home.social

#picoseconds — Public Fediverse posts

Live and recent posts from across the Fediverse tagged #picoseconds, aggregated by home.social.

  1. Reading magnetic states faster – in far infrared: Team of #HZDR and TU Dortmund University provides proof of feasibility of ultrafast data storage. Instead of electrical pulses, they use ultrashort #terahertz light pulses, enabling the read-out of magnetic structures within #picoseconds.

    ▶️ hzdr.de/presse/usmr

    Image: B. Schröder/HZDR

  2. Reading magnetic states faster – in far infrared: Team of #HZDR and TU Dortmund University provides proof of feasibility of ultrafast data storage. Instead of electrical pulses, they use ultrashort #terahertz light pulses, enabling the read-out of magnetic structures within #picoseconds.

    ▶️ hzdr.de/presse/usmr

    Image: B. Schröder/HZDR

  3. Reading magnetic states faster – in far infrared: Team of #HZDR and TU Dortmund University provides proof of feasibility of ultrafast data storage. Instead of electrical pulses, they use ultrashort #terahertz light pulses, enabling the read-out of magnetic structures within #picoseconds.

    ▶️ hzdr.de/presse/usmr

    Image: B. Schröder/HZDR

  4. Reading magnetic states faster – in far infrared: Team of #HZDR and TU Dortmund University provides proof of feasibility of ultrafast data storage. Instead of electrical pulses, they use ultrashort #terahertz light pulses, enabling the read-out of magnetic structures within #picoseconds.

    ▶️ hzdr.de/presse/usmr

    Image: B. Schröder/HZDR

  5. Reading magnetic states faster – in far infrared: Team of #HZDR and TU Dortmund University provides proof of feasibility of ultrafast data storage. Instead of electrical pulses, they use ultrashort #terahertz light pulses, enabling the read-out of magnetic structures within #picoseconds.

    ▶️ hzdr.de/presse/usmr

    Image: B. Schröder/HZDR

  6. Hiya fediverse, happy Friday. Here's your semi-occasional dose of #terahertz content:

    A #terahertz #image of a single #semiconductor #nanowire, taken about three #picoseconds after it was optically excited (spatial #resolution of image ~ 50 nanometers). It is brighter in the middle due to the mobile #electrons that are still floating around in there. The edges are darker because electrons near the edges can become trapped more readily.

    Taken from here:
    doi.org/10.1021/acsphotonics.1

  7. Hiya fediverse, happy Friday. Here's your semi-occasional dose of #terahertz content:

    A #terahertz #image of a single #semiconductor #nanowire, taken about three #picoseconds after it was optically excited (spatial #resolution of image ~ 50 nanometers). It is brighter in the middle due to the mobile #electrons that are still floating around in there. The edges are darker because electrons near the edges can become trapped more readily.

    Taken from here:
    doi.org/10.1021/acsphotonics.1

  8. Hiya fediverse, happy Friday. Here's your semi-occasional dose of #terahertz content:

    A #terahertz #image of a single #semiconductor #nanowire, taken about three #picoseconds after it was optically excited (spatial #resolution of image ~ 50 nanometers). It is brighter in the middle due to the mobile #electrons that are still floating around in there. The edges are darker because electrons near the edges can become trapped more readily.

    Taken from here:
    doi.org/10.1021/acsphotonics.1

  9. Hiya fediverse, happy Friday. Here's your semi-occasional dose of #terahertz content:

    A #terahertz #image of a single #semiconductor #nanowire, taken about three #picoseconds after it was optically excited (spatial #resolution of image ~ 50 nanometers). It is brighter in the middle due to the mobile #electrons that are still floating around in there. The edges are darker because electrons near the edges can become trapped more readily.

    Taken from here:
    doi.org/10.1021/acsphotonics.1

  10. Hiya fediverse, happy Friday. Here's your semi-occasional dose of #terahertz content:

    A #terahertz #image of a single #semiconductor #nanowire, taken about three #picoseconds after it was optically excited (spatial #resolution of image ~ 50 nanometers). It is brighter in the middle due to the mobile #electrons that are still floating around in there. The edges are darker because electrons near the edges can become trapped more readily.

    Taken from here:
    doi.org/10.1021/acsphotonics.1