{"id":13029,"date":"2023-01-24T16:20:09","date_gmt":"2023-01-24T14:20:09","guid":{"rendered":"https:\/\/www.weebit-nano.com\/?p=13029"},"modified":"2025-06-17T13:45:54","modified_gmt":"2025-06-17T10:45:54","slug":"weebit-nano-rram-reram-ip-nvm-for-semiconductors-green-materials-eco-friendly-technology-production","status":"publish","type":"post","link":"https:\/\/www.weebit-nano.com\/weebit-nano-rram-reram-ip-nvm-for-semiconductors-green-materials-eco-friendly-technology-production\/","title":{"rendered":"Weebit ReRAM:
NVM that\u2019s better for the planet"},"content":{"rendered":"

Together with our R&D partner CEA-Leti<\/a>, we recently completed an environmental initiative in which we analyzed the environmental impact of Weebit\u2019s Resistive Random-Access Memory (ReRAM<\/a> \/ RRAM<\/a>) technology compared to Magnetoresistive Random Access Memory (MRAM<\/a>) \u2013 another emerging non-volatile memory (NVM<\/a>) technology. The results were extremely positive for Weebit\u2019s Oxide-based ReRAM (OxRAM<\/a>), which was jointly developed with Leti, showing the environmental impact of ReRAM is much lower than that of MRAM.<\/p>\n

A bit of background<\/strong><\/p>\n

The overall contribution of the semiconductor industry to global greenhouse gas (GHG) emissions is increasing as demand for semiconductors continues to grow. To mitigate negative impacts, environmental programs are extremely important for all players in the semiconductor ecosystem. In addition to CO2<\/sub> emissions, semiconductor manufacturing can use a significant amount of energy, water, rare natural resources, and chemicals, which can contribute to global warming. The choices semiconductor companies make in design and specification phases, including their memory technology choices, are key to reducing a company\u2019s overall carbon footprint.<\/p>\n

MRAM is effectively the only other kind of emerging NVM that is commercially available today at foundries. It stores data as resistance using magnetic fields (versus ReRAM which stores it as resistance of a solid dielectric material, and flash which stores data as electric charges). MRAM has high endurance and is more often used as a replacement for embedded SRAM<\/a> than for embedded flash. Still, there are companies using MRAM today as a replacement for embedded flash that do so because until now there hasn\u2019t been a production-ready alternative at smaller geometries.<\/p>\n

Compared to MRAM, Weebit ReRAM is the logical choice for embedded applications, with the number one reason being ease of manufacturing. Weebit ReRAM requires significantly fewer layers and masks and doesn\u2019t use exotic materials or special equipment, so it can be manufactured in the standard CMOS<\/a> production line and doesn\u2019t require designated cleanroom facilities. All this translates to lower costs. MRAM adds an estimated 30-40% to wafer cost, compared to ReRAM\u2019s 5-7%. We will go into more depth on MRAM in a future article, but for now, suffice it to say that ReRAM has a long list of advantages over MRAM, and in our new study, we\u2019ve outlined yet another advantage \u2013 ReRAM is much more ecologically friendly!\u00a0<\/strong><\/p>\n

What we looked at<\/strong><\/p>\n

The team at CEA-Leti estimated the contribution of both OxRAM and MRAM to climate change, focusing on the production flows of each technology. To enable a fair comparison, the study looked at each technology in an identical die area in a similar process node and considered only the memory cell portion. They looked at raw materials and manufacturing processes (cradle to gate) without including infrastructure and abatement. Scroll to the end of the article to learn more about the data collection for the study*.<\/p>\n

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Key results<\/strong><\/p>\n

The study found that on all measured parameters, OxRAM demonstrated a better GHG related profile than MRAM. Below we\u2019ve listed some of the key results.<\/p>\n

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ReRAM demonstrated the following benefits over MRAM:<\/p>\n