Next-gen memory chips

The memory chips in phones, laptops and other electronic devices need to be small and fast, and to draw as little power as possible. For years, silicon chips have delivered on that promise.

But to dramatically extend the battery life of mobile gadgets, and to create data centres that use far less energy, engineers are developing memory chips based on new nanomaterials with capabilities that silicon can't match.

Stanford engineers have developed post-silicon materials and technologies that store more data per square inch and use a fraction of the energy of today’s memory chips. The unifying thread in the engineers’ three recent experiments is graphene — an extraordinary material isolated a decade ago but which had, until now, relatively few practical applications in electronics.

“Graphene is the star of this research,” said Eric Pop, associate professor of electrical engineering and a contributor to two of the three memory projects. “With these new storage technologies, it would be conceivable to design a smartphone that could store 10 times as much data, using less battery power, than the memory we use today.”

Professor H-S Philip Wong and Pop led an international group of collaborators who describe three graphene-centric memory technologies in separate articles in Nature Communications, Nano Letters and Applied Physics Letters.

Engineers think post-silicon memory chips may transform server farms that must store and deliver quick access to the vast quantities of data stored in the cloud.

“Data storage has become a significant, large-scale consumer of electricity, and new solid-state memory technologies such as these could also transform cloud computing,” Wong said.

Memory makeover

Memory chips store data as a string of ones and zeroes. Today most memory chips are based on silicon, and come in two basic types — volatile and non-volatile. Volatile memory, such as random-access memory (RAM), offers fast but temporary storage. When the power shuts off, the zeros and ones vanish. Non-volatile memory, such as the flash memory in mobile phones, is slow but stable. Even if the battery expires, the data remains.

The Stanford engineers show how to create memory with the speed of RAM and the persistence of flash by using new materials and technologies that require less energy than silicon to store the zeroes and ones.

In Nature Communications, Wong worked with postdoctoral fellow Seunghyun Lee and PhD candidate Joon Sohn on a technique known as resistive random-access memory, or RRAM for short.

In RRAM chips, tiny jolts of electricity switch certain metal oxides between resistive and conductive states. When the metal oxides resist the flow of electrons, that creates a zero. When the materials conduct electrons, that is a one. RRAM is fast, like volatile silicon memory; but like flash memory, it retains stored data when the power is turned off.

This work demonstrates the possibility of constructing non-volatile RRAM while densely storing data without consuming more energy.

New phases of memory

In two other papers, published in Applied Physics Letters and Nano Letters, Pop and Wong led research teams that used graphene to make advances with a different but conceptually similar storage approach called phase-change memory.

In phase-change memory, a tiny jolt of electricity causes an alloy of germanium, antimony and tellurium to change its atomic structure. One jolt tweaks the atoms into a regular, crystalline structure that allows electrons to flow, notated as a digital one. A second jolt makes the structure irregular, or amorphous, creating a zero. Each jolt quickly toggles the phase-change material from one to zero. Like RRAM, it retains its stored data when the power is turned off.

In the Applied Physics Letters paper, Pop led a team that included former students at the University of Illinois Urbana-Champaign and collaborators at the Universities of Modena and Bologna in Italy. They used ribbons of graphene as ultrathin electrodes to intersect phase-change memory cells, like skewers spearing marshmallows. This set-up also exploited the atomically thin edge of graphene to push current into the material and change its phase, again in an extremely energy-efficient manner.

In the Nano Letters paper, Pop and Wong used both the electrical and thermal properties of graphene in a phase-change memory chip. However, in a twist, here they used the surface of the graphene sheet to contact the phase-change memory alloy. In essence, the graphene prevented the heat from leaking out of the phase-change material, creating a more energy-efficient memory cell.

Image caption: Professor H-S Philip Wong, postdoctoral fellow Seunghyun Lee and graduate student Joon Sohn are developing high-capacity, energy-efficient memory chips that are not based on silicon. Image credit: Norbert von der Groeben.