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In multiple dimensions, the conservation of momentum applies in each direction independently. Hence, to solve collisions in multiple dimensions, we should write down the momentum conservation in each direction separately. To help understand collisions in multiple dimensions, consider an example.
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It is far more common for collisions to occur in two dimensions; that is, the initial velocity vectors are neither parallel nor antiparallel to each other. Let's see what complications arise from this. The first idea is that momentum is a vector. Like all vectors, it can be expressed as a sum of perpendicular components (usually, though not always, an x-component and a y-component, and a z-component if necessary). Thus, when the statement of conservation of momentum is written for a...
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Elastic collision of a system demands conservation of both momentum and kinetic energy. To solve problems involving one-dimensional elastic collisions between two objects, the equations for conservation of momentum and conservation of internal kinetic energy can be used. For the two objects, the sum of momentum before the collision equals the total momentum after the collision. An elastic collision conserves internal kinetic energy, and so the sum of kinetic energies before the collision equals...
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An elastic collision is one that conserves both internal kinetic energy and momentum. Internal kinetic energy is the sum of the kinetic energies of the objects in a system. Truly elastic collisions can only be achieved with subatomic particles, such as electrons striking nuclei. Macroscopic collisions can be very nearly, but not quite, elastic, as some kinetic energy is always converted into other forms of energy such as heat transfer due to friction and sound. An example of a nearly...
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When two or more objects collide with each other, they can stick together to form one single composite object (after collision). The total mass of the object after the collision is the sum of the masses of the original objects, and it moves with a velocity dictated by the conservation of momentum. Although the system's total momentum remains constant, the kinetic energy decreases, and thus such a collision is an inelastic collision. Most of the collisions between objects in daily life are...
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Base complementarity between the three base pairs of mRNA codon and the tRNA anticodon is not a failsafe mechanism. Inaccuracies can range from a single mismatch to no correct base pairing at all. The free energy difference between the correct and nearly correct base pairs can be as small as 3 kcal/ mol. With complementarity being the only proofreading step, the estimated error frequency would be one wrong amino acid in every 100 amino acids incorporated. However, error frequencies observed in...
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Updated: Sep 9, 2025

Augmenting Large Language Models via Vector Embeddings to Improve Domain-Specific Responsiveness
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Large Language Model-Empowered Compound Collision Cross-Section Prediction.

Zeyu Zhu1, Chengyi Xie2, Shaojie Lin1

  • 1Department of Electronic Science, National Institute for Data Science in Health and Medicine, Xiamen University, Xiamen 361005, China.

Analytical Chemistry
|September 1, 2025
PubMed
Summary
This summary is machine-generated.

HyperCCS enhances compound annotation accuracy in ion mobility-mass spectrometry using chemical large language models (CLLMs). This novel framework improves collision cross section (CCS) prediction, outperforming existing methods for diverse molecules.

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Area of Science:

  • Computational chemistry
  • Analytical chemistry
  • Biinformatics

Background:

  • Collision cross section (CCS) is vital for precise compound identification in ion mobility-mass spectrometry (IM-MS).
  • Current computational CCS prediction methods struggle with limited data and inadequate multimodal feature handling, leading to suboptimal performance.
  • Accurate CCS prediction is essential for building large-scale compound databases for IM-MS applications.

Purpose of the Study:

  • To develop a novel computational framework, HyperCCS, for accurate collision cross section (CCS) prediction.
  • To leverage chemical large language models (CLLMs) for capturing complex molecular information.
  • To integrate multimodal features effectively for improved predictive performance in IM-MS.

Main Methods:

  • Fine-tuned a chemical large language model (CLLM) pre-trained on extensive SMILES sequences.
  • Developed a cross-modal feature fusion module to integrate CLLM-derived features with other heterogeneous data.
  • Evaluated HyperCCS on benchmark datasets (METLIN-CCS, AllCCS2) and in-house experimental data.

Main Results:

  • HyperCCS demonstrated robust CCS prediction across various molecular masses, adduct types, and ion modes, outperforming existing methods.
  • The framework accurately resolved isomers and extrapolated predictions to high-mass analytes on experimental data.
  • SHAP analysis and ablation studies confirmed the significant contribution of CLLM features and the fusion mechanism.

Conclusions:

  • HyperCCS offers a significant advancement in computational CCS prediction for IM-MS.
  • The integration of CLLMs and cross-modal fusion effectively addresses limitations of previous prediction models.
  • HyperCCS provides a high-throughput, adaptable computational tool for metabolomics and structural biology research.