HMCT14AEERA147N Hynix 256GB DDR5-4800MHz ECC Memory Module PC5-38400

Highlights of Hynix HMCT14AEERA147N 256GB RAM

Key Specifications

• Manufacturer: Hynix
• Part Number: HMCT14AEERA147N
• Product Name: 256GB DDR5 SDRAM Memory Module

Memory Capacity and Technology

• Total Capacity: 256GB
• Memory Type: DDR5 SDRAM
• Number of Modules: Single module of 256GB

Performance Specifications

• Bus Speed: 38400MHz DDR5-4800/PC5-38400
• Data Integrity: ECC (Error-Correcting Code)
• Signal Processing: Registered (RDIMM)
• CAS Latency: CL46
• Rank Configuration: 8Rx4

Physical Attributes

• Form Factor: 288-pin RDIMM
• Dimensions: 1.00 inches in height, 6.75 inches in depth
• Weight: Approximately 0.20 lbs

Hynix HMCT14AEERA147N 256GB PC5-38400 RAM Overview

The Hynix HMCT14AEERA147N 256GB PC5-38400 DDR5-4800MHz ECC Memory Module represents a major advancement in next-generation server memory design, providing exceptional performance, stability and density for enterprise-grade environments. Within modern high-intensity data centers, memory capacity, bandwidth and reliability play decisive roles in determining overall operational efficiency. This module belongs to the expanding category of high-capacity DDR5 ECC server memory solutions engineered for compute-intensive workloads, virtualization clusters, hyperscale infrastructures and multi-tenant cloud frameworks. Systems relying on large data pools, parallelized processes and continuous multi-threaded operations gain substantial benefits from the improved electrical design, larger banks and smarter transaction management available through DDR5 technology. By offering an immense 256GB capacity in a single module, the HMCT14AEERA147N supports platforms that require dense configurations to maintain elevated throughput and consistent performance even under demanding operational pressures.

DDR5-4800MHz Technology

DDR5 architecture introduces transformative enhancements in memory throughput due to wider channels, increased burst lengths and more efficient refresh cycles. Operating at 4800MHz, the Hynix HMCT14AEERA147N delivers exceptional bandwidth to support workloads involving high-volume data streams. As server processors continue evolving with rising core counts, memory subsystems must supply sufficient data to avoid bottlenecks. DDR5’s improved channel architecture enables simultaneous data handling across dual independent 32-bit sub-channels, significantly reducing latency and enhancing parallel process efficiency. The module’s PC5-38400 rating underscores its ability to deliver sophisticated bandwidth levels, which are essential in systems demanding fast data access, real-time analytics and rapid-fire computational tasks. The architectural revisions also produce superior efficiency by offering dynamic refresh management, adaptive voltage regulation and advanced power control, culminating in an optimized performance envelope that aligns with enterprise demands.

Enhanced Signal Integrity for Data-Heavy Server Infrastructure

Signal clarity and electrical balance remain essential for consistent server operation. DDR5 utilizes on-module power management integrated circuits that enhance voltage precision, stabilizing performance even under significant workload fluctuations. The Hynix HMCT14AEERA147N leverages this design to provide higher resilience to variable power conditions, ensuring that data-intensive applications can execute without the disruptions historically associated with rapid load shifts. Furthermore, the increased bank groups, extended burst lengths and redesigned command structure contribute to minimized signal contention. In large-scale deployments, memory stability directly correlates with application reliability, and DDR5 represents a significant stride forward in minimizing risk factors tied to memory misreads or timing deviations.

High-Capacity Architecture Supporting Dense Server Memory Configurations

Enterprises increasingly depend on dense memory layouts to deliver superior computational throughput. The 256GB configuration of the Hynix HMCT14AEERA147N aligns with current trends toward maximizing performance per physical server unit. This capacity provides extensive headroom for virtual machine expansion, in-memory processing frameworks, scientific modeling, and large-scale data simulations. Memory-bound workloads such as massive relational database engines or enterprise resource planning systems operate more efficiently when equipped with larger direct-access memory pools. The ability to maintain expansive memory resources reduces paging operations, decreases latency spikes and provides a smoother operational landscape for mission-critical workloads. This single-module density enables administrators to increase total memory capacity without overcrowding the DIMM slot allocation, a valuable advantage in servers limited by physical channel availability.

ECC Reliability for Mission-Critical Environments

Error-Correcting Code (ECC) memory plays a crucial role in enterprise servers and professional-grade computing systems. Data integrity becomes increasingly essential as organizations move toward real-time data exchanges, big data analytics and continuous availability environments. The Hynix HMCT14AEERA147N incorporates robust ECC capabilities that detect and correct common types of memory data corruption before they can impact operations. This proactive protection helps avoid service interruptions, application failures and potential data loss. ECC is indispensable for high-reliability applications within sectors such as finance, medical computing, research institutions, telecommunications, and cloud platforms that require 24/7 operational consistency. As data complexity rises, ECC support enables organizations to maintain compliance requirements and operational trust by safeguarding memory transactions with continuously verified accuracy.

Advanced Data Correction Algorithms Enhancing System Stability

Modern ECC memory surpasses simple single-bit correction mechanisms by integrating refined algorithms capable of identifying and correcting a broader spectrum of memory errors. The HMCT14AEERA147N benefits from sophisticated fault isolation that analyzes error patterns to determine whether they stem from random interference or emerging component issues. This analytical capability allows administrators to detect potential hardware degradation before it compromises overall system performance. In large clusters, memory faults can propagate rapid system instabilities, making early correction essential. With advanced ECC layers, the module provides an efficient safeguard that maintains service uptime across even the most resource-intensive deployments.

Improved RAS Features for Enterprise Reliability Requirements

Reliability, Availability and Serviceability (RAS) features form the backbone of modern server architecture. DDR5 memory modules like the Hynix HMCT14AEERA147N integrate enhanced RAS capabilities to support predictive failure analysis, improved fault reporting and superior thermal management. Combined with ECC’s active protective measures, these enhancements strengthen system resilience and deliver long-term operational stability. Organizations seeking to reduce downtime cost and maximize service continuity view RAS-enhanced memory as an indispensable asset in crafting a highly dependable computing infrastructure.

Benefits in Virtualized and Cloud-Scale Deployments

Virtualized platforms rely heavily on memory density and bandwidth to maintain stable multi-tenant performance. As businesses expand digital services, the ability to run numerous virtual machines or containers per host becomes increasingly critical. The 256GB capacity of the Hynix HMCT14AEERA147N module enables significant consolidation of virtual workloads, reducing hardware footprint while optimizing efficiency. With DDR5’s increased parallelism and improved queue efficiency, virtual machines can benefit from low-latency memory access even when hosting diverse, memory-heavy applications. The enhanced throughput assists hypervisors in executing scheduling tasks without delays, thus improving overall user responsiveness and operational reliability.

Scalability Advantages for Growing Infrastructure Demands

Server infrastructure growth hinges on the ability to scale memory resources in alignment with computational expansion. The HMCT14AEERA147N supports large-scale deployments requiring flexible resource allocation. In cloud computing environments where workloads rise and fall based on user demand, memory scalability ensures seamless service delivery without performance dips. Systems designed for horizontal expansion find added value in DDR5 modules that sustain high transfer speeds while accommodating significant memory spaces. Whether supporting cloud hosting clusters, distributed computing networks or virtualization-as-a-service platforms, this memory module aligns with modern scalability requirements.

Enhanced Multi-Threaded and Parallelized Process Support

The increased number of cores in latest-generation processors demands memory capable of feeding data across many parallelized operations. DDR5 architecture provides expanded bank structures and superior access timing, enabling high-volume command processing with reduced contention. The Hynix HMCT14AEERA147N excels in multithreaded environments such as AI workloads, container orchestration, large-scale data transformation engines and real-time transactional systems. Improved queue handling minimizes slowdowns during peak usage, making the module a critical component for businesses that rely on simultaneous high-priority tasks.

Compatibility with Enterprise-Grade Server Platforms

Server platform compatibility plays a critical role in selecting memory modules for professional environments. The Hynix HMCT14AEERA147N adheres to DDR5 JEDEC standards, ensuring seamless integration with next-generation server architectures. Manufacturers designing boards for high-performance compute applications implement support for modules like this, allowing users to maximize memory density without compromising stability. This ensures reliable operation in systems built for virtualization, cloud computing, high-throughput databases and advanced research pipelines. Compatibility with server-grade chipsets further strengthens performance, guaranteeing that bandwidth and timing characteristics match motherboard specifications.

Optimized Thermal Performance for Continuous Operation

Thermal stability remains essential for memory longevity and performance consistency. The HMCT14AEERA147N employs efficient thermal distribution mechanisms, ensuring reliable operation throughout prolonged high-intensity workloads. DDR5’s improved efficiency reduces power draw per transferred bit, allowing sustained bandwidth without excessive heat generation. Data centers operating under high thermal loads appreciate memory solutions engineered to maintain predictable performance even under significant stress. This optimized thermal behavior assists administrators in maintaining balanced cooling strategies without necessitating aggressive power scaling or performance throttling.

Energy-Efficient Features Supporting Sustainable Computing

Sustainable infrastructure practices are increasingly embraced by organizations worldwide. DDR5 modules introduce lower operating voltages, advanced power management and granular control over refresh cycles. The Hynix HMCT14AEERA147N leverages integrated power management ICs to monitor and distribute power more efficiently, reducing wasted energy during idle or low-activity states. In hyperscale environments where servers operate non-stop, even minor reductions in power consumption can translate into considerable savings and reduced environmental impact. This makes DDR5 memory a forward-looking choice for companies aiming to balance performance with sustainability goals.

Data-Intensive Application Efficiency

Data-intensive workloads within fields such as biomedical modeling, AI training, machine learning research and large-scale business intelligence require significant memory support to handle vast arrays of complex datasets. The Hynix HMCT14AEERA147N, with its 256GB capacity, ensures that applications involving high-volume memory allocation run smoothly without resorting to slower secondary storage. In-memory analytics benefit greatly from large DDR5 modules that can temporarily store diverse datasets for immediate access, drastically improving response times. High-frequency trading platforms, scientific simulations and real-time monitoring systems experience enhanced performance due to expanded memory buffers that allow rapid calculation cycles without latency setbacks.

Improved Throughput for Scientific and Engineering Simulations

Scientific computing environments consist of models and simulations involving multi-layered data points requiring fast and efficient memory handling. DDR5’s increased bandwidth and larger internal structures allow computation engines to operate on large datasets with fewer delays. Engineers and researchers using simulation software, modeling frameworks and real-time data analysis tools benefit from the HMCT14AEERA147N’s ability to maintain speedy access across large multi-dimensional data repositories. When simulations require multiple simultaneous data access operations, DDR5’s dual independent channels provide significant improvements over prior generations.

Enterprise Database Performance Supported by High-Density Modules

Databases remain central to enterprise operations, and performance is deeply influenced by available memory resources. Large memory modules such as the HMCT14AEERA147N allow database engines to store more index tables, cache data and maintain simultaneous transactions with greater fluidity. This leads to shorter query times, faster transaction resolution and improved stability during high-concurrency activity. Memory-rich configurations lower I/O strain and create a more consistent environment for large ERP systems, data lakes and analytics engines handling real-time traffic.

Future-Proofing Server Infrastructure with DDR5 ECC Memory

Businesses planning long-term infrastructure strategies view DDR5 memory as a future-proof investment. As operating systems, hypervisors and application frameworks evolve, they increasingly leverage the expanded capabilities of DDR5 architecture. The Hynix HMCT14AEERA147N’s combination of high density, ECC protection, advanced performance metrics and power efficiency positions it as an ideal choice for forward-looking server deployments. Future hardware generations are expected to increase memory frequency and utilize enhanced parallelism, making DDR5 memory a stable foundation for years of growth. Deploying high-capacity modules today ensures smoother transitions into more demanding compute eras without requiring premature system overhauls.

Preparation for Evolving AI and Cloud-Native Technologies

Artificial intelligence, machine learning and cloud-native development all place significant pressure on memory performance. Larger datasets, sophisticated computation cycles and expanded container orchestration require robust memory support to avoid performance bottlenecks. The HMCT14AEERA147N’s high capacity and rapid bandwidth reduce constraints that would otherwise limit AI training throughput or cloud application responsiveness. As enterprises move toward continuous development and deployment cycles, they benefit from memory modules capable of supporting dynamic computational demands across distributed networks.

Supporting Edge Compute and Hybrid Cloud Models

Hybrid environments combining on-premises and cloud resources depend on reliable hardware to sustain workload distribution and real-time processing. DDR5 ECC memory modules like this provide the durability required for edge compute installations that operate in resource-intensive or latency-sensitive scenarios. With enhanced error correction and power efficiency, the HMCT14AEERA147N ensures consistent performance whether used in centralized data centers or distributed edge systems.

Robust Server Ecosystem Performance

Hynix continues to be a leading innovator in enterprise memory design, and the HMCT14AEERA147N showcases the brand’s commitment to developing technologies that align with modern data center priorities. Systems utilizing high-capacity DDR5 ECC modules benefit from improved efficiency, stability and throughput across a diverse range of applications. Whether supporting virtual machines, handling large datasets, enabling real-time analytics or managing multi-tenant workloads, this module delivers an elevated performance standard. As computing systems grow increasingly complex, robust memory foundations become indispensable for achieving sustained reliability and productivity.