A Unified Platform for
Materials Science.

Efficiently uncover patterns and relationships across multiple data streams.

Use it yourself within 24 hours.

What it is

Unified materials data unlocks the future of Materials Science.

Store, Manage, and Transform Your Data at Scale

1. Tailored data models make it easy to store all of your data, files, metadata, and notes, enabling users to find real-world relationships between context and observations.

2. Frictionless data ingestions and zero- or low-configuration automated analysis with AI and ML models extracts physical insights into first-of-their-kind datasets.

3. A workspace to test experimental hypotheses, organize investigations, and run predictive workflows in real-time.

4. Collaboration views with team members and colleagues to share interactive analyses, data access, process tools, and work products.

Image of a RHEED pattern

Built-in Automation and Growing Capabilities

An expanding set of automation capabilities unifies data and lowers the manual effort required to contextualize data streams containing information about atomic structure, composition, microstructure, and processing conditions.

Extracting information from files automatically accelerates analysis efforts and ensures continued and ongoing value to your data. Intelligent parsing of metadata, free-text notes, and filenames reduces friction to assemble the complete materials processing context.

On AtomCloud, the value of data from both positive and negative trials compounds over time to provide guidance for the next iteration of R&D.

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Why it helps

Materials science data covers a wide range of formats and file types, typically stored in file-tree structures on local or shared drives. Data is analyzed serially with an emphasis on deep, hands-on investigation. Conclusions or information are evaluated by the scientist at the center of this process. While effective, this approach runs into a scaling rate problem as it lacks a clear path for breaking through the challenge of nonlinear synthesis control.

AtomCloud's unified data platform aims to take major step forward in creating the infrastructure and tools to integrate data at the scale needed to accelerate the time-to-control for the synthesis and commercialization of new materials.

FAQs

Case Studies

AtomCloud helps operators extract insights from RHEED patterns across broad material systems.

Composition and RHEED pattern correleation

In-situ Proxy for Composition

Performing XPS to determine composition for each sample.AtomCloud's automatically extracted pattern features correlated closely with dopant concentration allowing compostion for subsiquent samples to be estimated from in-situ RHEED.
Composition and RHEED pattern correleation

Cross Data Stream Pattern Detection

Manual hypothesis-test iterations to identify relationships.AtomCloud's data model enables automated search for patterns within connected data. Early relationship identification accelerates materials engineering and synthesis control.
CoSi material system RHEED pattern image

Detecting Kinetic Transitions

A video of a CoSi material system with complex patterns, low-contrast, and long duration is difficult to analyze by eye.AtomCloud's RHEED analysis workflow was able to automatically detect a subtle but validated pattern change
CoSi material system RHEED pattern image

Analysis Technology

Analyzing RHEED patterns by eye is time-consuming and prone to errors.AtomCloud uses unsupervised learning algorithms and materials science-specifc clustering techniques to automatically analyze RHEED patterns.
CoSi material system RHEED pattern image

Analyzing Rotating Growths

RHEED videos of rotating growths are difficult to analyze.AtomCloud's RHEED analysis workflow accounts for rotation, unlocking rotating RHEED videos as a source of insight.

Try AtomCloud yourself.

Book a demo to see how AtomCloud can unify your materials characterization data.

Response within 24 hours.