Should I Buy Liquid Metal Stock
HiI read a lot about the framework laptop and the cooler seems to be capable of handeling the CPU. Has anybody tried liquid metal vs regular thermal compound?I was curious, since I read the fan can get pretty lound under heavy load and liquid metal could help here. Thanks for your answers.
should i buy liquid metal stock
If you accidentally spill liquid metal, it not only likely causes shorts on your board, it also mixes with the solder and makes it brittle over time. It also corrodes aluminum if it comes into contact with it (the framework case for example).
I have been using liquid metal on both my GPU and my old laptop. One thing I recommend when applying liquid metal on GPUs and CPUs that have caps close to the GPU/CPU is applying clear nail polish on the caps. That saved me from accidentally shorting one of the caps when I spilled a small amount on one of the caps.
Kryonaut Paste: Its just thermal paste, super easy to apply. cleaned the stock paste off with a paper towel and then cleaned the dies and heatsink with alcohol pads.Idle: 40-42C. After applying past I let the laptop sit for 15 minutes with only aida64 open to establish the baseline.CPU burn: 13 minutes of CPU only stress. leveled out at 78-80C. CPU clock held 4100 MHz, 24w. no throttling.let sit for 10 minutes to come back down to base temperature.CPU + FPU burn: 12 minutes of CPU and FPU stress. Quickly ramped up to hit 100C and throttled, once the fan caught up it dropped to 90-95C and stopped throttling hard. when the temp hit 95C it would throttle slightly and drop back to 90C. CPU was doing 3400-3600MHz, and 27-28w.Kryonaut charts22243000 155 KBHonestly very impressive improvement over stock without the risk of damage from liquid metal. If you lift the laptop up slightly to improve the air intake you can get zero throttling once the fan ramps up under full load.
Ambri's liquid metal battery is a design that's never before been done. Within a casing, two metal alloys of calcium and antimony are separated by molten salt. By heating the cell to 500C, the resulting electro-chemical reaction allows electricity to be either stored or discharged.
Chief Operating Officer of Ambri Jim Pruiett said once the technology is proven, it will be about scale the production up greatly. Pruiett says Ambri hopes to produce 1,000 shipping container sized liquid metal batteries to plug right into the grid.
I havent used liquid metal on my framework, but I did on my old sandy bridge laptop. The temperature difference between liquid metals and freshly applied arctic mx4 was about 15C with the fans spinning slower, iirc. It was a huge upgrade. I havent done it on the framework yet, since mine is very quietly and i have it in the low power setting. If you apply liquid metal carefully, there is nothing wrong with it. You have to cover all metal contacts close to the CPU with some kind of conformal coting (I used nail polish, but its not really made for this application). If you dont use too much of it, it should be fine.
It might wear out a little faster, but until it does, it gives you about the lowest temperatures, you can get without using liquid metal. Since the framework is not an old laptop, I dont think the stock paste is worn out yet, but its just not as good, as @Paul_Kim would like. He cleaned his laptop after less than a year, so I thought, that repasting wouldnt be such a big deal.
Replacing inefficient thermal paste with liquid metal is very popular in high-performance laptops. And it is no longer exclusively an enthusiastic modification. In this way, for example Asus in ROG G703 improved its cooling. However, accelerating the heat dissipation from the dies may be unhelpful in some circumstances. No matter how strange and weird it may sound so far, it has a rational justification. See what may surprise you.
For heating, I use a concurrent run of Prime95 (Small FFTs) with the FurMark stress test. Although the graphics core quickly reaches the TDP limit and the frequencies are therefore even lower than the weak base frequency, it does not change anything on the power draw, it is close to the limit. I tested first in the factory settings, then the same after replacing the original paste with liquid metal Thermal Grizzly Conductonaut and finally even after undervolting the processor. In the tests, in addition to heating (at an ambient temperature of 24 C) and CPU and GPU frequencies, you will also find the difference in power consumption and noise (with a sound level meter sensor approx. 10 cm above the center of the keyboard) of the entire system.
After a few trial runs with liquid metal application and consultation with Der8auer and VSG, we eventually got the method down and improved thermals significantly. Delidding was done with the Delid DieMate X (we later learned that the vertical clamp is used for resealing, so is unnecessary to the delid process), after which process a cleaning of the IHS and die took place. We scraped off the silicone adhesive on the IHS-side to permit better contact and lower the copper plate closer to the die, leaving a thin layer of adhesive as a placement guide on the double-substrate Intel i9-7900X. Speaking with Der8auer, there is minimal thermal headroom to be gained by removing 100% of the silicone adhesive, and the delidding expert suggested that we leave a thin layer to better place the IHS. Going into these results, know that there is another 1-3C that could be gained from removing all the adhesive, according to Der8auer.
We eventually got liquid metal application down to a better science: A single dot of the stuff was placed on the IHS and CPU die, then spread into a thin layer across each surface. Nail polish was used for its nitrocellulose and akyl acetate, adding a protective layer over the SMDs on the substrate. We did not re-glue the IHS, but rather carried the CPU horizontally to its test bed, then clamped it down under the socket and cooler.
The funding amount is intended to design and build its liquid metal battery manufacturing facilities in the US and other growing markets to meet the growing demand from the grid-scale energy storage market and large industrial energy customers, such as data centers.
Thickened material can be diluted by adding Diamant Thinner (#0079) (not possible with tube packaging), so that it can be used again. The Diamant Thinner (#0079) can also be used to change the consistency of liquid metal Alu #0076 and liquid metal Iron #0077. As a result the fillable material becomes more spreadable or pourable.
The areas to be repaired should be clean and dry. Deeper defects can be repaired by applying several coats, each of which should be cured before applying the next. Maximum layer thickness: 2mm-3mm.The applied metal filler hardens within 2 hours. After this time, the above-mentioned subsequent layers can be applied in the case of multi-layer applications. Curing takes place within 2 hours at +20C room temperature.reseal cans, jugs well after use. Diamond liquid metal steel and diamond thinner are combustible. Flame point below +21C/70F.
If you are talking about the cooler that comes with the AMD 2600 as stock then Liquid metal must not be used under any circumstances as Liquid metal contains traces of Gallium which is highly reactive and corrosive to Aluminium and will destroy that cooler fast, However if you have the cooler that comes with the 2600x or the 2700x these coolers use direct contact Copper heat pipes so liquid metal is ok to use on these coolers, But I recommend checking at least every six months for corrosion and changing out the liquid metal, Make sure you use 99% Isopropyl Alcohol to remove all traces from CPU heat spreader, but it will leave unremovable stains on your copper heat pipes or Copper bases AIO coolers, this is normal so don't be alarmed by this.
Therefore, to avoid overheating, you need the best CPU cooling solution. This is primarily a must if you plan to overclock your rig. You have two primary solutions when it comes to cooling your CPU. You can either use liquid metal or thermal paste. But what's the best way to cool your CPU? Read on to find out.
As a CPU cooling solution, liquid metal has its pros and cons. For starters, liquid metal is almost always electrically conductive. That means it can transfer current from one point to another. Let's dive into each.
One area where liquid metal beats thermal paste is thermal conductivity. Liquid metal's thermal conductivity is suitable if you need a cooling solution that dissipates heat faster from your CPU relative to the thermal paste. The best liquid metal has a thermal conductivity rating of more than 73 Watts per meter-Kelvin (W/mk).
A single drop outside the target area can lead to short-circuiting when you power on your rig, or worse, failure of specific components if you don't clean it. Also, since the main element is Gallium, liquid metal can chemically react with Aluminum. Therefore, you should not use it if your CPU cooler has an Aluminum cold plate.
Thermal paste, sometimes called thermal grease or thermal compound, is another cooling option for your PC. Unlike liquid metal, thermal paste is not electrically conductive. However, thermal paste and liquid metal have an identical working mechanism.
Thermal paste is dirt cheap per gram, but the major disadvantage is its thermal conductivity. Thermal paste's thermal conductivity doesn't stand a chance compared to liquid metal. For context, some of the best thermal paste at the time of writing have a thermal conductivity slightly above 15 W/mk, which is way less than what you get with liquid metal.
Now that you understand the pros and cons of each, you may be wondering which CPU cooling solution is better. And the answer is; it depends. Yes, liquid metal has a higher thermal conductivity but has significant risks in the application. And therefore, best left to those who know what they are doing.
On the other hand, thermal paste is cheaper, but you'll have to deal with its lower thermal conductivity ratings. However, you'll do just fine with thermal paste. It's easy to apply and doesn't pose the many risks of using liquid metal. 041b061a72