Hao Yu

About

Background

Hao Yu is a PhD student in Engineering at the University of Cambridge, building on an integrated master’s degree in Materials Science from the University of Oxford. His work spans low-dimensional materials, optoelectronics, photonic devices, and nanoscale fabrication—from close-space sublimation and transition metal dichalcogenide growth to micro-ring resonators and spectroscopy-intensive device studies.

He is motivated by how advanced material systems and careful device engineering can expand what is measurable and controllable in optical systems, including routes that may be relevant to emerging computing and sensing contexts where materials, photonics, and integration constraints intersect.

Experimentally, he works across fabrication-relevant processing and characterisation (including electron-beam lithography, thin-film processing, and multiple microscopy and spectroscopy modalities), complemented by modelling and scripting where it accelerates interpretation and reproducibility.

Research

Research interests

Photonic devices and resonance engineering

Micro-ring resonators and active tuning approaches, linking nanoscale processing with resonant wavelength control and optical test-bed measurements—building experience that transfers to precision photonic integration problems.

Low-dimensional materials and nanostructures

Transition metal dichalcogenides and related nanostructures, including core–shell geometries and nanowire systems, studied with an emphasis on formation pathways, morphology, and device-relevant interfaces.

Spectroscopy, characterisation, and data-driven analysis

Raman and photoluminescence workflows, correlative microscopy and spectroscopy, and Python tooling for batch analysis—reducing friction from raw spectra to stable parameters and maps.

Materials for emerging optoelectronics and instrumentation

Growth and processing routes that connect materials science to optoelectronic function—including close-space sublimation and chemistry-mediated formation—evaluated with an eye toward scalable processing and interpretable optical signatures.

Publications

Selected publications

Scalable High-Precision Trimming of Photonic Resonances by Polymer Exposure to Energetic Beams

N. Farmakidis, Hao Yu, J. S. Lee, Harish Bhaskaran*, et al.

Nano Letters, Vol. 23, Issue 11, pp. 4800–4806, 2023.

Demonstrates a scalable route to trim photonic resonances via polymer exposure—central to precision control of resonant photonic devices.

DOI

A Close-space Sublimation Approach to Tungsten Oxide and Sulfide Nanostructure Formation

Hao Yu, Stephan Hofmann*, et al.

Nanoscale, Advance Article, 2025.

Reports close-space sublimation pathways to tungsten oxide and sulfide nanostructures relevant to nanoscale materials formation and downstream device exploration.

DOI

Se Nanowire Crystal Formation via Oxidation of 2D HfSe₂: A Solid-State, In-situ Reaction Coupling for Heterogeneous Integration Technologies

Sunvir Sahota, …, Hao Yu, Stephan Hofmann*, et al.

ACS Applied Nano Materials, Vol. 8, Issue 15, pp. 7608–7615, 2025.

Describes solid-state formation of Se nanowires from a 2D precursor platform, framed for heterogeneous integration contexts.

DOI

How do microplastics adsorb metals? A preliminary study under simulated wetland conditions

M. Jian*, …, Hao Yu, Z. Lai, S. Liu, Elvis G. Xu, et al.

Chemosphere, Volume 309, Part 1, 136547, 2022.

Investigates metal adsorption onto microplastics under simulated wetland conditions—an environmental materials study complementary to his nanomaterials-focused work.

DOI

Projects

RamanPL_2D

Sep 2025 – Apr 2026 · Coding project

Tools: Raman spectroscopy, Python

Developed a Python toolkit for Raman and photoluminescence spectral analysis, including preprocessing, fitting, mapping, batch workflows, and metadata-aware export.
Built workflows for single spectra, mapping, and batch analysis to extract peak parameters efficiently from experimental datasets.

Focus: reproducible spectral analysis pipelines for 2D materials and mapping datasets.

Halides-facilitated CSS 2D-TMD formation

Apr 2025 – Apr 2026 · Experimental project

Tools: Raman spectroscopy, SEM, TEM, EDS, COMSOL

Investigated deposition of WS₂ and MoS₂ using halides in a close-space sublimation (CSS) setup.
Studied how growth parameters affect outcomes and presented results at a 2026 2DTMD conference.

Focus: growth science and correlative characterisation for high-quality 2D TMDs.

Laser-induced Se nanowire formation

Jan 2025 – Mar 2025 · Experimental project

Tools: Raman spectroscopy, SEM, TEM, EDS

Investigated amorphous–crystalline phase behaviour of Se upon annealing.
Characterised Se nanowire Raman signatures; results appear in ACS Applied Nano Materials (2025).

Focus: nanowire formation and optical fingerprinting with microscopy support.

High-throughput fabrications of WO_3−x–WS₂ nanotubes

Feb 2023 – Jan 2025 · Experimental project

Tools: Raman spectroscopy, SEM, TEM, EDS, XPS

Implemented one-step fabrication of WO_3−x to WS₂ core–shell nanotube devices on Si.
Traced morphological conversion; published in Nanoscale (2025) and presented at IWEPNM 2026 and Nanowireweek 2025.

Focus: scalable nanotube device fabrication and materials transformation pathways.

In-situ active tuning of MRR

Sep 2021 – Jun 2022 · Experimental project

Tools: Lumerical, electron-beam lithography, mask aligner, in-house optical test-bed

Investigated active trimming of resonant wavelengths of micro-ring resonators (MRRs).
Implemented UV etching of a PMMA coating to tune resonance wavelengths; published in Nano Letters (2023).

Focus: precision photonic resonance control with cleanroom processing and optical verification.

Er–Si nanowire growth and testing

Jun 2019 – Sep 2019 · Experimental project

Tools: Electron-beam evaporation (EBE), X-ray diffraction (XRD)

Developed a PVD route to Er–Si nanowires formed from thin Er films on semiconductor substrates.
Studied luminescence-related behaviour of Er–Si nanowires.

Focus: early nanowire growth and structural/optical screening.

Software-hardening of a latch circuit

May 2016 – Dec 2016 · Simulation project

Tools: Cadence

Developed mitigation strategies for extra-terrestrial radiation effects on space-based electronics.
Culminated in a prototype recognised with a Bronze Medal at the 2017 SSEF.

Focus: radiation-aware circuit robustness via simulation-led design.

Experience

Jan 2023 – Dec 2025

School Ambassador — China (remote)

BOE Technology Group Co., Ltd

Ran online and in-person BOE career events at highly ranked UK universities.
Identified potential university collaborators for MicroLED display technology development in the UK.

Jan 2026 – Apr 2026

EnterpriseTECH analyst

Cambridge Judge Business School · Cambridge, UK

Market and application analysis for photonic PV technology, including roadmap and IP licensing support.

Market sizing, application analysis, and competitor mapping for indoor solar and ambient IoT markets for photonic PV technology.
Supported development of a TRL 2–TRL 4 roadmap and IP licensing strategy, including MVP definition, scale-up considerations, and revenue-model logic.

Education

University of Cambridge — PhD in Engineering (Oct 2022–present), Cambridge, United Kingdom
University of Oxford — MEng in Materials Science (Oct 2018–Jul 2022), Oxford, United Kingdom
Final classification: Upper Second-Class Honours (2:1), 70% average

Capabilities

Skills

Programming & modelling

Python; MATLAB; COMSOL Multiphysics. Coursework-style foundations in machine learning (LinkedIn Learning certificates, 2021 and 2025).

Fabrication & processing

Chemical vapour deposition (CVD); dry exfoliation; reaction ion etching (RIE); spin-coating; electron-beam lithography; mask alignment; thin-film processing routes used across listed projects (including CSS and PVD-style growth contexts).

Characterisation & metrology

Raman spectroscopy; photoluminescence workflows; X-ray diffraction (XRD); scanning electron microscopy (SEM); transmission electron microscopy (TEM); energy-dispersive X-ray spectroscopy (EDS); X-ray photoelectron spectroscopy (XPS); optical characterisation on an in-house optical test-bed.

Research areas

Transition metal dichalcogenides (TMDs) and low-dimensional materials; optoelectronics; nanoscale fabrication and device prototyping; photonic resonators and trimming approaches.

Professional registration: Institute of Materials, Minerals & Mining (IOM3) Chartered Engineer (CEng), Aug 2022.

Leadership

Leadership & service

Oct 2023 – Oct 2024

Executive Vice-President

Cambridge Chinese Students and Scholars Association (CSSA Cambridge)

Directed the 2023 Cambridge Innovation Month and the 2024 Innovation and Entrepreneurship Competition.
Organised the 2024 Return Trip for “Global Elite Students.”
Served as General Director of the 2024 Cambridge Chinese New Year Gala for an audience of about 1000, including the Cambridge city mayor and a Pro-Vice-Chancellor of the University of Cambridge.

Sep 2020 – Sep 2021

Vice-President

Oxford Chinese Students and Scholars Association (OxCSSA)

Co-hosted the 2020 UK-wide Entrepreneurship Forums (online) with participation from investment institutions including FreesFund and MiraclePlus.
Managed the society’s WeChat public account and Facebook page.

Honours

Awards & funding

Cambridge Philosophical Society Studentship — 2025–2026
Trinity College Exhibition Scholar — 2020–2022, University of Oxford (recognition for top-tier (about top 5%) academic performance)
Singapore Ministry of Education SM1 scholarship — 2014–2017 (four-year fully funded senior high school studies in Singapore)

CV

A PDF CV is available for committees, collaborators, and hosts. Replace the file in assets/Hao_Yu_CV.pdf with your latest version before publishing.

Download CV (PDF)

Contact

If you are working on photonics, advanced materials, or emerging optoelectronic systems—and want a careful experimental collaborator with fabrication and spectroscopy depth—please get in touch.

Email

hy377@cam.ac.uk

Phone

+44 7529 151667

Location

Cambridge, United Kingdom (CB2 9GR)

Languages

English (fluent), Mandarin (native), Japanese (conversational)