Abstract: According to some embodiments, system and methods are provided comprising providing an energy storage device including two or more energy storage elements; initiating execution of an energy storage capacity module operative to test a capacity of a first energy storage element; removing the storage element from service, while maintaining service of the energy storage device; measuring a capacity of the removed storage element; receiving the measured capacity at a lifing model; executing the lifing model to generate an output; and manipulating operation of the energy storage device based on the generated output. Numerous other aspects are provided.

Abstract: A system and method generate a trip plan for a trip of a vehicle system along a route. The usage of an engine during the trip is determined based on engine operational parameters, energy storage device operational parameters, and one or more objectives of the trip desired to be achieved. The usage of the energy storage device during the trip is also determined based on the engine operational parameters, the energy storage device operational parameters, and the one or more objective, including when to charge or discharge the energy storage device during the trip.

Abstract: The present disclosure relates to characterization of biological samples by amplification detection in a porous substrate. By way of example, a porous substrate may include amplification reagents configured to provide a signal when released during amplification. When a sample is applied, amplification occurs as a wavefront from the application point, and the time that the wavefront reaches a distance on the porous substrate is related to an initial concentration of the sample applied. By detecting the distance traveled by the amplification products at one or more time points, an initial concentration of the sample may be estimated.

Abstract: A system is provided for separating particulates dispersed within a base fluid wherein at least one of the particulates and the base fluid is an organic liquid. The system relies on a microfluidic separation device comprising a microchannel in fluid communication across a microporous body with a collection chamber. Particulates and a portion of the base fluid traverse the microporous body under the influence of an external force field and are collected in the collection chamber. A first fluid flow having a first flow rate through the microchannel together with the microporous body operationally generate a second fluid flow within the collection chamber as base fluid and particulates traverse the microporous body and enter the collection chamber, and as base fluid re-traverses the microporous body and re-enters the microchannel, the second fluid flow having a flow rate which is a fraction of the first flow rate.

Abstract: A system is provided for separating particulates dispersed within a base fluid wherein at least one of the particulates and the base fluid is an organic liquid. The system relies on a microfluidic separation device comprising a microchannel in fluid communication across a microporous body with a collection chamber. Particulates and a portion of the base fluid traverse the microporous body under the influence of an external force field and are collected in the collection chamber. A first fluid flow having a first flow rate through the microchannel together with the microporous body operationally generate a second fluid flow within the collection chamber as base fluid and particulates traverse the microporous body and enter the collection chamber, and as base fluid re-traverses the microporous body and re-enters the microchannel, the second fluid flow having a flow rate which is a fraction of the first flow rate.

Abstract: The present disclosure relates to characterization of biological samples by amplification detection in a porous substrate. By way of example, a porous substrate may include amplification reagents configured to provide a signal when released during amplification. When a sample is applied, amplification occurs as a wavefront from the application point, and the time that the wavefront reaches a distance on the porous substrate is related to an initial concentration of the sample applied. By detecting the distance traveled by the amplification products at one or more time points, an initial concentration of the sample may be estimated.

Abstract: The present invention relates to compositions and methods for achieving the efficient allylic oxidation of organic molecules, especially olefins and steroids, under aqueous conditions. The invention concerns the use of dirhodium (II,II) “paddlewheel complexes, and in particular, dirhodium carboximate and tert-butyl hydroperoxide as catalysts for the reaction. The use of aqueous conditions is particularly advantageous in the allylic oxidation of 7-keto steroids, which could not be effectively oxidized using anhydrous methods, and in extending allylic oxidation to enamides and enol ethers.

Abstract: The present invention relates to compositions and methods for achieving the efficient allylic oxidation of organic molecules, especially olefins and steroids, under aqueous conditions. The invention concerns the use of dirhodium (II,II) “paddlewheel complexes, and in particular, dirhodium carboximate and tert-butyl hydroperoxide as catalysts for the reaction. The use of aqueous conditions is particularly advantageous in the allylic oxidation of 7-keto steroids, which could not be effectively oxidized using anhydrous methods, and in extending allylic oxidation to enamides and enol ethers.