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Neotech NEI-3001 G-UP OCC Graphene / NER-OCC II G-UP OCC
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Description - Neotech NEI-3001 G-UP OCC Graphene / NER-OCC II G-UP OCC
Neotech NEI-3001 G-UP OCC Graphene / NER-OCC II G-UP OCC Gold
All conductors are treated with Graphene and also the inner walls of the connector. The cable consists of four conductors each of pure monocrystalline copper, two pairs are hard wire and two are stranded...
How it plays:
The sound is very open, like a real music scene in its concert form. Clarity of musical expression, speed and great natural dynamics. What is important is that the cable plays great from the first moment, no burning in and waiting to hear how it plays! I would say the ideal cable for most equipment! Some might miss the taught ambiance of the music on some tracks. Every track is a full on concert! The cable is offered with connectors that are also G series graphene treated. I'm not a big fan of gold plated connectors to pure copper wires, but they really fit here, no need to add rhodium! Highly recommended! One of the best performing cables I can offer and still good money! A true high end cable without the aftertaste of a disgusting price...
Graphene features:
Shielding - Carbon and Graphene
High Frequency (RF) noise from Wi-Fi and satellites is ubiquitous today, damaging audio signals more than ever before. That's why the signal cable uses a sophisticated noise cancellation system. In addition to universally proven wire direction control, a shielding layer consisting of a carbon and graphene resistive network (graphene is an ultra-thin high-tech material) is applied to reduce the effects of RF noise. These technologies from Neotech Cable significantly minimize RF noise, which thus cannot enter the active circuits, affect the audio signal and be the cause of transparency losses.
Graphene is a super-thin form of carbon similar in structure to graphite, one of the strongest known materials in the world.1 It is only one atom in height and transparent, and as a result of this de facto 2D structure, it also has some special physical properties. It is made up of a planar network of a single layer of carbon atoms arranged in a hexagonal shape connected by sp² bonds. Graphene also occurs in multiple layers, but according to ISO 80004-13:2017, only materials with a maximum of 10 layers may be referred to as graphene[4].
No other material has been observed to have electrons that behave as if they have no effective mass and move at nearly the speed of light. Scientists hypothesize that graphene could be used in the proof of the so-called Klein paradox. This is because, according to current knowledge, this phenomenon should only occur in very extreme conditions (e.g. around black holes). If this were to be proven, it would open the way to the development of a completely new kind of transistor.
In addition to its electrical conductivity, graphene is also light-permeable, so it could be used in the manufacture of displays and photovoltaic cells. It could thus replace existing devices made of thin metal oxide layers. In addition, a display made of graphene is stronger than those previously made from tin and indium oxides, of which there is a limited amount.5][6][7]
Due to its semiconductivity and a mesh thickness of only one atom, graphene can be used to make transistors that are theoretically capable of operating up to a frequency of 1 THz. Moreover, they can be assembled into very compact units. Thanks to these properties, graphene is expected to be used in microprocessors and memories in the future[8][9][10].