 So we hear the ID Tech Act show and who are you? I'm David Arthur, I'm the CEO of Kazum Advanced Materials and we're exhibiting today, we're featuring Agent, our carbon nanotube hybrid transparent conducted film materials. So, how does it work? First of all, a carbon nanotube, a hybrid material is a case where you take one material, combine it with another where one plus one is much greater than two, something like ten or a hundred. And so in our carbon nanotube hybrid we have silver nanowires that are coated onto a surface and we have carbon nanotube materials that are printed on top of the silver nanowires. So this noodle-like structure and this rigid rod type structure is the hybrid material. So you do hybrid between the silver nano and carbon. That's exactly correct. And this carbon nanotube hybrid transparent conductive film is better than either material alone. The silver nanowires are highly conductive and highly transparent. And the carbon nanotubes are very robust materials. And the printing technology allows circuit patterns to be made very affordably. So the combination allows for better performance and lower cost. So what do you talk about here in this part? This is our carbon nanotube ink platform and basically we combine carbon nanotubes that we make. We have a factory in Norman, Oklahoma that makes the carbon nanotubes. We mix in polymer binder and then we have our own proprietary ink vehicle technology. The three of these ingredients get mixed together to make an ink. And this ink can be printed using conventional screen printing which is very convenient. It can be dried at low temperature which makes it compatible with plastic film substrates. And the end result is low cost printed flexible electronics. So here you have some demos showing off the implementation how this is set up to work. Like all these right here. So hi, so who are you? Hi, my name is Ken Clapperoth. I'm the Vice President of Marketing for CASM. And I'd like to show you some of the demonstrations that we have available for people that are coming to the show today. So what are these? We have a variety of different products that have been made by our technology. The transparent antennas give you better performance at a better form factor. Covering a broad range of spectrums for wireless. These can be put into or onto an existing platform. Transparent heaters that are formable and flexible. So this is hot? This is hot. So what's the advantage of doing the transparent heater? So the transparent heater allows you to place the heater in front of any object without it being seen. So in an automotive application where microwires might interfere with an optical camera, the transparent can be optically clear so it can ensure that all of your safety devices are still running. Would that be in the seat? It would be in the windshield. It could be in the headlamps and it could also be in the seat. And electric car companies are looking to get rid of the air conditioning that occurs where you're heating and cooling air and put the heating sources and cooling sources right next to where the people are for better mileage on the car. So how transparent there's got to be a little bit of loss of transparency, right? There is a little bit of loss of transparency but we have a full range of materials to give you everything from 99% VLT to 90% VLT and the conductivity that's necessary for the application. So are you able to make different recipes or what's it called? Yeah, the nice thing about the CNT Hybrid as David had mentioned is we can tune the recipe to be most effective to give you the combination of transparency and conductivity that's necessary for your application. Are you in mass deployment? Is it huge already? What are you doing? We are in deployment of the application with a variety of different customers in the variety industries. It's not in full mass production but we are working to fill out both customers and partners who can support us in bringing this to market. So this could be revolutionary for all kinds of consumer electronics and everything also? We are banking on it being revolutionary throughout the industry. It's the only CNT Hybrid that's on the market today and because it gives you advantages that the others do not we think this will be a real game changer. So let's say if you put it for example on the phone or tablet or something like that, what does it improve in the device? So the first thing is it gives better formability and flexibility so for the new flexible format phones that are coming out you've seen some very spectacular failures that have happened. As David had mentioned the CNTs encapsulate the silver so if you're doing a lot of flexing and folding it gives you redundancy there at the joint where it's most needed. Are you talking about the reviewers who are testing out the Galaxy Fold and then they had some kind of issues with the screen breaking or something? Does it have anything to do with the part that you're doing or is it maybe the flexible AMOLED is also fragile? So the failure point in any of those is going to be at the joint and if you've looked at any of the models of the phones that are on the market today they have very complex and very precise hinges to prevent any kind of cross twisting and it's that twisting that can cause the failure. So in both Samsung and in Huawei you can see that they've taken different approaches but they put a lot of effort into making sure that that bending is just across the axis and it doesn't twist. So how's the performance difference between glass and your solution? Is it possible that the consumer would be 100% happy with the efficiency of the system? Yeah, so we are certainly going after the flexible market. We're not really interested in going after IT on glass. IT on glass is very mature and very stable and so if the customer wants to just be on a glass substrate we invite them to continue with that but if they have any need for flexibility, they have any need for formability then our solution provides a superior solution. And he is showing touch screen? Yeah, so we have a variety of different touch screens. So there's one on top of the other. So one is a resistive touch and the other is a capacitive touch. So in both of those you can see it's really quite transparent. What's the happening on the side here, the tracks? So those are the traces that carry the signal back to the controller. So generally those are off the screen in a bezel somewhere so they're printed in silver that's common practice. But people like to do those bezel less devices. Are you able to be bezel less or is it specific to your technology, these tracks? No, the tracks are typical to any flexible printed circuit and we can do our best to hide those in an area where they won't be conspicuous to the users. Nice. And what's this part here? So this is transparent circuitry so if you're an automotive manufacturer and you'd like to put LEDs in the middle of a sculpted surface, this is technology that allows you to place the LEDs right where you need them. So you can put LEDs right in the middle of the device? Correct. So think of smart surfaces today. Smart surfaces are very popular. People want to be able to put touch interfaces and responsive LEDs in the middle of a sculpted surface. This technology allows you to do that. And this is an example of thermo-forming so there is unformed and formed. You can see that we've printed the circuit a little bit heavier so you can actually see the difference. But even forming to this shape of a dome it still maintains the conductivity that's necessary. That's what's more like formed, what's called formed electronics? Yeah, in mold electronics or formed electronics this is the direction that... It's also huge. It's also going to be huge, right? Correct. People are automotive companies want to go this way. You can use this technology to build the heaters into headlamps so you can see the headlamps on cars today are very sculpted. And how about this one? So this is a particular invention that we have. We're selling in two different forms. So this is called our RF shielding film and what this does is it protects users of cellular phones from radiation due to RF signals. So this is a particular pattern in a particular recipe of our technology that will actually direct cell phone signals away from the user and back towards the antenna so it does not degrade antenna performance but it does lower SAR exposure to the user by 25% or more depending upon the phone model. And it can be in an OEM installation which is the thin film or aftermarket which is the screen protector. And this is right on the screen the part that connects, that touches the ear and everything. Correct. For the aftermarket version it's a replacement to the screen protector that you might be using today. The best installation though is in the OEM situation where we put it into the display module it actually provides better protection so we invite any of the cell phone manufacturers to come see us if they're struggling with how to balance signal strength for 5G and protecting the users from exposure. And some people are a little bit nervous about 5G. They say it is more all kinds of stuff happening with the spectrum and there might be a selling point to say that you have a phone that's safer. Correct. And what we're looking to do is talk to the design engineers because what this allows them to do is tune their balance between RF energy output that they need in order to get the signal quality with 5G and the exposure to the user. So they don't have to make the compromise anymore. They can bump up the signal strength to get to the 5G clarity that they need but they can also provide this film that gives the SAR exposure. And how about if we go over there what do you talk about on the screen? People can Google CNT Hybrid to see more stuff. Yeah, so we have a website at chasm. You can visit us on chasmtech.com or you can Google CNT Hybrid and it will bring you to our website where we have more information that people can see and interact with. What more has been shown in this video? So this is a thermal heating video. This is one of our transparent heaters as it goes through the heating cycle. This is a one-to-ones time. It will go up to 50 degrees C. This is the response rate that you can experience with our heaters. Is something about the heating right there? Is this some other? Yeah, this is a variety of different samples that we offer to customers. So a range of the recipes that we talked about earlier. You can see the different types of transparency that's available with the different versions. Plus this is an example of one of those heaters that's been printed showing the bus bars and how the material is put down. So you have been working on this for a while but what's going to happen next? What do you think is in the company 2020 is going to be a big year for this? 2020 I think is going to be an extremely big year for the company. We're working with Lighthouse name customers in all the different industries. Design and wins to their next generation products that they're developing. So we're going to have a big year with respect to sales to end customers. But we're also cultivating a group of preferred integration partners that can help us bring this to market. And where are you based and what are you working on? We are based in Canton, Massachusetts and we have a manufacturing facility in Norman, Oklahoma. So between those two facilities we cover both R&D and manufacturing of the product line that's known as agent. Thank you.