Methods for detecting, identifying, and/or quantifying a target molecule in a complex fluid using thermal analysis are disclosed. Exemplary complex fluids include biofluids and environmental fluids. Exemplary target molecules include proteins, peptides, nucleic acids, lipids, carbohydrates, viruses, and combinations thereof. A method for using thermal analysis to determine whether purification affects one or more characteristics, such as binding characteristics, of a target molecule is also disclosed.

A differential scanning calorimetry sensor, comprises a substrate; a heater trace comprising a conductive material, on the substrate; an encapsulation layer, on the substrate and on the heater trace; and a sample heating area, which is on the heater trace. The heater trace has a thickness of 50 to 1000 nm, a width of 1 to 100 pm, and a path length of 5 to 500 mm. Also described are a sample holder, a sensor enclosure and a thermal analysis sensor system.

A subsurface monitoring system and method is provided for measuring a rate of change in an amount of a reactive material within a subsurface formation using measurements of thermal parameters at one or more positions within the subsurface without the need for background correction which may lead erroneous calculations and require additional monitoring equipment. The measured thermal parameters may be used to determine the heat generated by the degradation of the reactive material. The method may include measuring a first temperature near the surface of a subsurface region and a second temperature further from the surface. In some instances, an estimated location of a planar subsurface heat source/sink due to exothermic degradation reactions within the subsurface may be selected. With the derived thermal parameters and the estimated location of the subsurface heat source/sink, change rates for the reactive materials in the subsurface region may be determined or estimated.

Described is a differential scanning calorimeter (DSC) instrument capable of performing analyses of multiple samples at the same time. Some embodiments of DSC instruments described herein include a thermal substrate that provides a substantially uniform temperature across a surface of the substrate. A plurality of DSC units is in thermal communication with the substrate, for example, by mounting the units directly to the surface of the substrate. Each DSC unit includes a second thermal substrate for further thermal isolation, and a reference platform and sample platform to receive a reference cell and a sample cell, respectively. A thermoelectric device is disposed between each platform and the second thermal substrate. Optionally, the reference and sample cells may be disposable chips that can be discarded after measurement are performed, thereby reducing or eliminating the need to clean instrument components to prevent cross-contamination for subsequent instrument operation.

The present invention is directed to devices and methods for monitoring the purity of monomers, adjusting the polymerization conditions, and consequently improving a polymerization reaction process. In one method, monomer purity is estimated using an on-line evaluation by raising the temperature of the monomer formulation having a defined melting point to a first elevated temperature at least 20° C. above a preset melting point for a selected monomer formulation; cooling the monomer formulation at a controlled cooling rate in the range from about 0.5 to 50° C. per minute; measuring at least one critical property selected from the group consisting of a) crystallization peak temperature at the onset of crystallization, b) an area under the crystallization peak, which represents the heat or enthalpy of crystallization, ΔHc and combinations thereof, comparing the at least one of the selected critical properties measures relative to such properties for standard setting monomer formulations.

Described is a zone box for a differential scanning calorimeter. The zone box includes sheets of thermocouple alloy disposed between thermally conductive electrical insulator layers. A thermocouple alloy wire is electrically coupled to each one of the thermocouple alloy sheets. In addition, a pure metal wire is electrically coupled to each one of the thermocouple alloy sheets to enable remote measurement of voltage differences between the different thermocouple alloy sheets. The high thermal conductivity of the electrical insulator layers substantially reduces any thermal gradients across the sheets and maintains the connections of the thermocouple alloy wires and pure metal wires to the sheets to be at substantially the same temperature. The zone box reduces temperature difference measurement errors that result from inhomogeneity in the thermocouple alloy wires and variable temperature distributions along the length of the wires.

A method for characterizing a melting transition in a semicrystalline polymer is disclosed. The method includes incorporating a fluorophore into the semicrystalline polymer, changing a temperature of the semicrystalline polymer to vary across a range of temperatures comprising a plurality of temperatures, and capturing an emission spectrum of the incorporated fluorophore at each temperature of the plurality of temperatures. The method also includes integrating each emission spectrum to determine a temperature-dependent integrated fluorescence intensity for the semicrystalline polymer, numerically differentiating the temperature-dependent integrated fluorescence intensity, and characterizing the melting transition of the semicrystalline polymer by identifying a stepwise change in value of the differentiated intensity. The semicrystalline polymer may be a thermoplastic. Incorporating the fluorophore into the semicrystalline polymer may include physically doping the semicrystalline polymer with the fluorophore or covalently labeling the semicrystalline polymer with the fluorophore.

A pressure-sensitive adhesive is provided that is a dried product of a latex composition, which is formed from an emulsion composition. The latex composition and the emulsion composition are also provided. The emulsion composition has droplets that contain various monomers plus a (meth)acrylate polymer dissolved in the monomers. Additionally, an article containing Ca layer of the pressure-sensitive adhesive and a method of forming the pressure-sensitive adhesive are provided. The pressure-sensitive adhesives often have both high peel adhesion and high shear strength (i.e., high cohesive strength or high shear holding power).

A battery includes: a positive electrode; a negative electrode; and an electrolyte. At least one of the electrolyte and the negative electrode contains an aluminum hydroxide, at least a part of a surface of the aluminum hydroxide being modified.

The present application provides vanadium dioxide doped with Ti, or vanadium dioxide further doped with other atoms selected from the group of W, Ta, Mo, and Nb. The vanadium dioxide of the present application is excellent in moisture resistance and in which deterioration of endothermic characteristics due to moisture is suppressed.