Henniker announce further expansion into Benelux


Van Loenen Instruments

We are extremely pleased to announce our new distribution partners in the Benelux region, Van Loenen.

Van Loenen Instruments are a regional distributor of scientific equipment & consumables for the Microscopy Industry. They provide the necessary equipment for both industrial and research facilities and have many years experience within the industry. Henniker are delighted to be working with such a reputable company and one with such specialist knowledge. Our collaboration  will provide an important European outlet for our plasma cleaning equipment and specialist TEM Sample preparation equipment to become part of their valued range. We look forward to working together with Van Loenen in the future.

For more information on VAN LOENEN please click here

Categorised in: News & Events

Scientist Uncovers Physics Behind Plasma Etching Process

Scientist Uncovers Physics Behind Plasma Etching Process

Physicist Igor Kaganovich at the Department of Energy’s (DOE) Princeton Plasma Physics Laboratory (PPPL) and collaborators have uncovered some of the physics that make possible the etching of silicon computer chips, which power cell phones, computers, and a huge range of electronic devices. Specifically, the team found how electrically charged gas known as plasma makes the etching process more effective than it would otherwise be. The research, published in two papers appearing in the September and December 2016 issues of Physics of Plasmas, was supported by the DOE’s Office of Science (FES).



Kaganovich, Deputy Head of the PPPL Theory Department, together with Dmytro Sydorenko of the University of Alberta, knew that the plasma etching process was effective, but were not sure exactly how the process worked. So they investigated the process’s theoretical underpinnings.

During the etching process, a piece of silicon is placed in a chamber and immersed within a thin layer of plasma, about two centimeters wide. Also within the plasma are two electrodes spaced a couple of centimeters apart that produce a beam of electrons.

As the electrons flow through the plasma, they start a process known as a two-stream instability, which excites plasma waves that enable the plasma to etch the silicon more efficiently.

Image Courtsey of www.scientificcomputing.com

Sydorenko and Kaganovich modeled this process. They showed that the waves created by the electron beam can become much more intense than in plasmas that are not bounded by electrodes. In other words, when a plasma is bounded, the wave driven by the two-stream instability can become very strong.

“The simulations indicate that the placing of plasma within a pair of electrodes supports the excitation of large plasma waves, which then lead to the acceleration of plasma electrons that can aid etching,” Kaganovich said.


Understanding the physics undergirding the plasma etching technique could help researchers design more efficient processes to etch circuits on silicon chips.

PPPL, on Princeton University’s Forrestal Campus in Plainsboro, N.J., is devoted to creating new knowledge about the physics of plasmas — ultra-hot, charged gases — and to developing practical solutions for the creation of fusion energy. The Laboratory is managed by the University for the U.S. Department of Energy’s Office of Science, which is the largest single supporter of basic research in the physical sciences in the United States, and is working to address some of the most pressing challenges of our time. For more information, please visit science.energy.gov.

For the original article click here

For more information on plasma etching techniques and equipment visit here



Categorised in: News & Events