HMCT14AGERA204N Hynix 256GB 5600Mhz Pc5-44800 Ecc Registered Octal Rank X4 1.2v RAM Module For Server

Highlights of Hynix 256GB 5600Mhz RAM

The Hynix HMCT14AGERA204N 256GB DDR5 SDRAM memory module delivers exceptional speed and reliability for advanced computing systems. Designed with cutting-edge technology, this registered DIMM ensures seamless performance for enterprise and high-demand environments.

Product Information

• Manufacturer: Hynix
• Model Number: HMCT14AGERA204N
• Product Type: Memory Module

Technical Highlights

• Capacity: 256GB
• Memory Type: DDR5 SDRAM
• Module Count: 1 x 256GB

Performance Specification

• Bus Speed: 5600MHz DDR5-44800 / PC5-5600MHz
• Error Correction: ECC (Error-Correcting Code)
• Signal Processing: Registered
• Latency: CL52
• Rank Features: 8Rx4

Physical Characteristics

Form Factor

• Design: 288-pin RDIMM

Dimensions and Weight

Shipping Measurements

• Height: 1.00 inches
• Depth: 6.75 inches

Shipping Weight

• Weight: 0.20 lb

Hynix HMCT14AGERA204N 256GB DDR5 Memory Overview

The Hynix HMCT14AGERA204N 256GB 5600MHz PC5-44800 CL52 DDR5 SDRAM 288-pin RDIMM memory module represents a highly advanced class of enterprise-grade system memory engineered for next-generation server infrastructures. This category focuses on extremely high-capacity modules that support modern data-driven workloads, enabling improved multitasking, enhanced throughput efficiency, and optimized application performance across cloud computing environments, virtualization frameworks, and advanced computational fields. As memory demand continues to rise due to rapidly expanding datasets, this class of high-density DDR5 RDIMM modules supports architectural enhancements necessary to maintain system stability and overall performance consistency in enterprise deployments.

Advancements of High-Capacity DDR5 RDIMM Memory

DDR5 introduces a wide range of engineering improvements over DDR4, establishing a new benchmark for bandwidth, scalability, energy management, and data integrity. Modules in this category leverage new circuit layouts, refined signaling, dual-channel DIMM architecture within a single module, and doubled burst lengths to create a more efficient memory platform capable of meeting the requirements of today’s high-intensity workloads. With the Hynix HMCT14AGERA204N model offering a massive 256GB storage capacity, it demonstrates the importance of next-generation design in providing faster data access cycles, reduced latency variations, and efficient parallel processing across computational cores.

Enhanced Signaling and Optimized Data Throughput

One of the defining characteristics of this memory class is its support for 5600MHz data transfer rates, corresponding to the PC5-44800 classification. This bandwidth ensures that server-class processors can access large data arrays without bottlenecks, significantly improving real-time computing, database indexing, and multi-layered virtualization operations. The refined signaling mechanisms reduce noise interference and maintain signal integrity even under heavy processing loads. For IT professionals implementing memory-dense configurations, this ensures predictable performance scaling and consistent throughput regardless of environmental conditions or workload variations.

Improved Burst Length and Dual Sub-Channel Architecture

DDR5 memory utilizes a longer burst length, enabling larger packets of data to be transferred in each cycle. This directly improves the overall throughput potential during high-intensity workloads such as live data streaming, scientific simulations, machine learning model training, and high-transaction database services. Internal dual sub-channel architecture enhances parallelism, reducing efficiency loss during partial memory fetch operations and providing more evenly distributed access pathways. The Hynix HMCT14AGERA204N module maximizes these capacities, delivering notable improvements in real-world application responsiveness.

Category Focus on Enterprise-Level Reliability and Data Integrity

High-capacity DDR5 RDIMMs must meet strict reliability standards due to their deployment in mission-critical systems. The registered design improves signal stability across the memory controller, ensuring larger modules remain operational even under heavy system stress. Enterprise modules often operate in multi-socket servers where memory loads exceed several terabytes; therefore, signal conditioning and timing coordination must be exceptionally precise. The Hynix HMCT14AGERA204N category emphasizes error management, thermal regulation, and system-level compatibility to minimize downtime and maintain operational continuity.

Advanced ECC and On-Die Error Correction Architecture

Error correcting capabilities are fundamental to the stability of enterprise-grade memory. DDR5 expands error control techniques by adding On-Die ECC to each DRAM die in addition to standard server-level ECC. This protects data from corruption caused by electrical interference, cosmic radiation, or cell degradation. These modules ensure accuracy and prevent inconsistencies during memory-intensive operations such as analytics processing, AI inference workloads, or large-scale cloud resource management. With growing demand for precision in computational models, the data integrity enhancements in this category offer critical protection for organizations relying on uninterrupted server functionality.

Integrity Monitoring and Predictive Failure Analysis Support

Within this category, memory modules often interact with platform-level reliability frameworks that provide monitoring insights to administrators. Real-time integrity checks, thermal measurements, and adaptive error logging allow predictive maintenance strategies and reduce potential service interruptions. Servers equipped with the Hynix HMCT14AGERA204N memory module can benefit from improved lifecycle management, allowing IT teams to allocate resources and plan system upgrades with higher confidence.

Benefits of Ultra-High-Capacity 256GB DDR5 RDIMMs

Memory configurations utilizing 256GB modules provide immense advantages for compute-heavy workflows. These benefits transform the responsiveness and scalability of servers, particularly when handling complex datasets, running several hypervisors, or supporting multi-tenant cloud infrastructure. With its 5600MHz speed and robust latency calibration, the Hynix HMCT14AGERA204N excels in balancing power efficiency and performance output.

Optimized Environment for Virtualization and Multi-Threaded Processing

Virtual machines, containerized applications, and distributed compute environments rely heavily on available system memory. High-capacity modules such as the Hynix 256GB DDR5 RDIMM support multiple concurrent VMs without compromising performance, ensuring consistent application execution. Enhanced bandwidth reduces context switching delays and improves throughput across simultaneous operations, enabling organizations to scale workloads dynamically while maintaining operational stability.

Support for Data-Heavy Computational Frameworks

Scientific computation, AI training workloads, deep learning inference engines, and large data modeling operations demand extremely high memory bandwidth and storage per module. This memory category enables servers to store significantly larger datasets directly in RAM, reducing the need for continuous disk access and allowing faster algorithmic processing. Hosting larger models in-memory accelerates research environments, reduces training cycles, and supports more advanced architectures in real-time.

Workload Specific Optimization Through High-Bandwidth Memory

High-bandwidth memory modules support optimized task execution by reducing cycle delays and lowering data fetch latency. This benefit becomes particularly clear when processing multi-gigabyte arrays, running high-resolution simulations, or performing real-time prediction tasks in financial analytics and medical research platforms. With the Hynix HMCT14AGERA204N, servers can significantly expand resource allocation, supporting more advanced computational instructions across varied industries.

Scalable Infrastructure for Enterprise Data Centers

Modern data centers require components capable of scaling efficiently as capacity demands increase. Deploying high-density DDR5 RDIMM modules allows IT teams to expand server memory without needing additional hardware, reducing operational footprint and lowering long-term cost. The Hynix HMCT14AGERA204N fits into modern multi-channel memory architectures, giving system builders flexibility when designing powerful and scalable compute nodes.

Reduced Bottlenecks in Multi-CPU and Multi-Memory Channel Systems

High-end servers employing multi-socket CPU systems require efficient memory distribution across all channels to prevent bottlenecks. DDR5 technology provides improved power management and enhanced memory efficiency that align with the requirements of modern processors. The increased prefetch size and more sophisticated memory controller interactions ensure that even data-intensive processes experience uninterrupted access cycles across all active threads.

More Efficient Deployment Across Hybrid Cloud Architectures

Businesses adopting hybrid cloud strategies depend on infrastructure components that integrate smoothly across on-premise hardware and virtualized data frameworks. High-capacity DDR5 RDIMMs offer the reliability and speed necessary to maintain consistency when scaling operations across multiple environments. The Hynix HMCT14AGERA204N facilitates workload portability and maintains operational responsiveness across dynamic deployment structures.

Architectural Enhancements Unique to DDR5 Technology

The category of DDR5 RDIMM memory expands performance horizons through architectural innovations that significantly surpass older generations. These design improvements include enhanced bank structure, better refresh operations, improved channel organization, and more intelligent power regulation circuitry integrated directly into the module.

Advanced Bank Group and Refresh Operation Design

DDR5 increases bank groups and introduces more flexible refresh schemes to reduce delays. This results in improved performance during continuous read and write operations, particularly when handling large and fragmented datasets. Optimized refresh cycles reduce system wait times and contribute to a smoother and more efficient performance curve.

Smarter Power Management Using On-Module PMIC

DDR5 relocates important power management functions onto the module itself via an integrated PMIC. This provides more balanced voltage regulation, reduced ripple, and precise power allocation to each memory section. Servers benefit from improved energy efficiency, lower electrical stress, and enhanced module stability even under demanding loads. The Hynix HMCT14AGERA204N delivers consistent power performance that supports long operational cycles.

Higher Component Density and Improved Thermal Distribution

Large-capacity RDIMMs require efficient thermal balancing to maintain consistent module operation. DDR5 modules use enhanced PCB layering, improved heat distribution patterns, and upgraded component spacing to minimize thermal hotspots. This contributes to extended lifespan, reduced thermal strain, and optimized performance under sustained high-bandwidth activity.

Compatibility and Use Case Applications

This memory category supports enterprise servers requiring massive memory allocations. It is widely used in cloud hosting clusters, data analytics nodes, scientific computing environments, and business-critical database servers. Many organizations depend on high-density RDIMM modules to meet expanding workload requirements while reducing the need for additional server hardware.

Compatibility with Modern Server Platforms

DDR5 RDIMMs are engineered for compatibility with cutting-edge server processors from major vendors. These platforms capitalize on DDR5’s increased speed, improved multi-channel communication, and advanced reliability features. The Hynix HMCT14AGERA204N adheres to JEDEC standards, ensuring dependable interoperability with enterprise-class systems.

Support for Large-Scale Databases and In-Memory Analytics

High-density memory modules provide the capacity necessary to store frequently accessed data directly in memory, boosting query speed and minimizing response delays. This level of optimization is essential for industries involved in financial analytics, retail intelligence, supply chain planning, and scientific modeling.

Effective Resource Allocation Across Multi-Tenant Virtualized Systems

In multi-tenant environments, memory distribution efficiency determines system reliability and workload isolation. This category supports high VM densities by enabling large allocations without sacrificing stability. The consistent performance delivered by 5600MHz RDIMMs strengthens virtualization efficiency in multi-user environments.