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Main Authors: Shin, Seohyeon, Choi, HanJun, Park, Jun-Hyung, Kim, Hong Kook, Kim, Mansu
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2604.04403
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author Shin, Seohyeon
Choi, HanJun
Park, Jun-Hyung
Kim, Hong Kook
Kim, Mansu
author_facet Shin, Seohyeon
Choi, HanJun
Park, Jun-Hyung
Kim, Hong Kook
Kim, Mansu
contents Large Language Models (LLMs) have significantly advanced molecular discovery, but existing multimodal molecular architectures fundamentally rely on autoregressive (AR) backbones. This strict left-to-right inductive bias is sub-optimal for generating chemically valid molecules, as it struggles to account for non-local global constraints (e.g., ring closures) and often accumulates structural errors during sequential generation. To address these limitations, we propose MolDA (Molecular language model with masked Diffusion with mAsking), a novel multimodal framework that replaces the conventional AR backbone with a discrete Large Language Diffusion Model. MolDA extracts comprehensive structural representations using a hybrid graph encoder, which captures both local and global topologies, and aligns them into the language token space via a Q-Former. Furthermore, we mathematically reformulate Molecular Structure Preference Optimization specifically for the masked diffusion. Through bidirectional iterative denoising, MolDA ensures global structural coherence, chemical validity, and robust reasoning across molecule generation, captioning, and property prediction.
format Preprint
id arxiv_https___arxiv_org_abs_2604_04403
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle MolDA: Molecular Understanding and Generation via Large Language Diffusion Model
Shin, Seohyeon
Choi, HanJun
Park, Jun-Hyung
Kim, Hong Kook
Kim, Mansu
Artificial Intelligence
Large Language Models (LLMs) have significantly advanced molecular discovery, but existing multimodal molecular architectures fundamentally rely on autoregressive (AR) backbones. This strict left-to-right inductive bias is sub-optimal for generating chemically valid molecules, as it struggles to account for non-local global constraints (e.g., ring closures) and often accumulates structural errors during sequential generation. To address these limitations, we propose MolDA (Molecular language model with masked Diffusion with mAsking), a novel multimodal framework that replaces the conventional AR backbone with a discrete Large Language Diffusion Model. MolDA extracts comprehensive structural representations using a hybrid graph encoder, which captures both local and global topologies, and aligns them into the language token space via a Q-Former. Furthermore, we mathematically reformulate Molecular Structure Preference Optimization specifically for the masked diffusion. Through bidirectional iterative denoising, MolDA ensures global structural coherence, chemical validity, and robust reasoning across molecule generation, captioning, and property prediction.
title MolDA: Molecular Understanding and Generation via Large Language Diffusion Model
topic Artificial Intelligence
url https://arxiv.org/abs/2604.04403