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Main Authors: Krijt, Sebastiaan, Banzatti, Andrea, Zhang, Ke, Pinilla, Paola, Kaeufer, Till, Bergin, Edwin A., Salyk, Colette, Pontoppidan, Klaus, Blake, Geoffrey A., Long, Feng, Huang, Jane, Colmenares, María José, Williams, Joe, Houge, Adrien, Narang, Mayank, Vioque, Miguel, Lambrechts, Michiel, Cleeves, L. Ilsedore, Öberg, Karin, collaboration, the JDISCS
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2508.10402
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author Krijt, Sebastiaan
Banzatti, Andrea
Zhang, Ke
Pinilla, Paola
Kaeufer, Till
Bergin, Edwin A.
Salyk, Colette
Pontoppidan, Klaus
Blake, Geoffrey A.
Long, Feng
Huang, Jane
Colmenares, María José
Williams, Joe
Houge, Adrien
Narang, Mayank
Vioque, Miguel
Lambrechts, Michiel
Cleeves, L. Ilsedore
Öberg, Karin
collaboration, the JDISCS
author_facet Krijt, Sebastiaan
Banzatti, Andrea
Zhang, Ke
Pinilla, Paola
Kaeufer, Till
Bergin, Edwin A.
Salyk, Colette
Pontoppidan, Klaus
Blake, Geoffrey A.
Long, Feng
Huang, Jane
Colmenares, María José
Williams, Joe
Houge, Adrien
Narang, Mayank
Vioque, Miguel
Lambrechts, Michiel
Cleeves, L. Ilsedore
Öberg, Karin
collaboration, the JDISCS
contents The influx of icy pebbles to the inner regions of protoplanetary disks constitutes a fundamental ingredient in most planet formation theories. The observational determination of the magnitude of this pebble flux and its dependence on disk substructure (disk gaps as pebble traps) would be a significant step forward. In this work we analyze a sample of 21 T Tauri disks (with ages $\approx 0.5{-}2\mathrm{~Myr}$) using JWST/MIRI spectra homogeneously reduced with the JDISCS pipeline and high-angular-resolution ALMA continuum data. We find that the 1500/6000 K water line flux ratio measured with JWST - a tracer of cold water vapor and pebble drift near the snowline - correlates with the radial location of the innermost dust gap in ALMA continuum observations (ranging from 8.7 to 69 au), confirming predictions from recent models that study connections between the inner and outer disk reservoirs. We develop a population synthesis exploration of pebble drift in gapped disks and find a good match to the observed trend for early and relatively effective gaps, while scenarios where pebble drift happens quickly, gaps are very leaky, or where gaps form late are disfavored on a population level. Inferred snowline pebble mass fluxes (ranging between $10^{-6}$ and $10^{-3}~M_\oplus/\mathrm{yr}$ depending on gap position) are comparable to fluxes used in pebble accretion studies and those proposed for the inner Solar System, while system-to-system variations suggest differences in the emerging planetary system architectures and water budgets.
format Preprint
id arxiv_https___arxiv_org_abs_2508_10402
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Cosmic cascades: How disk substructure regulates the flow of water to inner planetary systems
Krijt, Sebastiaan
Banzatti, Andrea
Zhang, Ke
Pinilla, Paola
Kaeufer, Till
Bergin, Edwin A.
Salyk, Colette
Pontoppidan, Klaus
Blake, Geoffrey A.
Long, Feng
Huang, Jane
Colmenares, María José
Williams, Joe
Houge, Adrien
Narang, Mayank
Vioque, Miguel
Lambrechts, Michiel
Cleeves, L. Ilsedore
Öberg, Karin
collaboration, the JDISCS
Earth and Planetary Astrophysics
Solar and Stellar Astrophysics
The influx of icy pebbles to the inner regions of protoplanetary disks constitutes a fundamental ingredient in most planet formation theories. The observational determination of the magnitude of this pebble flux and its dependence on disk substructure (disk gaps as pebble traps) would be a significant step forward. In this work we analyze a sample of 21 T Tauri disks (with ages $\approx 0.5{-}2\mathrm{~Myr}$) using JWST/MIRI spectra homogeneously reduced with the JDISCS pipeline and high-angular-resolution ALMA continuum data. We find that the 1500/6000 K water line flux ratio measured with JWST - a tracer of cold water vapor and pebble drift near the snowline - correlates with the radial location of the innermost dust gap in ALMA continuum observations (ranging from 8.7 to 69 au), confirming predictions from recent models that study connections between the inner and outer disk reservoirs. We develop a population synthesis exploration of pebble drift in gapped disks and find a good match to the observed trend for early and relatively effective gaps, while scenarios where pebble drift happens quickly, gaps are very leaky, or where gaps form late are disfavored on a population level. Inferred snowline pebble mass fluxes (ranging between $10^{-6}$ and $10^{-3}~M_\oplus/\mathrm{yr}$ depending on gap position) are comparable to fluxes used in pebble accretion studies and those proposed for the inner Solar System, while system-to-system variations suggest differences in the emerging planetary system architectures and water budgets.
title Cosmic cascades: How disk substructure regulates the flow of water to inner planetary systems
topic Earth and Planetary Astrophysics
Solar and Stellar Astrophysics
url https://arxiv.org/abs/2508.10402