Abstract: Aspects of the present disclosure generally relate to systems and methods for accessing, managing, and exchanging patient information across a plurality of providers that may have various discrete medical record systems, including, but not limited to medical facilities, clinics, ambulatory emergency health systems, and other providers (e.g., heterogeneous healthcare providers). In various embodiments, the system receives a request from a requesting party for one or more records of a particular patient. In response, in one or more embodiments, the system identifies what information (if any) the requester is authorized to receive, retrieves the information the requester is authorized to receive from various discrete medical record systems, then normalizes and aggregates the retrieved information. In a particular embodiment, the system also denormalizes the data (e.g., converts the data to the local format and terms of the requester) before transmitting the retrieved data to the requester.

Abstract: The present disclosure relates to electric double layer capacitors (EDLCs) that include an alkylating or arylating agent additive capable of scavenging nucleophilic species generated during operation of the EDLC. The additives for the electric double layer capacitors (EDLCs) including an alkylating or arylating agent are described herein. The alkylating or arylating reagent comprises a compound of the formula I: R—X??(I) wherein R and X are described herein.

Abstract: Electric double layer capacitors (EDLCs) including an alkylating or arylating agent are described herein. The alkylating or arylating reagent comprises a compound of the formula I: R—X??(I) wherein R and X are described herein.

Abstract: Electrochemical devices which incorporate cathode materials that include layered crystalline compounds for which a structural modification has been achieved which increases the diffusion rate of multi-valent ions into and out of the cathode materials. Examples in which the layer spacing of the layered electrode materials is modified to have a specific spacing range such that the spacing is optimal for diffusion of magnesium ions are presented. An electrochemical cell comprised of a positive intercalation electrode, a negative metal electrode, and a separator impregnated with a nonaqueous electrolyte solution containing multi-valent ions and arranged between the positive electrode and the negative electrode active material is described.

Abstract: A rechargable magnesium battery having an non-aqueous electrolyte is provided. The properties of the electrolyte include high conductivity, high Coulombic efficiency, and an electrochemical window that can exceed 3.5 V vs. Mg/Mg+2. The use of the electrolyte promotes the electrochemical deposition and dissolution of Mg without the use of any Grignard reagents, other organometallic materials, tetraphenyl borate, or tetrachloroaluminate derived anions. Other Mg-containing electrolyte systems that are expected to be suitable for use in secondary batteries are also described.

Abstract: Aspects of the present disclosure generally relate to systems and methods for accessing, managing, and exchanging patient information across a plurality of providers that may have various discrete medical record systems, including, but not limited to medical facilities, clinics, ambulatory emergency health systems, and other providers (e.g., heterogeneous healthcare providers). In various embodiments, the system receives a request from a requesting party for one or more records of a particular patient. In response, in one or more embodiments, the system identifies what information (if any) the requester is authorized to receive, retrieves the information the requester is authorized to receive from various discrete medical record systems, then normalizes and aggregates the retrieved information. In a particular embodiment, the system also denormalizes the data (e.g., converts the data to the local format and terms of the requester) before transmitting the retrieved data to the requester.

Abstract: Aspects of the present disclosure generally relate to systems and methods for accessing, managing, and exchanging patient information across a plurality of providers that may have various discrete medical record systems, including, but not limited to medical facilities, clinics, ambulatory emergency health systems, and other providers (e.g., heterogeneous healthcare providers). In various embodiments, the system receives a request from a requesting party for one or more records of a particular patient. In response, in one or more embodiments, the system identifies what information (if any) the requester is authorized to receive, retrieves the information the requester is authorized to receive from various discrete medical record systems, then normalizes and aggregates the retrieved information. In a particular embodiment, the system also denormalizes the data (e.g., converts the data to the local format and terms of the requester) before transmitting the retrieved data to the requester.

Abstract: Aspects of the present disclosure generally relate to systems and methods for accessing, managing, and exchanging patient information across a plurality of providers that may have various discrete medical record systems, including, but not limited to medical facilities, clinics, ambulatory emergency health systems, and other providers (e.g., heterogeneous healthcare providers). In various embodiments, the system receives a request from a requesting party for one or more records of a particular patient. In response, in one or more embodiments, the system identifies what information (if any) the requester is authorized to receive, retrieves the information the requester is authorized to receive from various discrete medical record systems, then normalizes and aggregates the retrieved information. In a particular embodiment, the system also denormalizes the data (e.g., converts the data to the local format and terms of the requester) before transmitting the retrieved data to the requester.

Abstract: Electrochemical devices which incorporate cathode materials that include layered crystalline compounds for which a structural modification has been achieved which increases the diffusion rate of multi-valent ions into and out of the cathode materials. Examples in which the layer spacing of the layered electrode materials is modified to have a specific spacing range such that the spacing is optimal for diffusion of magnesium ions are presented. An electrochemical cell comprised of a positive intercalation electrode, a negative metal electrode, and a separator impregnated with a nonaqueous electrolyte solution containing multi-valent ions and arranged between the positive electrode and the negative electrode active material is described.

Abstract: Electrochemical devices which incorporate cathode materials that include layered crystalline compounds for which a structural modification has been achieved which increases the diffusion rate of multi-valent ions into and out of the cathode materials. Examples in which the layer spacing of the layered electrode materials is modified to have a specific spacing range such that the spacing is optimal for diffusion of magnesium ions are presented. An electrochemical cell comprised of a positive intercalation electrode, a negative metal electrode, and a separator impregnated with a nonaqeuous electrolyte solution containing multi-valent ions and arranged between the positive electrode and the negative electrode active material is described.

Abstract: An electrolyte for use in electrochemical cells is provided. The properties of the electrolyte include high conductivity, high Coulombic efficiency, and an electrochemical window that can exceed 3.5 V vs. Mg/Mg+2. The use of the electrolyte promotes the electrochemical deposition and dissolution of Mg without the use of any Grignard reagents, other organometallic materials, tetraphenyl borate, or tetrachloroaluminate derived anions. Other Mg-containing electrolyte systems that are expected to be suitable for use in secondary batteries are also described.

Abstract: A system and method for tracking trending topics on social media (e.g., Twitter) associated with a particular event and identifying relevant images or videos that are associated with the trending topic. For example, the system may monitor Twitter feeds associated with a particular sports event and analyze content posted in those feeds. Comments about a particular play made during the sports event (e.g., a touchdown) are detected by the system in the monitored feed content and used to locate and retrieve photos or videos associated with that particular play for display on a website or other content portal.

Abstract: The present invention generally relates to lithium based energy storage devices. According to the present invention there is provided a lithium energy storage device comprising: at least one positive electrode; at least one negative electrode; and an ionic liquid electrolyte comprising an anion, a cation counterion and lithium mobile ions, wherein the anion comprises a nitrogen, boron, phosphorous, arsenic or carbon anionic group having at least one nitrile group coordinated to the nitrogen, boron, phosphorous, arsenic or carbon atom of the anionic group.

Abstract: Electrochemical devices which incorporate cathode materials that include layered crystalline compounds for which a structural modification has been achieved which increases the diffusion rate of multi-valent ions into and out of the cathode materials. Examples in which the layer spacing of the layered electrode materials is modified to have a specific spacing range such that the spacing is optimal for diffusion of magnesium ions are presented. An electrochemical cell comprised of a positive intercalation electrode, a negative metal electrode, and a separator impregnated with a nonaqueous electrolyte solution containing multi-valent ions and arranged between the positive electrode and the negative electrode active material is described.

Abstract: An electrolyte for use in electrochemical cells is provided. The properties of the electrolyte include high conductivity, high Coulombic efficiency, and an electrochemical window that can exceed 3.5 V vs. Mg/Mg+2. The use of the electrolyte promotes the electrochemical deposition and dissolution of Mg without the use of any Grignard reagents, other organometallic materials, tetraphenyl borate, or tetrachloroaluminate derived anions. Other Mg-containing electrolyte systems that are expected to be suitable for use in secondary batteries are also described.

Abstract: Electrochemical devices which incorporate cathode materials that include layered crystalline compounds for which a structural modification has been achieved which increases the diffusion rate of multi-valent ions into and out of the cathode materials. Examples in which the layer spacing of the layered electrode materials is modified to have a specific spacing range such that the spacing is optimal for diffusion of magnesium ions are presented. An electrochemical cell comprised of a positive intercalation electrode, a negative metal electrode, and a separator impregnated with a nonaqueous electrolyte solution containing multi-valent ions and arranged between the positive electrode and the negative electrode active material is described.

Abstract: Electrochemical devices which incorporate cathode materials that include layered crystalline compounds for which a structural modification has been achieved which increases the diffusion rate of multi-valent ions into and out of the cathode materials. Examples in which the layer spacing of the layered electrode materials is modified to have a specific spacing range such that the spacing is optimal for diffusion of magnesium ions are presented. An electrochemical cell comprised of a positive intercalation electrode, a negative metal electrode, and a separator impregnated with a nonaqeuous electrolyte solution containing multi-valent ions and arranged between the positive electrode and the negative electrode active material is described.

Abstract: A electrochemical cell having an non-aqueous electrolyte is provided. The properties of the electrolyte include high conductivity, high Coulombic efficiency, and an electrochemical window that can exceed 3.5 V vs. Mg/Mg+2. The use of the electrolyte promotes the electrochemical deposition and dissolution of Mg without the use of any Grignard reagents, other organometallic materials, tetraphenyl borate, or tetrachloroaluminate derived anions. Other Mg-containing electrolyte systems that are expected to be suitable for use in secondary batteries are also described.

Abstract: A rechargable magnesium battery having an non-aqueous electrolyte is provided. The properties of the electrolyte include high conductivity, high Coulombic efficiency, and an electrochemical window that can exceed 3.5 V vs. Mg/Mg+2. The use of the electrolyte promotes the electrochemical deposition and dissolution of Mg without the use of any Grignard reagents, other organometallic materials, tetraphenyl borate, or tetrachloroaluminate derived anions. Other Mg-containing electrolyte systems that are expected to be suitable for use in secondary batteries are also described.

Abstract: An organic cation for a battery, including a heteroatom-containing cyclic compound having at least (2) ring structures formed from rings that share at least one common atom, the cyclic compound having both a formal positive charge of at least +1 and a partial negative charge.