WEBVTT 00:00:00.000 --> 00:00:03.840 Happy birthday me! Here's my present. 00:00:03.840 --> 00:00:10.400 Previously on LTT, I showed you guys this incredible $30,000 CPU cooler 00:00:10.400 --> 00:00:14.160 that is designed for one reason and one reason only. 00:00:14.160 --> 00:00:21.280 To chase PC performance records. But while you guys might have expected me to turn a CPU blue, 00:00:21.280 --> 00:00:27.480 instead, it was your balls. Because I teased it, but never actually hooked it up to any hardware. 00:00:27.480 --> 00:00:31.440 Well that changes today. And our goal is simple. 00:00:31.440 --> 00:00:36.600 Break a world record. An overclocking legend Charles Fuggerworth here 00:00:36.600 --> 00:00:40.120 gave me his personal guarantee that we will do it. 00:00:40.120 --> 00:00:43.880 So what are we waiting for? Well, we've got to prep the motherboard, 00:00:43.880 --> 00:00:47.880 we've got to insulate the socket, we've got to update the BIOS, we've got to upgrade the VGA BIOS, 00:00:47.880 --> 00:00:51.280 we've got to install the Windows, we've got to tune the Windows, 00:00:51.280 --> 00:00:55.760 and we've got to prep the VGA driver. And we've got to get the power cords. 00:00:55.760 --> 00:00:59.280 Oh, oh no, we've got those, we've got the power cords. 00:00:59.320 --> 00:01:03.320 We've got seven circuits to work with. Just seven? What, is that not enough? 00:01:03.320 --> 00:01:07.160 I think seven will work. Okay, as for the rest of it, well, 00:01:07.160 --> 00:01:12.160 it's a good thing we've got the whole day booked for this. And we've got the next 20 seconds booked for our sponsor. 00:01:20.960 --> 00:01:26.120 Before we can begin, one of the key enemies of subzero overclocking is condensation. 00:01:26.120 --> 00:01:29.160 See, the air around us is full of moisture. 00:01:29.160 --> 00:01:35.320 And it will gather on any cold surface, turn to liquid, and drip all over your sensitive electronics. 00:01:35.320 --> 00:01:38.760 Now, there are a number of different ways of approaching this problem. 00:01:38.760 --> 00:01:43.320 The board I'm holding in my hand uses a very similar approach to what you guys saw recently 00:01:43.320 --> 00:01:46.920 when we were chasing world records with our RTX 5090 Astral. 00:01:46.920 --> 00:01:50.280 You basically take PlastiDip, suck it up into a syringe, 00:01:50.280 --> 00:01:53.560 and drip it all over the sensitive components. 00:01:53.560 --> 00:01:56.640 Being sure to keep it away from any contact pins, 00:01:56.640 --> 00:02:00.200 say in PCI Express sockets, or in your power plugs. 00:02:00.200 --> 00:02:04.520 Next, you find a high quality neoprene-like closed cell foam, 00:02:04.520 --> 00:02:07.840 cut it up into nice little shapes, and fill in any big gaps. 00:02:07.840 --> 00:02:11.080 Of course, that's a ton of work, makes your board super ugly, 00:02:11.080 --> 00:02:16.540 and in the event that anything goes wrong, ASUS certainly isn't taking this back for an RMA. 00:02:16.540 --> 00:02:19.720 So Charles has a technique that he likes better. 00:02:19.720 --> 00:02:23.000 And it's to use nothing? Absolutely not. 00:02:23.000 --> 00:02:27.560 I just use a kingpin socket heater. Oh, so that goes on the back here? 00:02:27.560 --> 00:02:31.040 Yeah, it goes on the back of the board. It's a couple hundred watts of heating element. 00:02:31.040 --> 00:02:35.600 So counter-intuitively, you're heating the CPU area? 00:02:35.600 --> 00:02:39.240 Correct, correct, correct. It prevents moisture from building up 00:02:39.240 --> 00:02:45.200 on the backside of the board. Okay, and then what about the front? I use a little bit of insulation, just neoprene. 00:02:45.200 --> 00:02:49.360 Just kind of like this? Yeah, just a little bit of neoprene. Any glue or anything? No, no, no, I'll eat. 00:02:49.360 --> 00:02:52.520 And then I use WD-40, WD-40 specialist. 00:02:52.520 --> 00:02:55.840 Shut up. No, I- You put WD-40 in your CPU socket. 00:02:55.840 --> 00:03:01.000 I spray it directly in the socket, and I fill the socket, and I can actually fire the system up with the socket wet. 00:03:01.000 --> 00:03:04.120 Now, you told me that you thought a manufacturer 00:03:04.120 --> 00:03:08.440 like wouldn't be able to tell you'd put that in there. Is that true? Correct, it's undetectable. 00:03:08.440 --> 00:03:12.400 Completely undetectable. That's a tech tip. 00:03:12.400 --> 00:03:16.560 Little bit of RMA fraud tips. We're not actually advocating for that. 00:03:16.560 --> 00:03:18.400 Oh, you need your board clean. 00:03:20.320 --> 00:03:23.560 We're actually gonna be using the first board today though, and it looks great. 00:03:23.560 --> 00:03:28.880 Like, we could probably run Sub-Zero for hours, days at a time on this. 00:03:28.880 --> 00:03:34.080 But there is one small problem. Noctua probably doesn't make a secu-firm mounting bracket 00:03:34.080 --> 00:03:37.440 for your Cascade Chiller, so how do we get the thing on the thing? 00:03:37.440 --> 00:03:41.680 I make my own custom 3D printed brackets. These are for different sockets. 00:03:41.680 --> 00:03:46.720 That's for X299. Oh, cool, okay. And this is for AMD, AM5, AM4. 00:03:46.720 --> 00:03:50.400 Oh, cool. Hey, got the Extreme Systems logo on there. 00:03:50.400 --> 00:03:53.760 Now, it looks like you're using, oh, crap. 00:03:53.760 --> 00:03:57.800 Nylon. It's the, oh. That's the HP Multi-Jet Fusion. 00:03:57.800 --> 00:04:01.920 Wow, it feels, you can't break it. Feels great. 00:04:01.920 --> 00:04:05.800 It's the HP Multi-Jet Fusion 4200. Like, I don't think I could break this. 00:04:05.800 --> 00:04:08.960 No. Just in case I ever have to swap it. Can you show me how to do it? 00:04:08.960 --> 00:04:13.960 Sure. You said you wanted a screw? Yeah, yeah. So just pull it back a little bit. 00:04:13.960 --> 00:04:17.000 Expose the O-ring. Uh-huh. Pull the O-ring. 00:04:17.000 --> 00:04:21.640 And I just give it the old, ow, I stabbed myself. Well, we're off to a good start today. 00:04:21.640 --> 00:04:23.560 Okay, there we go. Okay, O-ring's off. 00:04:25.080 --> 00:04:29.160 And that's that. Zip-tie engineering. Now, have you ever shown anyone 00:04:29.160 --> 00:04:32.920 what's inside this evap-head? 20 years ago. Super cool. 00:04:32.920 --> 00:04:37.480 And can you kind of describe it for us? Like, is it a maze style or like, what are- 00:04:37.480 --> 00:04:41.000 This is a spiral evap-er. This is the prototype spiral evap-er. 00:04:41.000 --> 00:04:44.000 This is the first one I ever made. What's better about the newer ones? 00:04:44.000 --> 00:04:48.720 The newer ones are a thinner material. So better, faster heat transfer. 00:04:48.720 --> 00:04:52.520 Now, if I wanted to swap it out for AMD then, do you want to show us what that would look like? 00:04:52.520 --> 00:04:58.480 This is a mounting plate. Yeah. Goes into the adapter, goes right on. 00:04:58.480 --> 00:05:03.040 Goes on like that. Install the O-ring. Oh, that's actually shockingly elegant. 00:05:03.040 --> 00:05:06.600 Now, are these O-rings one-time use? Did you just- No, no, no, they're multi-time use, 00:05:06.600 --> 00:05:10.000 but I got a lot of them. Oh, I see, okay. You were just worried I was going to ruin it. 00:05:10.000 --> 00:05:13.120 Yes, I was. Being honest. I've watched your videos, come on. 00:05:13.120 --> 00:05:17.120 Why does he have the sickest burns? For the coldest machine. Yeah. 00:05:17.120 --> 00:05:20.120 Now, is there a reason that we're going Intel today, 00:05:20.120 --> 00:05:25.000 specifically the 285K? The 285K is great for the benchmark 00:05:25.000 --> 00:05:28.880 that we're going to run. An NPU boost is extremely strong in the benchmark. 00:05:28.880 --> 00:05:33.840 Last question for you. Did you choose nylon for its ruggedness or for its insulating properties or both? 00:05:33.840 --> 00:05:37.360 Both. I went with PLA at first and the PLA broke right off the bat. 00:05:37.360 --> 00:05:40.880 Before I put this on, maybe dumb question, but how flexible is this? 00:05:40.880 --> 00:05:46.480 Um, okay. The hose itself, this part is flexible. 00:05:46.480 --> 00:05:50.560 That part is not. Okay. So is everything I'm doing okay? 00:05:52.280 --> 00:05:53.240 Okay, yep. 00:05:55.280 --> 00:05:58.920 Okay. Oh, great. We don't even have any thermal compound, 00:05:58.920 --> 00:06:02.840 but here's the thing. You can't use just any thermal compound. 00:06:02.840 --> 00:06:06.440 What would you go with? Probably some thermal grizzly cryonaut. And the reason for that 00:06:06.440 --> 00:06:12.500 is that certain thermal compounds might perform great at ambient temperature or hot, 00:06:12.500 --> 00:06:15.680 like a liquid metal, for instance, highly thermally conductive, 00:06:15.680 --> 00:06:18.940 but here's the thing. We're not gonna be at room temperature. 00:06:18.940 --> 00:06:22.920 We're gonna be way below and that liquid metal would become solid metal. 00:06:23.900 --> 00:06:27.800 Not too great. Also liquid metal is a bit messy. You're not into the mess. 00:06:27.800 --> 00:06:33.040 No, not at all, actually. I guess you do this for enough years. You just, you become not into the mess 00:06:33.040 --> 00:06:36.040 and it just goes on like this. Hold on one more second here. We got one more piece. 00:06:36.040 --> 00:06:40.280 We got a new piece of neoprene here. Right, for around the bottom here. 00:06:40.280 --> 00:06:43.440 Correct, correct. I need to cut it so it needs to clear the memory slots 00:06:43.480 --> 00:06:47.040 because these are dual dim board. Oh, sure. 00:06:47.040 --> 00:06:50.240 And then that just goes on there or a little something like that. Once you get to there, 00:06:50.240 --> 00:06:53.880 then we'll bring it down another, about a centimeter. About a centimeter, okay. 00:06:53.880 --> 00:06:59.920 Now it's funny. You were making fun of me the other day for using a rando mixture of imperial and metric units, 00:06:59.920 --> 00:07:04.400 but I just heard you use a centimeter. Well, it was less than an inch, so I had to use something else. 00:07:04.400 --> 00:07:07.420 You're measuring things like a Canadian now, boys. 00:07:07.420 --> 00:07:11.840 Well, I'm in Canada. And what's special about this particular Viper kit? 00:07:11.840 --> 00:07:16.240 That's the new ultra sets from Patriot. That's the 6000 C28. 00:07:16.240 --> 00:07:19.560 So just super tight latencies and good rated speed. 00:07:19.560 --> 00:07:22.800 Correct. With CPUs, you know, you guys would take the time 00:07:22.800 --> 00:07:27.800 and you would hand bin. But in the case of memory, do you basically trust that the top kits 00:07:27.800 --> 00:07:31.560 from someone like a Patriot are already binned enough or do you bin those further? 00:07:31.560 --> 00:07:35.440 We've been them further. Okay, so this is a particularly nice kit of this. 00:07:35.440 --> 00:07:39.040 Correct, super binned. God binned. 00:07:39.040 --> 00:07:42.120 The last thing we're gonna need before we can fire up our bench is a GPU. 00:07:42.120 --> 00:07:46.520 Now, we're not gonna need RTX 5090 performance for the first record we're chasing 00:07:46.520 --> 00:07:49.940 because it's solely concerned with CPU benchmarks. 00:07:49.940 --> 00:07:54.760 But it's here already anyway. It's subzero prepped with plastic dip all over it, 00:07:54.760 --> 00:08:01.080 not to mention paper towel. And it's hooked up to Bruce Chillis, 00:08:01.080 --> 00:08:04.560 our industrial chiller, which we don't have to run at subzero speed. 00:08:04.560 --> 00:08:09.600 So we're probably just gonna run it at, you know, 10, 20 C for starters. 00:08:09.600 --> 00:08:13.680 Let's get this on here. Now that the bench is together, it's time to fire up the chiller. 00:08:13.680 --> 00:08:18.520 But there's a specific launch sequence starting with the first phase. 00:08:18.520 --> 00:08:23.240 If you haven't seen part one, this is a cascade system that essentially uses 00:08:23.240 --> 00:08:26.960 a refrigeration system to cool a refrigeration system, 00:08:26.960 --> 00:08:32.240 to cool a third refrigeration system in order to reach ungodly low temperatures. 00:08:32.240 --> 00:08:35.840 We're expecting negative 90 Celsius on our CPU, 00:08:35.840 --> 00:08:41.320 rock freaking solid. But we can't just turn on the compressors willy-nilly. 00:08:41.320 --> 00:08:45.040 We've got to turn on the first phase first, which is the bottom one. 00:08:45.040 --> 00:08:49.840 Correct, neat. Because Charles actually legitimately doesn't know 00:08:49.840 --> 00:08:52.860 how much power it draws. This will be fun for both of us. 00:08:52.860 --> 00:08:57.000 We got a few kilowatts and we're gonna hook them all up in line with, 00:08:57.000 --> 00:09:00.360 here we go, our power. Ah, it's alive. 00:09:02.520 --> 00:09:06.520 Oh, what do we got? What do we got? Oh, 116.7 volts. 00:09:07.000 --> 00:09:10.720 941, 941 watts. Just a few. 00:09:10.720 --> 00:09:15.160 So you can see why Intel's recent woes around power consumption of their chips 00:09:15.160 --> 00:09:20.160 doesn't bother him. His cooler, a third of it, draws 1,000 watts. 00:09:20.160 --> 00:09:25.840 Now that the first two phases are kind of settled in, they're at 700, 750 watts each, 00:09:25.840 --> 00:09:29.080 but we haven't even added the third phase yet. 00:09:29.080 --> 00:09:32.520 I can't read it. What does it say? Said 250. 00:09:32.520 --> 00:09:36.000 Oh, that's not bad. And then it jumped to 1,100. That's a lot more. 00:09:36.000 --> 00:09:40.080 And now we're settling in around the same. Now we know how much power it consumes. 00:09:40.080 --> 00:09:43.080 Now let's see how much power it can make. Oh, wow. 00:09:43.080 --> 00:09:46.520 We're already at 13 below. 17, 20. 00:09:46.520 --> 00:09:50.880 I guess we can turn on the computer, hey? Charles actually brought up an overclocking buddy of his. 00:09:50.880 --> 00:09:55.840 They're a member of the same team. This is Max, it's actually his memory that we're borrowing. 00:09:55.840 --> 00:10:00.240 And board. So do you wanna tell us what you're changing? We're going to change the performance preferences 00:10:00.240 --> 00:10:04.040 from the Intel default settings to the ASUS advanced OC profile. 00:10:04.040 --> 00:10:07.280 Well, multi-core enhancement, we are going to enable it and remove all the limits. 00:10:07.280 --> 00:10:10.400 We're going to set manual for AI overclock tuner. 00:10:10.400 --> 00:10:15.560 NPU boost level three, DRAM timing control. The Apex has a lot of nice, useful profiles. 00:10:15.560 --> 00:10:19.240 You have 9,600 gear four for the 24 gig sticks. 00:10:19.240 --> 00:10:23.240 Oh, cool. 9,000 for the 16 gig sticks and the 24 gig sticks. 00:10:23.240 --> 00:10:26.440 So we're gonna run 9,000 on the 24 gig sticks and just leave it at that. 00:10:26.440 --> 00:10:31.240 So you don't even have to tune any of the sub timings or any of that crap, they just did all the work for us. 00:10:31.240 --> 00:10:36.240 Yep, make it really easy. Now, is that something that you would find on anything other than like an Apex, 00:10:36.240 --> 00:10:39.880 like a top tier board? I think the lower end boards do have some features. 00:10:39.880 --> 00:10:43.240 The Strix does have that. The Strix has that as well, very good. We aren't as aggressive. 00:10:43.240 --> 00:10:47.600 I don't think you're going to be running 9,000 on a four dim stick. Well, the cache is 49. 00:10:47.600 --> 00:10:51.720 49? Seems high, but. If you want to go 48, that's fine. 00:10:51.720 --> 00:10:55.800 All right, we'll go 48 for the start. We'll take it to 48. Hacking the main frame. 00:10:55.800 --> 00:11:00.400 So the D2D ratio is the interconnect. There is a chiplet design. 00:11:00.400 --> 00:11:03.680 So you have your SOC on here, your memory controller 00:11:03.680 --> 00:11:07.960 is I think on there too. And if we cared about onboard GPU performance, for instance, 00:11:07.960 --> 00:11:11.720 maybe we'd care about that or? Yeah, it increases performance across the board. 00:11:11.720 --> 00:11:16.240 Memory band with really high speeds, with like no NPU boost on this. 00:11:16.240 --> 00:11:19.720 That's right, the IMC is on a separate chiplet, isn't it? 00:11:19.720 --> 00:11:24.000 Latency is kind of an issue. Intel, okay, you'll get them next time, boys. 00:11:24.000 --> 00:11:27.640 It's a very strange design. It's effectively a monolithic CPU 00:11:27.640 --> 00:11:32.320 that is a chiplet on a single die. So we're going to change our V-Core to 1.35 volts. 00:11:32.320 --> 00:11:36.160 That's all we need, huh? You tend to not need as much voltage as you would 00:11:36.160 --> 00:11:40.000 going to the colder you go, but it really is dependent on the chips. There's a leakage factor, 00:11:40.000 --> 00:11:43.520 which is how much power these chips draw. And typically a higher leakage chip 00:11:43.520 --> 00:11:49.520 will require less voltage and will scale better with temperature. Ironically, the leaky chips are not necessarily 00:11:49.520 --> 00:11:54.360 the ones that Intel wants for the chips they're going to ship to consumers. 00:11:54.360 --> 00:11:58.440 They tend to not be as efficient when you're operating them normally. 00:11:58.440 --> 00:12:03.440 And then we're going to change it to from regulation mode, which is using the DLVR on the CPU. 00:12:03.440 --> 00:12:06.440 So the VRM will output a higher voltage to the CPU 00:12:06.440 --> 00:12:10.000 and the CPU steps it down. We're going to bypass that with power gate mode. 00:12:10.000 --> 00:12:14.360 Got it. So we're just going to let our board do the work because we know that we have an outstanding board 00:12:14.360 --> 00:12:19.080 that's going to deliver nice stable power. Something we'd never recommend that you actually do 00:12:19.080 --> 00:12:23.400 for real world performance, but if you're just trying to chase the highest possible number. 00:12:23.400 --> 00:12:28.560 It is very fun. Once we're done running PCMark 7, it'll have the screen up with the result. 00:12:28.560 --> 00:12:32.760 We're going to open up four copies of the CPU ID. We're going to set up four boxes. 00:12:32.760 --> 00:12:36.960 We're going to set up the CPU, the amount of the board, the memory tabs. 00:12:36.960 --> 00:12:41.440 And then we're going to do a screenshot. And then we're going to have a world record for you. 00:12:41.440 --> 00:12:44.520 That easy? That easy. You got to be kidding me. 00:12:44.520 --> 00:12:48.680 Well, we got to save the result. All right, here we go. 00:12:48.680 --> 00:12:52.520 PCMark 7, let's go boys. Wait, before we actually do the run, 00:12:52.520 --> 00:12:57.080 I mean, can we just put it under load and see how stable the temperature is? 00:12:57.080 --> 00:13:00.120 Okay, okay. W prime? Yep. 00:13:00.120 --> 00:13:03.880 Okay. Are we at 64.4? Yeah, okay. It's a very popular older benchmark. 00:13:03.880 --> 00:13:07.720 Wait. We got down. Did that run? Yeah. 00:13:07.720 --> 00:13:11.400 It didn't even move. That is crazy. 00:13:11.400 --> 00:13:14.960 It's gone up a degree and a half. And so my expansion valve will kick in 00:13:14.960 --> 00:13:19.800 and it'll compensate for the load. Balance out now. It is so cool. 00:13:19.800 --> 00:13:22.820 And we're going the other way now in temperature. Look at this. 00:13:22.820 --> 00:13:27.320 Yeah, he's right. That's the wrong way. He's right. We're going back down. 00:13:27.320 --> 00:13:32.320 We went from negative 104.4 to like 0.5, 0.6, 00:13:33.440 --> 00:13:38.560 back to 0.5 still. It'll fluctuate a little bit. We're within like 0.3. 00:13:38.560 --> 00:13:45.400 0.5, yeah. But with the e-cores on and running around 5.8 or 5.7, 00:13:45.400 --> 00:13:49.840 we might have like a two degree fluctuation. And that's with a 285K. 00:13:49.840 --> 00:13:53.160 With the Raptor Lake, we might have like a four degree. Right. 00:13:53.160 --> 00:13:57.840 He's on the Intel team, but you know, if we're being honest, she was a hungry boy. 00:13:57.840 --> 00:14:02.280 So we're just finishing up and we're at our coldest temperature yet. So we're pretty damn stable 00:14:02.280 --> 00:14:06.280 if we're able to run like a stability test right now. So this is a thermal expansion valve right here. 00:14:06.280 --> 00:14:11.120 And this is a expansion valve that responds under load. So now it'll go back down in temperature again 00:14:11.120 --> 00:14:15.600 as we have no load. Right, okay. But then it'll go, oh, hold on a second. 00:14:15.600 --> 00:14:18.840 We're good. I don't need all of this extra coolant 00:14:18.840 --> 00:14:22.480 and it'll back it off. Yeah. Cause there's nothing you can do 00:14:22.480 --> 00:14:28.000 about the temperature of the refrigerant, right? It's within reason, right? 00:14:28.000 --> 00:14:31.040 You're not going to run your compressors at like a variable load. 00:14:31.040 --> 00:14:34.920 This is not a sophisticated, you know, modern heat pump or air conditioning system. 00:14:34.920 --> 00:14:38.080 These are running at a fixed speed. 00:14:38.080 --> 00:14:43.800 So what you would do then to achieve this kind of temperature control is you're adjusting the flow rate 00:14:43.800 --> 00:14:47.160 through the evaporator head. So it's the, my understanding is the temperature 00:14:47.160 --> 00:14:50.840 of the refrigerant should be basically the same ish. Correct. 00:14:50.840 --> 00:14:54.800 But we just juice it way more when we need more cooling. 00:14:54.800 --> 00:14:58.680 Right, it opens up the valve more. Cool. Are we ready to do the run 00:14:58.680 --> 00:15:01.720 or did you guys need to go double check something? No, no, we're all good to go. 00:15:01.720 --> 00:15:06.440 We just got to press the go button. Yeah, you can really see how much he runs benchmarks. 00:15:06.440 --> 00:15:11.000 Is it the current world? Yep, that is. Do you ever run actual video games? 00:15:11.000 --> 00:15:14.840 Yeah. Oh, okay. I mean, some people get, they get so into the benchmarking 00:15:14.840 --> 00:15:19.440 they don't actually game. What's your game right now? Well, I just finished up battlefield four is Riker. 00:15:19.440 --> 00:15:23.240 Riker, sorry. He's still working his way through his backlog. Yeah. 00:15:23.240 --> 00:15:27.120 Okay, so we're ready. Okay, so we're gonna go. Click the go button. All right, I click go. 00:15:27.120 --> 00:15:31.360 I mean, we're all on the same page that just because I click go doesn't mean I set the record. 00:15:31.360 --> 00:15:35.000 Like this is- No, no, no, you click go, you set the world record. Yeah, I really don't think that's how it works. 00:15:35.000 --> 00:15:39.040 It's how it works. I really- I set the rules, that's how it works. 00:15:39.040 --> 00:15:44.040 How long does this take to run? So this is 15, 20 minutes. But actually what's hard about this for the Ellen too guys 00:15:44.040 --> 00:15:48.160 is the duration of this benchmark and pouring and keeping this thing under a consistent load. 00:15:48.160 --> 00:15:52.240 As to where the cascade can keep this under a very consistent load for a very long duration. 00:15:52.240 --> 00:15:55.400 In case you have to rerun it and rerun it again and rerun it again. 00:15:55.400 --> 00:16:00.620 Right. The cascade, you can just rerun this thing all day long and have it consistent runs every single time. 00:16:00.620 --> 00:16:04.360 So it's gonna be extremely hard to catch your score. Right, got it. 00:16:04.360 --> 00:16:07.760 It's gonna be extremely hard. My score. You're gonna be on the world record rankings 00:16:07.760 --> 00:16:11.080 for a long time and let the other guys chase you down. 00:16:11.080 --> 00:16:16.800 Good luck. Oh, we didn't get it on the first run. 00:16:16.800 --> 00:16:19.840 That's his fault. Can you stop assigning blame to everyone around here? 00:16:19.840 --> 00:16:23.640 Hey, he told me what settings to put in. He did do that. But you had the RAM set up though. 00:16:23.640 --> 00:16:27.080 Yeah. That's weird, that's not memory. Yeah, because it meant that that could be memory. 00:16:27.080 --> 00:16:30.280 That is CPU, I know for a fact it is. That wasn't CPU, we'll need a minute. 00:16:30.280 --> 00:16:33.840 Now you guys tuned one more thing. This is our third run. 00:16:33.840 --> 00:16:37.000 What did you guys change? The NPU boost, I dropped it down. 00:16:37.000 --> 00:16:40.560 But we're still at 9,000 mega transfers on the memory. I think about there. 00:16:40.560 --> 00:16:45.040 It's gotta be 15,017. Oh. 00:16:45.040 --> 00:16:48.680 So it'll take two runs. So close. 00:16:48.680 --> 00:16:51.800 We're so close. We got this. 00:16:51.800 --> 00:16:56.240 Okay, we got this, we got this. Graphics 315, we just need to bring up our GPU 00:16:56.240 --> 00:17:00.320 just a little bit. Oh yeah, we could do that. Just bring up our GPU a little bit and we're there. 00:17:00.320 --> 00:17:05.160 And now we play the waiting game. Here we are, run number two. 00:17:05.160 --> 00:17:09.520 Well, three, but who's counting? Oh no. Oh, it was data file corruption. 00:17:09.520 --> 00:17:13.520 Yeah. So we made it this far and then it's upset 00:17:13.520 --> 00:17:17.280 that it doesn't know the CPU name. Third time's a charm. 00:17:17.280 --> 00:17:21.240 This is a third run, right? Sure. I mean, it's movie magic. It can be whatever run you want it to be. 00:17:21.240 --> 00:17:25.520 If you edit it, it can be the first. All right. Oh, it went down. 00:17:25.520 --> 00:17:29.480 How'd we go down? You're on frame for a second to go up. You didn't put any GPU clock on it, man. 00:17:29.480 --> 00:17:32.280 Oh, I rebooted. One moment, please. 00:17:33.240 --> 00:17:36.480 Time to get the results from our second attempt. 00:17:36.480 --> 00:17:39.960 Movie magic, right? The same error again? 00:17:39.960 --> 00:17:43.000 Get CPU name. Big moment. 00:17:43.000 --> 00:17:43.960 First run. 00:17:46.760 --> 00:17:50.320 Next plan. We're gonna try and adjust the cache speed a little bit. 00:17:50.320 --> 00:17:54.560 Maybe try to tune the CPU speed up a little bit. We got second place again, but not quite. 00:17:54.560 --> 00:17:59.920 First place. What do you think's up? Well, if we look at the GPU Z tab here, 00:17:59.920 --> 00:18:04.680 we have our 59, is it 6X? It says it's 16X, right, gen five. 00:18:04.680 --> 00:18:08.600 Running it. But it's actually 8X. The SSD is in the wrong slot. 00:18:09.120 --> 00:18:13.880 Had it in the correct slot earlier, I don't know if somebody moved it or not. It got pulled and put back in at one point. 00:18:13.880 --> 00:18:19.120 Linus isn't here, so we'll blame him. Yes, we'll blame him. I'm pretty sure we have it on video that it was him. 00:18:19.120 --> 00:18:22.920 Okay, then let's move that over and let's try again. 00:18:22.920 --> 00:18:28.640 Whoa, whoa, whoa, whoa, whoa. Whoa, whoa, you guys blamed me for putting in the SSD. 00:18:28.640 --> 00:18:33.880 I didn't put in the SSD. Yeah, because you moved the 5090. I actually know who put it in. 00:18:33.880 --> 00:18:37.840 Oh, who? Unlike you guys. 00:18:37.840 --> 00:18:42.400 It was not me. I'm not a filthy rat, so I would never rat. 00:18:42.400 --> 00:18:45.960 Wait, do you have footage of who put it in? No, I don't, maybe. 00:18:45.960 --> 00:18:49.800 Editor, roll the clip if there is one. Oh, oh my God. 00:18:49.800 --> 00:18:54.880 Seriously? Well, fortunately it's only our first run. 00:18:54.880 --> 00:18:58.600 In case you're curious about the finer details, we just the CPU clocks a little bit, 00:18:58.600 --> 00:19:02.160 just the cache, and this is gonna be it. 00:19:02.160 --> 00:19:05.920 Ninth run. First try. Yeah, first try. 00:19:05.920 --> 00:19:09.600 Man, it's gonna be cool when we nail this. We got this. On the first try. 00:19:09.600 --> 00:19:13.120 Oh my God, it's so close. It's so close. Thousand watt BIOS? 00:19:14.080 --> 00:19:18.680 Ah? I think so. I think that would do it. On the next first try, we're gonna nail it. 00:19:18.680 --> 00:19:22.000 On the next first try. Yay, there it is. 00:19:22.000 --> 00:19:25.240 Nice, first place. Good job. Taiwan number one. 00:19:25.240 --> 00:19:29.560 It's only first try. You got a world record. The bad news is, this took all day, 00:19:29.560 --> 00:19:34.480 so I guess we're not gonna get to 3DMark today, but hey, this is staying here, 00:19:34.480 --> 00:19:40.120 so you can expect to see plenty of shenanigans make sure you absolutely pound that subscribe button. 00:19:40.120 --> 00:19:43.880 Like I'm talking a hole in your TV or monitor 00:19:43.880 --> 00:19:46.960 so you don't miss any of the future sub-zero updates 00:19:46.960 --> 00:19:50.240 with Charles coming up here in the future to build a single phase, 00:19:50.240 --> 00:19:54.360 and also just, I don't know, man, Elijah, we're gonna have to play with this thing like lots. 00:19:54.360 --> 00:19:58.320 Sounds good to me. Just like I'm gonna play with our sponsor. 00:19:59.320 --> 00:20:04.760 It's weird, right? Yeah. If you guys enjoyed this video, maybe go check out part one 00:20:04.800 --> 00:20:08.480 where we unboxed what I am calling the Beast, which it turns out, 00:20:08.480 --> 00:20:11.760 isn't that exactly what you call it? Yes. Cool. 00:20:11.760 --> 00:20:15.320 We both named it the same thing. Ironically, yeah. 00:20:15.320 --> 00:20:16.720 Good job on the world record.