Transforming the future
Capabilities
Transforming the future
OUR CORE CAPABILITIES
Khanjur specializes in the creation of shape-shifting materials known as nickel-titanium (NiTi and NiTi-X) shape memory alloys. These advanced metals undergo stress-induced and temperature-induced phase transformations, enabling them to reversibly shift between programmed shapes and generate controlled motion.
Across all manufacturing pathways, we combine advanced alloy composition and structuring to engineer application-specific material systems. From nanoscale thin films to macro-scale adaptive components, we optimize composition, thickness, geometry, and integration strategy to meet defined performance targets.
Explore each of our core capabilities below to learn how we align materials, geometry, and integration with your application needs.
Thin-Film Manufacturing of NiTi and NiTi-X Materials
Our low-cost, rapid precision laser platform enabled fabrication and structure of custom NiTi and NiTi-X devices from:
- Freestanding NiTi-X thin films
- Substrate-supported NiTi-X films
- Commercial NiTi foils, strips and sheets
Laser structuring provides a flexible pathway from feasibility studies to high-volume production of functional NiTi devices with thicknesses between 20–500 µm.
Laser Manufacturing of Superelastic and Shape Memory Alloys
Our low-cost, rapid precision laser platform enabled fabrication and structure of custom NiTi and NiTi-X devices from:
- Freestanding NiTi-X thin films
- Substrate-supported NiTi-X films
- Commercial NiTi foils, strips and sheets
Laser structuring provides a flexible pathway from feasibility studies to high-volume production of functional NiTi devices with thicknesses between 20–500 µm.
Custom NiTi-X SMA Alloy Engineering
We develop thin-film ternary and quaternary NiTi-X alloys (X = Cu, Hf, Co, and others) to tailor functional material performance like transformation temperature, force output, fatigue life, and electrical behavior.
By pairing advanced alloy design with our thin film and laser manufacturing platforms, we create application-specific materials exhibiting superelastic, shape memory, and elastocaloric effects.
Thin-Film Manufacturing of NiTi and NiTi-X Materials
Our low-cost, rapid precision laser platform enabled fabrication and structure of custom NiTi and NiTi-X devices from:
- Freestanding NiTi-X thin films
- Substrate-supported NiTi-X films
- Commercial NiTi foils, strips and sheets
Laser structuring provides a flexible pathway from feasibility studies to high-volume production of functional NiTi devices with thicknesses between 20–500 µm.
Laser Manufacturing of Superelastic and Shape Memory Alloys
Our low-cost, rapid precision laser platform enabled fabrication and structure of custom NiTi and NiTi-X devices from:
- Freestanding NiTi-X thin films
- Substrate-supported NiTi-X films
- Commercial NiTi foils, strips and sheets
Laser structuring provides a flexible pathway from feasibility studies to high-volume production of functional NiTi devices with thicknesses between 20–500 µm.
Custom NiTi-X SMA Alloy Engineering
We develop thin-film ternary and quaternary NiTi-X alloys (X = Cu, Hf, Co, and others) to tailor functional material performance like transformation temperature, force output, fatigue life, and electrical behavior.
By pairing advanced alloy design with our thin film and laser manufacturing platforms, we create application-specific materials exhibiting superelastic, shape memory, and elastocaloric effects.
MEMS, NEMS & INTERFACIAL ENGINEERING
We support the integration of NiTi and NiTi-X thin films within MEMS and NEMS device architectures to allow precise placement of functional SMA layers within semiconductor-compatible manufacturing workflows.
Through careful control of thickness, composition, and interfacial adhesion, we support integration beneath, above, or alongside electronic layers to enhance system-level performance.
FLEXIBLE, STRETCHABLE & CONFORMAL ELECTRONICE
Khanjur designs and fabricates structured NiTi and NiTi-X geometries that enable stretchability, compliance, and conformal behavior across complex surfaces.
We create application-specific architectures capable of large reversible strain to enable adaptability to complex 3D surfaces.
These engineered geometries support wearable systems, soft robotics, adaptive surfaces, and conformal electronic integration.
ACTUATOR PLATFORMS & ADAPTIVE SYSTEMS
Khanjur engineers and designs NiTi and NiTi-X actuator platforms tailored for force, stroke, response speed, and lifecycle requirements across microscale and macroscale systems.
Our Actuator Platforms Include
• Stretchable actuators
• Conformal actuators
• Bending actuators
These engineered actuator systems support MEMS devices, aerospace mechanisms, robotics, and adaptive electronic platforms.
MEMS, NEMS & INTERFACIAL ENGINEERING
We support the integration of NiTi and NiTi-X thin films within MEMS and NEMS device architectures to allow precise placement of functional SMA layers within semiconductor-compatible manufacturing workflows.
Through careful control of thickness, composition, and interfacial adhesion, we support integration beneath, above, or alongside electronic layers to enhance system-level performance.
FLEXIBLE, STRETCHABLE & CONFORMAL ELECTRONICE
Khanjur designs and fabricates structured NiTi and NiTi-X geometries that enable stretchability, compliance, and conformal behavior across complex surfaces.
We create application-specific architectures capable of large reversible strain to enable adaptability to complex 3D surfaces.
These engineered geometries support wearable systems, soft robotics, adaptive surfaces, and conformal electronic integration.
ACTUATOR PLATFORMS & ADAPTIVE SYSTEMS
Khanjur engineers and designs NiTi and NiTi-X actuator platforms tailored for force, stroke, response speed, and lifecycle requirements across microscale and macroscale systems.
Our Actuator Platforms Include
• Stretchable actuators
• Conformal actuators
• Bending actuators
These engineered actuator systems support MEMS devices, aerospace mechanisms, robotics, and adaptive electronic platforms.