Dienstag, 27. Februar 2018, 11:56 Uhr

DRESDEN, Germany, Feb 26, 2018 – SILTECTRA GmbH, a leader in advanced wafering technology solutions and services, today reports that it has validated a breakthrough capability for its COLD SPLIT technology. COLD SPLIT is a proven wafer-thinning technique for substrate materials like silicon carbide (SiC), gallium nitride (GaN), silicon (Si) and sapphire. A disruptive laser-based technology, COLD SPLIT out-performs traditional grinding methods by thinning wafers to 100 microns and below in minutes, with virtually no material loss. Now, thanks to a novel adaptation known as “twinning”, SILTECTRA has demonstrated that COLD SPLIT can reclaim substrate material generated (and previously wasted) during backside grinding, and create a second fully optimizable bonus wafer in the process.

The breakthrough enriches SILTECTRA’s wafering solution and promises substantial benefits for manufacturers of SiC-based ICs like power electronics and RF devices. SILTECTRA believes that the solution’s combined advantages which include fewer process steps, potentially lower equipment costs, and ultra-efficient use of substrate material, could reduce total device production costs by as much as 30 percent.

SILTECTRA validated the process by producing a GaN on SiC high electron-mobility power transistor (HEMT) device on a split-off (or “twinned”) wafer at its new state-of-the-art facility in Dresden. The HEMT showed results that were superior to a non- Cold- Split-enabled HEMT when measured for CMP characterization, as well as GaN EPI, metal layer and gate layer outcomes.

Leading integrated device manufacturers (IDMs) are now evaluating the technology.

SILTECTRA’s CEO, Dr. Harald Binder, called “twinning” the “holy grail” on the company’s technology roadmap, and noted that the breakthrough was achieved ahead of schedule. “We were confident that we could not only produce a faster and cheaper thinning solution for substrates like SiC, but that we could double the value for customers by extending COLD SPLIT’s reach to create a twin wafer from material previously lost during backside grinding,” he said. “We’re thrilled to report the validation milestone, and excited to help leading IDMs realize new performance and cost benefits in their manufacturing operations.”

New Substrate Materials Present New Lower-Cost Manufacturing Imperatives

SiC is expected to be the go-to substrate for the production of power electronics, RF, and other devices. Devices made from SiC have a smaller form-factor than those manufactured on silicon, and can handle higher voltages and frequencies with lower power consumption. Although SiC is substantially more expensive than silicon, the market is growing fast thanks to the substrate’s inherent enabling advantages. Not surprisingly, IDMs are seeking new technologies to cut the cost of producing devices based on SiC and other costly substrates.

Until now, the traditional method to thin wafers to less than 20 percent of the original thickness was grinding, which involves the use of expensive diamond grinding wheels. While valued as a reliable solution for silicon, certain challenges make it difficult for grinding to achieve the extreme level of thinness required for SiC-based devices. Unlike silicon, which is relatively soft, SiC is an extraordinarily hard substance (second only to the hardness of a diamond), which makes cutting and grinding arduous and expensive. What’s more, grinding is not a fast process, and the cost of consumables for the grinding wheels can be substantial. Finally, grinding generates material loss, and the process lowers overall yield, which further drives up cost.

The COLD SPLIT Advantage

SILTECTRA engineered COLD SPLIT as a faster, higher-yield, lower-cost alternative to grinding for advanced substrates like SiC. The technique employs a chemical-physical process that uses thermal stress to generate a force that splits the material with exquisite precision along the desired plane. The solution accomplishes the thinning task in minutes instead of an hour like traditional grinding tools, and cuts material loss by as much as 90 percent.

The “twinning” breakthrough extends COLD SPLIT’s capabilities. The adaptation provides a simple way for IDMs to avoid expensive kerf-loss when slicing ingots or boules into wafers. It effectively replaces backside grinding processes, while producing an identical wafer primed for a second device run.

SILTECTRA is qualifying the process on customers’ SiC material at its newly extended facility in Dresden, while preparing to apply the COLD SPLIT technique to additional substrate materials. The company also provides wafering and thinning services at the same location.


SILTECTRA provides advanced wafering technology solutions and services to global semiconductor manufacturers. The company’s proprietary COLD SPLIT solution thins wafer substrates to 100 microns and below in minutes, with virtually no material loss. With a specialized focus on advanced substrate materials like silicon carbide (SiC), gallium nitride (GaN) and sapphire, SILTECTRA’s laser-based technology equipment and process solution is enabling manufacturers of power electronics, RF and other IC devices with dramatic new performance and cost advantages. Founded in 2010 and headquartered in Dresden, Germany, SILTECTRA is privately held and supported by a leading venture capital firm.


Johannes Froehling; email: johannes.froehling@siltectra.com.

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Siltectra GmbH

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SILTECTRA versteht sich als Technologiespezialist für kerf-less Wafering, einer neuartigen Technologie für die Herstellung von Wafern. Kerf-less Wafering von SILTECTRA ist eine Plattformtechnologie, die sich in verschiedenen Industrien und für unterschiedliche Materialien einsetzen lässt. Am Standort Dresden entwickelt die SILTECTRA ein innovatives Herstellungsverfahren für monokristalline Wafer. Es beruht auf einem chemisch-physikalischen Vorgang: Durch thermischen Stress werden Kräfte erzeugt, die den Kristall entlang der gewünschten Ebene spalten. So ist es möglich, in einem Bruchteil von Sekunden einen Wafer von einem Halbleitermaterial abzutrennen – und das ganz ohne Materialverluste. Darüber hinaus ist es möglich, auch teilprozessierte Wafer, gezielt zu splitten.