Data Storage | Bruker

Data Storage

Quantitative Nanomechanical, Nanotribological, and Interfacial Adhesion Characterization of Ultra-Thin DLC Films

One effective methodology for increasing the data density of magnetic storage media is to decrease the distance from the bottom of the read-write head to the top of the magnetic media on the disk. The smaller the head-media spacing (HMS), the higher the read-write signal integrity is at large areal densities. New generations of magnetic storage media with constantly increasing data densities requires the integration and control of new ultra-thin DLC coatings and protective films/lubricants. Future magnetic data storage technologies involve heat-assisted magnetic recording and bit-patterned recording to increase data density.

The mechanical and tribological performance of these ultra-thin DLC films is of critical importance to minimize or eliminate damage due to a slider/disk crash. DLC films can have a broad spectrum of mechanical and tribological properties due to a mixed structure of C-C sp2 and sp3 bonding. The ability to quantitatively characterize the nanomechanical and nanotribological performance of these films, oftentimes only a few atomic layers in thickness, enables engineers to optimize chemistries and processes to achieve a high degree of tetrahedral bonding. Additionally, the ability to quantitatively measure the DLC/undercoat/media interfacial adhesion is critical to product reliability.

Bruker has a long history in characterizing ultra-thin DLC coatings used in the magnetic data storage industry and continually develops next-generation technologies for nanomechanical and nanotribological characterization in these areas. New transducer technologies have enabled quantitative, rigid probe nanoindentation at length scales previously impossible. Combined with patented models to provide substrate-free, film-only mechanical properties, new levels of DLC performance can be achieved. Additionally, nanoscale scratch measurements provide quantitative friction and scratch resistance measurements and can be used to simulate head-media crashes and evaluate deformation severity in a production environment. 

Application Notes

Standalone Test Equipment for Ultra-Thin DLC Film Characterization

Hysitron TI 980 TriboIndenter | Bruker

TI 980 TriboIndenter

Bruker's most advanced nanomechanical and nanotribological test instrument, operating at the intersection of maximum performance, flexibility, reliability, sensitivity and speed.

Hysitron TI Premier | Bruker

TI Premier

Versatile nanomechanical and nanotribological test instrument, supporting a broad range of hybrid and correlative characterization techniques.

Hysitron TS 77 Select Nanoindenter | Bruker

TS 77 Select

Dedicated nanomechanical test instruments, providing an essential toolkit of core nanoscale mechanical characterization techniques.

Microscope Test Equipment for Ultra-Thin DLC Film Characterization

Hysitron PI 85L SEM PicoIndenter | Bruker

PI 85L SEM PicoIndenter

Depth-sensing nanomechanical test instrument that can be interfaced with scanning electron microscopes (SEM).

Hysitron PI 8X SEM PicoIndenter BRUKER

PI 89 SEM PicoIndenter

Bruker’s comprehensive in-situ nanomechanical test instrument for SEM and FIB/SEM, featuring our full suite of techniques.

Hysitron PI 95 TEM PicoIndenter | Bruker

PI 95 TEM PicoIndenter

The first full-fledged depth-sensing indenter capable of direct-observation nanomechanical testing inside a transmission electron microscope (TEM).


Hysitron TS 75 TriboScope | Bruker

TS 75 TriboScope

Quantitative, rigid-probe nanoindentation and nanotribological characterization on your existing AFM.