 Oh hi everybody, so I'm here to talk about an Argentinean solar, which hopefully you rather buy that one instead of a Chilean solar. So our name is Neo Lithium and we are essentially developing a new lithium solar called Tres Quebradas, a 3Q lithium project. A little bit of cautionary statements and this is why we think Neo Lithium is the right place to be in. First of all, we're pure play. We have one asset, which is in Catamarca in Argentina, it's a new discovery which we essentially discovered in December of 2015. We own 100% of the project, there's nobody around us and the complex and it's fully permitted into feasibility. We fast-tracked this asset, we've raised over 45 million dollars, we put back almost now 9 to 10 million dollars into the project, we've reconditioned the road, we have ICAMP, a lab, we already have a pilot pond which is evaporating as we speak and we have extremely and very encouraging results on process studies which we can do regular evaporation, not with any new processes and we also put out some press releases with extremely good drilling results which are one of the highest in Argentina and one of the highest in the world in terms of brine. We intend to have a resource in the next, let's say, a couple weeks, I believe, and a new PEA in Q3 of this year. We believe we have the right asset, we not only have high grade but we also have the lowest combined impurities of any known solar. When you look at brines, you need to look at two things, grade and also impurities and we have both. We have a large footprint, you need that because if you don't have that, you cannot be able to have a big enough resource to make this thing happen and be economic and, of course, the people are one of the most important parts here. Our CEO, Waldo Perez was the CEO and founder of Lithium Americas. He took Kaucharisalar and Lithium Americas up to feasibility. He is the CEO of our company. Our chairman, Konstantin, obviously, has opened a lot of doors in Asia and Europe in order for us to have strategic partners come in and help us finance the project and the local team that's currently working with us is basically the same team that was in Lithium Americas and we've already hired three people from SQM as well so that are have experience in the Lithium side and obviously operations. In terms of the structure, we have about 89 million shares, 105 fully eluded, with fully financed feasibility and we raised $45 million. We have a good institutional base with 40% and the insider's on about 20. So this is where we are. We are at the bottom of the Lithium Triangle. We're essentially about 10 kilometers from the border with Argentina. Our project essentially goes up to the border. On a straight line, we're about 40 kilometers to the Maricunga Salar and we're extremely close to Argentina to achieve it. In fact, we are one of the closest salars, even though we're in the Argentina side, to the port in Chile. There's no inhabitants of our original communities in the area, I'm sorry. And as I said, we have 100% ownership of our complex. This is a picture looking north on a salar. One of the unique aspects of our complex is that we have three brine lakes. It looks like a lake, a water lake, but it's not water. It's brine, essentially now crop of our resource. If you look south, this is what our salar looks like. It's a bit more rocky-ish than your regular salar, which is very flat. This is what we've done so far. This is the camp that we build on site. It's about 60 people a year-round with solar panels and diesel generation that we're able to assist over winter if need be for many months. Here we go. This is the road that we've upgraded to the camp. It's about a 60-kilometer road from the highway to the project. These are the solar panels and diesel generators. We have a state-of-the-art weather monitoring station, which is extremely important to understand the weather conditions in the area. You can essentially tap into other salars to understand what the evaporation rates and the weather are during the area, but in this case, we have to put one there in order to provide enough information to build your definitive feasibility study, which is next year. This is a lab full chemical lab that we have on site to test all the evaporation ponds and some of the salar sampling. We have wells and pump tests already within the salar, and we already built a pile of evaporation ponds. In fact, they've been evaporating since January of this year. This is a satellite view of our salar or our complex on the north. The black spot on the north is the lake that I showed a picture of before. Then you have a transition period, transitions part of the salar, which is light blue, and then the white is the entire salar, then another lake, another salar, and another lake at the bottom. Another unique aspect of the salar is that we have geothermal springs coming into the top, as you see in the north and on the west side of the salar, that the top or the northern geothermal springs bring in cleansing agents, mostly calcium, and on the west side, it's bringing high-grade lithium, meaning we get up to almost 1,000 milligrams per liter in some spots, but on average we're 500 milligrams per liter constantly, and that is 500 liters per second of high-grade lithium. On the west and on the north, we get about 700 to 800 liters per second of rich calcium geothermal springs coming into the salar on the north. We haven't explored yet the ones on essentially the middle one. We are obviously advancing the project very rapidly because of the experience of our team. We're currently at a resource definition stage. We'll have a resource in the next couple of weeks, and we'll have a PEA later this year in Q3. This is a picture just to give you an idea of how one of the hot springs are. This is the hot spring that brings in high-grade lithium. I'm not sure if I have a pointer here, but there we go. This right here are cars, and over here you see some people walking. So you give you an idea of how big this geothermal spring is. This is what with geochemistry. This is what we did back in April to establish what we thought was our grade and our impurities. We did about 250 samples, almost 300, I'm sorry, and that helped us understand what we had. This is the results. All the black dots here are the sampling work. On the left-hand side, you'll see the high-grade lithium on the north, on the blue, and on the green, you see the high-grade potassium also on the north. Now, obviously, that's the grade. We have on the northern target, the average grade there is about 800 milligrams per liter, and importantly, as well, on the northern target, you see the white color that is very low on the left-hand side is the magnesium-to-lithium ratio, and on the right-hand side is the sulfate ratio, very low on both the northern target. So obviously, again, you not only need to look about grade, you also need to understand the critical impurities. After that, we did some geophysics to understand where we should focus our drilling program. We did about 55 kilometers, nine geophysical lines, and this showed us, as you see on the right-hand side of the map, where we did those lines. We expanded what we call the northern target to 20 kilometers instead of 14 kilometers, and we saw, in this case, we saw a brine up to almost 200 meters. What we've done so far, we've already finished, but it's 12 platforms, 24 holes, about 2,500 meters drilled, and a combination of diamond drills and rodeoes. This is a bit of geology. The interesting part about this is that we found two types of aquifers. We have an upper aquifier and a lower aquifier. The upper aquifier is about 70 meters up to 70 meters deep on average, and then there's a halide core there without not much porosity, and then again, at about 120 meters, we have a lower aquifer that is still open. So we haven't even found the bottom of that yet. These are the drilling results. As you can see, the drilling confirmed the high grade on the north side with up to almost 1,000 milligrams per liter, 600, 700, and so forth. What we did is that we expanded our drilling down to what we call the southern target, where sampling work, about a meter, gave us grades of almost maybe 200 milligrams per liter. But when we drilled, we found four to five or even 600 milligrams per liter at death, still open. So that expanded again, yet again, are essentially our targets to the south. And by the way, the impurity ratios did not change either on the drilling. Maintained very low on both magnesium and sulfate. Pumping porosity tests, we also obviously did this for the calculation of the resource, which is imminent. These are some of the results. Essentially, what we found here is extraordinary in terms of the porosity and pump test. We believe we have more than enough to produce from our solar. And essentially, some of the results that we've gotten, you don't see those anywhere in Argentina, and they're comparable to Atacama solar. They're on the top there. Okay, so we also did process studies. And one of the reasons we were able to do this is that we have a lake or a reservoir or a brine outcropping. Without that, we wouldn't be able to do the process as we could. You need to bulk sample that and send it to labs. So we did this and the results came back with extremely positive that we are able to essentially have a very simple evaporation technology to produce lithium. The recovery of 25 times per hectare is comparable to any solar. And I think somebody mentioned yesterday that salars, in terms of the brine, takes up to 18 months to two years to evaporate. That's wrong. I just want to make sure that everybody understands that our salar takes 8 to 12 months. So and it's a continuous batch process, not just one batch every 18 to 24 months. It's continuous batch after eight months. This is a comparison based solely on the sampling work that we've done. We are the highest grade in Argentina and we are the fourth highest grade in the world in terms of brine. This tells you a little bit about the impurities. As you can see, we're at the bottom corner, the red dot. This tells you all things being equal, where your cost is going to be. So you want to be on the zero zero. However, the majority of the salars are way off that. So the producing ones are in the 10 range there on the sulfate. And then anything beyond 10 on the magnesium side almost essentially very difficult to put in operation because of the cost associated with taking the magnesium out. There's a little bit of our history timeline and track record. We've moved very fast. What I want you to take away from this slide is that we just discovered this property in December of 2015 and we're about to issue a resource statement next couple of weeks and we'll have a PA by Q3. And we made it a race, we're fully financed to feasibility. There's no more dilution. A bit of the timeline and this essentially just tells you about what's going to happen over the next little while. We're going to have a feasibility in 2020 this year. I mean, sorry, PA this year and a feasibility one year after. The pilot plan will have results continuously, but we'll finalize in Q3 of next year. A bit of our capital structure, which I mentioned before, we have about 30 million today in the bank. And we have a pretty good ownership and institutional base. So, high grade, low impurity, simple evaporation process, large project, 35,000 hectares, 100% on. We're not sharing the project with anybody. So, the straws are going in our straws and we'll pull whatever we need to pull out. And we have an experienced team. So, catalyst, resource and PA this year with a feasibility next year. Thank you very much.