Cloud Inspired. Caching Optimized.

Key Benefits

  • An SSD optimized for cloud storage architectures

  • Optimized for caching across a range of workloads

  • Manageability to maximize IT efficiency

  • Industry-leading reliability and security

  • Designed for today’s modern data centers



Pairing a new Intel developed controller, unique firmware innovations, and industry-leading 3D NAND density, the Intel® 3D NAND SSD Data Center P4600 Series delivers an all new design to support the data caching needs of cloud storage and software-defined infrastructures. The Intel® SSD DC P4600 Series is stacked with a combination of performance, capacity, manageability, and reliability to help data centers fast-track their business and meet the overall demands of their digital business.

An SSD Optimized for Cloud Storage Architectures
The cloud continues to drive innovation, new services, and agility for businesses, which are seeing the need to deploy services faster, scale effectively, and remove the human costs of managing assets. Multi-cloud has become a core element for any enterprise strategy, with top cloud providers openly embracing PCIe*/NVMe*-based SSDs because of the scalable performance, low latency, and continued innovation.

Within the shift to the cloud is an increased adoption of software-defined and converged infrastructures. This fast adoption is being driven by the need to increase efficiency, refresh existing hardware, deploy new workloads, and reduce operational expenditures. The DC P4600 significantly increases server agility and utilization, while also accelerating applications, across a wide range of cloud workloads.

Optimized for Caching Across a Range of Workloads
This cloud-inspired SSD is built with an entirely new NVMe controller that is optimized for mixed workloads commonly found in data caching and is architected to maximize CPU utilization.

With controller support for up to 128 queues, the DC P4600 helps minimize the risk of idle CPU cores and performs most effectively on Intel platforms with Intel® Xeon® processors. The queue pair-to-CPU core mapping supports high drive count and also supports multiple SSDs scaling on Intel platforms.

With the DC P4600, data centers can accelerate caching to enable more users, add more services, and perform more workloads per server. Now you can cache faster and respond faster.

Manageability to Maximize IT Efficiency
The DC P4600 is built for software-defined cloud infra-structures across the multi-cloud environment to enable greater efficiency within existing server footprints.

New firmware manageability features help reduce server downtime through improved update processes and expanded monitoring capabilities.

SMART management and Intel custom log pages provide advanced drive telemetry to manage thermals, monitor endurance, and track drive health status. Management coverage is now expanded across a wider range of drive states with support for the NVMe-Management Interface (NVMe-MI) specification, an industry standard way to manage the SSD out-of-band.

Industry-Leading Quality, Reliability, and Security
As capacity per server continues to scale, the risk of data corruption and errors increases. With an eye toward this risk, Intel has built industry-leading end-to-end data protection into the DC P4600.1 This includes protection from silent data corruption, which can cause catastrophic downtime and errors in major businesses.

Power Loss Imminent (PLI) provides protection from unplanned power loss, and is obtained through a propriety combination of power management chips, capacitors, firmware algorithms, and a built-in PLI self-test. Intel’s PLI feature provides data centers with high confidence of preventing data loss during unplanned power interrupts.

Designed for Today’s Modern Data Centers
The DC P4600 is Intel’s new 3D NAND SSD for mixed workloads that are common to the data caching needs of cloud-driven data centers. The mix of performance, capacity, endurance, manageability, and reliability make it the ideal solution for data caching in software-defined and converged infrastructures.

Features At-a-Glance


1.6, 2, 3.2 TB in U.2 form factor

2, 4 TB in AIC form factor

Performance2 3

64k sequential read/write – up to 3280 / 2100 MB/s

4k random read/write – up to 702,500 / 257,000 IOPS


Support for NVM Express*-Management Interface (NVMe*-MI), NVMe* SMART / Health and Log Pages


End-to-end data protection from silent data corruption, uncorrectable bit error rate < 1 sector per 1017 bits read


PCIe* 3.1 x4, NVMe* 1.2

Form factors

U.2 2.5 in x 15mm (for serviceability, hot-plug, and density)

Add-in-card: Half-height half-length, low profile (for legacy and mainstram server compatibility)




Random/JEDEC up to 2.9 DWPD (5 Years) / 21.7 PBW, sequential workload up to 4 DWPD (5 Years) / 29.2 PBW


Max sequential read/write 9.9 W / 20.7 W


5 year warranty

Informazioni su prodotti e prestazioni


Fonte - Intel. La protezione dei dati end-to-end si riferisce all'insieme di metodi utilizzati per rilevare e correggere l'integrità dei dati nel percorso completo man mano che vengono letti o scritti tra l'host, il controller SSD e il supporto. Test eseguiti con unità SSD Intel® DC S3520, SSD Intel® DC P3520, SSD Intel® DC P3510, SSD Intel® DC P4500, Samsung* PM953, Samsung PM1725, Samsung PM961, Samsung PM863, Micron* 7100, Micron 510DC, Micron 9100, HGST* SN100, Seagate* 1200.2, SanDisk* CS ECO. L'affermazione è basata sulla media dei tassi di errore delle unità Intel rispetto alla media dei tassi di errore delle unità dei concorrenti. La radiazione di neutroni viene utilizzata per determinare i tassi di corruzione silente dei dati e come misura dell'efficacia globale della protezione dei dati da end-to-end. Tra le cause di corruzione dei dati in un controller SSD si registrano radiazioni ionizzanti, rumore del segnale e crosstalk e instabilità della SRAM. Gli errori silenti sono stati misurati durante il run-time e dopo il riavvio in seguito a un “blocco” dell’unità, confrontando i dati attesi con i dati reali restituiti dall'unità. È stata effettuata una proiezione del tasso annuale di corruzione dei dati in base al tasso durante il testing accelerato diviso per l’accelerazione del fascio (vedere lo standard JEDEC JESD89A).


Test and System Configuration: Processor: Intel® Xeon® E5-2699 v3 processor, Speed: 2.30GHz, Intel® BIOS: Internal Release, DRAM: DDR3–32GB, OS: Linux* CentOS* 7.0 kernel 4.6, Intel® SSD DC P4500 Series Masthead.


Prestazioni misurate con profondità di coda (QD) = 1 e QD = 256 (QD = 64, lavoratori = 4). Misurazioni eseguite su gamma completa Logical Block Address (LBA) dell'unità.