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update readme
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README.md
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dataset_info:
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features:
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- name: image
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dtype: image
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- name: question
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dtype: string
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- name: choices
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list: string
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- name: answer
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dtype: int32
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- name: meta_info
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struct:
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- name: title
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dtype: string
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- name: journal
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dtype: string
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- name: doi
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dtype: string
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- name: url
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dtype: string
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- name: question_type
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dtype: string
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splits:
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- name: en
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num_bytes: 546653187.125
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num_examples: 1525
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- name: zh
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num_bytes: 546319847.125
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num_examples: 1525
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download_size: 218606009
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dataset_size: 1092973034.25
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configs:
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- config_name: RxnBench-VQA
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data_files:
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- split: en
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path: data/en-*
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- split: zh
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path: data/zh-*
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license: cc-by-nc-4.0
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task_categories:
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- visual-question-answering
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language:
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- en
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- zh
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tags:
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- chemistry
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---
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# SpecVQA: A Benchmark for Spectral Understanding and Visual Question Answering in Scientific Images
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1. NMR (Nuclear Magnetic Resonance) involves interpreting chemical shifts (
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2. IR (Infrared Absorption Spectroscopy) involves identifying characteristic vibrational frequencies ($\text{cm}^{-1}
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3. XRD (X-ray Diffraction) requires analyzing diffraction peak positions ($2\theta$), intensities, and widths to infer crystal structures, lattice parameters, and crystallite sizes.
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4. Raman (Raman Spectroscopy) focuses on interpreting Raman-active vibrational modes to probe molecular symmetry and bonding characteristics, particularly in materials such as carbon-based systems.
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5. MS (Mass Spectrometry) involves analyzing molecular ion peaks and fragmentation patterns to determine molecular weight and identify structural fragments.
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# SpecVQA: A Benchmark for Spectral Understanding and Visual Question Answering in Scientific Images
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1. NMR (Nuclear Magnetic Resonance) involves interpreting chemical shifts \(\delta\), integration areas, coupling constants \(J\), and multiplicity to deduce molecular structures.
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2. IR (Infrared Absorption Spectroscopy) involves identifying characteristic vibrational frequencies \($\text{cm}^{-1}$\) to determine the presence or absence of specific functional groups.
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3. XRD (X-ray Diffraction) requires analyzing diffraction peak positions ($2\theta$), intensities, and widths to infer crystal structures, lattice parameters, and crystallite sizes.
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4. Raman (Raman Spectroscopy) focuses on interpreting Raman-active vibrational modes to probe molecular symmetry and bonding characteristics, particularly in materials such as carbon-based systems.
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5. MS (Mass Spectrometry) involves analyzing molecular ion peaks and fragmentation patterns to determine molecular weight and identify structural fragments.
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