Thursday, January 16th 2025
G.Skill Announces DDR5-6400 CL30 96GB (2x 48GB) Low-Latency Memory Kits
G.SKILL International Enterprise Co., Ltd., the world's leading brand of performance overclock memory and PC components, is announcing the release of low latency DDR5-6400 CL30-39-39-102 memory specification in high-capacity kit configurations, up to 96 GB (2x 48 GB) kit capacity. This high performance memory kit specification will be available under the Trident Z5 RGB and Trident Z5 Royal series, with Intel XMP 3.0 memory overclock profile support.
The G.SKILL DDR5-6400 CL30 memory kit at 96 GB (2x 48 GB) combines high-capacity and low-latency to enable higher performance for memory intensive platforms and uses. The screenshot below shows this 96 GB (2x 48 GB) memory kit operating at DDR5-6400 CL30-39-39-102 with the ASUS ROG Maximus Z890 Hero motherboard and Intel Core Ultra 7 265K desktop processor.
Demonstrating DDR5-6400 CL30 96 GB (2x48GB) on AMD AM5 Platform
Under extensive research and development, G.SKILL is also demonstrating the possibility of this low-latency, high-capacity memory kit running on the new AMD Ryzen 9000 series CPU and AMD X870 chipset motherboard. The following screenshot showcases a 96 GB (2x 48 GB) memory kit operating at DDR5-6400 CL30-39-39-102 with the ASUS ROG Crosshair X870E Hero motherboard and AMD Ryzen 7 9800X3D desktop processor.
Overclock Profile Support & Availability
This new DDR5-6400 CL30 specification supports the Intel XMP 3.0 memory overclock profile under the Trident Z5 RGB and Trident Z5 Royal memory series for easy memory overclocking via the motherboard BIOS on supported platforms. In addition to the large 96 GB (2x 48 GB) kit capacity, 64 GB (2x 32 GB) and 48 GB (2x 24 GB) capacity kits are also slated for release. These memory kits will be rolling out to G.SKILL worldwide distribution partners starting in Q1 2025.
The G.SKILL DDR5-6400 CL30 memory kit at 96 GB (2x 48 GB) combines high-capacity and low-latency to enable higher performance for memory intensive platforms and uses. The screenshot below shows this 96 GB (2x 48 GB) memory kit operating at DDR5-6400 CL30-39-39-102 with the ASUS ROG Maximus Z890 Hero motherboard and Intel Core Ultra 7 265K desktop processor.
Under extensive research and development, G.SKILL is also demonstrating the possibility of this low-latency, high-capacity memory kit running on the new AMD Ryzen 9000 series CPU and AMD X870 chipset motherboard. The following screenshot showcases a 96 GB (2x 48 GB) memory kit operating at DDR5-6400 CL30-39-39-102 with the ASUS ROG Crosshair X870E Hero motherboard and AMD Ryzen 7 9800X3D desktop processor.
Overclock Profile Support & Availability
This new DDR5-6400 CL30 specification supports the Intel XMP 3.0 memory overclock profile under the Trident Z5 RGB and Trident Z5 Royal memory series for easy memory overclocking via the motherboard BIOS on supported platforms. In addition to the large 96 GB (2x 48 GB) kit capacity, 64 GB (2x 32 GB) and 48 GB (2x 24 GB) capacity kits are also slated for release. These memory kits will be rolling out to G.SKILL worldwide distribution partners starting in Q1 2025.
6 Comments on G.Skill Announces DDR5-6400 CL30 96GB (2x 48GB) Low-Latency Memory Kits
16 GB x2 kits?
Question is... DDR5 6000 CL 26 or DDR5 6400 CL30?
Otherwise, you're trading like 1/2 billionth of a second latency difference, if that.
This one is dual rank (32GB/48GB).
If you have 6000 CL 30 and ran them 6400 CL 30, that would lower the latency. Your don't need to tighten Cas latency to lower it.
Also, the cpu overclock will lower memory latency.
And increasing IF frequency will lower memory latency.
I have a 14700K, so can't test theories on AMD systems, but when I want true performance and low latency, I concentrate on Cache OC. For AMD, that would be similar to IF overclocking.
But just setting XMP and go, you're not lowering latency a great deal from 8000 CL 38 to 6000 CL 30. But you will be reducing bandwidth by 1000mhz (2000mt/s).
In short, these are small differences that people take time and tweak to lower latency as much as possible. If you're willing to put in the time and effort anyways.