Teaching physics to AI allows it to discover new insights into material properties

Teaching physics to AI makes the student a master
Silicon metamaterials such as this, featuring rows of cylinders extending into the distance, can manipulate light depending on the features of the cylinders. Research has now shown that incorporating known physics into a machine learning algorithm can reveal new insights into how to design them. Credit: Duke University

Researchers at Duke University have demonstrated that incorporating known physics into machine learning algorithms can help the inscrutable black boxes attain new levels of transparency and insight into material properties.

In one of the first projects of its kind, researchers constructed a modern algorithm to determine the properties of a class of engineered materials known as metamaterials and to predict how they interact with .

Because it first had to consider the metamaterial's known physical constraints, the program was essentially forced to show its work. Not only did the approach allow the algorithm to accurately predict the metamaterial's properties, it did so more efficiently than previous methods while providing new insights.

The results appear online the week of May 9 in the journal Advanced Optical Materials.

"By incorporating known physics directly into the machine learning, the algorithm can find solutions with less training data and in less time," said Willie Padilla, professor of electrical and computer engineering at Duke. "While this study was mainly a demonstration showing that the approach could recreate known solutions, it also revealed some insights into the inner workings of non-metallic metamaterials that nobody knew before."

Metamaterials are composed of many individual engineered features, which together produce properties not found in nature through their structure rather than their chemistry. In this case, the metamaterial consists of a large grid of silicon cylinders that resemble a Lego baseplate.

Depending on the size and spacing of the cylinders, the metamaterial interacts with in various ways, such as absorbing, emitting or deflecting specific wavelengths. In the new paper, the researchers sought to build a type of machine learning model called a neural network to discover how a range of heights and widths of a single cylinder affects these interactions. But they also wanted its answers to make sense.

"Neural networks try to find patterns in the data, but sometimes the patterns they find don't obey the laws of physics, making the model it creates unreliable," said Jordan Malof, assistant research professor of electrical and computer engineering at Duke. "By forcing the neural network to obey the , we prevented it from finding relationships that may fit the data but aren't actually true."

The physics that the research team imposed upon the neural network is called a Lorentz model—a set of equations that describe how the intrinsic properties of a material resonates with an electromagnetic field. Rather than jumping straight to predicting a cylinder's response, the model had to learn to predict the Lorentz parameters that it then used to calculate the cylinder's response.

Incorporating that extra step, however, is much easier said than done.

"When you make a neural network more interpretable, which is in some sense what we've done here, it can be more challenging to fine tune," said Omar Khatib, a postdoctoral researcher working in Padilla's laboratory. "We definitely had a difficult time optimizing the training to learn the patterns."

Once the model was working, however, it proved to be more efficient than previous neural networks the group had created for the same tasks. In particular, the group found this approach can dramatically reduce the number of parameters needed for the model to determine the metamaterial properties.

They also found that this physics-based approach is capable of making discoveries all on its own.

As an electromagnetic wave travels through an object, it doesn't necessarily interact with it in exactly the same way at the beginning of its journey as it does at its end. This phenomenon is known as spatial dispersion. Because the researchers had to tweak the spatial dispersion parameters to get the model to work accurately, they discovered insights into the physics of the process that they hadn't previously known.

"Now that we've demonstrated that this can be done, we want to apply this approach to systems where the is unknown," Padilla said.

"Lots of people are using to predict , but getting enough training data from simulations is a giant pain," Malof added. "This work also shows a path toward creating models that don't need as much data, which is useful across the board."


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More information: Omar Khatib et al, Learning the Physics of All‐Dielectric Metamaterials with Deep Lorentz Neural Networks, Advanced Optical Materials (2022). DOI: 10.1002/adom.202200097
Journal information: Advanced Optical Materials

Provided by Duke University
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