Elcora Closes First Tranche of Private Placement

Elcora Advanced Materials recently announced the closing of the first tranche of its private placement, for gross proceeds of CAD$1,120,500 (around USD$898,362). The Company may issue further Units to raise total gross proceeds of up to CAD$3,000,000 (around USD$2,370,000).

The Company intends to use the net proceeds for general working capital purposes. Elcora was founded in 2011 and has been structured to become a vertically integrated graphite & graphene company. Elcora processes, refines, and produces both graphite & graphene. As part of the vertical integration strategy Elcora is securing high-grade graphite and graphene precursor graphite from operations in Sri Lanka and other countries which are already in production. Elcora has developed a cost-effective process to make high-quality graphite, graphite products and graphene that are commercially scalable.

Read the full story Posted: Oct 03,2021

ZEN Graphene Solutions finalizes definitive commercial agreement with Trebor Rx

ZEN Graphene Solutions recently announced the signing of a definitive commercial agreement with Trebor Rx for the manufacturing of ZENGuard-enhanced personal protective equipment. The agreement includes surgical masks, filters for Trebor’s patent pending Pro+ mask, nitrile gloves and other potential products.

Greg Fenton, Zen's CEO, commented: After working closely with George Irwin and the Trebor team over the last year, we have developed an excellent working relationship and are eager to launch our first product together, the Trebor Rx surgical mask with ZENGuard technology delivering over 99.99% bacterial and viral filtration efficiency. This is a significant commercial success for both our organizations, but more importantly, it brings a new option to healthcare employees and others in higher risk settings that wish to significantly enhance the bacterial and viral filtration efficiency compared to a typical, disposable ASTM level 3 mask.

Read the full story Posted: Oct 02,2021

Metal–Insulator–Graphene diodes enable terahertz rectennas on flexible substrates

Researchers from AMO GmbH, RWTH Aachen University, Chalmers University and the University of Wuppertal have recently developed a novel type of graphene-based flexible energy harvester, which reportedly shows good prospects for powering wearable and conformal devices.

A terahertz rectenna on polyimide image

The device is a 'rectenna' - an antenna directly coupled to a diode, which is able to detect radiation and to transform it into a DC output. Rectennas working in the microwave region have been well established since the sixties, thanks to the availability of Schottky diodes with a sufficiently short response time. The challenge is to extend the working principle of rectennas to higher frequency ranges in particular terahertz (THz) and optical frequencies.

Read the full story Posted: Oct 02,2021

The U.S. Army funds expansion of "flash" process

The Army Corps of Engineers will work with Prof. Tour and his collaborators at Rice University through a $5.2 million, four-year grant to expand the process that turns waste into graphene through flash Joule heating, to additional materials as well. Among the initiatives is a strategy to recover cobalt, lithium and other elements through the process developed by Tour’s group.

The grant through a Department of the Interior Cooperative Research and Development Agreement will allow the Rice-based team to extend the impact of its discovery that flashing food waste and other trash with a high-voltage jolt of electricity turns it into graphene. Through further experiments, the team realized the process could do much more. We’re pushing the idea that flash Joule heating can go way beyond just graphene, Tour said.

Read the full story Posted: Oct 02,2021

Moiré graphene may assist in harnessing Bloch oscillations

For many years, scientists have been trying to harness Bloch oscillations, an exotic kind of behavior by electrons that could introduce a new field of physics and important new technologies. Now, MIT physicists report on a new approach to achieving Bloch oscillations in recently introduced graphene superlattices. Graphene's electronic properties undergo an interesting transformation in the presence of an electric mesh (a periodic potential), resulting in new types of electron behavior not seen in pristine materials. In their recent work, the scientists show why graphene superlattices may be game changers in the pursuit of Bloch oscillations.

Normally, electrons exposed to a constant electric field accelerate in a straight line. However, Quantum Mechanics predicts that electrons in a crystal, or material composed of atoms arranged in an orderly fashion, can behave differently. Upon exposure to an electric field, they can oscillate in tiny waves—Bloch oscillations. This surprising behavior is an iconic example of coherent dynamics in quantum many-body systems, says Leonid Levitov, an MIT professor of physics and leader of the current work. Levitov is also affiliated with MIT’s Materials Research Laboratory.

Read the full story Posted: Oct 01,2021