Korea Advanced Institute of Science and Technology (KAIST)

South Korea

KAIST is the first and top science and technology university in Korea. In the wake of its 50th anniversary, KAIST is scaling up new research initiatives in order to become a ‘first mover.’ This is in line with its plan to pivot away from its previous role as a ‘fast follower,’ a role that led to Korea’s rapid industrialization.

Established in 1971 by the Korean government, KAIST was tasked with the very clear institutional mission to make innovations that would drive the country’s economic growth engine, especially in the fields of ICT and electronics. KAIST has fully achieved its institutional mission, creating a very successful educational model that is now being benchmarked by many other countries.

Turning 50 years old in 2021, its R&D strategy has shifted to focus on creating global value for the future. Among others, the Global Singularity Research Project aims to identify the most critical projects which will make the biggest difference in people’s lives.

This innovative research project selects the two most creative and future-oriented research projects every year. Young researchers’ projects on new materials, neuro-rehabilitation, and brain function redesign selected as this research program will surely bring breakthroughs which will serve as game changers for the future.

For more information on KAIST research, visit https://www.kaist.ac.kr/en/html/research/04.html

KAIST retains sole responsibility for content © 2020 KAIST.

1 June 2019 - 31 May 2020

Region: Global
Subject/journal group: All

The table to the right includes counts of all research outputs for Korea Advanced Institute of Science and Technology (KAIST) published between 1 June 2019 - 31 May 2020 which are tracked by the Nature Index.

Hover over the donut graph to view the FC output for each subject. Below, the same research outputs are grouped by subject. Click on the subject to drill-down into a list of articles organized by journal, and then by title.

Note: Articles may be assigned to more than one subject area.

Count Share
378 152.13

Outputs by subject (Share)

Subject Count Share
Life Sciences 97 29.64
Physical Sciences 209 81.43
23 8.30
24 12.64
Complementary n‐Type and p‐Type Graphene Films for High Power Factor Thermoelectric Generators
Multiarray Nanopattern Electronic Nose (E‐Nose) by High‐Resolution Top‐Down Nanolithography
Ex‐Solved Ag Nanocatalysts on a Sr‐Free Parent Scaffold Authorize a Highly Efficient Route of Oxygen Reduction
Human‐Palm‐Inspired Artificial Skin Material Enhances Operational Functionality of Hand Manipulation
Macroporous Hydrogels for Fast and Reversible Switching between Transparent and Structurally Colored States
Selective, Quantitative, and Multiplexed Surface‐Enhanced Raman Spectroscopy Using Aptamer‐Functionalized Monolithic Plasmonic Nanogrids Derived from Cross‐Point Nano‐Welding
Materials, Mechanics Designs, and Bioresorbable Multisensor Platforms for Pressure Monitoring in the Intracranial Space
Silica Nanodepletors: Targeting and Clearing Alzheimer's β‐Amyloid Plaques
Metal–Organic Framework‐Derived Graphitic Nanoribbons Anchored on Graphene for Electroionic Artificial Muscles
Plasmon‐Induced Hot Carrier Separation across Dual Interface in Gold–Nickel Phosphide Heterojunction for Photocatalytic Water Splitting
Heme Cofactor‐Resembling Fe–N Single Site Embedded Graphene as Nanozymes to Selectively Detect H2O2 with High Sensitivity
The Biomolecular Corona in 2D and Reverse: Patterning Metal–Phenolic Networks on Proteins, Lipids, Nucleic Acids, Polysaccharides, and Fingerprints
Self‐Assembled Room Temperature Multiferroic BiFeO3‐LiFe5O8 Nanocomposites
Mutually Exclusive p‐Type and n‐Type Hybrid Electrode of MoS2 and Graphene for Artificial Soft Touch Fingers
Microfluidic Fabrication of Capsule Sensor Platform with Double‐Shell Structure
A Bioresorbable Magnetically Coupled System for Low‐Frequency Wireless Power Transfer
Ferroelectric‐Polymer‐Enabled Contactless Electric Power Generation in Triboelectric Nanogenerators
Rapid and Large‐Scale Fabrication of Full Color Woodpile Photonic Crystals via Interference from a Conformal Multilevel Phase Mask
A General Synthesis of Crumpled Metal Oxide Nanosheets as Superior Chemiresistive Sensing Layers
Additive Manufacturing of Biomechanically Tailored Meshes for Compliant Wearable and Implantable Devices
Heterogeneous, Porous 2D Oxide Sheets via Rapid Galvanic Replacement: Toward Superior HCHO Sensing Application
Hall Effect in Polycrystalline Organic Semiconductors: The Effect of Grain Boundaries
Precious‐Metal‐Free Electrocatalysts for Activation of Hydrogen Evolution with Nonmetallic Electron Donor: Chemical Composition Controllable Phosphorous Doped Vanadium Carbide MXene
Janus Microcarriers for Magnetic Field‐Controlled Combination Chemotherapy of Hepatocellular Carcinoma
15 6.53
6 4.33
9 2.54
39 14.93
16 9.42
3 0.21
30 8.73
2 0.21
2 1.05
3 1.44
3 0.15
1 0.08
2 0.17
10 3.86
1 0.08
6 2.96
3 0.49
10 3.05
1 0.25
Chemistry 156 73.65
Earth & Environmental Sciences 3 0.43

Highlight of the month

Stretchable tissue samples make for faster analysis

© Andriy Onufriyenko/Getty

© Andriy Onufriyenko/Getty

A technique that temporally makes tissue samples both robust and stretchy will speed up studies that involve running multiple tests over extended times on the same tissue samples.

Some research projects require delicate tissues samples to be interrogated multiple times over several years. This is both time consuming and difficult to do without damaging the samples.

Now, a team that included researchers from the Korea Advanced Institute of Science and Technology (KAIST) has found a way to convert biological tissues into elastic hydrogels.

The stretchability of the treated tissues makes them more robust and easier to label them with fluorescent dyes. Furthermore, the change is reversible so that the tissues revert to their normal state.

The team demonstrated the technique by using to produce elasticized slabs of brain tissue. They anticipate that the team will accelerate the investigation of animal models and human samples.

Supported content

  1. Nature Methods 17, 609–613 (2020). doi: 10.1038/s41592-020-0823-y

View the article on the Nature Index

See more research highlights from Korea Advanced Institute of Science and Technology (KAIST)

More research highlights from Korea Advanced Institute of Science and Technology (KAIST)

1 June 2019 - 31 May 2020

International vs. domestic collaboration by Share

  • 48.28% Domestic
  • 51.72% International

Note: Hover over the graph to view the percentage of collaboration.

Note: Collaboration is determined by the fractional count (Share), which is listed in parentheses.

Affiliated joint institutions and consortia

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