YAGEO Presents NANOMET Soft Magnetic Cores for High‑Density Power Conversion

Higher switching frequencies and tighter power-density targets are reshaping inductor design across server, industrial and automotive power electronics. NANOMET soft magnetic material from YAGEO KEMET addresses that shift by combining high saturation capability, temperature-stable behavior and reduced dependence on large external air gaps, making it relevant for compact inductors in high-current and high-frequency converter stages.

As converter designers push beyond traditional ferrite comfort zones, the limiting factor is increasingly the complete inductor loss balance rather than a single magnetic parameter. In that context, YAGEO NANOMET stands out as a material platform aimed at improving the trade-off between core loss, copper loss, size and EMI.

Why this material matters

The move to GaN- and SiC-based power conversion has increased the pressure on magnetic components to deliver more power in less volume. In many designs, switching frequencies now extend into the several-hundred-kilohertz range, while multiphase buck regulators for high-performance processors operate around 1 MHz.

That trend changes the way inductors must be evaluated. Downsizing a magnetic component with a conventional material often increases core loss and makes thermal management harder, especially where magnetic flux density and current ripple are both high. A more suitable core material can therefore unlock not just smaller magnetics, but a better system-level efficiency and cooling balance.


Figure 1. Increasing power density in modern server applications.

Core behavior and practical implications

The key material parameters are permeability, saturation behavior and frequency-related loss. Permeability determines how much inductance can be achieved for a given geometry, while saturation behavior defines how far the inductor can be pushed before inductance starts to collapse under current load.

In practical power inductor design, ferrites often require a discrete air gap to avoid abrupt saturation. That solves one problem, but creates others: flux leakage, fringing losses, EMI challenges and added volume. A material with softer saturation behavior and a more distributed internal gap structure reduces those penalties.

The core-loss plot is especially relevant in high-frequency converter design, while the B/H curve shows why the material can be attractive where designers need usable inductance under high current without a strongly leaky external gap.

Key features and benefits

Material positioning against ferrite and metal composite

NANOMET does not replace every existing soft magnetic material, but it does fill an important performance window between ferrite and conventional metal composite solutions. Ferrites remain attractive where very low core loss dominates the design target, while metal composites remain useful in some compact molded designs. NANOMET becomes particularly relevant where high saturation margin, manageable core loss and compact size must all be met together.

Material familyFerritesMetal compositeNANOMET
CompositionMn-ZnFeSiCrFeSiBPCuCr
ProcessPowder mold sinteringPowder mold curingHot mold
Permeability μ900, usually reduced by gap in use25100
Bc0.5 T1.2 T1.3 T
μ versus temperatureNot stableStableStable
Relative core lossLowHighMid

Air-gap reduction as an EMI and thermal advantage

Large external air gaps are often accepted as a normal part of ferrite inductor design, yet they are also a common source of local field leakage. That leakage can drive fringing losses in nearby conductors and increase radiated or coupled noise in dense converter layouts.

Every core material has process foundations that lead the way to mechanical inductor designs. While typical metal composite materials can be processed to form a core around a coil specifically for surface-mounted power inductors, the process for ferrites and NANOMET™ dictates forming a solid block shape first and assembling the coil afterwards. The process conditions of those materials require enormous pressure and heat that would soften electrical isolation materials and can cause deformation, which is called “Hot Press Molding” technology.


Figure 7 – Typical NANOMET™ core shapes used that can be manufactured

Metal composite and NANOMET™ inductors have a built-in airgap structure in the material that ensures each metal powder grain is coated with a Silicon shell, which represents the magnetic gap. Ferrite designs typically need to operate with an air gap to avoid saturation by applied current. An air gap allows the magnetic field to leak through the whole design and can cause EMI challenges. The field leakage also causes fringing losses to structures close to the winding. In high-power designs, this can introduce a significant amount of heat in the conductor.

With some core designs, even metal composite or NANOMET™ component structures require minimal airgaps to increase the saturation capability or cater for the required mechanical conditions that the application demands and the core assembly process dictates. In any case, the gap is smaller with iron-based silicon-coated materials, and the impact of EMI emission and fringing losses is much less.


Figure 8. Influence of air gaps in power inductor designs.

This explains why air-gap architecture is not just a material-science detail. In practical designs, a smaller or internally distributed gap can reduce both EMI and localized heating near the winding, particularly in high-current storage inductors.

Typical applications

The material is relevant across several distinct inductor classes. It spans both low-inductance, very high-current parts and higher-inductance, higher-power choke designs:

Figure 9. Examples of component shapes.

#1 Power bead case study: 90 nH in a server VR environment

In low-inductance, high-current server regulator stages, inductor volume, DCR and saturation current all directly affect efficiency and thermal headroom. A 90 nH comparison shows that a NANOMET power bead in the same basic footprint class can deliver lower DCR, lower total loss and a lower component height than a ferrite alternative, while also improving saturation current.

The relevant engineering takeaway is that total inductor loss matters more than isolated core loss. Even where ferrite may retain an advantage in one loss component, the shorter winding and lower copper losses of a NANOMET-based design can produce a better overall result, especially as current rises.

#2 TLVR case study: faster transient response with smaller magnetics

Transient load voltage regulator architectures are designed for extremely fast current slew during CPU and GPU load steps. In this environment, inductors must support both dynamic response and manageable efficiency.

The comparison points to lower DCR and lower profile for the NANOMET version, alongside a favorable total-loss result. This makes the material attractive where board density and transient performance must improve together without accepting a large EMI penalty from a gapped ferrite structure.

#3 PFC choke case study: compact magnetics at higher power

The material case becomes even more interesting in larger front-end magnetics. In PFC or boost inductors, designers need to control core loss while also meeting mechanical volume and thermal limits.

In this application space, the attraction of NANOMET is its ability to support compact choke geometry while still meeting inductance and loss targets at elevated switching frequency. The data also reinforces a realistic design rule: even with a strong core material, winding losses remain important and must be paired with an effective thermal extraction path.

#4 SMD inductor case study: 150 nH PCB-mount design

For compact local power conversion, DCR and saturation current are often the first two filters in part selection. In the 150 nH SMD comparison, the NANOMET example achieves much lower resistance and significantly higher saturation current than the compared METCOM parts at similar nominal inductance.

This makes the material relevant not only for very high-end server hardware, but also for smaller DC/DC stages where every square millimeter and every milliohm matter.

Design-in notes for engineers

Source

This article is based on an official YAGEO KEMET technical release covering NANOMET soft magnetic material, its material characteristics and four application comparisons spanning power beads, TLVR inductors, PFC chokes and compact SMD power inductors.

References

  1. YAGEO KEMET — NANOMET™: Soft Magnetic Material Evolves to Achieve Benchmark Power Conversion Performance
  2. YAGEO Group official website
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