When you’re buying a new computer, DDR5 memory is the fastest option you’ll want to get your hands on. Out of all the options, the Netac Z RGB DDR5-6200 32GB (2x 16GB) Gaming Memory is a real eye-catcher. It’s not just fast with a speed of 6,200 MHz; it’s also got this cool, mirror-like finish and RGB that really makes it stand out. With high-performance timings of 32-38-38-96 and running at 1.35V for its 6200 MT/s Intel XMP profile, this kit is ready to compete with the best in the game. It’s a piece of hardware that shines—literally.
The Netac Z RGB DDR5-6200 MHz Gaming Memory is priced at $130 (PHP 7,389.53) for the 32GB silver variant, positioning itself competitively in the market.
In this review, we’ll dig into how it stacks up in terms of speed, reliability, and whether that shiny finish is more than just for show.
The packaging is pretty slick, coming in a compact black box. Right up front, you get a good look at the DDR5 RAM you’re about to unbox. It highlighted the RGB compatibility, which works with major lighting setups like ASUS Aura Sync, MSI Mystic Light, GigaByte’s RGB Fusion 2.0, and ASROCK Polychrome SYNC. Plus, the front gives a shoutout to the Lifetime Warranty, so you can chill knowing you’re covered.
On the back, you’ll find the memory kit’s description in several languages, showing off how Netac reached globally. There’s also a small sticker that gives you the lowdown on the RAM’s timings, handy for anyone thinking about overclocking and compatibility with your existing RAM.
Once you get past the cover, there’s another black box waiting for you. This one’s solid and holds the DDR5 memory itself. It’s got a minimalist matte vibe, featuring just the NETAC logo in shiny silver at the center.
When you open up that second box, you’ll find the DDR5 memory snug in a soft foam tray to keep it safe from any drops. And yep, the RAM is wrapped in protective plastic. If you’re wondering how shiny that plate is, just wait until you peel off that plastic.
The Netac Z RGB DDR5 Memory
After you take off the plastic, you’ll see this RAM is seriously shiny—so much so that taking a clear photo is a challenge, this thing reflects like a mirror. Although it doesn’t have a fingerprint-resistant coating, a provided cleaning cloth ensures it stays spotless. Given that you won’t frequently touch it once it’s installed on the motherboard, the absence of a coating isn’t a significant concern. The RAM rocks a carved ‘Z’ design that adds some flair. On one side, you’ll find a sticker that lists all the important specs. The other side looks the same, just without the sticker info.
The Netac logo is in the top-right corner and also shows up in the top-left corner at the back of the memory. Plus, there’s a warranty sticker at the top-left as well covering the other screws.
Snap a few pics from various angles, and you’ll notice the plate’s color morphs. While it’s technically silver, the reflective finish makes it look like it can be any color you want. This means it’ll effortlessly adapt to whatever color scheme you’ve got going on in your PC rig. Convenience when switching from a black PC rig to a white PC rig.
The top part of the RAM, where the Netac logo is, looks brownish-black initially. But once you shine some light underneath, it’s actually transparent.
Once you pop this RAM into your rig, the RGB lights start doing their thing. The colors can sync up with your rig’s settings, but right out of the box, you get the classic rainbow effect.
If you’re wondering how the RGB lights appear in various lighting settings, take a bright room for example. The RGB colors sort of resemble the hues you’d see in a test tube filled with colored liquid.
In low light or even complete darkness, the RGB effects shine just like you’d expect from regular RGB memory.
Also, if you check out the bottom left corner, you’ll spot the Netac logo stamped on the memory kit.
Next, we’re diving into performance. We’ve got a lineup of benchmarking tools ready to see how this DIMMS holds up. Specifically, we’ll be testing its default stock speed of 4,800MHz, as well as the overclocked XMP profile at 6,200MHz.
For our tests, we’ll be using the following setup:
- CPU: AMD Ryzen 9 7900 12-Core Processor (Stock Cooler)
- Motherboard: GIGABYTE X670 GAMING X AX Motherboard
- RAM Memory: Netac Z RGB DDR5-6200Mhz 32GB (2x16GB)
- Graphics Card: NVIDIA GeForce 3070 Founders Edition
- Storage: Netac NV7000-T 1TB SSD
- OS: Windows 11 Pro
First up, we’re going to dig into some important specs for this RAM, specifically its timing options. Currently, there’s one XMP profile to choose from. For standard JEDEC timings, you’ve got two based frequency of 2,400MHz (effective frequency of 4,800MHz) options: one with a 42 CAS Latency and another with just 40.
As you can see, the default stock speed actually operates on the JEDEC #6 standard. This gives us a 2,400MHz base frequency (or effective frequency 4,800MHz) with timings set at 40-40-40-77, all running at 1.10V.
AIDA64 Cache & Memory Benchmark
This tool is the most popular benchmarking tool used in the tech world. It provides comprehensive details about your system’s cache and memory performance. Not only does it measure the raw speed of your RAM, but it also tests latency and the efficiency of your memory cache. These metrics are super important for understanding how well your RAM is performing in real-world scenarios.
At its stock speed of 4,800MHz, the memory demonstrated Memory Read speeds of 60,245 MB/s, Memory Write speeds of 64,369 MB/s, and Memory Copy speeds of 56,173 MB/s, accompanied by a latency of 84.4 ns.
However, when pushed to its 6,200MHz potential, the memory kit truly shone. The Memory Read speed soared to 79,915 MB/s, marking a 32.65% increase from the stock speed. Similarly, Memory Write speeds rose to 81,662 MB/s, indicating a 26.85% boost. Memory Copy wasn’t left behind, either, reaching speeds of 70,215 MB/s—an uplift of 25.04%. In terms of latency, which is crucial for memory responsiveness, there was a reduction to 73.1 ns, translating to a 13.39% improvement.
Super Pi Mod 2.1 WP
Another tool we’re using for our benchmarking journey is Super Pi Mod. While this might initially seem like it’s all about calculating Pi, it’s actually a valuable utility for RAM benchmarking. It’s particularly great for stressing the system to its limits and testing the efficiency and speed of the memory in complex calculations. The tool is widely trusted and frequently used in overclocking competitions, making it a reliable measure for evaluating RAM performance.
At its stock configuration, the memory recorded a completion time of 5 minutes, 40 seconds, and 219 milliseconds. When pushed to its overclocked potential, a marginal yet valuable improvement was observed: the task was accomplished in 5 minutes, 38.703 seconds. This translates to a 0.47% faster computation time.
Next, we’re also including the WinRAR Benchmark in our testing toolkit. While WinRAR is commonly used for compressing and decompressing files, it also has a built-in benchmarking function. This is particularly useful for assessing memory performance because file compression and decompression are memory-intensive tasks. By using this benchmark, we get a good idea of how the RAM will perform in everyday, real-world situations.
At its stock speed, the memory posted a Resulting Speed of 41,636. However, when pushed to its one-click overclock, performance shot up to register a speed of 50,110. This impressive jump represents a 20.33% increase in archiving speed.
Another vital tool we’re employing is Cinebench R23. Known for its prowess in benchmarking CPUs, it’s also quite useful for evaluating memory performance. Cinebench R23 puts your system through various demanding tasks that mimic real-world applications and workloads. By doing this, it helps us gauge how well the RAM can handle complex computing scenarios, especially those that require quick data access and storage. This makes it an excellent tool for understanding your memory’s limitations or capabilities.
Interestingly, when examining the Single Core CPU results, both the baseline and overclocked settings yielded virtually identical outcomes: 1942 pts and 1946 pts, respectively. This mere 0.21% improvement in the overclocked setting underscores the consistent performance of the memory kit in single-threaded tasks.
However, a shift is seen when we delve into the Multi-Core results. The baseline setting reported a commendable score of 24,927 pts. Yet, when the memory was overclocked, there was a drop to 23,802 pts, amounting to a 4.51% reduction. Importantly, this decreased performance might not be attributed to the memory kit itself. Instead, indications lean towards potential CPU throttling, likely a result of the stock fan being employed in our setup. This serves as a reminder of the intertwined dynamics of system components and how a limiting factor in one can influence the performance of another.
PCMark 10 Full
Adding to our selection of benchmark tools, we have PCMark 10 Full. This is an all-in-one benchmarking suite that simulates a variety of real-world activities such as web browsing, video conferencing, and app launching. While it’s often used to evaluate overall system performance, it offers specific memory-focused tests as well. Using PCMark 10 allows us to see how our RAM kit performs in situations that mimic everyday computing tasks, giving us a well-rounded view of its capabilities.
For the stock speed, the memory yielded a score of 9,155. Yet, when the system was dialed up to its overclocked limits, the performance saw an uptick, registering a score of 9,381. This represents an enhancement of approximately 2.47% over the stock setting.
PCMark 10 Application
Continuing with our series of tests, we’re also using PCMark 10 Application. This specialized benchmark focuses on real-world application performance, running actual Microsoft Office and Microsoft Edge for its tests. Although it may seem like it’s all about the CPU, your RAM is also put to the test here, affecting how efficiently these applications operate. By including this benchmark, we can get a practical sense of how the RAM performs in commonly used professional software.
The Netac Z RGB DDR5-6200 memory kit in its stock configuration achieved a score of 16,523. When overclocked, the score saw a modest rise to 16,827, marking a 1.84% improvement over the stock setting.
PCMark 10 Express
Next on our benchmarking agenda is PCMark 10 Express. This streamlined version of the PCMark suite is designed for quick performance assessment and is less demanding than the full version. Though it might seem lighter, it still covers essential areas such as web browsing, video conferencing, and app start-up times. This makes it a good choice for those interested in gauging how the RAM contributes to general, everyday computing tasks. It adds another layer to our comprehensive testing approach.
In its stock configuration, the Netac Z RGB DDR5-6200 memory kit registered a score of 7,235. Upon overclocking, the score nudged up to 7,330, indicating a 1.31% enhancement.
3D Mark – Time Spy Benchmark
Moving on to something a bit more visually intensive, we have the 3DMark Time Spy Benchmark. This is a DirectX 12 benchmark test for gaming PCs running Windows 10 and Windows 11. It features a multi-level demo that renders sequences full of detail, all designed to put strain on the GPU and CPU alike. But what does this have to do with RAM? Well, your memory plays a role in how smooth these sequences run, which in turn affects your in-game experience. By using this benchmark, we’ll get a glimpse into how well this RAM kit can handle more graphically demanding tasks.
In its stock configuration, tallied a score of 13,192. After being overclocked, the score edged up to 13,429, reflecting a 1.79% boost in performance.
Shifting gears, we delve into the realm of virtualization with the LDPlayer Antutu Benchmark. LDPlayer is a popular Android emulator, and Antutu is one of the most recognized mobile device benchmarking apps. You might wonder, ‘Why test mobile benchmarks on a gaming PC?’ The answer is simple: Virtualization is another form of demanding computing. Good RAM can significantly improve the emulator’s performance, making this test an interesting measure of how well this memory kit fares when running complex applications within a virtual environment.
During the Virtualization testing with LD Player using the Antutu Benchmark, the Netac Z RGB DDR5-6200 memory kit recorded a score of 3,202,895 in its stock configuration. When overclocked, the performance rose to 3,329,294, marking a 3.95% increase.
Next up is a benchmark that gamers will especially appreciate: Cyberpunk 2077’s in-game test. This benchmark doesn’t just stress your GPU and CPU; it also puts your RAM through its paces. With the game’s intricate settings and dynamic AI, the performance of your memory can have a noticeable impact on gameplay smoothness.
In Cyberpunk 2077, version 2, the stock configuration delivered an average FPS of 71.81. When overclocked, this figure climbed to 73.44, representing a 2.27% improvement.
A Total War Saga: Troy Benchmark
This benchmark challenges not just your graphics card but also gives a robust workout to your memory. With detailed battle simulations and vast, open maps, your RAM’s speed and capacity can make a crucial difference in how the game runs.
In the A Total War Saga: Troy Benchmark, two distinct tests were conducted. For the first test, the stock configuration rendered an average FPS of 144.7, which rose to 147.2 when overclocked, indicating a 1.73% increase. In the second test, the stock setup achieved 192.4 FPS, which jumped to 200.4 FPS with overclocking, showcasing a 4.15% enhancement.
Shadow of the Tomb Raider
This action-adventure game is known for its lush graphics and complex environments. The game’s built-in benchmark tests multiple aspects of your system, including your memory. It’s a solid measure of how well your RAM will handle gaming loads, especially in scenarios requiring fast data access.
The stock configuration produced an average FPS of 205. Upon overclocking, this number increased to 214, marking a 4.39% boost in performance.
Ragnarok Origin SEA PC
Developed using the Unity engine, Ragnarok Origin is a popular MMORPG that tests your PC’s ability to handle complex interactions and real-time rendering, but it’s generally easier on the RAM compared to other titles. It’s a good yardstick for seeing how your memory performs under less stressful conditions, typical of many modern MMORPGs.
Both the stock and overclocked configurations delivered identical FPS results. This consistency could be attributed to various factors, such as the game’s optimization or the potential that the game’s engine or inherent frame rate limits might be capping performance at a certain threshold, preventing the overclocked memory from showcasing its advantage.
After rigorously testing, we can now examine how it measures up to its competitors in the market. We will juxtapose the performance metrics we’ve gathered in this review against those of other RAM kits, providing a comprehensive look at where this particular memory stands.