Researchers at the International Center for Materials Nanoarchitectonics 
(WPI-MANA), a unit of the National Institute for Materials Science (NIMS), have 
investigated the dynamical behavior of neuromorphic systems made of memristive 
nano-switches connected together forming complex networks. They have shown 
experimentally the interplay between network topology and memristor dynamics 
giving rise to self-organized states.

(Image: 
https://kyodonewsprwire.jp/prwfile/release/M105739/202003037623/_prw_PI1fl_e41Ta93K.jpg)


In self-assembled networks of polymer-coated silver nanowires, the junction 
between two connected nanowires acts as a memristive switch. Upon application 
of current-voltage cycles it is seen that the network as a whole also behaves 
as a memristor, showing critical activation. However, when transient signals 
are applied to the network, random events produced by the breakage of 
individual junctions could affect the conduction properties of the whole 
network.

Thousands of memristive junctions interact when electrical current is passing 
through, dynamically routing current through the network as switching events 
occur between individual nanowires. This complex dynamical landscape has been 
sorted out by devising an original measurement scheme in which both the static 
and dynamic properties of the network are systematically distinguished. It has 
been shown that the critical activation that is characterized by a sudden 
increase in conductance through networks is accompanied by a change in the 
power-law collective dynamics. The MANA researchers discovered that an 
activated network finds a route to convey current in a self-organized manner, 
but sudden bursts of reorganization events occur whenever individual junctions 
fail, and the network finds other pathways, thus self-repairing. 

This emergent and collective behavior provides a promising venue not only to 
understand better the collective dynamics of other complex systems, i.e., the 
brains, but also to explore new strategies for hardware integration of these 
networks as unconventional computing devices with the capability to perform 
machine learning tasks.

This research was carried out by Tomonobu Nakayama (Deputy Director, MANA 
Principal Investigator (PI), MANA, NIMS) and his team.

"Emergent dynamics of neuromorphic nanowire networks"
Adrian Diaz-Alvarez et al., Scientific Reports (October 17, 2019);
DOI: 10.1038/s41598-019-51330-6

MANA E-BULLETIN
https://www.nims.go.jp/mana/ebulletin/


SOURCE:
International Center for Materials Nanoarchitectonics (WPI-MANA), National 
Institute for Materials Science (NIMS)