Synopsys QuantumATK 2024.09 full crack Synopsys QuantumATK vW-2024.09

download crack Synopsys QuantumATK 2024.09

QuantumATK is a professional and effective solution for materials modeling and atomistic simulation. It provides efficient and realistic material simulation modeling, deriving the true physical properties of a variety of complex materials.

The entire process is simple and fast, making in-depth exploration and development of new materials easier and saving time and resources.

All simulation methods are centralized in a single, easy-to-use platform, making the screening and selection of new materials more efficient. We strictly adhere to customer needs and tailor the most suitable products for them.

 

QuantumATK is an integrated platform of electronic and atomic-scale modeling tools written in Python and C++. It gives you access to a powerful set of simulation engines for R&D at the atomic scale:

• Density Functional Theory (DFT)
• Many-Body Perturbation Theory Method GW
• Semi-Empirical Tight Binding
• Classical Conventional and Machine-Learned Force Fields
• Non-Equilibrium Green’s Functions (NEGF) Method for device simulations

A QuantumATK installation comes with two executables – atkpython and quantumatk. The first one is an enhanced Python interpreter that includes the QuantumATK simulation engines. It is meant for running QuantumATK simulations via Python scripts directly from a terminal. The second executable launches QuantumATK NanoLab which provides an intuitive graphical user interface (GUI) on top of the QuantumATK engine.

The recommended way of using QuantumATK is via NanoLab. It helps you focus on your modeling task rather than technical details, by assisting you with the preparation steps. NanoLab also offers important tools for data analysis.

About QuantumATK 2024:

QuantumATK is a powerful simulation platform developed by Synopsys for atomic-scale modeling of materials, nanostructures, and devices. It combines:

• Density Functional Theory (DFT)
• Semi-empirical quantum mechanical methods
• Classical force fields
• Device simulation (NEGF + DFT for transport)

It is widely used in academia and industry for research in nanoelectronics, materials science, and quantum device design.