Vision & Mission

Vision

To be a global leader in cutting-edge research, development and education in sustainable energy generation, storage, distribution and utilization through multidisciplinary methodologies.
 

Mission

  • To engage in emerging energy research that will have a long-term, transformative impact on Hong Kong and nation's energy future.
  • To develop technologies, policies, and educational programs that have the potential to offer high-impact solutions to pressing near-term energy issues
  • To develop and organize undergraduate and postgraduate educational energy programs
  • To develop and influence energy strategies and policies in Hong Kong in response to the urgency of energy concerns

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News

Prof. Tim Cheng (fourth from right) joined the award presentation ceremony held in Taiwan via video conferencing.
Prof. Tim Cheng (fourth from right) joined the award presentation ceremony held in Taiwan via video conferencing.
The team has successfully made the prototype of the “super human eye” – an artificial visual system that uses a spherical biomimetic electrochemical eye with hemispherical retina made of a high-density perovskite nanowire array. From left: Swapnadeep Poddar, Shu Lei, Zhang Daquan, Prof. Fan Zhiyong, Dr. Gu Leilei and Long Zhenghao.
The team has successfully made the prototype of the “super human eye” – an artificial visual system that uses a spherical biomimetic electrochemical eye with hemispherical retina made of a high-density perovskite nanowire array. From left: Swapnadeep Poddar, Shu Lei, Zhang Daquan, Prof. Fan Zhiyong, Dr. Gu Leilei and Long Zhenghao.
E-fuel – Prof. Zhao’s latest breakthrough in smart and sustainable energy storage, was featured on campus.
E-fuel – Prof. Zhao’s latest breakthrough in smart and sustainable energy storage, was featured on campus.
Impression of the HKUST(GZ) campus. Photo credit: KPF
Impression of the HKUST(GZ) campus. Photo credit: KPF

RESEARCH HIGHLIGHTS

Energy Efficient Adsorption Cooling System for Buildings and Industrial Applications

Adsorption refrigeration is a green technology in which the system can be powered by low-grade heat energy, such as solar energy and/or low-grade waste heat. The system does not rely on traditional refrigerants (e.g. HCFCs and HFCs) or compressors. Advanced composite adsorbent material developed at HKUST is very economical, creates no pollution during operation and disposal and can be recycled.

Direct Alcohol Fuel Cells

Direct alcohol fuel cells (DAFC) convert the chemical energy of liquid alcohol directly into electricity. This type of fuel cell creates the potential for a simple, low-cost, compact and high energy-conversion system that is highly efficient and clean.

Flow Batteries for Grid-Scale Energy Storage

The most striking feature of flow batteries is that, for a given power pack with a rated power, the energy capacity can be increased by increasing the volume of the energy-storage tanks to meet the requirements of particular applications, without a change in the cell. This system scalability, along with other unique characteristics, makes flow batteries a promising solution to the energy storage challenge of many types of renewable energy systems with intermittent sources, such as wind and solar power.

Nanocarbon Materials for Ultra-High Performance Energy Storage

Of the various energy conversion and storage devices, rechargeable Li batteries and percapacitors are considered the most promising candidates to power next generation electric vehicles. The ever-increasing demands for higher energy/power densities of these electrochemical storage devices have led to search for novel electrode materials. This project aims to study different nanocarbon materials, in particular, carbon nanotubes, graphene nanosheets, graphene foams and electrospun carbon nanofibers, along with metal oxides.

Nano and Molecular Scale Engineering of Solar Cells

This project area aims to develop and investigate the next generation of sensitized solar cells with high efficiency, low cost, high stability and green impacts. A conceptually new quantum well sensitizer for semiconductor sensitized solar cells has been proposed and nicely demonstrated by developing a quasi-quantum well structure supported on tetrapods.

High Performance and High Cycle-life Lead-Acid Batteries with Carbon-based Electrodes

This project aims to reduce lead-acid batteries’ sulfation problem and enhance its cycle life through addition of graphene into electrodes. It also explores the fundamental electrochemical mechanism of the interface between graphene and active material, as well as its impact on the battery performance.