{
  "$type": "site.standard.document",
  "description": "This disclosure, and the exemplary embodiments provided herein, include microfluidic devices and methods of producing microfluidic devices including 3D-printable structures which are scalable, robust, parallel, fast, and efficient for generating vast networks of electrodes in-situ. For example…",
  "path": "/patents/1352368",
  "publishedAt": "2023-10-05T00:00:00.000Z",
  "site": "at://did:plc:oql6ds5vnff4ugar6rruliwd/site.standard.publication/3mn3ohu7oxx5w",
  "tags": [
    "H01M8/16",
    "The United States of America, as represent by the Secretary of the Navy"
  ],
  "textContent": "This disclosure, and the exemplary embodiments provided herein, include microfluidic devices and methods of producing microfluidic devices including 3D-printable structures which are scalable, robust, parallel, fast, and efficient for generating vast networks of electrodes in-situ. For example, benthic microbacterial fuel cells including networks of electrodes to harvest electrons ejected from bacteria positioned in a complex multilevel structure containing those bacteria suspended in aqueous solution or feeding medium. In addition to biofuel cells, the use of 3D-printed T channels as disclosed extends to other applications where similar networks of conducting channels can be rapidly and efficiently generated in existing structures.",
  "title": "T-CHANNEL MICROFLUIDIC DEVICES AND 3D PRINTING METHODS FOR PRODUCING T-CHANNEL MICROFLUIDIC DEVICES"
}