# Accelerate Mass Transport of Proton and Carbon Sources by Super‐Hygroscopic and Porous Nanosheets for Continuous CO2‐To‐Ethylene Upgrade

**Authors:** Silong Dong, Guobin Wen, Xinyu Yang, Xiaowen Zhang, Shuxuan Liu, Haoyang Xiong, Yinyi Liu, Kai Zong, Hao Li, Yifan Li, Yi Cui, Bohua Ren, Xin Wang, Mingliang Jin, Zhongwei Chen

PMC · DOI: 10.1002/advs.202502306 · Advanced Science · 2025-05-14

## TL;DR

This paper presents a new design for copper nanosheets that improve CO2-to-ethylene conversion by enhancing proton and CO2 transport.

## Contribution

A dual-functional channel design inspired by Tillandsia leaves that accelerates mass transport in CO2 reduction.

## Key findings

- The superhygroscopic network converts water vapor into liquid for proton delivery.
- Microporous CO2 channels enhance carbon source diffusion and ethylene production.
- The design achieves 96% Faradaic efficiency for ethylene with high stability over 170 hours.

## Abstract

Gas‐water/catalyst triple‐phase interface and the microenvironment play critical roles in the reaction kinetics and production rate of electrochemical carbon dioxide reduction reactions (CO2RR), which steer concerted proton‐electron transfer steps. Inspired by Tillandsia leaves, which efficiently capture H2O and CO2 from the air, copper nanosheets with dual‐functional channels are we designed: the superhygroscopic network enables capillary condensation, converting H2O(g) into H2O(l) to form H2O channels that ensure a stable supply of protons, while the CO2 channels formed by the microporous structure enhance the diffusion of CO2, thus enriching the carbon source. This synergistic design creates an optimal microenvironment for CO2 conversion by simultaneously delivering both protons and CO2 to the reaction interface. Time‐of‐flight secondary‐ion mass spectroscopy (TOF‐SIMS), X‐ray absorption spectroscopy (XAS) and multiphysics simulations further reveal the designed H2O and CO2 channels in the microenvironment to boost mass transports. Hence, the Faradaic efficiency (FE) for ethylene reaches up to 96% at ‐200 mA cm−2 with such localized triple‐phase interfaces, which simultaneously exhibits ultra‐high stability for over 170 h in the membrane electrode assembly (MEA) system. This strategy provides a construction methodology of H2O and CO2 channels for improving the selectivity and stability of electrochemical CO2 upgrades.

The conceptual diagram of the Tillandsia and a localized enlargement of its leaves.

## Linked entities

- **Chemicals:** CO2 (PubChem CID 280), ethylene (PubChem CID 6325)
- **Species:** Tillandsia (taxon 15170)

## Full text

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## Figures

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## References

48 references — full list in the complete paper: https://tomesphere.com/paper/PMC12302532/full.md

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Source: https://tomesphere.com/paper/PMC12302532