Vertical Structure of Protoplanetary Disks in Scattered Light: A large sample analysis

TL;DR

This study develops a new method to measure the vertical structure of 92 protoplanetary disks using scattered-light images, revealing diverse flaring behaviors and exploring their relation to disk and stellar properties.

Contribution

Introduction of the SEEF algorithm for extracting vertical height profiles from scattered-light images across a large, diverse disk sample.

Findings

Vertical heights are consistent with flared disk geometries.

Extended disks (>150 au) show a clear power-law flaring trend.

No strong correlations found with stellar mass, age, or dust mass.

Abstract

High-resolution scattered-light imaging has revealed complex morphologies in protoplanetary and circumstellar disks. Measuring the vertical height of the scattering surface is key to understanding disk structure, evolution, and the properties of embedded dust. We develop a methodology for fitting elliptical shapes to scattered-light images of protoplanetary disks in order to extract vertical height profiles of the dust scattering surface across a large and morphologically diverse disk sample. The dataset consists of 92 near-infrared polarimetric images obtained with VLT/SPHERE. The aim is to identify trends in vertical structure across different disk morphologies and test for correlations with stellar mass, age, and disk dust mass, as well as to investigate the implications of the derived height profiles for the masses of potential embedded planets. We implement a structure extraction and ellipse fitting (SEEF) algorithm that uses edge detection and Gaussian fitting to locate disk structures. Ellipse fitting reveals spatial offsets between the ellipse centre and the stellar position, which are interpreted as vertical height assuming circular ring geometry. Disk inclination, position angle, and the aspect ratio h/r are also derived. The method yields vertical height measurements for 92 disks, showing profiles consistent with flared disk geometries. However, the full sample cannot be described by a single power-law relation. Subdivision by morphology shows no strong correlations for most disk classes, except for extended disks with outer radii larger than about 150 au, which exhibit a clear power-law flaring trend. The lack of strong correlations with other system properties suggests that either different morphologies exhibit distinct vertical structures or that additional physical factors influence disk flaring.