- Joined
- Oct 9, 2007
- Messages
- 47,301 (7.52/day)
- Location
- Hyderabad, India
System Name | RBMK-1000 |
---|---|
Processor | AMD Ryzen 7 5700G |
Motherboard | ASUS ROG Strix B450-E Gaming |
Cooling | DeepCool Gammax L240 V2 |
Memory | 2x 8GB G.Skill Sniper X |
Video Card(s) | Palit GeForce RTX 2080 SUPER GameRock |
Storage | Western Digital Black NVMe 512GB |
Display(s) | BenQ 1440p 60 Hz 27-inch |
Case | Corsair Carbide 100R |
Audio Device(s) | ASUS SupremeFX S1220A |
Power Supply | Cooler Master MWE Gold 650W |
Mouse | ASUS ROG Strix Impact |
Keyboard | Gamdias Hermes E2 |
Software | Windows 11 Pro |
Toshiba Group has announced the world's first demonstration of HDD recording performance improvement with Microwave Assisted Switching-Microwave Assisted Magnetic Recording (MAS-MAMR), a next-generation magnetic recording technology. The demonstration confirms that the technology delivers substantial storage capacity gains, and Toshiba now aims to realize early commercialization of nearline HDDs with capacities exceeding 30 TB.
Toshiba is placing considerable R&D effort on MAMR, a breakthrough technology that boosts HDD recording density. In 2021, the company started shipment of 18 TB HDDs that apply Flux Control MAMR (FC-MAMR ), which uses spin torque oscillators to assist recording. MAS-MAMR is expected to improve recording density beyond that of FC-MAMR by locally exposing microwave to -recording media. However, this was not shown to be possible in practice until the recent demonstration.
Toward proving the fundamental superiority of MAS-MAMR, Toshiba has been promoting its development with Showa Denko K.K. (SDK), an HDD medium manufacturer, and TDK Corporation (TDK), a HDD head manufacturer. This three-way cooperation recently bore fruit in the demonstration of MAS-MAMR's improved recording performance.
Toshiba will announce details of the newly developed spin torque oscillator and its oscillation characteristics at the Joint MMM-INTERMAG Conference 2022, an international conference scheduled on January 10-14, 2022.
Development Background
Digital data storage on data centers is a pillar of the modern information infrastructure supporting digitalization and digital transformation, and is now more important than ever due to the COVID-19 pandemic. Continuing storage demand is on explosive pace, and the market for high-capacity nearline HDDs, the workhorses of both cloud-scale and traditional data centers, is expected to grow to US$ 17.5 billion in 2025. This evolving needs for storage devices are also fueling demand for further capacity increases in HDDs.
Any attempt to increase the recording density of an HDD must reconcile a trilemma of three conflicting goals: miniaturize the magnetic grains on the recording medium; realize thermally stable magnetic grains; and secure sufficient recording performance. The recording medium is coated with a layer of fine magnetic grains that retain information according to the direction of their magnetization. While recording density could be improved by miniaturization of the recording bit on the recording media, this requires even smaller magnetic grains, which reduces thermal stability of their magnetization. Loss of thermal stability may result in data losses.
Increasing thermal stability on increasing recording density requires a material with a higher "coercivity" that can maintain the magnetization. However, a higher coercivity makes it difficult for the recording head to generate the sufficient magnetic field for recording. Overcoming this requires next-generation magnetic recording technology in which recording is assisted by external energy.
Advances are being made in R&D of a next-generation magnetic recording technology to overcome this trilemma. While MAS-MAMR to assist using microwaves is expected to improve the recording density drastically in theory, the confirmation of microwave-assisted switching effect (MAS-MAMR effect) on recording condition and improved recording performance with MAS-MAMR have not yet been demonstrated.
Features of the Technology
Toshiba has invented a "bi-oscillation type spin torque oscillator device (dual FGL STO)" that irradiates microwaves by a two-layer field generating layer. The "dual FGL STO" generates microwaves efficiently, with less current and on focused spots. Incorporated into a recording head, it can improve recording performance with MAS-MAMR.
In the work to demonstrate MAS-MAMR, TDK has developed new recording heads equipped with the STO, SDK has developed new recording media, and Toshiba has confirmed stable oscillation of STOs in the new recording heads.
Subsequently, Toshiba confirmed the MAS-MAMR effect by combining the newly developed STOs, recording heads and media, and for the first time in the world demonstrated an approximately 6dB improvement in recording performance with MAS-MAMR. This technology makes it possible to realize HDDs with large capacity of over 30 TB. By the demonstration, MAS-MAMR has taken a major step forward as a practical next-generation magnetic recording technology that can significantly improve recording density.
Future prospects
Toshiba now aims to realize early commercialization of nearline HDDs with capacities exceeding 30 TB with MAS-MAMR technology. The company will continue to develop MAMR technologies (FC-MAMR and MAS-MAMR) and to expand the capacity of nearline HDDs. Toshiba will also continue to develop the Thermal Assisted Magnetic Recording (TAMR) technology in parallel, to meet a wide range of storage needs.
View at TechPowerUp Main Site
Toshiba is placing considerable R&D effort on MAMR, a breakthrough technology that boosts HDD recording density. In 2021, the company started shipment of 18 TB HDDs that apply Flux Control MAMR (FC-MAMR ), which uses spin torque oscillators to assist recording. MAS-MAMR is expected to improve recording density beyond that of FC-MAMR by locally exposing microwave to -recording media. However, this was not shown to be possible in practice until the recent demonstration.
Toward proving the fundamental superiority of MAS-MAMR, Toshiba has been promoting its development with Showa Denko K.K. (SDK), an HDD medium manufacturer, and TDK Corporation (TDK), a HDD head manufacturer. This three-way cooperation recently bore fruit in the demonstration of MAS-MAMR's improved recording performance.
Toshiba will announce details of the newly developed spin torque oscillator and its oscillation characteristics at the Joint MMM-INTERMAG Conference 2022, an international conference scheduled on January 10-14, 2022.
Development Background
Digital data storage on data centers is a pillar of the modern information infrastructure supporting digitalization and digital transformation, and is now more important than ever due to the COVID-19 pandemic. Continuing storage demand is on explosive pace, and the market for high-capacity nearline HDDs, the workhorses of both cloud-scale and traditional data centers, is expected to grow to US$ 17.5 billion in 2025. This evolving needs for storage devices are also fueling demand for further capacity increases in HDDs.
Any attempt to increase the recording density of an HDD must reconcile a trilemma of three conflicting goals: miniaturize the magnetic grains on the recording medium; realize thermally stable magnetic grains; and secure sufficient recording performance. The recording medium is coated with a layer of fine magnetic grains that retain information according to the direction of their magnetization. While recording density could be improved by miniaturization of the recording bit on the recording media, this requires even smaller magnetic grains, which reduces thermal stability of their magnetization. Loss of thermal stability may result in data losses.
Increasing thermal stability on increasing recording density requires a material with a higher "coercivity" that can maintain the magnetization. However, a higher coercivity makes it difficult for the recording head to generate the sufficient magnetic field for recording. Overcoming this requires next-generation magnetic recording technology in which recording is assisted by external energy.
Advances are being made in R&D of a next-generation magnetic recording technology to overcome this trilemma. While MAS-MAMR to assist using microwaves is expected to improve the recording density drastically in theory, the confirmation of microwave-assisted switching effect (MAS-MAMR effect) on recording condition and improved recording performance with MAS-MAMR have not yet been demonstrated.
Features of the Technology
Toshiba has invented a "bi-oscillation type spin torque oscillator device (dual FGL STO)" that irradiates microwaves by a two-layer field generating layer. The "dual FGL STO" generates microwaves efficiently, with less current and on focused spots. Incorporated into a recording head, it can improve recording performance with MAS-MAMR.
In the work to demonstrate MAS-MAMR, TDK has developed new recording heads equipped with the STO, SDK has developed new recording media, and Toshiba has confirmed stable oscillation of STOs in the new recording heads.
Subsequently, Toshiba confirmed the MAS-MAMR effect by combining the newly developed STOs, recording heads and media, and for the first time in the world demonstrated an approximately 6dB improvement in recording performance with MAS-MAMR. This technology makes it possible to realize HDDs with large capacity of over 30 TB. By the demonstration, MAS-MAMR has taken a major step forward as a practical next-generation magnetic recording technology that can significantly improve recording density.
Future prospects
Toshiba now aims to realize early commercialization of nearline HDDs with capacities exceeding 30 TB with MAS-MAMR technology. The company will continue to develop MAMR technologies (FC-MAMR and MAS-MAMR) and to expand the capacity of nearline HDDs. Toshiba will also continue to develop the Thermal Assisted Magnetic Recording (TAMR) technology in parallel, to meet a wide range of storage needs.
View at TechPowerUp Main Site