throughput screening, Nanoscience & Nanotechnology

Abstract

Nanoparticle-mediated mRNA delivery has emerged as a promising therapeutic modality, but its growth is still limited by the discovery and optimization of effective and well-tolerated delivery strategies. Lipid nanoparticles containing charged or ionizable lipids are an emerging standard for in vivo mRNA delivery, so creating facile, tunable strategies to synthesize these key lipid-like molecules is essential to advance the field. Here, we generate a library of N-substituted glycine oligomers, peptoids, and undertake a multistage down-selection process to identify lead candidate peptoids as the ionizable component in our Nutshell nanoparticle platform. First, we identify a promising peptoid structural motif by clustering a library of >200 molecules based on predicted physical properties and evaluate members of each cluster for reporter gene expression in vivo. Then, the lead peptoid motif is optimized using design of experiments methodology to explore variations on the charged and lipophilic portions of the peptoid, facilitating the discovery of trends between structural elements and nanoparticle properties. We further demonstrate that peptoid-based Nutshells leads to expression of therapeutically relevant levels of an anti-respiratory syncytial virus antibody in mice with minimal tolerability concerns or induced immune responses compared to benchmark ionizable lipid, DLin-MC3-DMA. Through this work, we present peptoid-based nanoparticles as a tunable delivery platform that can be optimized toward a range of therapeutic programs.

Published

2024

17. Rapid Synthesis of Ruthenium–Copper Nanocomposites as High‐Performance Bifunctional Electrocatalysts for Electrochemical Water Splitting

Author

Pan, Dingjie, Liu, Qiming, Yu, Bingzhe, DuBois, Davida Briana, Tressel, John, Yu, Sarah, Kaleekal, Noah, Trabanino, Sophia, Jeon, Yillin, Bridges, Frank, and Chen, Shaowei

Subjects

Macromolecular and Materials Chemistry, Chemical Sciences, Engineering, Materials Engineering, Nanotechnology, Affordable and Clean Energy, bifunctional catalyst, in situ X-ray absorption spectroscopy, magnetic induction heating, ruthenium/copper nanocomposite, water splitting, in situ X‐ray absorption spectroscopy, Nanoscience & Nanotechnology

Abstract

Development of high-performance, low-cost catalysts for electrochemical water splitting is key to sustainable hydrogen production. Herein, ultrafast synthesis of carbon-supported ruthenium-copper (RuCu/C) nanocomposites is reported by magnetic induction heating, where the rapid Joule's heating of RuCl3 and CuCl2 at 200 A for 10 s produces Ru-Cl residues-decorated Ru nanocrystals dispersed on a CuClx scaffold, featuring effective Ru to Cu charge transfer. Among the series, the RuCu/C-3 sample exhibits the best activity in 1 m KOH toward both the hydrogen evolution reaction (HER) and oxygen evolution reaction (OER), with an overpotential of only -23 and +270 mV to reach 10 mA cm-2, respectively. When RuCu/C-3 is used as bifunctional catalysts for electrochemical water splitting, a low cell voltage of 1.53 V is needed to produce 10 mA cm-2, markedly better than that with a mixture of commercial Pt/C+RuO2 (1.59 V). In situ X-ray absorption spectroscopy measurements show that the bifunctional activity is due to reduction of the Ru-Cl residues at low electrode potentials that enriches metallic Ru and oxidation at high electrode potentials that facilitates the formation of amorphous RuOx. These findings highlight the unique potential of MIH in the ultrafast synthesis of high-performance catalysts for electrochemical water splitting.

Published

2024

18. Role of Tensile Stress in DNA Nanoresonators for Epigenetic Studies

Author

Legittimo, Francesca, Marini, Monica, Stassi, Stefano, Tortello, Mauro, Sader, John E, Ashby, Paul D, Rad, Behzad, Ralston, Corie Y, Di Fabrizio, Enzo, and Ricciardi, Carlo

Subjects

Biological Sciences, Genetics, Human Genome, Generic health relevance, epigenetics, DNA methylation, DNAnanoresonators, nanomechanical sensing, AFM forcecurve, Industrial biotechnology, Macromolecular and materials chemistry, Nanotechnology

Abstract

The evaluation of epigenetic features such as DNA methylation is becoming increasingly important in many biochemical processes like gene expression and transcription as well as in several diseases like schizophrenia or diabetes. Here, we report that self-assembled nanomechanical resonators entirely composed of DNA molecules can be used to explore gross changes in DNA methylation levels (0-25-50%), while careful control of tensile stress is needed to reduce the variability of resonance frequency for rigorous quantification. The effect of the tensile stress retained by the suspended DNA nanoresonators on the application of the technique is extensively explored using a combination of laser Doppler vibrometry and atomic force spectroscopy. DNA nanoresonators are real-time, label-free sensors and could avoid chemical functionalization and sample amplification. Therefore, they may represent in the future a key complementary routine tool for global DNA methylation analysis needed to evaluate the consequences of environmental stresses on the human genome.

Published

2024

19. Beyond microroughness: novel approaches to navigate osteoblast activity on implant surfaces.

Author

Matsuura, Takanori, Komatsu, Keiji, Cheng, James, Park, Gunwoo, and Ogawa, Takahiro

Subjects

Bone and implant integration, Meso-structuring, Nanotechnology, Osseointegration, UV photofunctionalization, Osteoblasts, Humans, Surface Properties, Osseointegration, Dental Implants, Cell Differentiation, Cell Proliferation, Titanium, Osteogenesis

Abstract

Considering the biological activity of osteoblasts is crucial when devising new approaches to enhance the osseointegration of implant surfaces, as their behavior profoundly influences clinical outcomes. An established inverse correlation exists between osteoblast proliferation and their functional differentiation, which constrains the rapid generation of a significant amount of bone. Examining the surface morphology of implants reveals that roughened titanium surfaces facilitate rapid but thin bone formation, whereas smooth, machined surfaces promote greater volumes of bone formation albeit at a slower pace. Consequently, osteoblasts differentiate faster on roughened surfaces but at the expense of proliferation speed. Moreover, the attachment and initial spreading behavior of osteoblasts are notably compromised on microrough surfaces. This review delves into our current understanding and recent advances in nanonodular texturing, meso-scale texturing, and UV photofunctionalization as potential strategies to address the biological dilemma of osteoblast kinetics, aiming to improve the quality and quantity of osseointegration. We discuss how these topographical and physicochemical strategies effectively mitigate and even overcome the dichotomy of osteoblast behavior and the biological challenges posed by microrough surfaces. Indeed, surfaces modified with these strategies exhibit enhanced recruitment, attachment, spread, and proliferation of osteoblasts compared to smooth surfaces, while maintaining or amplifying the inherent advantage of cell differentiation. These technology platforms suggest promising avenues for the development of future implants.

Published

2024

20. DNA Delivery by Virus-Like Nanocarriers in Plant Cells

Author

Islam, Reyazul, Youngblood, Marina, Kim, Hye-In, González-Gamboa, Ivonne, Monroy-Borrego, Andrea Gabriela, Caparco, Adam A, Lowry, Gregory V, Steinmetz, Nicole F, and Giraldo, Juan Pablo

Subjects

Plant Biology, Biological Sciences, Medical Biotechnology, Biomedical and Clinical Sciences, Gene Therapy, Biotechnology, Nanotechnology, Bioengineering, Genetics, Arabidopsis, Green Fluorescent Proteins, Gene Transfer Techniques, Plasmids, Polyamines, Protoplasts, Nanostructures, DNA, virus, nanoparticles, gene delivery, protoplasts, plant genetics, agriculture, Nanoscience & Nanotechnology

Abstract

Tobacco mild green mosaic virus (TMGMV)-like nanocarriers were designed for gene delivery to plant cells. High aspect ratio TMGMVs were coated with a polycationic biopolymer, poly(allylamine) hydrochloride (PAH), to generate highly charged nanomaterials (TMGMV-PAH; 56.20 ± 4.7 mV) that efficiently load (1:6 TMGMV:DNA mass ratio) and deliver single-stranded and plasmid DNA to plant cells. The TMGMV-PAH were taken up through energy-independent mechanisms in Arabidopsis protoplasts. TMGMV-PAH delivered a plasmid DNA encoding a green fluorescent protein (GFP) to the protoplast nucleus (70% viability), as evidenced by GFP expression using confocal microscopy and Western blot analysis. TMGMV-PAH were inactivated (iTMGMV-PAH) using UV cross-linking to prevent systemic infection in intact plants. Inactivated iTMGMV-PAH-mediated pDNA delivery and gene expression of GFP in vivo was determined using confocal microscopy and RT-qPCR. Virus-like nanocarrier-mediated gene delivery can act as a facile and biocompatible tool for advancing genetic engineering in plants.

Published

2024

21. Ultrafast preparation of ruthenium nanoparticle/molybdenum oxide/nitrogen-doped carbon nanocomposites by magnetic induction heating for efficient hydrogen evolution reaction

Author

Yu, Bingzhe, Liu, Qiming, Pan, Dingjie, Singewald, Kevin, DuBois, Davida, Tressel, John, Hou, Bryan, Millhauser, Glenn L, Bridges, Frank, and Chen, Shaowei

Subjects

Engineering, Materials Engineering, Chemical Sciences, Nanotechnology, Affordable and Clean Energy, Macromolecular and Materials Chemistry, Interdisciplinary Engineering, Macromolecular and materials chemistry, Chemical engineering, Materials engineering

Abstract

Synergetic interactions between ruthenium and molybdenum oxide weaken H adsorption on ruthenium active sites and hence enhance the electrocatalytic activity towards hydrogen evolution reaction.

Published

2024

22. Scanning electrochemical probe microscopy investigation of two-dimensional materials

Author

Adanigbo, Pelumi, Romo-Jimenez, Jorge, Zhang, Kaidi, Maroo, Sonal, Bediako, Kwabena, and Yu, Yun

Subjects

Engineering, Materials Engineering, Affordable and Clean Energy, SECM, SECCM, electrochemistry, Macromolecular and Materials Chemistry, Nanotechnology, Materials engineering, Condensed matter physics

Abstract

Research interests in two-dimensional (2D) materials have seen exponential growth owing to their unique and fascinating properties. The highly exposed lattice planes coupled with tunable electronic states of 2D materials have created manifold opportunities in the design of new platforms for energy conversion and sensing applications. Still, challenges in understanding the electrochemical (EC) characteristics of these materials arise from the complexity of both intrinsic and extrinsic heterogeneities that can obscure structure-activity correlations. Scanning EC probe microscopic investigations offer unique benefits in disclosing local EC reactivities at the nanoscale level that are otherwise inaccessible with macroscale methods. This review summarizes recent progress in applying techniques of scanning EC microscopy (SECM) and scanning EC cell microscopy (SECCM) to obtain distinctive insights into the fundamentals of 2D electrodes. We showcase the capabilities of EC microscopies in addressing the roles of defects, thickness, environments, strain, phase, stacking, and many other aspects in the heterogeneous electron transfer, ion transport, electrocatalysis, and photoelectrochemistry of representative 2D materials and their derivatives. Perspectives for the advantages, challenges, and future opportunities of scanning EC probe microscopy investigation of 2D structures are discussed.

Published

2024

23. Fundamentals and emerging optical applications of hexagonal boron nitride: a tutorial

Author

Su, Cong, Janzen, Eli, He, Mingze, Li, Chi, Zettl, Alex, Caldwell, Joshua D, Edgar, James H, and Aharonovich, Igor

Subjects

Quantum Physics, Physical Sciences, Condensed Matter Physics, Optical Physics, Nanotechnology, Atomic, molecular and optical physics, Classical physics

Abstract

Hexagonal boron nitride (hBN), also known as white graphite, is a transparent layered crystal with a wide bandgap. Its crystal structure resembles graphite, featuring layers composed of honeycomb lattices held together through van der Waals forces. The layered crystal structure of hBN facilitates exfoliation into thinner flakes and makes it highly anisotropic in in-plane and out-of-plane directions. Unlike graphite, hBN is both insulating and transparent, making it an ideal material for isolating devices from the environment and acting as a waveguide. As a result, hBN has found extensive applications in optical devices, electronic devices, and quantum photonic devices. This comprehensive tutorial aims to provide readers with a thorough understanding of hBN, covering its synthesis, lattice and spectroscopic characterization, and various applications in optoelectronic and quantum photonic devices. This tutorial is designed for both readers without prior experience in hBN and those with expertise in specific fields seeking to understand its relevance and connections to others.

Published

2024

24. Characterization of Mass, Diameter, Density, and Surface Properties of Colloidal Nanoparticles Enabled by Charge Detection Mass Spectrometry

Author

Harper, Conner C, Jordan, Jacob S, Papanu, Steven, and Williams, Evan R

Subjects

Analytical Chemistry, Biomedical and Clinical Sciences, Chemical Sciences, Physical Chemistry, Engineering, Medical Biotechnology, Nanotechnology, Bioengineering, mass, charge, characterization, nanoparticle, density, precision, surface, Nanoscience & Nanotechnology

Abstract

A variety of scattering-based, microscopy-based, and mobility-based methods are frequently used to probe the size distributions of colloidal nanoparticles with transmission electron microscopy (TEM) often considered to be the "gold standard". Charge detection mass spectrometry (CDMS) is an alternative method for nanoparticle characterization that can rapidly measure the mass and charge of individual nanoparticle ions with high accuracy. Two low polydispersity, ∼100 nm diameter nanoparticle size standards with different compositions (polymethyl methacrylate/polystyrene copolymer and 100% polystyrene) were characterized using both TEM and CDMS to explore the merits and complementary aspects of both methods. Mass and diameter distributions are rapidly obtained from CDMS measurements of thousands of individual ions of known spherical shape, requiring less time than TEM sample preparation and image analysis. TEM image-to-image variations resulted in a ∼1-2 nm range in the determined mean diameters whereas the CDMS mass precision of ∼1% in these experiments leads to a diameter uncertainty of just 0.3 nm. For the 100% polystyrene nanoparticles with known density, the CDMS and TEM particle diameter distributions were in excellent agreement. For the copolymer nanoparticles with unknown density, the diameter from TEM measurements combined with the mass from CDMS measurements enabled an accurate measurement of nanoparticle density. Differing extents of charging for the two nanoparticle standards measured by CDMS show that charging is sensitive to nanoparticle surface properties. A mixture of the two samples was separated based on their different extents of charging despite having overlapping mass distributions centered at 341.5 and 331.0 MDa.

Published

2024

25. Oversaturating Liquid Interfaces with Nanoparticle‐Surfactants

Author

Wu, Xuefei, Xue, Han, Fink, Zachary, Helms, Brett A, Ashby, Paul D, Omar, Ahmad K, and Russell, Thomas P

Subjects

Macromolecular and Materials Chemistry, Chemical Sciences, Nanotechnology, Bioengineering, out-of-equilibrium assembly, nanoparticle-surfactants, in situ small-angle X-ray scattering, explosive emulsification, liquid/liquid interface, Organic Chemistry, Chemical sciences

Abstract

Assemblies of nanoparticles at liquid interfaces hold promise as dynamic "active" systems when there are convenient methods to drive the system out of equilibrium via crowding. To this end, we show that oversaturated assemblies of charged nanoparticles can be realized and held in that state with an external electric field. Upon removal of the field, strong interparticle repulsive forces cause a high in-plane electrostatic pressure that is released in an explosive emulsification. We quantify the packing of the assembly as it is driven into the oversaturated state under an applied electric field. Physiochemical conditions substantially affect the intensity of the induced explosive emulsification, underscoring the crucial role of interparticle electrostatic repulsion.

Published

2024

26. Uncovering the three-dimensional structure of upconverting core–shell nanoparticles with multislice electron ptychography

Author

Ribet, Stephanie M, Varnavides, Georgios, Pedroso, Cassio CS, Cohen, Bruce E, Ercius, Peter, Scott, Mary C, and Ophus, Colin

Subjects

Physical Sciences, Engineering, Nanotechnology, Bioengineering, Technology, Applied Physics, Physical sciences

Abstract

In photon upconverting core-shell nanoparticles, structure strongly dictates performance. Typical imaging in scanning transmission electron microscopy has sufficient resolution to probe the atomic structure of these nanoparticles, but contrast, dose, and projection limitations make conventional methods insufficient for fully characterizing these structures. Phase retrieval techniques provide a promising alternative imaging mode, and, in particular, multislice electron ptychography can recover depth-dependent information. Here, we study beam-sensitive photon upconverting core-shell nanoparticles with a multislice ptychography approach using a low electron dose to avoid damage. Large strain fields arise in these heterostructures due to the mismatch in lattice parameter between the core and the shell. We reconstruct both a nanoparticle that appears defect-free and one that has a large break in the side and map the distribution of strain in 3D by computing distortion fields from high-resolution potential images of each slice. In the defect-free nanoparticle, we observe twisting of the shell, while in the broken nanoparticle, we measure the 3D position of the crack, the core, and dislocations. These results highlight the advantage of multislice electron ptychography to recover 3D information from a single scan, even under strict electron dose requirements from beam-sensitive samples.

Published

2024

27. Multifunctional self-priming hairpin probe-based isothermal nucleic acid amplification and its applications for COVID-19 diagnosis

Author

Kim, Hansol, Lee, Seoyoung, Ju, Yong, Kim, Hyoyong, Jang, Hyowon, Park, Yeonkyung, Lee, Sang Mo, Yong, Dongeun, Kang, Taejoon, and Park, Hyun Gyu

Subjects

Analytical Chemistry, Chemical Sciences, Biotechnology, Infectious Diseases, Coronaviruses, Emerging Infectious Diseases, 4.2 Evaluation of markers and technologies, Humans, Nucleic Acids, COVID-19, COVID-19 Testing, Nucleic Acid Amplification Techniques, SARS-CoV-2, Biosensing Techniques, Sensitivity and Specificity, Isothermal amplification, Molecular diagnostics, Self-priming hairpin probe, Biomedical Engineering, Nanotechnology, Bioinformatics, Analytical chemistry, Biomedical engineering

Abstract

We herein present a multifunctional self-priming hairpin probe-based isothermal amplification, termed MSH, enabling one-pot detection of target nucleic acids. The sophisticatedly designed multifunctional self-priming hairpin (MSH) probe recognizes the target and rearranges to prime itself, triggering the amplification reaction powered by the continuously repeated extension, nicking, and target recycling. As a consequence, a large number of double-stranded DNA (dsDNA) amplicons are produced that could be monitored in real-time using a dsDNA-intercalating dye. Based on this unique design approach, the nucleocapsid (N) and the open reading frame 1 ab (ORF1ab) genes of SARS-CoV-2 were successfully detected down to 1.664 fM and 0.770 fM, respectively. The practical applicability of our method was validated by accurately diagnosing 60 clinical samples with 93.33% sensitivity and 96.67% specificity. This isothermal one-pot MSH technique holds great promise as a point-of-care testing protocol for the reliable detection of a wide spectrum of pathogens, particularly in resource-limited settings.

Published

2024

28. A personal glucose meter-utilized strategy for portable and label-free detection of hydrogen peroxide

Author

Lee, Sangmo, Kim, Hyoyong, Yoon, Junhyeok, Ju, Yong, and Park, Hyun Gyu

Subjects

Analytical Chemistry, Chemical Sciences, Breast Cancer, Cancer, Women's Health, Hydrogen Peroxide, Biosensing Techniques, Catalysis, Choline, Glucose, Ferri/ferrocyanide, Horseradish peroxidase, Hydrogen peroxide, Personal glucose meter, Biomedical Engineering, Nanotechnology, Bioinformatics, Analytical chemistry, Biomedical engineering

Abstract

Rapid and precise detection of hydrogen peroxide (H2O2) holds great significance since it is linked to numerous physiological and inorganic catalytic processes. We herein developed a label-free and washing-free strategy to detect H2O2 by employing a hand-held personal glucose meter (PGM) as a signal readout device. By focusing on the fact that the reduced redox mediator ([Fe(CN)6]4-) itself is responsible for the final PGM signal, we developed a new PGM-based strategy to detect H2O2 by utilizing the target H2O2-mediated oxidation of [Fe(CN)6]4- to [Fe(CN)6]3- in the presence of horseradish peroxidase (HRP) and monitoring the reduced PGM signal in response to the target amount. Based on this straightforward and facile design principle, H2O2 was successfully determined down to 3.63 μM with high specificity against various non-target molecules. We further demonstrated that this strategy could be expanded to identify another model target choline by detecting H2O2 produced through its oxidation promoted by choline oxidase. Moreover, we verified its practical applicability by reliably determining extracellular H2O2 released from the breast cancer cell line, MDA-MB-231. This work could evolve into versatile PGM-based platform technology to identify various non-glucose target molecules by employing their corresponding oxidase enzymes, greatly advancing the portable biosensing technologies.

Published

2024

29. Characterization of a HPHT boron ion-implanted diamond X-ray mirror following high vacuum annealing

Author

Margraf-O'Neal, RA, Ynsa, MD, Krzywinski, J, Ng, ML, MacArthur, JP, Ke, F, Zhong, Y, Mo, S-K, Pradhan, P, Robles, R, Robert, A, Sato, T, Zhu, D, Halavanau, A, and Marcus, G

Subjects

Quantum Physics, Physical Sciences, Chemical Engineering, Manufacturing Engineering, Materials Engineering, Applied Physics, Materials engineering, Nanotechnology, Condensed matter physics

Abstract

The incorporation of boron into a diamond lattice holds the potential to advance X-ray optics, offering the capability to manipulate various parameters of the lattice. This includes enhancing near-infrared absorption relative to pure diamond, thereby enabling Q-switchable optics. The use of MeV boron implantation emerges as a promising method for precisely doping the diamond lattice. However, for these optics to function effectively as Bragg-reflecting mirrors, ion implantation must be executed with meticulous attention to maintaining a strain-free, perfect diamond lattice. This study aimed to investigate the feasibility of utilizing a 9 MeV ion beam for high energy boron implantation. Different areas of a high-pressure, high-temperature (HPHT) diamond sample were subjected to irradiation with 9 MeV Boron ions, ranging in fluences from 5×1015 to 2.5×1016ions/cm2. Following boron implantation, high-temperature vacuum annealing was performed to restore the diamond lattice. Our assessment utilized X-ray rocking curve imaging, surface profilometry, and micro-Raman spectroscopy, with additional observations on near-infrared transmission properties. Our measurement of high-quality Bragg reflection through X-ray rocking curve imaging, sensitive to implantation-induced strain and defects, served as an key diagnostic for the effectiveness of this ion-implanted sample as a Bragg-reflecting optic.

Published

2024

30. Complete miscibility of immiscible elements at the nanometre scale

Author

Chen, Peng-Cheng, Gao, Mengyu, McCandler, Caitlin A, Song, Chengyu, Jin, Jianbo, Yang, Yao, Maulana, Arifin Luthfi, Persson, Kristin A, and Yang, Peidong

Subjects

Engineering, Nanotechnology, Bioengineering, Nanoscience & Nanotechnology

Abstract

Understanding the mixing behaviour of elements in a multielement material is important to control its structure and property. When the size of a multielement material is decreased to the nanoscale, the miscibility of elements in the nanomaterial often changes from its bulk counterpart. However, there is a lack of comprehensive and quantitative experimental insight into this process. Here we explored how the miscibility of Au and Rh evolves in nanoparticles of sizes varying from 4 to 1 nm and composition changing from 15% Au to 85% Au. We found that the two immiscible elements exhibit a phase-separation-to-alloy transition in nanoparticles with decreased size and become completely miscible in sub-2 nm particles across the entire compositional range. Quantitative electron microscopy analysis and theoretical calculations were used to show that the observed immiscibility-to-miscibility transition is dictated by particle size, composition and possible surface adsorbates present under the synthesis conditions.

Published

2024

31. Transition Metal Impurities as Shallow Donors in β‐Ga2O3

Author

Karbasizadeh, Siavash, Mu, Sai, Turiansky, Mark E, and Van de Walle, Chris G

Subjects

Inorganic Chemistry, Chemical Sciences, Physical Sciences, Condensed Matter Physics, binding energy, gallium oxide, hyperfine structure, shallow donors, transition metal oxide, Materials Engineering, Nanotechnology, Applied Physics, Chemical sciences, Engineering, Physical sciences

Abstract

An in‐depth investigation of transition metal impurities (Hf, Zr, Nb, and W) is presented as shallow donors in monoclinic Ga2O3 using first‐principles calculations within the framework of density functional theory. A combination of semilocal and hybrid functionals is used to predict their binding energies and hyperfine parameters. The generalized gradient approximation (GGA) allows performing calculations for supercells of up to 2500 atoms, enabling an extrapolation to the dilute limit. The shortcoming of GGA in correctly describing the electron localization is then overcome by the use of the hybrid functional. Results are presented and discussed in light of the application of these transition‐metal elements as shallow donors in Ga2O3 and their identification in the experiment. The methodology applied here can be used in calculations for shallow donors in other systems.

Published

2024

32. Low Resistance Contact to P‑Type Monolayer WSe2

Author

Xie, Jingxu, Zhang, Zuocheng, Zhang, Haodong, Nagarajan, Vikram, Zhao, Wenyu, Kim, Ha-Leem, Sanborn, Collin, Qi, Ruishi, Chen, Sudi, Kahn, Salman, Watanabe, Kenji, Taniguchi, Takashi, Zettl, Alex, Crommie, Michael F, Analytis, James, and Wang, Feng

Subjects

Physical Sciences, Engineering, Nanotechnology, Condensed Matter Physics, ohmic contacts, p-type monolayer WSe2 FET, charge transfer, type-III band alignment, alpha-RuCl3, α-RuCl3, Nanoscience & Nanotechnology

Abstract

Advanced microelectronics in the future may require semiconducting channel materials beyond silicon. Two-dimensional (2D) semiconductors, with their atomically thin thickness, hold great promise for future electronic devices. One challenge to achieving high-performance 2D semiconductor field effect transistors (FET) is the high contact resistance at the metal-semiconductor interface. In this study, we develop a charge-transfer doping strategy with WSe2/α-RuCl3 heterostructures to achieve low-resistance ohmic contact for p-type monolayer WSe2 transistors. We show that hole doping as high as 3 × 1013 cm-2 can be achieved in the WSe2/α-RuCl3 heterostructure due to its type-III band alignment, resulting in an ohmic contact with resistance of 4 kΩ μm. Based on that, we demonstrate p-type WSe2 transistors with an on-current of 35 μA·μm-1 and an ION/IOFF ratio exceeding 109 at room temperature.

Published

2024

33. STORM Super-Resolution Visualization of Self-Assembled γPFD Chaperone Ultrastructures in Methanocaldococcus jannaschii

Author

Cha, Hee-Jeong, He, Changdong, Glover, Dominic J, Xu, Ke, and Clark, Douglas S

Subjects

Biochemistry and Cell Biology, Physical Sciences, Biological Sciences, Bioengineering, Nanotechnology, Methanocaldococcus, Molecular Chaperones, Archaeal Proteins, Microscopy, Fluorescence, Imaging, Three-Dimensional, archaeal chaperone, prefoldin, super-resolutionmicroscopy, self-assembled nanostructures, super-resolution microscopy, Nanoscience & Nanotechnology

Abstract

Gamma-prefoldin (γPFD), a unique chaperone found in the extremely thermophilic methanogen Methanocaldococcus jannaschii, self-assembles into filaments in vitro, which so far have been observed using transmission electron microscopy and cryo-electron microscopy. Utilizing three-dimensional stochastic optical reconstruction microscopy (3D-STORM), here we achieve ∼20 nm resolution by precisely locating individual fluorescent molecules, hence resolving γPFD ultrastructure both in vitro and in vivo. Through CF647 NHS ester labeling, we first demonstrate the accurate visualization of filaments and bundles with purified γPFD. Next, by implementing immunofluorescence labeling after creating a 3xFLAG-tagged γPFD strain, we successfully visualize γPFD in M. jannaschii cells. Through 3D-STORM and two-color STORM imaging with DNA, we show the widespread distribution of filamentous γPFD structures within the cell. These findings provide valuable insights into the structure and localization of γPFD, opening up possibilities for studying intriguing nanoscale components not only in archaea but also in other microorganisms.

Published

2024

34. Dimensionality effects on trap-assisted recombination: the Sommerfeld parameter

Author

Turiansky, Mark E, Alkauskas, Audrius, and Van de Walle, Chris G

Subjects

Physical Sciences, Condensed Matter Physics, Biotechnology, density functional theory, defects and impurities, recombination mechanisms, Sommerfeld parameter, Coulomb interaction, Materials Engineering, Nanotechnology, Fluids & Plasmas, Materials engineering, Condensed matter physics

Abstract

In the context of condensed matter physics, the Sommerfeld parameter describes the enhancement or suppression of free-carrier charge density in the vicinity of a charged center. The Sommerfeld parameter is known for three-dimensional systems and is integral to the description of trap-assisted recombination in solids. Here we derive the Sommerfeld parameter in one and two dimensions and compare with the results in three dimensions. We provide an approximate analytical expression for the Sommerfeld parameter in two dimensions. Our results indicate that the effect of the Sommerfeld parameter is to suppress trap-assisted recombination in decreased dimensionality.

Published

2024

35. Self‐Propulsion by Directed Explosive Emulsification

Author

Wu, Xuefei, Xue, Han, Bordia, Gautam, Fink, Zachary, Kim, Paul Y, Streubel, Robert, Han, Jiale, Helms, Brett A, Ashby, Paul D, Omar, Ahmad K, and Russell, Thomas P

Subjects

Engineering, Chemical Sciences, Physical Chemistry, Nanotechnology, Bioengineering, charged nanoparticle-surfactants, directed explosive emulsification, liquid-liquid interface, self-assembly, self-propulsion, charged nanoparticle‐surfactants, liquid–liquid interface, self‐assembly, self‐propulsion, Physical Sciences, Nanoscience & Nanotechnology, Chemical sciences, Physical sciences

Abstract

An active droplet system, programmed to repeatedly move autonomously at a specific velocity in a well-defined direction, is demonstrated. Coulombic energy is stored in oversaturated interfacial assemblies of charged nanoparticle-surfactants by an applied DC electric field and can be released on demand. Spontaneous emulsification is suppressed by an increase in the stiffness of the oversaturated assemblies. Rapidly removing the field releases the stored energy in an explosive event that propels the droplet, where thousands of charged microdroplets are ballistically ejected from the surface of the parent droplet. The ejection is made directional by a symmetry breaking of the interfacial assembly, and the combined interaction force of the microdroplet plume on one side of the droplet propels the droplet distances tens of times its size, making the droplet active. The propulsion is autonomous, repeatable, and agnostic to the chemical composition of the nanoparticles. The symmetry-breaking in the nanoparticle assembly controls the microdroplet velocity and direction of propulsion. This mechanism of droplet propulsion will advance soft micro-robotics, establishes a new type of active matter, and introduces new vehicles for compartmentalized delivery.

Published

2024

36. Room-Temperature Ferroelectric Epitaxial Nanowire Arrays with Photoluminescence

Author

Le, Han KD, Zhang, Ye, Behera, Piush, Vailionis, Arturas, Phang, Amelyn, Brinn, Rafaela M, and Yang, Peidong

Subjects

Macromolecular and Materials Chemistry, Chemical Sciences, Physical Chemistry, Engineering, Materials Engineering, Nanotechnology, metal halide perovskites, nanowire, epitaxialgrowth, optical properties, ferroelectric, epitaxial growth, Nanoscience & Nanotechnology

Abstract

The development of large-scale, high-quality ferroelectric semiconductor nanowire arrays with interesting light-emitting properties can address limitations in traditional wide-bandgap ferroelectrics, thus serving as building blocks for innovative device architectures and next-generation high-density optoelectronics. Here, we investigate the optical properties of ferroelectric CsGeX3 (X = Br, I) halide perovskite nanowires that are epitaxially grown on muscovite mica substrates by vapor phase deposition. Detailed structural characterizations reveal an incommensurate heteroepitaxial relationship with the mica substrate. Furthermore, photoluminescence that can be tuned from yellow-green to red emissions by varying the halide composition demonstrates that these nanowire networks can serve as platforms for future optoelectronic applications. In addition, the room-temperature ferroelectricity and ferroelectric domain structures of these nanowires are characterized using second harmonic generation (SHG) polarimetry. The combination of room-temperature ferroelectricity with photoluminescence in these nanowire arrays unlocks new avenues for the design of novel multifunctional materials.

Published

2024

37. Emergence of two distinct phase transitions in monolayer CoSe2 on graphene

Author

Rhee, Tae Gyu, Lam, Nguyen Huu, Kim, Yeong Gwang, Gu, Minseon, Hwang, Jinwoong, Bostwick, Aaron, Mo, Sung-Kwan, Chun, Seung-Hyun, Kim, Jungdae, Chang, Young Jun, and Choi, Byoung Ki

Subjects

Engineering, Nanotechnology, Angle-resolved photoemission spectroscopy, Charge-density wave, Electron-boson coupling, Molecular beam epitaxy, Scanning tunneling microscopy, Transition metal chalcogenides

Abstract

Dimensional modifications play a crucial role in various applications, especially in the context of device miniaturization, giving rise to novel quantum phenomena. The many-body dynamics induced by dimensional modifications, including electron-electron, electron-phonon, electron-magnon and electron-plasmon coupling, are known to significantly affect the atomic and electronic properties of the materials. By reducing the dimensionality of orthorhombic CoSe2 and forming heterostructure with bilayer graphene using molecular beam epitaxy, we unveil the emergence of two types of phase transitions through angle-resolved photoemission spectroscopy and scanning tunneling microscopy measurements. We disclose that the 2 × 1 superstructure is associated with charge density wave induced by Fermi surface nesting, characterized by a transition temperature of 340 K. Additionally, another phase transition at temperature of 160 K based on temperature dependent gap evolution are observed with renormalized electronic structure induced by electron-boson coupling. These discoveries of the electronic and atomic modifications, influenced by electron-electron and electron-boson interactions, underscore that many-body physics play significant roles in understanding low-dimensional properties of non-van der Waals Co-chalcogenides and related heterostructures.

Published

2024

38. Role of ESCCAL-1 in regulating exocytosis of AuNPs in human esophageal squamous carcinoma cells

Author

Gong, Fenfen, Cui, Yuanbo, Lv, Penju, Liu, Jia, Sun, Xiaoyan, Han, Pengli, Zhou, Lijuan, Xia, Tian, and Cao, Wei

Subjects

Biochemistry and Cell Biology, Biological Sciences, Bioengineering, Genetics, Nanotechnology, Rare Diseases, Cancer, Underpinning research, 1.1 Normal biological development and functioning, Generic health relevance, Exocytosis mechanisms, Gold nanoparticles, lncRNA ESCCAL-1, Chemical Sciences, Technology, Nanoscience & Nanotechnology, Biological sciences, Chemical sciences

Abstract

Exocytosis is a critical factor for designing efficient nanocarriers and determining cytotoxicity. However, the research on the exocytosis mechanism of nanoparticles, especially the role of long non-coding RNAs (lncRNA), has not been reported. In this study, the exocytosis of AuNPs in the KYSE70 cells and the involved molecular pathways of exocytosis are analyzed. It demonstrates that nanoparticles underwent time-dependent release from the cells by exocytosis, and the release of β-hexosaminidase confirms that AuNPs are excreted through lysosomes. Mechanistic studies reveal that lncRNA ESCCAL-1 plays a vital role in controlling the exocytosis of AuNPs through activation of the MAPK pathway, including the phosphorylation of ERK and JNK. The study implies that the ESCCAL-1-mediated pathway plays an important role in the exocytosis of AuNPs in KYSE70 cells. This finding has implications for the role of ESCCAL-1 on the drug resistance of esophagus cancer by controlling lysosome-mediated exocytosis.

Published

2024

39. Nanophotonics out of equilibrium

Author

Manjavacas, Alejandro, Pelton, Matthew, Sheldon, Matthew, and Sukharev, Maxim

Subjects

Quantum Physics, Engineering, Physical Sciences, Atomic, Molecular and Optical Physics, Nanotechnology, Optical Physics, Electrical and Electronic Engineering, Atomic, molecular and optical physics, Quantum physics

Published

2024

40. Carbon capture in polymer-based electrolytes

Author

Wang, Yang, Feric, Tony G, Tang, Jing, Fang, Chao, Hamilton, Sara T, Halat, David M, Wu, Bing, Celik, Hasan, Rim, Guanhe, DuBridge, Tara, Oshiro, Julianne, Wang, Rui, Park, Ah-Hyung Alissa, and Reimer, Jeffrey A

Subjects

Macromolecular and Materials Chemistry, Chemical Sciences, Physical Chemistry, Bioengineering, Nanotechnology, Climate Action

Abstract

Nanoparticle organic hybrid materials (NOHMs) have been proposed as excellent electrolytes for combined CO2 capture and electrochemical conversion due to their conductive nature and chemical tunability. However, CO2 capture behavior and transport properties of these electrolytes after CO2 capture have not yet been studied. Here, we use a variety of nuclear magnetic resonance (NMR) techniques to explore the carbon speciation and transport properties of branched polyethylenimine (PEI) and PEI-grafted silica nanoparticles (denoted as NOHM-I-PEI) after CO2 capture. Quantitative 13C NMR spectra collected at variable temperatures reveal that absorbed CO2 exists as carbamates (RHNCOO- or RR'NCOO-) and carbonate/bicarbonate (CO32-/HCO3-). The transport properties of PEI and NOHM-I-PEI studied using 1H pulsed-field-gradient NMR, combined with molecular dynamics simulations, demonstrate that coulombic interactions between negatively and positively charged chains dominate in PEI, while the self-diffusion in NOHM-I-PEI is dominated by silica nanoparticles. These results provide strategies for selecting adsorbed forms of carbon for electrochemical reduction.

Published

2024

41. Nanosafety: a Perspective on Nano‐Bio Interactions

Author

Fadeel, Bengt and Keller, Arturo A

Subjects

Medical Biotechnology, Biomedical and Clinical Sciences, Nanotechnology, Prevention, Bioengineering, Generic health relevance, Affordable and Clean Energy, Good Health and Well Being, bio-corona, eco-corona, nanomaterials, nanosafety, safe-by-design, bio‐corona, eco‐corona, safe‐by‐design, Nanoscience & Nanotechnology

Abstract

Engineered nanomaterials offer numerous benefits to society ranging from environmental remediation to biomedical applications such as drug or vaccine delivery as well as clean and cost-effective energy production and storage, and the promise of a more sustainable way of life. However, as nanomaterials of increasing sophistication enter the market, close attention to potential adverse effects on human health and the environment is needed. Here a critical perspective on nanotoxicological research is provided; the authors argue that it is time to leverage the knowledge regarding the biological interactions of nanomaterials to achieve a more comprehensive understanding of the human health and environmental impacts of these materials. Moreover, it is posited that nanomaterials behave like biological entities and that they should be regulated as such.

Published

2024

42. Mechanism of DNA origami folding elucidated by mesoscopic simulations.

Author

DeLuca, Marcello, Duke, Daniel, Ye, Tao, Poirier, Michael, Ke, Yonggang, Castro, Carlos, and Arya, Gaurav

Subjects

Nanotechnology, Nucleic Acid Conformation, DNA, Nanostructures, Kinetics

Abstract

Many experimental and computational efforts have sought to understand DNA origami folding, but the time and length scales of this process pose significant challenges. Here, we present a mesoscopic model that uses a switchable force field to capture the behavior of single- and double-stranded DNA motifs and transitions between them, allowing us to simulate the folding of DNA origami up to several kilobases in size. Brownian dynamics simulations of small structures reveal a hierarchical folding process involving zipping into a partially folded precursor followed by crystallization into the final structure. We elucidate the effects of various design choices on folding order and kinetics. Larger structures are found to exhibit heterogeneous staple incorporation kinetics and frequent trapping in metastable states, as opposed to more accessible structures which exhibit first-order kinetics and virtually defect-free folding. This model opens an avenue to better understand and design DNA nanostructures for improved yield and folding performance.

Published

2024

43. Reversible Intrapore Redox Cycling of Platinum in Platinum-Ion-Exchanged HZSM‑5 Catalysts

Author

Yalcin, Kaan, Kumar, Ram, Zuidema, Erik, Kulkarni, Ambarish R, Ciston, Jim, Bustillo, Karen C, Ercius, Peter, Katz, Alexander, Gates, Bruce C, Kronawitter, Coleman X, and Runnebaum, Ron C

Subjects

Chemical Sciences, Physical Chemistry, Bioengineering, Nanotechnology, platinum, ZSM-5, encapsulation in zeolite, electron-tomography, hydrogenation, Inorganic Chemistry, Organic Chemistry, Chemical Engineering, Industrial biotechnology, Organic chemistry, Physical chemistry

Abstract

Isolated platinum(II) ions anchored at acid sites in the pores of zeolite HZSM-5, initially introduced by aqueous ion exchange, were reduced to form platinum nanoparticles that are stably dispersed with a narrow size distribution (1.3 ± 0.4 nm in average diameter). The nanoparticles were confined in reservoirs within the porous zeolite particles, as shown by electron beam tomography and the shape-selective catalysis of alkene hydrogenation. When the nanoparticles were oxidatively fragmented in dry air at elevated temperature, platinum returned to its initial in-pore atomically dispersed state with a charge of +2, as shown previously by X-ray absorption spectroscopy. The results determine the conditions under which platinum is retained within the pores of HZSM-5 particles during redox cycles that are characteristic of the reductive conditions of catalyst operation and the oxidative conditions of catalyst regeneration.

Published

2024

44. Continuous-wave GaAs/AlGaAs quantum cascade laser at 5.7 THz

Author

Shahili, Mohammad, Addamane, Sadhvikas J, Kim, Anthony D, Curwen, Christopher A, Kawamura, Jonathan H, and Williams, Benjamin S

Subjects

Quantum Physics, Engineering, Physical Sciences, quantum cascade laser, terahertz, Reststrahlen band, gallium arsenide, nonequilibrium Green's function, nonequilibrium Green’s function, Optical Physics, Electrical and Electronic Engineering, Nanotechnology, Atomic, molecular and optical physics, Quantum physics

Abstract

Design strategies for improving terahertz (THz) quantum cascade lasers (QCLs) in the 5-6 THz range are investigated numerically and experimentally, with the goal of overcoming the degradation in performance that occurs as the laser frequency approaches the Reststrahlen band. Two designs aimed at 5.4 THz were selected: one optimized for lower power dissipation and one optimized for better temperature performance. The active regions exhibited broadband gain, with the strongest modes lasing in the 5.3-5.6 THz range, but with other various modes observed ranging from 4.76 to 6.03 THz. Pulsed and continuous-wave (cw) operation is observed up to temperatures of 117 K and 68 K, respectively. In cw mode, the ridge laser has modes up to 5.71 THz - the highest reported frequency for a THz QCL in cw mode. The waveguide loss associated with the doped contact layers and metallization is identified as a critical limitation to performance above 5 THz.

Published

2024

45. Effect of fabrication processes on BaTiO3 capacitor properties

Author

Jiang, Yizhe, Tian, Zishen, Kavle, Pravin, Pan, Hao, and Martin, Lane W

Subjects

Engineering, Materials Engineering, Physical Sciences, Electrical and Electronic Engineering, Mechanical Engineering, Materials engineering, Nanotechnology, Condensed matter physics

Abstract

There is an increasing desire to utilize complex functional electronic materials such as ferroelectrics in next-generation microelectronics. As new materials are considered or introduced in this capacity, an understanding of how we can process these materials into those devices must be developed. Here, the effect of different fabrication processes on the ferroelectric and related properties of prototypical metal oxide (SrRuO3)/ferroelectric (BaTiO3)/metal oxide (SrRuO3) heterostructures is explored. Two different types of etching processes are studied, namely, wet etching of the top SrRuO3 using a NaIO4 solution and dry etching using an Ar+-ion beam (i.e., ion milling). Polarization-electric-field hysteresis loops for capacitors produced using both methods are compared. For the ion-milling process, it is found that the Ar+ beam can introduce defects into the SrRuO3/BaTiO3/SrRuO3 devices and that the milling depth strongly influences the defect level and can induce a voltage imprint on the function. Realizing that such processing approaches may be necessary, work is performed to ameliorate the imprint of the hysteresis loops via ex situ “healing” of the process-induced defects by annealing the ferroelectric material in a barium-and-oxygen-rich environment via a chemical-vapor-deposition-style process. This work provides a pathway for the nanoscale fabrication of these candidate materials for next-generation memory and logic applications.

Published

2024

46. Unidirectional multipulse helicity-independent all-optical switching in [Ni/Pt] based synthetic ferrimagnets

Author

Sait, Connor RJ, Dąbrowski, Maciej, Scott, Jade N, Hendren, William R, Newman, David G, N'Diaye, Alpha T, Klewe, Christoph, Shafer, Padraic, van der Laan, Gerrit, Keatley, Paul S, Bowman, Robert M, and Hicken, Robert J

Subjects

Physical Sciences, Engineering, Nanotechnology, Chemical sciences, Physical sciences

Abstract

Nickel-platinum-based synthetic ferrimagnets (SFi's) are highly tunable and rare-earth-free materials that allow ultrafast all optical control of magnetism to be explored. This study considers a SFi composed of a ferromagnetic [Ni/Pt] multilayer and a ferromagnetic Co layer, separated by an Ir layer that mediates an antiferromagnetic coupling. Helicity-independent all optical switching (HI-AOS) between two antiparallel magnetization states is observed. AOS may be realized at increased temperature through reduction of the thickness of the Pt layers. Switching is unidirectional and has a strong dependence on the applied magnetic field history, which suggests the possible presence of a nanoscale magnetic texture that may be important in controlling AOS in SFi systems.

Published

2024

47. Mixed Nanosphere Assemblies at a Liquid–Liquid Interface

Author

Fink, Zachary, Wu, Xuefei, Kim, Paul Y, McGlasson, Alex, Abdelsamie, Maged, Emrick, Todd, Sutter‐Fella, Carolin M, Ashby, Paul D, Helms, Brett A, and Russell, Thomas P

Subjects

Engineering, Nanotechnology, Bioengineering, liquid interface, nanoparticle adsorption, phase separation, plasmon resonance, UV-vis reflection spectroscopy, UV–vis reflection spectroscopy, Nanoscience & Nanotechnology

Abstract

The in-plane packing of gold (Au), polystyrene (PS), and silica (SiO2) spherical nanoparticle (NP) mixtures at a water-oil interface is investigated in situ by UV-vis reflection spectroscopy. All NPs are functionalized with carboxylic acid such that they strongly interact with amine-functionalized ligands dissolved in an immiscible oil phase at the fluid interface. This interaction markedly increases the binding energy of these nanoparticle surfactants (NPSs). The separation distance between the Au NPSs and Au surface coverage are measured by the maximum plasmonic wavelength (λmax) and integrated intensities as the assemblies saturate for different concentrations of non-plasmonic (PS/SiO2) NPs. As the PS/SiO2 content increases, the time to reach intimate Au NP contact also increases, resulting from their hindered mobility. λmax changes within the first few minutes of adsorption due to weak attractive inter-NP forces. Additionally, a sharper peak in the reflection spectrum at NP saturation reveals tighter Au NP packing for assemblies with intermediate non-plasmonic NP content. Grazing incidence small angle X-ray scattering (GISAXS) and scanning electron microscopy (SEM) measurements confirm a decrease in Au NP domain size for mixtures with larger non-plasmonic NP content. The results demonstrate a simple means to probe interfacial phase separation behavior using in situ spectroscopy as interfacial structures densify into jammed, phase-separated NP films.

Published

2024

48. Nanometre-resolved observation of electrochemical microenvironment formation at the nanoparticle–ligand interface

Author

Shan, Yu, Zhao, Xiao, Fonseca Guzman, Maria, Jana, Asmita, Chen, Shouping, Yu, Sunmoon, Ng, Ka Chon, Roh, Inwhan, Chen, Hao, Altoe, Virginia, Gilbert Corder, Stephanie N, Bechtel, Hans A, Qian, Jin, Salmeron, Miquel B, and Yang, Peidong

Subjects

Macromolecular and Materials Chemistry, Chemical Sciences, Bioengineering, Nanotechnology, Inorganic chemistry, Physical chemistry, Chemical engineering

Abstract

The dynamic response of surface ligands on nanoparticles (NPs) to external stimuli critically determines the functionality of NP–ligand systems. For example, in electrocatalysis the collective dissociation of ligands on NP surfaces can lead to the creation of an NP/ordered-ligand interlayer, a microenvironment that is highly active and selective for CO2-to-CO conversion. However, the lack of in situ characterization techniques with high spatial resolution hampers a comprehensive molecular-level understanding of the mechanism of interlayer formation. Here we utilize in situ infrared nanospectroscopy and surface-enhanced Raman spectroscopy, unveiling an electrochemical bias-induced consecutive bond cleavage mechanism of surface ligands leading to formation of the NP/ordered-ligand interlayer. This real-time molecular insight could influence the design of confined localized fields in multiple catalytic systems. Moreover, the demonstrated capability of capturing nanometre-resolved, dynamic molecular-scale events holds promise for the advancement of using controlled local molecular behaviour to achieve desired functionalities across multiple research domains in nanoscience. (Figure presented.).

Published

2024

49. Unraveling the Highly Plastic Behavior of ALD‐Aluminum Oxide Encapsulations by Small‐Scale Tensile Testing

Author

Vogl, Lilian M, Schweizer, Peter, Minor, Andrew M, Michler, Johann, and Utke, Ivo

Subjects

Engineering, Materials Engineering, Nanotechnology, ALD, characterization, EELS, in situ electron microscopy, metal oxides, nanowires, TEM, Materials, Civil engineering, Materials engineering, Mechanical engineering

Abstract

We present a study directly measuring the electron‐beam‐induced plasticity of amorphous Al2O3 coatings. Core–shell nanostructures are employed as small‐scale model systems for two‐dimensional coatings made by atomic layer deposition (ALD). Copper nanowires (NWs) are used as substrates for ALD deposition, representing a model system for interconnects commonly found in integrated circuits. Experiments are performed in situ in a transmission electron microscope (TEM) and further analyzed with electron energy loss spectroscopy (EELS). Our in situ TEM tensile experiments reveal the highly plastic behavior of the ALD shell, which withstands a maximum strain of 188%. Comparable samples under beam‐off conditions show a brittle fracture, which underlines the effect of electron irradiation. The electron‐beam‐activated bond switching within the amorphous network enables compensation of the applied tensile strain, leading to viscous flow. By incorporating an intermediate nanocrystalline layer within the Al2O3 shell, the plasticity is suppressed and brittle fracture occurs. This work directly demonstrates the tuning of mechanical properties in amorphous ALD structures through electron irradiation.

Published

2024

50. Probing chromatin accessibility with small molecule DNA intercalation and nanopore sequencing

Author

Bai, Gali, Dhillon, Namrita, Felton, Colette, Meissner, Brett, Saint-John, Brandon, Shelansky, Robert, Meyerson, Elliot, Hrabeta-Robinson, Eva, Hodjat, Babak, Boeger, Hinrich, and Brooks, Angela N

Subjects

Biological Sciences, Bioinformatics and Computational Biology, Genetics, Human Genome, Bioengineering, Nanotechnology, Underpinning research, 1.1 Normal biological development and functioning, Generic health relevance

Abstract

Genome-wide identification of chromatin organization and structure has been generally probed by measuring accessibility of the underlying DNA to nucleases or methyltransferases. These methods either only observe the positioning of a single nucleosome or rely on large enzymes to modify or cleave the DNA. We developed adduct sequencing (Add-seq), a method to probe chromatin accessibility by treating chromatin with the small molecule angelicin, which preferentially intercalates into DNA not bound to core nucleosomes. We show that Nanopore sequencing of the angelicin-modified DNA is possible and allows visualization and analysis of long single molecules with distinct chromatin structure. The angelicin modification can be detected from the Nanopore current signal data using a neural network model trained on unmodified and modified chromatin-free DNA. Applying Add-seq to Saccharomyces cerevisiae nuclei, we identified expected patterns of accessibility around annotated gene loci in yeast. We also identify individual clusters of single molecule reads displaying different chromatin structure at specific yeast loci, which demonstrates heterogeneity in the chromatin structure of the yeast population. Thus, using Add-seq, we are able to profile DNA accessibility in the yeast genome across long molecules.

Published

2024