An Introduction to the TeslatronPT Plus: Low-Temperature Measurement Made Simple

Register for the 8 am or 3 pm BST session

Advancing experimental research in quantum materials, superconductivity, and low-temperature transport requires more than just reaching extreme conditions - it demands a stable measurement environment, high signal integrity, and efficient experimental workflows.

In this technical webinar, we will introduce the TeslatronPT Plus, Oxford Instruments NanoScience’s measurement solution, launched earlier this year. Designed with an open architecture, the system enables reduced time-to-measurement, enhanced usability, and high data confidence. As part of the webinar, we’ll highlight the system’s integration with the Lake Shore M81 synchronous source measure system and the M91 FastHall Measurement Controller, forming a fully pre-validated signal chain optimized for electrical transport measurements at low-temperatures and high magnetic fields.

Our experts will walk through an overview of the TeslatronPT Plus system including research applications. In addition, the webinar will cover:

The TeslatronPT Plus optimized signal chain and modular hardware
End-to-end software suite for managing experiments, from system control to data interpretation
Real-world electrical transport measurement examples
A Lake Shore M81 and M91 systems overview

Whether you’re setting up a new low-temperature lab or looking to upgrade your existing TeslatronPT system, this webinar will demonstrate how TeslatronPT Plus offers a high-performance measurement solution for today’s demanding research challenges.

Register for the 8 am or 3 pm BST session

02 July 2025

Time:

8 : 00 AM (BST)
3 : 00 PM (BST)

Duration:

60 minutes

Language:

English

Businesses:

NanoScience

The webinar is in collaboration with

Agenda

Time (IST)	Talk Title	Presenter
13:30 - 14:00	Recent cryogenic platform developments from Oxford Instruments for quantum computing and quantum technology research	Harriet van der Vliet
14:00 - 14:30	Atomic-scale processing techniques for quantum device fabrication	Nicholas Chittock
14:30 - 14:50	Transforming Quantum Computing and Research with Next-Gen Control: Inside Quantum Machines' approach	Michaela Eichinger
14:50 - 15:00	Q&A

Abstracts

Recent cryogenic platform developments from Oxford Instruments for quantum computing and quantum technology research
Dr Harriet van der Vliet, Oxford Instruments NanoScience

In this webinar you will hear an update on the technological advancements and cryogenic platform developments from Oxford Instruments NanoScience, focusing on our data centre installations, customer research and our recent introduction of QCoDeS to our Proteox platform.

The ProteoxS, the most compact dilution refrigerator, with the same specifications as its larger family members which is ideal for spin qubit applications, will be introduced with latest data presented from the platform. This is a dilution refrigerator that is perfect not only for small numbers of qubits and fundamental research, but as a tool for educating the quantum workforce, from cryogenic technicians to quantum engineers in academic labs.
At the other end of the scale, the ProteoxQX, the only true modular, scalable solution for the 1000+ qubit regime will be presented, a system suitable to allow users to deliver their roadmaps and achieve their national goals.

Atomic-scale processing techniques for quantum device fabrication
Dr Nicholas Chittock, Oxford Instruments Plasma Technology

Current generation quantum devices are limited by losses. A primary source of these losses is poor quality interfaces and damaged surfaces, which are generated during device fabrication. To minimise (or avoid) the formation of these loss channels in quantum devices advanced nanofabrication techniques are required.

In this webinar, we will discuss the application of atomic layer deposition (ALD) and atomic layer etching (ALE) to materials relevant for quantum applications. ALD of superconducting nitrides for superconducting nanowire single photon detectors and through silicon vias will be discussed. While for ALE, the use of both anisotropic and isotropic ALE for low damage material removal for superconducting, colour center and waveguide applications will be highlighted. Utilising processing techniques that are inherently low damage may enable the fabrication of quantum devices with lower losses, helping to provide longer coherence times and quantum devices with higher Q-factors.

Transforming Quantum Computing and Research with Next-Gen Control: Inside Quantum Machines' approach
Dr Michaela Eichinger, Quantum Machines

Speakers

Dr Harriet van der Vliet - Oxford Instruments NanoScience

Product Segment Manager for Quantum Technologies

Harriet has been the product segment manager for quantum technologies at Oxford In...

Dr Nicholas Chittock - Oxford Instruments Plasma Technology

Quantum Technologies Market Specialist

Nick previously worked for Oxford Instruments Plasma Technology as an ALD process technician, befo...

Dr Michaela Eichinger - Quantum Machines

Product Solutions Physicist

Michaela Eichinger is a Product Solutions Physicist at Quantum Machines, holding a Ph.D. in Experi...

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