Advanced search

Filter By:

Journal Check one or more journals to show results from those journals only.

Choose more journals

Article type Check one or more article types to show results from those article types only.
Subject Check one or more subjects to show results from those subjects only.
Date Choose a date option to show results from those dates only.

Custom date range

Clear all filters
Sort by:
Showing 1–6 of 6 results
Advanced filters: Author: Ingo Pinnau Clear advanced filters

  • Conventional separations account for a large share of global energy consumption. Efficient membrane technologies have the potential to substantially reduce energy use, costs and CO2 emissions — particularly through ultramicroporous polymers, a key class of materials advancing membrane-based gas separations first reported by Budd and McKeown in 2004.

    • Ingo Pinnau
    • Yingge Wang
    News & Views
    Nature Chemical Engineering
    Volume: 3, P: 20-21

  • As part of the first anniversary issue of Nature Chemical Engineering, we present a collection of opinions from 40 researchers within the field on what they think are the most exciting opportunities that lie ahead for their respective topics.

    • Claire S. Adjiman
    • Panagiota Angeli
    • Yushan Yan
    Special Features
    Nature Chemical Engineering
    Volume: 2, P: 19-25

  • Ethylene separation from ethane is the most energy-intensive separation in the chemical process industry, but so far membranes have not exceeded an ethylene/ethane selectivity of >20 in mixed gases. Here a carbon molecular sieve with an ethylene selectivity of ~100 and long-term stability under high-pressure gas is reported.

    • Khalid Hazazi
    • Yingge Wang
    • Ingo Pinnau
    Research
    Nature Materials
    Volume: 22, P: 1218-1226

  • Carbon nanomaterials such as graphene show intriguing molecular transport properties, but to achieve regular channels over a large area requires perfect sheet alignment. Here, a large-area two-dimensional conjugated-polymer-framework is grown with regular pore distribution, enabling 99.5% salt rejection by forward osmosis.

    • Jie Shen
    • Yichen Cai
    • Yu Han
    Research
    Nature Materials
    Volume: 21, P: 1183-1190

  • Radioactive molecular iodine (I2) and methyl iodide (CH3I) coexist in the off-gas stream of nuclear power plants at low concentrations and only few adsorbents can effectively adsorb low-concentration I2 and CH3I simultaneously. Here, the authors demonstrate simultaneous capture of I2 and CH3I at low concentrations by exploiting different adsorptive sites in a covalent organic framework.

    • Yaqiang Xie
    • Tingting Pan
    • Yu Han
    ResearchOpen Access
    Nature Communications
    Volume: 13, P: 1-10