ABOUT US
At the New Phase Metallics and Manufacturing Laboratory (the NPMM Lab) we work at the forefront of liquid metals—a family of low-melting-temperature metals and alloys that, despite their long history, have not received substantial attention until recently. We find interest in fundamental questions that drive scientific breakthroughs and inspire engineering innovations. Our liquid metal-focused research is highly interdisciplinary in terms of both the material systems involved and the methodologies employed. In a new phase of making and utilizing metallic materials, we aim to create transformative impact through the ways of liquid metals.
The NPMM Lab is part of the Department of Materials Science and Engineering within the School of Engineering at Westlake University.
Navigate the NPMM Lab
Interactive Keyword Cloud
OXIDATION
Oxidation transforms metals into semiconducting metal oxides
DROPLETS
Droplets are capillary objects. Small volumes of liquid metals are very likely to form droplets owing to their high surface tension. Liquid metal droplets are often shielded by an easy-to-overlook thin oxide layer
METALLICS
Yes! We carry out metal-intensive research at the NPMM Lab. With a strong focus on liquid metals, our interest extends to metals and alloys in a more general context, metal derivatives (e.g., metal oxides), as well as other non-metallics processable using liquid metals
NEW PHASE
A new material phase—what we always look for in daily experiments! A transformative era reshaping how we process and utilize metals and alloys
APPLICATIONS
LIQUID METALS
A unique state of metallic matter that is easy melting, free flowing when melted, electrically/thermally conductive, atomically frustrated yet dynamic, and chemically active. These futuristic-looking metallic liquids can have surprising properties and behaviors
INTERMETALLIC
A tale of long-range-order compound metals
MANUFACTURING
Our material manufacturing practices combine cross-disciplinary methodologies to drive technological innovations. We aim to manipulate material structures/properties at the smallest possible scale while achieving large-scale, high-throughput production
CRYSTAL GROWTH
Crystals grown in our lab have a strong metallic flavor. We use liquid metal solvents to grow crystals with well-defined phases and shapes
PATTERN FORMATION
A usually autonomous but describable structural evolution process in developmental material systems
WETTING & SPREADING
The dance of a liquid (metal) phase trying to balance the three-phase contact line
ALLOYING/DEALLOYING
Performing addition/subtraction operations by forming, breaking or rearranging metallic bonds
PHASE TRANSFORMATION
SPONTANEOUS PROCESSES
We are interested in (controlling) spontaneous processes such as phase transformation, oxidation, alloying, dealloying, wetting/spreading
SURFACE-CRETICAL PHENOMENA
A material’s surface can behave (e.g., melt, solidify, form structures, or react) rather differently compared to its bulk. This is particularly true when it comes to dynamic liquid metal systems
INTERMETALLIC WETTING/REACTION
An irreversible wetting state resulting from the intimate (direct) interfacial contact established by a suitable metallic liquid-solid couple, usually involves interdiffusion and new phase formation
Ordering
Catalysts
Thin Films
Electronics
Instabilities
Composites
Bio Sensing
Soft Matters
Gas Sensing
Surface Flows
Fluids & Flows
Optoelectronics
Self-Assembling
Electrochemistry
Self-Organization
Nanoporous Metals
Material Intelligence
Biomimetic Systems
Thermal Management
Nature-Inspired Design
Liquid Phase Processing
Advanced Manufacturing
Thermal Interface Materials
NEWS & EVENTS
May 21, 2025 | ACS Nano
A new way of growing substrate-supported crystals from a liquid metal solvent
Liquid phase deposition is widely employed for growing substrate-supported thin films and structures...Read more
Apr 04, 2025 | Adv. Funct. Mater.
Collaborative project on 2D indium oxide with self-embedded Schottky junctions for room-temperature hydrogen sensing
Semiconductor-based hydrogen sensors provide cost-efficient solutions for safety and a circular...Read more
Mar 12, 2025 | Adv. Funct. Mater.
Liquid metal solutions for p-type 2D gallium oxide
The naturally self-limiting oxide formed on the surface of liquid metals can be exfoliated and...Read more
Feb 24, 2025 | ACS Nano
Biosensing with liquid metal-synthesized mesoporous noble metal thin films
Nanoporous thin films of noble metals are known for their exceptional durability, biocompatibility...Read more
Jan 13, 2025 | Engineering Special Seminar
Bio-inspired nanoionic materials for wearable devices
Dewei Chu a Full Professor and ARC Mid-career Industry Fellow in the School of Materials Science...Read more
Jan 06, 2025 | Engineering Special Seminar
Soft conductive nanocomposites for wearables
Shuhua Peng is a Senior Lecturer and Australian Research Council (ARC) Future Fellow in the School of...Read more
Jan 06, 2025 | Engineering Special Seminar
Polymer Nanocomposites for High-performance Wearable Sensors and Composite Structures
Shuying Wu is a Senior Lecturer in the School of Aerospace, Mechanical and Mechatronic Eng...Read more
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ACS Nano (May 21, 2025)
Yuanzhu Mao et al | A new way of growing substrate-supported crystals from a liquid metal solvent
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Adv. Funct. Mater. (Apr 04, 2025)
Yang Yang et al | Collaborative project on 2D indium oxide with self-embedded Schottky junctions for room-temperature hydrogen sensing
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Adv. Funct. Mater. (Mar 12, 2025)
Laetitia Bardet et al | Liquid metal solutions for p-type 2D gallium oxide
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ACS Nano (Feb 24, 2025)
Lucy Johnston et al | Biosensing with liquid metal-synthesized mesoporous noble metal thin films
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Engineering Special Seminar (Jan 13, 2025)
Dewei Chu | Bio-inspired nanoionic materials for wearable devices
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Engineering Special Seminar (Jan 06, 2025)
Shuhua Peng | Soft conductive nanocomposites for wearables
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Engineering Special Seminar (Jan 06, 2025)
Shuying Wu | Polymer Nanocomposites for High-performance Wearable Sensors and Composite Structures