Perhaps also practical for intersecting applications: "These Superabsorbent Batteries Charge Faster the Larger They Get: In the lab, the prototype quantum batteries are charged with light" https://spectrum.ieee.org/quantum-battery :
> Previous work found that matter could act collectively in surprising ways due to quantum physics. For example, in "superradiance," a group of atoms charged up with energy can release a far more intense pulse of light than they could individually.
> In the past decade, researchers have also discovered the reverse of superradiance was possible—superabsorption, with atoms cooperating to display enhanced absorption. However, until now superabsorption was seen for only small numbers of atoms.
[…]
> The new device consists of a reflective waferlike microcavity enclosing a semiconducting organic Lumogen F orange dye, which the researchers charged with energy using a laser. Ultrafast detectors helped the team monitor the way in which this dye charged and stored light energy at femtosecond resolution. As the microcavity size and the number of dye molecules increased, the charging time decreased.
Could a combo PV photovoltaic, storage, full-spectrum e.g. LED product for outdoor and/or indoor applications be created with super absorption, , and superradiance?
Maybe also wrap the thing in thin film (and/or graphene sheets that throw off electrons) to harvest energy off the thermal gradient around the unit; and shape it like self-cleaning petals.
> Previous work found that matter could act collectively in surprising ways due to quantum physics. For example, in "superradiance," a group of atoms charged up with energy can release a far more intense pulse of light than they could individually.
> In the past decade, researchers have also discovered the reverse of superradiance was possible—superabsorption, with atoms cooperating to display enhanced absorption. However, until now superabsorption was seen for only small numbers of atoms.
[…]
> The new device consists of a reflective waferlike microcavity enclosing a semiconducting organic Lumogen F orange dye, which the researchers charged with energy using a laser. Ultrafast detectors helped the team monitor the way in which this dye charged and stored light energy at femtosecond resolution. As the microcavity size and the number of dye molecules increased, the charging time decreased.
Could a combo PV photovoltaic, storage, full-spectrum e.g. LED product for outdoor and/or indoor applications be created with super absorption, , and superradiance?
Maybe also wrap the thing in thin film (and/or graphene sheets that throw off electrons) to harvest energy off the thermal gradient around the unit; and shape it like self-cleaning petals.