Abstract: A method of producing a composite product is provided. The method includes providing a fluidized bed of metal oxide particles in a fluidized bed reactor, providing a catalyst or catalyst precursor in the fluidized bed reactor, providing a carbon source in the fluidized bed reactor for growing carbon nanotubes, growing carbon nanotubes in a carbon nanotube growth zone of the fluidized bed reactor, and collecting a composite product comprising metal oxide particles and carbon nanotubes.

Abstract: Aspects of the present disclosure generally relate to battery technology, and more specifically relate to current collectors and uses thereof. In an aspect, a current collector is provided. The current collector includes a first component comprising a carbon nanotube; and a second component comprising a boron-nitride nanotube, wherein the first component is coupled to the second component. In another aspect, a battery of the present disclosure includes an electrode; and a current collector disposed over at least a portion of the electrode, the current collector comprising: a first fiber comprising a carbon nanotube, a boron-nitride nanotube, or a combination thereof; and a second fiber comprising a carbon nanotube, a boron-nitride nanotube, or a combination thereof, wherein an amount of boron-nitride nanotube in the current collector is about 20 wt % or more based on a total weight of the carbon nanotube and the boron-nitride nanotube in the current collector.

Abstract: Articles and devices comprising a multifunctional conductive wire having a first electrode including a first carbon nanotube composite yarn containing carbon nanotubes and secondary particles; a second electrode including a second carbon nanotube composite yarn containing carbon nanotubes and secondary particles; a first separator membrane surrounding the first electrode; a second separator membrane surrounding the second electrode; an electrolyte surrounding the first and second electrodes; a flexible insulator layer surrounding the electrolyte; and a flexible conducting layer at least partially surrounding the flexible insulator layer. Also provided are method of making and using the articles, devices, and multifunctional conductive wires herein.

Abstract: Methods of making single walled carbon nanotubes (SWNTs) including a single step for preparing a homogeneous dispersion of SWNTs in a battery electrode powder. The method may comprise providing a reactor in fluid communication with a mixer, wherein an aerosol containing SWNTs is transmitted from the reactor directly to the mixer containing a battery electrode powder.

Abstract: Aspects of the present disclosure generally relate to catalyst compositions including metal chalcogenides, processes for producing such catalyst compositions, processes for enhancing catalytic active sites in such catalyst compositions, and uses of such catalyst compositions in, e.g., processes for producing conversion products. In an aspect, a process for forming a catalyst composition is provided. The process includes introducing an electrolyte material and an amphiphile material to a metal chalcogenide to form the catalyst composition. In another aspect, a catalyst composition is provided. The catalyst composition includes a metal chalcogenide, an electrolyte material, and an amphiphile material. Devices for hydrogen evolution reaction are also provided.

Abstract: The present disclosure generally relates to compositions and devices for, e.g., hosting qubits, and processes of use. In an embodiment, a quantum device is provided. The quantum device includes a composition, the composition comprising a first component comprising a nanotube and a second component comprising a compound, the compound comprising a metal-bound cyclic tetrapyrrole, an ion thereof, or a combination thereof. In another embodiment, a process for controlling a quantum spin is provided. The process includes cooling a composition described herein to a temperature of about 1 K or more, applying a voltage to the composition, introducing a magnetic field to the composition, and introducing microwave radiation to the composition.

Abstract: A method for generating hydrogen including contacting a catalyst with a proton source, the catalyst having a catalytic component with a first surface comprising a plurality of catalytic sites and a carbon component provided as a layer on the first surface, wherein the carbon component comprises a plurality of pores. Also provided are catalysts for catalyzing the hydrogen evolution reaction and methods of making the same.

Abstract: The present disclosure is directed to methods of securing battery tab structures to binderless, collectorless self-standing electrodes, comprising electrode active material and carbon nanotubes and no foil-based collector, and the resulting battery-tab secured electrodes. Such methods and the resulting battery tab-secured electrodes may facilitate the use of such composites in battery and power applications.

Abstract: The present disclosure generally relates to apparatus and processes for wirelessly monitoring the structural health of an energy storage device, and more specifically to energy storage devices with wireless operando monitoring and processes of use. In an aspect, an apparatus for wireless monitoring of an energy storage device is provided. The apparatus includes an energy storage device comprising an electrode, the electrode comprising a nanotube network; a radio-frequency identification (RFID) system comprising: a RFID tag comprising a conductive material, the RFID tag attached to, or embedded within, the electrode; and a RFID reader external to the energy storage device. The apparatus further includes a processor configured to determine a first value of current of the electrode of the energy storage device based on an induced magnetic field acting on the conductive material, and compare the first value of current to a threshold value or range.

Abstract: The present disclosure generally relates to apparatus and processes for monitoring the structural health of an energy storage device, and more specifically to energy storage devices with operando monitoring and processes of use. In an aspect, an apparatus is provided that includes an energy storage device comprising an electrode, the electrode comprising a nanotube network and an active material. The apparatus further includes a processor configured to determine a first value of potential change of the electrode of the energy storage device and to compare the first value of potential change to a threshold value or range.

Abstract: Aspects of the present disclosure generally relate to catalyst compositions including metal chalcogenides, processes for producing such catalyst compositions, processes for enhancing catalytic active sites in such catalyst compositions, and uses of such catalyst compositions in, e.g., processes for producing conversion products. In an aspect, a process for forming a catalyst composition is provided. The process includes introducing an electrolyte material and an amphiphile material to a metal chalcogenide to form the catalyst composition. In another aspect, a catalyst composition is provided. The catalyst composition includes a metal chalcogenide, an electrolyte material, and an amphiphile material. Devices for hydrogen evolution reaction are also provided.

Abstract: The present disclosure is directed to a method and apparatus for continuous production of composites of carbon nanotubes and electrode active material from decoupled sources. Composites thusly produced may be used as self-standing electrodes without binder or collector. Moreover, the method of the present disclosure may allow more cost-efficient production while simultaneously affording control over nanotube loading and composite thickness.

Abstract: Aspects of the present disclosure generally relate to catalyst compositions, processes for producing such catalyst compositions, and uses of such catalyst compositions. In an embodiment, a composition is provided. The composition includes an electrolyte material or an ion thereof, an amphiphile material or an ion thereof, and a metal component, the metal component comprising an alloy having the formula (M1)a(M2)b, wherein M1 is a Group 10-11 metal of the periodic table of the elements, M2 is a first Group 8-11 metal of the periodic table of the elements, M1 and M2 are different, and a and b are positive numbers. In another embodiment, a device is provided that includes an electrolyte material or ion thereof, an amphiphile material or ion thereof, and a metal component disposed on an electrode, the metal component comprising a bimetallic nanoframe, a trimetallic nanoframe, or a combination thereof.

Abstract: The present disclosure generally relates to bilayer metal dichalcogenides, to processes for forming bilayer metal dichalcogenides, and to uses of bilayer metal dichalcogenides in devices for quantum electronics. In an aspect, a device is provided. The device includes a gate electrode, a substrate disposed over at least a portion of the gate electrode, and a bottom layer including a first metal dichalcogenide, the bottom layer disposed over at least a portion of the substrate. The device further includes a top layer including a second metal dichalcogenide, the top layer disposed over at least a portion of the bottom layer, the first metal dichalcogenide and the second metal dichalcogenide being the same or different. The device further includes a source electrode and a drain electrode disposed over at least a portion of the top layer.

Abstract: The present disclosure is directed to methods and embedding battery tab attachment structures within composites of electrode active materials and carbon nanotubes, which lack binder and lack collector foils, and the resulting self-standing electrodes. Such methods and the resulting self-standing electrodes may facilitate the use of such composites in battery and power applications.

Abstract: Aspects of the present disclosure generally relate to catalyst compositions including metal chalcogenides, processes for producing such catalyst compositions, processes for enhancing catalytic active sites in such catalyst compositions, and uses of such catalyst compositions in, e.g., processes for producing conversion products. In an aspect, a process for forming a catalyst composition is provided. The process includes introducing an electrolyte material and an amphiphile material to a metal chalcogenide to form the catalyst composition. In another aspect, a catalyst composition is provided. The catalyst composition includes a metal chalcogenide, an electrolyte material, and an amphiphile material. Devices for hydrogen evolution reaction are also provided.

Abstract: Aspects of the present disclosure generally relate to electronic textiles and more specifically to self-sustaining, interactive electronic textiles, to systems incorporating such electronic textiles, and to uses thereof. In an embodiment, a system to assist with an intended motion of a user is provided. The system includes one or more processors, and an electronic textile. The electronic textile includes a textile substrate, an actuator coupled to the textile substrate, a sensor coupled to the textile substrate, and a battery coupled to the textile substrate, the battery electrically coupled to a conductive yarn, the conductive yarn further electrically coupled to the actuator and the sensor. Embodiments also include a system to assist with blood circulation of a user and a method of assisting blood circulation of a user.

Abstract: A method of producing a composite product is provided. The method includes providing a fluidized bed of carbon-based particles in a fluidized bed reactor, providing a catalyst or catalyst precursor in the fluidized bed reactor, providing a carbon source in the fluidized bed reactor for growing carbon nanotubes, growing carbon nanotubes in a carbon nanotube growth zone of the fluidized bed reactor, and collecting a composite product comprising carbon-based particles and carbon nanotubes.

Abstract: The present disclosure is directed to multifunctional conductive wire and methods of making multifunctional conductive wire. According to some aspects, the multifunctional conductive wire disclosed herein can function as a current carrier and as a battery, either for providing or storing power. The multifunctional conductive wires disclosed herein can eliminate the need for heavy metal conductors in various devices while improving power efficiency.

Abstract: A method of making a carbon nanotube composite yarn, the method including growing floating carbon nanotubes in a reactor, forming a mat of carbon nanotubes from the floating carbon nanotubes, a deposition step including depositing secondary particles on at least a portion of the mat of carbon nanotubes to provide a carbon nanotube composite mat, and a densification step including densifying the carbon nanotube composite mat to provide a carbon nanotube composite yarn.