Prior-Art Clarity, Faster IP Decisions, Reduce Risk
Device-level prior-art analysis supports patentability, freedom-to-operate, and R&D direction before costly filing or development choices are locked in.
From idea Genesis to Technological advantage
Where Science Meets Strategic IP; Deep-tech patent intelligence that reduces patent risk and speeds product decisions.
Deep-Tech Patent Strategy for Defensible IP.
TechnoGenesis helps R&D teams and IP counsel turn complex physics, photonics, materials and device innovation into clear patent strategy, stronger claim positions, and decision ready prior art evidence.
With combined expertise in quantum physics, photonics and intellectual property, TechnoGenesis transforms complex technologies into strong, defensible IP assets.
QPIP-Certified Patent Analysis
Independent QPIP certification in patent information practice strengthens search quality, evidence mapping, and interpretation for complex deep-tech matters.
QPIPDirect Senior Patent Support
You work directly with a senior deep-tech patent specialist from scope to delivery, keeping strategy, execution, and accountability aligned.
Our Services
Technical patent-information services tailored to deep-tech innovation and strategic IP decisions.
Patent Research & Analysis
- Patentability searches
- Freedom-to-Operate (FTO)
- State-of-the-Art / Prior Art
- Validity / Invalidity
- Patent landscapes
- Competitor IP strategy analysis
Deep-Tech Expertise
- Semiconductor physics
- Optoelectronics & photonics
- Laser & LED technologies
- Nano-photonics
- Automotive cockpit innovation (HUD, displays, plastronics)
IP Strategy Support
- R&D patent training (Minesoft, search methodology)
- Patent monitoring & alerts
- AI-assisted patent search evaluation
- Collaboration with patent attorneys for drafting & office actions
Why Work With TechnoGenesis
Technical depth with strategic clarity.
Patent aware engineering that turns science into business outcomes: we combine hands on deep tech engineering with practical patent strategy to turn technical insight into defensible, market ready choices.
Deep Domain Fluency
Semiconductor physics, optoelectronics, and quantum devices are highly specialised fields. Work happens directly at that technical layer, not at a superficial product level, so recommendations are technically accurate and immediately implementable.
IP Strategy That Executes
Every analysis is tied to concrete objectives: stronger filing decisions, clearer freedom to operate paths, and more defensible portfolio positions that align with your business goals.
Decision-Ready Communication
You receive concise, structured deliverables your teams can act on quickly, without losing the technical nuance that matters for engineering and legal decisions.
Polarization response of quantum-confined structures using edge-photovoltage spectroscopy
This study proposes a method to obtain the ratio of the fundamental TE/TM optical response of a quantum-confined system from the measurement of the polarization dependence of the edge photovoltage spectrum, by correcting for polarization-dependent features of the experimental system. When applied to compressive- and tensile-strained InGaP quantum well structures, the results are in excellent agreement with known ratios of the band-edge matrix elements. This method is of particular value in the study of quantum dot systems where the polarization behaviour is difficult to predict.
Polariton lasing in a hybrid bulk ZnO microcavity
This work demonstrates polariton lasing in a bulk ZnO planar microcavity under non-resonant optical pumping at a small negative detuning (δ ≈ −1/6 of the 130 meV vacuum Rabi splitting) and at a temperature of 120 K. The strong coupling regime is maintained at lasing threshold, since the coherent nonlinear emission from the lower polariton branch (LPB) occurs at zero in-plane wavevector, well below the uncoupled cavity mode. The contribution of multiple localized polariton modes above threshold and the non-thermal polariton statistics indicate that the system operates in a far-from-equilibrium regime, likely related to the moderate photon lifetime and in-plane photonic disorder in the cavity.
High quality factor nitride-based optical cavities: microdisks with embedded GaN/Al(Ga)N quantum dots
This work reports a considerable improvement in the optical quality factor (Q) of GaN-based microdisk (μ-disk) resonators embedding GaN quantum dots (QDs) grown on AlN and AlGaN barriers. Room-temperature photoluminescence (PL) spectroscopy reveals a large number of high-Q whispering gallery modes (WGMs) spanning a wide spectral range (2.6 to 3.4 eV), enabling identification of different radial mode families through comparison with simulations. GaN/AlN QD-based μ-disks demonstrate record-high Q values (Q > 7000 for a 5 μm diameter disk and Q ≈ 5000 for a 2 μm disk), representing the state of the art for nitride photonic structures. The superior performance is attributed to the high etching quality and to the comparatively lower sub-bandgap absorption of QDs with respect to quantum wells.
Industries & Clients
Support for R&D teams, tech companies, patent attorneys, and IP firms.
View industries & clients →For R&D Teams & Tech Companies
- Accelerate innovation cycles
- Identify patentable breakthroughs
- Avoid costly infringement
- Understand competitor IP strategies
For Patent Attorneys & IP Firms
- Highprecision prior art
- Deeptech technical support
- Reliable FTO & validity analysis
- Collaboration on drafting & office actions
Industries served
- Automotive
- Semiconductors
- Photonics
- Displays & optoelectronics
- Advanced materials
- Deeptech startups
QPIP (Qualified Patent Information Professional) is the international professional qualification for patent information specialists. In France, only a limited number of practitioners and top patent firms hold this certification.
Learn more at qpip.org