MTC20F208XS1RC64BCZ Micron 48GB DDR5 6400MHz PC5-51200 ECC RDIMM RAM

Overview of Micron MTC20F208XS1RC64BCZ 48GB RDIMM RAM

The Micron MTC20F208XS1RC64BCZ 48GB DDR5 RDIMM memory module is designed for next-generation servers, enterprise workstations, and data center platforms. Featuring DDR5-6400 speed, PC5-51200 bandwidth, ECC protection, and Registered architecture, this server memory module delivers exceptional reliability, improved efficiency, and superior performance for demanding workloads.

General Information

• Manufacturer: Micron
• Part Number: MTC20F208XS1RC64BCZ
• Product Type: Memory Module

Technical Specifications

• Memory Capacity: 48GB
• Memory Technology: DDR5 SDRAM
• Memory Standard: PC5-51200
• Memory Speed: 6400 MHz
• CAS Latency: CL52 (52-52-52)
• Error Checking: ECC (Error-Correcting Code)
• Signal Processing: Registered (RDIMM)
• Rank Configuration: 2Rx8 Dual Rank
• Operating Voltage: 1.1V

Physical Characteristics

Module Dimensions

• Form Factor: 288-pin RDIMM
• Shipping Dimensions: 177.8 mm x 54.7 mm x 6.35 mm (7.0 x 2.15 x 0.25 inches)
• Shipping Weight: 0.20 lb (Approx. 90 g)

Compatibility

Supported Devices

• Rack servers
• Tower servers
• Enterprise workstations
• Professional motherboards supporting DDR5 RDIMM

The Micron MTC20F208XS1RC64BCZ 6400MHz PC5-51200 Ram

The Micron MTC20F208XS1RC64BCZ 48GB DDR5 6400MHz PC5-51200 1.1V Dual Rank CL52 ECC Registered 288-Pin RDIMM Server Memory Module is a high-performance enterprise-grade memory solution designed for modern data centers, cloud infrastructure, and mission-critical computing environments. Built with advanced DDR5 technology, this module delivers significant improvements in bandwidth, efficiency, and reliability compared to previous DDR4 generations. It is engineered for demanding workloads such as virtualization, artificial intelligence, high-performance computing, and large-scale database systems where consistent memory performance is essential.

Next-Generation DDR5 Architecture

DDR5 memory introduces a major leap forward in server memory technology, offering higher bandwidth, improved efficiency, and better scalability compared to DDR4. The Micron 48GB RDIMM operates at 6400MHz, enabling extremely fast data transfer between memory and CPU. This architecture is optimized for multi-core processors and parallel workloads commonly found in enterprise environments. It ensures smoother performance under heavy computational demand.

48GB High-Capacity Module

The 48GB capacity provides an optimal balance between memory density and flexibility for enterprise server configurations. It allows data centers to maximize system memory while conserving DIMM slots for future expansion. This is especially important in virtualization environments where memory allocation per virtual machine is critical. High-capacity modules help reduce hardware complexity and improve scalability.

Efficient Memory Slot Utilization

By using higher-capacity memory modules, server systems can achieve large memory configurations with fewer DIMM slots. This improves airflow, reduces heat density, and simplifies system design. It also allows for more efficient upgrade paths in enterprise environments. Efficient slot utilization is key for modern data center optimization.

Improved Virtual Machine Density per Host

The 48GB capacity enables higher virtual machine density per physical server. This improves resource utilization and reduces infrastructure costs. It supports workloads requiring multiple concurrent virtual machines. Higher density enhances overall virtualization efficiency.

6400MHz High-Speed Frequency

Operating at 6400MHz, this DDR5 RDIMM delivers exceptional memory bandwidth for data-intensive applications. High frequency ensures rapid data transfer between CPU and memory, reducing bottlenecks in processing pipelines. This is particularly beneficial for AI workloads, analytics platforms, and scientific computing tasks. Faster memory speeds improve overall system responsiveness and efficiency.

Accelerated Data Processing

High-speed memory significantly improves data processing capabilities in enterprise environments. It reduces latency and increases throughput for demanding workloads. Applications such as databases and analytics benefit greatly from this improvement. Faster processing enhances productivity and system performance.

Reduced Memory Bottlenecks in Multi-Core Systems

Modern CPUs rely heavily on memory bandwidth to deliver peak performance. The 6400MHz speed ensures efficient data flow to multiple cores simultaneously. This reduces contention and improves scalability. Reduced bottlenecks lead to smoother system operation.

PC5-51200 Standard Ensures Peak Memory

The PC5-51200 specification represents a theoretical bandwidth of 51.2GB/s, making this module suitable for high-performance enterprise workloads. This bandwidth supports data-heavy applications such as machine learning, financial modeling, and real-time analytics. It ensures processors remain fully utilized during intensive operations. High bandwidth is essential for modern server performance.

Throughput for Data-Intensive Workloads

Data-intensive applications require fast and reliable memory access. This module delivers consistent throughput to support continuous processing demands. It enhances application efficiency in enterprise systems. Optimized throughput improves workload execution speed.

Large-Scale Distributed Computing

Distributed computing systems depend on fast memory to synchronize data across nodes. The high bandwidth of DDR5 improves communication efficiency. This reduces latency in distributed workloads. It enhances scalability in cloud and HPC environments.

ECC Registered Technology

Error Correcting Code Registered DIMM architecture ensures memory reliability by detecting and correcting errors automatically. This prevents data corruption and system instability in mission-critical environments. Registered buffering improves signal integrity when multiple modules are installed. ECC memory is essential for enterprise-grade systems.

Enhanced System Uptime for Critical Applications

By preventing memory errors from affecting system stability, ECC improves uptime. This is essential for enterprise applications requiring continuous availability. It reduces downtime risks and service interruptions. Enhanced uptime supports business continuity.

CL52 CAS Latency for DDR5 Performance

The CL52 latency specification is optimized for high-speed DDR5 operation. While latency values are higher compared to DDR4, the increased frequency results in superior real-world performance. This balance ensures efficient data access and system responsiveness. It is suitable for demanding enterprise workloads.

Balanced Performance Across High-Frequency Operations

CL52 timing ensures stable operation at 6400MHz frequency. It maintains synchronization between memory controller and DRAM chips. This balance supports consistent system performance. It improves workload efficiency.

Improved Real-World Application Performance

Despite higher latency numbers, DDR5 delivers better overall performance due to increased bandwidth. Applications benefit from faster data availability. This improves user experience in enterprise systems. Real-world performance gains are significant.

1.1V Low Power Consumption

Operating at 1.1V, this DDR5 module significantly reduces power consumption compared to DDR4 memory. Lower voltage reduces heat generation and improves energy efficiency in server environments. This helps reduce cooling requirements and operational costs. Energy efficiency is critical in modern data centers.

Reduced Thermal Load in Server Environments

Lower power consumption leads to reduced heat output in dense server racks. This improves cooling efficiency and system stability. It helps maintain optimal operating temperatures. Reduced thermal load enhances hardware longevity.

Dual Rank Architecture

The dual rank design allows the memory module to access multiple sets of memory banks independently. This improves parallelism and increases effective throughput under heavy workloads. Dual rank modules often outperform single rank designs in enterprise environments. This architecture enhances system efficiency.

Improved Memory Interleaving

Memory interleaving allows simultaneous access to multiple memory banks. This reduces delays and improves data processing efficiency. It enhances performance in multi-threaded workloads. Improved interleaving boosts system throughput.

Balanced Load Distribution Across Memory Channels

Dual rank architecture distributes workloads more evenly across memory channels. This reduces bottlenecks and improves stability. It enhances overall system responsiveness. Balanced distribution improves performance consistency.

288-Pin RDIMM Form Factor for Server

The 288-pin RDIMM standard ensures compatibility with modern DDR5 server platforms. It provides stable electrical signaling and supports large memory configurations. Registered design improves reliability in multi-module systems. This form factor is widely used in enterprise servers.

Stable Electrical Signal Integrity

Registered DIMMs improve signal stability between CPU and memory modules. This reduces electrical load and enhances reliability. It ensures consistent performance under heavy workloads. Signal integrity is critical in enterprise systems.

Scalable Multi-DIMM Server Configurations

The RDIMM design supports multiple modules in a single system. This enables high-capacity memory configurations. It supports scalable enterprise deployments. Scalability is essential for modern IT infrastructure.

Cloud and Virtualization Environments

The Micron DDR5 RDIMM is ideal for cloud computing and virtualization platforms that require scalable and high-speed memory. It supports multi-tenant workloads and dynamic resource allocation. ECC protection ensures data integrity in shared environments. It improves performance consistency across workloads.

Improved Virtual Machine Responsiveness

Faster memory access improves VM responsiveness and performance. It reduces latency during workload execution. This enhances user experience in virtualized systems. Improved responsiveness is essential for cloud services.

Machine Learning and High-Performance

AI and HPC workloads require large memory bandwidth and capacity for efficient processing. This DDR5 module accelerates training and inference operations. It reduces computational delays and improves throughput. It is ideal for advanced computing environments.

Faster Machine Learning Model

Machine learning workloads benefit from high-speed memory access. This reduces training time significantly. It improves model development efficiency. Faster training enhances productivity.

Data Handling in Scientific Computing

Scientific simulations require fast memory to handle large datasets. This module improves processing efficiency. It supports complex computational models. Efficient data handling improves research outcomes. This module provides a powerful foundation for next-generation server infrastructure.