Multiphysics platform for the toughest superconductor simulations
Simulate your most demanding models efficiently and accurately with Quanscient Allsolve.
Key advantages in superconductor design
Runtimes from weeks to hours without compromising accuracy.
High-fidelity 3D simulations of your most demanding models.
Capture complex interactions in highly nonlinear systems.
Custom design processes with the Quanscient API.
Trusted by industry professionals
Quanscient Allsolve is the 'go-to' tool for our most sophisticated superconductor simulations in stellarator design.
Lucio M. Milanese, PhD
Co-founder and COO

Quanscient Allsolve is a groundbreaking tool for advanced 3D superconductor simulations.
Antti Stenvall, PhD
Adjunct professor

Allsolve is a key tool for us modelling HTS cables and coils, especially when dealing with complex 3D multiphysics simulations. It has significantly enhanced our efficiency.
Jiabin Yang
Magnet Engineer

With Quanscient Allsolve, I can run complex simulations in under a day, which would otherwise take a week to complete.
Nicolo Riva, PhD
Magnet Engineer

Legacy solutions struggle with the complexities of modern superconductor design
Simulating large superconducting systems often exceeds the limits of traditional on-premise tools, resulting in long runtimes and delays in development.
Intricate, asymmetrical coil designs (e.g., stellarators) are difficult to model. Traditional tools struggle, leading to longer simulations and reduced accuracy.
Capturing the dynamic behavior of superconductors under varying currents and fields requires computationally heavy transient analysis, often taking days to complete.
Design optimization and AI model training demand extensive parameter sweeps. Traditional tools can’t scale efficiently, stalling iteration and innovation.
Built for the design of advanced superconducting systems
Natively coupled multiphysics out-of-the-box
- Natively coupled thermal, mechanical, and electromagnetic physics
- Robust algorithms with strongly coupled multiphysics
- All physics interactions readily available and integrated

Nonlinear solver fine-tuned for superconductors
- Strong nonlinear solver tuned to handle superconducting materials
- H-Phi formulation and Thin-Shell method implementations for high-fidelity electromagnetic field calculations
- Quadruple precision for increased accuracy in complex models

Domain Decomposition Method (DDM) and cloud-based scalability
- Efficient parallel processing of large-scale simulations
- Cloud scalability for fast turnaround times
- Solves previously intractable superconducting systems

API for automation, integration & proprietary workflows
- Automate repetitive tasks and programmatically control simulations
- Integrate with existing software and systems
- Build custom tools and proprietary simulation workflows

Learn more about the real-world impact of Allsolve

Webinar recording & PDF summary
How Proxima Fusion uses Quanscient Allsolve in stellarator and HTS magnet design
Blog
How cloud-based multiphysics software is used today for advanced HTS design
Webinar recording & PDF summary
Live simulation of a nuclear stellarator with other real-world results
Complete features for a comprehensive simulation workflow


Unlimited users within an organization. Secure project sharing with custom permissions. No version incompatibilites.

Flexible pricing according to capacity requirements. Access to high-performance computing resources without the overhead costs. Unlimited users with every plan.

End-to-end data encryption. Strict access control protocols. Regular security audits (SOC2 & ISO 27001).

Intuitive and modern GUI. Python scripting interface for full control and customization. Pre-built script libraries.

Comprehensive documentation and user guides. Support accessible directly in the platform. Expert support from our application engineers.
Other real-life case examples

In this paper, we cover the case study with Proxima Fusion and Atled Engineering simulating a full-scale stellarator (300M+ unknowns) in under 9 minutes using 500 cores.

Step-by-step simulation of magnetoquasistatic and thermal behavior of a complex, non-insulated 3D HTS coil. demonstrating the intuitive GUI and automated features (e.g., cuts for unconstrained coils) simplifying the setup.

Allsolve accurately predicted AC losses in a superconducting filament simulation (1.4M degrees of freedom). It solved the problem in 1 hour 45 minutes (640 cores), compared to 8 days for a leading desktop solver on a 96-core HPC.

Request a live demo
In the live demo, we'll
- Explore use cases and workflow integration
- Discuss pricing and value
- Discover features and benefits
We'll get back to you within 1 business day.