How do billions of transistors work together to create a chip? 💡 http://ms.spr.ly/6045oZK35 Microchips are the powerhouses behind modern technologies, driving everything from smartphones to AI. In the latest episode of ASML Nanoland, ASMLer Sabil explains how these tiny brains perform tasks ranging from basic logic functions to advanced computations. Watch now!
소개
Who are we? ASML is an innovation leader in the global semiconductor industry. We make machines that chipmakers use to mass produce microchips. Founded in 1984 in the Netherlands with just a handful of employees, we’ve now grown to over 40,000 employees, 143 nationalities and more than 60 locations around the world. What do we do? We provide chipmakers with hardware, software and services to mass produce patterns on silicon through lithography. Our lithography systems use ultraviolet light to create billions of tiny structures on silicon that together make up a microchip. We push our technology to new limits to enable our customers to create smaller, faster and more powerful chips. Who are our people? While you may think that only engineers and mathematicians work at ASML, you'll be surprised to find out that our people come from a wide variety of backgrounds. Across ASML, we have dedicated teams that manage customer support, communications and media, IT, software development and more. Every team in the company is essential for pushing our technology and the industry forward. If you love to tackle challenges and innovate in a collaborative, supportive and inclusive environment with all the flexibility and freedom to unleash your full potential, ASML is the place to be. Join us!
- 웹사이트
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https://www.asml.com
ASML 외부 링크
- 업계
- 반도체 제조
- 회사 규모
- 직원 10,001명 이상
- 본사
- Veldhoven
- 유형
- 상장기업
- 설립
- 1984
- 전문 분야
- semiconductor, technology, hardware, software, lithography machine 및 innovation
위치
ASML 직원
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Sebastiaan in 't Hout
Availability Architect at ASML
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Michael Abrams, EdD (candidate), MBA, M.Ed, CPCC
Head of U.S. Talent, Learning & Organizational Effectiveness
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Leonard Tsai
Thinker and doer to solve problems with fresh thinking, pick up projects to finish line and to achieve results with extra helping hands.
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Joshua Brown
업데이트
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In the 2000s, chip requirements pushed lithography to its limits – how could we still achieve affordable shrink for our customers? 🤔 Our answer? Holistic lithography. By combining our lithography systems with metrology and inspection, computational lithography and software solutions, we turned a challenge into a breakthrough...
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Reflecting extreme ultraviolet light takes extremely smooth mirrors. On the mirrors in our High NA EUV lithography systems, the largest allowable deviation is just tens of picometers. That’s like the thickness of a playing card on a surface the size of Earth. 🃏🌍 And, to get the system’s unmatched 8 nm resolution, we have to reach that smoothness on a mirror that’s 1 meter across. Engineering these ultrasmooth surfaces wasn’t easy, and we collaborated closely with our strategic partner ZEISS Semiconductor Manufacturing Technology to make them a reality. It took innovating together to deliver the systems that will print the tiniest features for tomorrow's advanced microchips.
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Developing the light source for our EUV lithography systems took years of continuous effort. But there were also times when a single innovation drove a leap in progress. One of those pivotal moments? Developing and industrializing the seed isolation module in collaboration with our partner TRUMPF. 💡
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Today, we celebrate the six iconic women mathematicians who made groundbreaking contributions to the ENIAC! The ENIAC was the world's first electronic general-purpose computer, which used vacuum tubes to run mathematical operations. Equipped with 18,000 vacuum tubes and consuming 150 kW of power, this titan boasted a computational power 1,000 times greater than its contemporaries, leaving electromechanical machines in the dust. 💨 Here’s to progress and the brilliant minds that drive it forward! 🚀
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Microchips couldn’t do what they do without transistors. 👉 http://ms.spr.ly/6048o1Ris Curious about how these tiny switches perform complex tasks and power the tech around us? In episode 2 of ASML Nanoland, ASMLer Joep reveals what makes transistors essential in chip design. Watch now!
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Today is #GivingTuesday! 🎁 At ASML, we're proud to support this global movement of generosity and kindness. Through our Matching Gifts Program, ASML employees can maximize their impact when donating to nonprofit organizations of their choice. From December 3 to 20, 2024, we will double match all employee donations to amplify the positive change ASMLers are creating worldwide. Small acts. Big impact. Thrive Together.
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Happy Systems Engineer Day! 🔧 At ASML, we couldn't do what we do without our systems engineers. The architects of high-tech, they manage the design, integration and improvement of our complex lithography machines. The bridges they build between disciplines enable us to deliver performance and reliability to our customers and keep pushing technology forward. How are our systems engineers enabling the most advanced microchips? Learn about the role they played in developing extreme ultraviolet (EUV) lithography. 👇
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Printing billions of transistors with nanometer precision is a joint effort: It takes hardware and software working together to produce the microscopic circuitry for today’s advanced microchips. Our computational lithography software is powered by physical models and algorithms enabled by cutting-edge machine learning and data science techniques. From early design to high-volume manufacturing, it lets us use our unique knowledge about the inner workings of lithography systems to optimize the chip patterning process. Layer by layer, chip by chip, wafer by wafer, computational lithography is enabling chipmakers to push microchip technology to new limits.