Provided is a simulation model sample for evaluation of heat treatment including a porous water absorbing material that is flexible and deformable; and a container that is configured to be able to contain the porous water absorbing material having water absorbed therein. Also provided is a method for evaluating heat treatment using a simulation model sample including a step of allowing a flexible and deformable porous water absorbing material to absorb water, and the porous water absorbing material to be contained in a container, to produce a simulation model sample; and a step of subjecting the simulation model sample to heat treatment, while measuring a temperature inside the simulation model sample.

Embodiments in accordance with the present disclosure are directed to methods and apparatuses used for extracting heavy rare gas. An example method includes passing inlet air through an airflow path of an apparatus, removing carbon dioxide and gaseous water from the inlet air, and cooling the inlet air to a threshold temperature while passing along the airflow path. The method further includes passing the cooled inlet air through an adsorption chamber of the apparatus to adsorb heavy rare gas from the cooled inlet air while the cooled inlet air is in a gaseous state, and extracting the heavy rare gas from the adsorption chamber.

Provided is a simulation model sample for evaluation of heat treatment including a porous water absorbing material that is flexible and deformable; and a container that is configured to be able to contain the porous water absorbing material having water absorbed therein. Also provided is a method for evaluating heat treatment using a simulation model sample including a step of allowing a flexible and deformable porous water absorbing material to absorb water, and the porous water absorbing material to be contained in a container, to produce a simulation model sample; and a step of subjecting the simulation model sample to heat treatment, while measuring a temperature inside the simulation model sample.

Provided is a simulation model sample for evaluation of heat treatment including a porous water absorbing material that is flexible and deformable; and a container that is configured to be able to contain the porous water absorbing material having water absorbed therein. Also provided is a method for evaluating heat treatment using a simulation model sample including a step of allowing a flexible and deformable porous water absorbing material to absorb water, and the porous water absorbing material to be contained in a container, to produce a simulation model sample; and a step of subjecting the simulation model sample to heat treatment, while measuring a temperature inside the simulation model sample.

Modified thermoplastic hydrocarbon thermoplastic resins are provided, as well as methods of their manufacture and uses thereof in rubber compositions. The modified thermoplastic resins are modified by decreasing the relative quantity of the dimer, trimer, tetramer, and pentamer oligomers as compared to the corresponding unmodified thermoplastic resin polymers, resulting in a product that exhibits a greater shift in the glass transition temperature of the elastomer(s) used in tire formulations. This translates to better viscoelastic predictors of tire tread performance, such as wet grip and rolling resistance. The modified thermoplastic resins impart remarkable properties on various rubber compositions, such as tires, belts, hoses, brakes, and the like. Automobile tires incorporating the modified thermoplastic resins are shown to possess excellent results in balancing the properties of rolling resistance, tire wear, snow performance, and wet braking performance.

A method for calorimetry includes providing a sample to a test chamber and applying heat to the test chamber with the sample provided therein, the heat being applied at a known heat rate. In a synchronized manner with respect to applying heat to the test chamber, transmission of light through plural Nano Hole Array (NHA) sensors coupled to the test chamber is measured to obtain a series of extraordinary optical transmission (EOT) measurements. A calorimetry measurement is calculated as a function of the heat rate and the series of EOT measurements, the calorimetry measurement being indicative of energy released as a result of the sample undergoing a change during the application of heat to the test chamber. Samples, including fluids and solids, can be transferred into the test chamber by a pump or other suitable means. Example test chambers include a microchannel injection cell and a co-flow reactor microchannel.

A sample holder for a system for analyzing energetic materials, including a first holder element having a first heating element, the heating element embodied as a resistance heater and having at least one first sample region provided for accommodating a sample. A second holder element having a second heating element, the heating element embodied as a resistance heater and having at least one second sample region provided for being brought into contact with a sample. A device for connecting the holder elements so as to enclose a sample between the first sample region and the second sample region.

The present disclosure provides devices and methods for diagnosing, monitoring the disease progression of, and/or evaluating the risk for developing a disease by detecting thermostable variants of proteins and/or metabolites in biological samples using differential scanning calorimetry. Also disclosed herein are methods for monitoring the efficacy of a particular therapeutic regimen in patients in need thereof.

Many construction materials are chemically active materials whose structural properties parameters, physical-mechanical properties, etc. need to be determined. By exploiting embedded wireless sensors within these materials from initial wet manufactured state to final solid capillary-porous material assessment of initial and subsequent properties can be established allowing determination of current and future performance of the construction material. Embedded sensors can also monitor lifetime properties to identify performance degradations in the construction material as well as other construction elements embedded within or around the construction material. Further, the data accumulated from initial manufacturing to extended lifetime allows for additional assessments and improvements with respect to selection of construction material mix for a particular project at a particular location and time, improving the assessment of proactive repair and/or remedial work, quality control monitoring, cost reduction etc.

Devices for ligand capture and methods of using the device are disclosed. The ligand may be captured from a sample, such as a plasma sample. Methods of identifying, quantifying, and/or characterizing captured ligands also are disclosed. Computer systems and methods for analyzing thermograms and determining the characteristics of ligands present in a sample are disclosed.