Replies to post #81755 on Lightwave Logic Inc (LWLG)

[redspinelpinktopaz]

Beautiful. Thank you

[prototype_101]

KCC, the MRR's are of great interest to me, but from everything we have seen, the complexities involved in the management of them seems formidable, and I would guess that long term RT would have relatively high failure rates, remember each MRR has to be goldilocks temperature controlled by it's own IC, and also maintained at its specific frequency variation, PG posted some details on this here also,

https://investorshub.advfn.com/boards/read_msg.aspx?message_id=159954378

also, keep in mind that there has been much work done in the past on polymer MRR's as well, I believe it would also be possible to implement LWLG's Polymer Plus on Intel/Ayer MRR's, possibly work being done under NDA currently, would not surprise me

also, the recent news on LWLG & Polariton record breaking transmissions were done with a "racetrack" modulator, which I believe is an MRR, I could be wrong, here,

Lightwave Logic and Polariton Technologies Achieve World-Record Performance for Ultra-High-Speed Modulators

Breakthrough Results Presented in Peer Reviewed Paper at Prestigious 2021 European Conference on Optical Communications (ECOC)

ENGLEWOOD, Colo. and ZURICH, Sept. 16, 2021 /PRNewswire/ -- Lightwave Logic, Inc. (NASDAQ: LWLG), a technology platform company leveraging its proprietary electro-optic (EO) polymers to transmit data at higher speeds with less power, today announced the achievement of world-record performance for a polymer modulator, as demonstrated in an optical transmission experiment by ETH Zurich, using the Company's proprietary, advanced Perkinamine™ chromophores and Polariton Technologies Ltd.'s newest plasmonic EO modulator, a silicon-photonics-based plasmonic racetrack modulator offering energy-efficient, low-loss, and high-speed modulation in a compact footprint.


The groundbreaking results were presented as a post-deadline paper at the prestigious European Conference on Optical Communications (ECOC) industry exhibition and conference in Bordeaux on September 16, 2021. Polariton's plasmonic modulator transmitted 220 Gbit/s OOK and 408 Gbit/s 8PAM. Transmission of an optical signal was conducted over 100 m using a low-voltage electrical drive of 0.6Vp, an on-chip loss of 1 dB, and an optical 3 dB bandwidth of beyond 110 GHz.

"Our mission at Lightwave Logic is to continually push the frontiers of high-speed performance for electro-optic polymers, shaping the 'impossible' into reality and a new normal for the industry," said Dr. Michael Lebby, Chief Executive Officer of Lightwave Logic. "Through our collaboration with Polariton, we have achieved a new world-record for a racetrack plasmonic modulator device structure. The acceptance of a post-deadline peer reviewed paper at ECOC 2021 provides third party validation of this incredible result.

"We now turn our attention to further optimizing this performance with silicon foundries through both materials and optical device design. With performance achievements such as this, we believe that many companies will quickly see the potential impact that high performance optical switching devices using our polymers can have on their business," concluded Lebby.

Dr. Wolfgang Heni, Co-CTO at Polariton, added: "Polariton has always been dedicated to providing best-in-class devices with the highest-performance. Our goal is to make optical communications faster, the technology more scalable and with it, components and infrastructure more energy-efficient. Our recent demonstration of a plasmonic racetrack modulator once again showcased how the unique combination of plasmonics, silicon photonics, and organic electro-optics offers high-speed and energy-efficient components. We are pleased to have worked with Lightwave Logic, providing us with high-performance and reliable Perkinamine™ chromophores to demonstrate this new world record, further highlighting the benefits of our plasmonic modulator technology. Together, we hope to revolutionize the future of the internet through adoption of next-generation electro-optic polymer platforms."