Fact-checked by Grok 2 weeks ago

3D Systems

3D Systems Corporation is an American additive manufacturing company that develops and sells 3D printers, materials, software, and related services for industrial and healthcare applications. Founded in 1986 by Charles "Chuck" Hull, the inventor of (SLA), it became the world's first company and commercialized the SLA-1, the initial stereolithography-based 3D printer, in 1987. Headquartered in , the company has pioneered key technologies in the field, transforming traditional workflows across multiple sectors. Over its nearly four-decade history, 3D Systems has expanded from its origins in to encompass a broad portfolio of additive solutions, including ColorJet (CJP) and MultiJet (MJP) in the , direct metal printing (DMP) in the , and production-scale plastic printing systems. The company serves high-value markets such as and , healthcare and , automotive and motorsports, and durable goods , providing end-to-end digital workflows that enable , custom production, and on-demand services. Notable innovations include the first 3D-printed part in the 1980s, underscoring its role in advancing and medical applications. Today, 3D Systems operates as a full-service solutions partner, leveraging global expertise to deliver customized technologies that address complex challenges in and . With co-founder and chief technology officer for β€”who was elected to the in February 2025β€”the company continues to drive innovation in additive manufacturing, reporting ongoing developments in its third-quarter 2025 financial results (released November 4, 2025) as it supports industries adapting to advanced digital fabrication.

Company History

Founding and Early Innovations

3D Systems was founded in 1986 in , by Charles W. (", who had invented () two years earlier in 1984 while working at a UV curing company. Hull's breakthrough came from experimenting with ultraviolet light to solidify resins, leading to the creation of the first 3D-printed object in 1983 and the formalization of the SLA concept by 1984. This invention laid the groundwork for additive manufacturing, enabling the precise construction of complex three-dimensional structures from digital designs. The process involves selectively curing a liquid layer by layer using a ultraviolet to trace cross-sectional patterns on the 's surface, solidifying it into solid form while an elevator platform incrementally lowers to form subsequent layers. The cure depth, which determines the layer thickness, is governed by the 's optical and chemical properties and the 's energy delivery; a fundamental relation is the cure depth D_c = D_p \ln \left( \frac{E_{\max}}{E_c} \right), where D_p is the of light into the , E_{\max} is the maximum (influenced by P, scan speed v, and ), and E_c is the critical threshold for initiation. This highlights how adjustments in parameters and sensitivity control the precision and build rate of the object. Early commercialization began with the launch of the , the world's first commercial 3D printer, in 1987, which dramatically shortened prototyping timelines from weeks of traditional machining to mere hours by directly fabricating parts from CAD models without tooling. filed the initial application for SLA apparatus on October 29, 1984 (US Patent 4,575,330), which was granted on March 11, 1986, securing the core intellectual property that propelled 3D Systems as the pioneer in technology. These foundational patents established legal protections for the layer-by-layer photopolymerization method, enabling the company's early market dominance.

Growth, Acquisitions, and Leadership

3D Systems went public on March 10, 1988, listing on the under the ticker TDSC, marking an early milestone in its expansion as a in additive . By the , the company's had grown substantially, positioning it as a leader in the sector, with annual system sales dominating the market alongside emerging competitors. The company pursued aggressive growth through strategic acquisitions, particularly in the early , to broaden its technological portfolio. In January 2012, 3D Systems acquired Z Corporation for $137 million, enhancing its capabilities in color jet . This was followed by the $55 million purchase of Geomagic in February 2013, which strengthened its software offerings for design and inspection. In 2014, the firm acquired Studios to advance for entertainment and consumer applications, and Simbionix for $120 million to bolster medical simulation and training solutions. By 2015, 3D Systems completed the acquisition of LayerWise, a specialist in metal additive , further expanding its expertise; overall, the company executed 25 acquisitions between 2013 and 2015 to integrate diverse technologies. Leadership transitions have shaped the company's direction since its founding. Charles "Chuck" Hull, the inventor of stereolithography and co-founder, served as CEO from 1986 until 2011, overseeing initial commercialization efforts. Avi Reichental succeeded him as CEO from 2011 to 2016, driving the acquisition spree and market expansion during a period of rapid industry growth. Vyomesh Joshi took over in April 2016, focusing on financial stabilization and product quality improvements until his retirement announcement in February 2020. In May 2020, Dr. Jeffrey Graves was appointed CEO, emphasizing industrial applications alongside healthcare to streamline operations and target high-value markets. Post-2010, 3D Systems shifted strategically toward high-impact sectors, placing greater emphasis on healthcare through acquisitions like Simbionix and on for applications. In September 2025, the company updated its software strategy to prioritize automation in metal printing workflows, aiming to accelerate design-to-manufacturing processes and boost adoption of production-scale .

Relocations and Strategic Shifts

In 2005, 3D Systems relocated its headquarters from Valencia, California, to Rock Hill, South Carolina, to leverage favorable business conditions, lower operational costs, and proximity to a skilled workforce. The move culminated in the opening of an 80,000-square-foot facility in 2006, which included a dedicated research and development center to support the company's expanding additive manufacturing operations. In June 2021, 3D Systems sold its On-Demand manufacturing business, which operated from U.S. hubs in ; Seattle, Washington; ; and , to Trilantic for $82 million to streamline operations and focus on core technologies. These facilities had enabled specialized additive and subtractive manufacturing, serving industries from to healthcare with localized expertise. Following the appointment of Jeff Graves as CEO in May 2020, 3D Systems pivoted strategically from consumer-oriented products to a sharper focus on industrial and healthcare applications, aiming to accelerate adoption of production-scale . This shift emphasized high-value sectors like and medical devices, divesting non-core assets to prioritize scalable solutions amid evolving market demands. In 2025, the company highlighted its emphasis on application-specific solutions at the +TCT conference, unveiling workflows such as the Figure 4 135 printer paired with flame-retardant materials for precision, low-volume production in sectors like motorsports and consumer goods. These innovations underscored a commitment to cost-efficient, end-to-end tailored to real-world challenges. In September 2025, 3D Systems divested its Oqton and 3DXpert software businesses to Hubb Global Holdings to refocus on core solutions and automation tools like 3D Sprint for metal . Amid intensifying competition in additive manufacturing from 2020 to 2023, 3D Systems undertook multiple restructurings to streamline operations, including a 2020 reorganization that reduced costs by approximately $100 million annually through workforce reductions and vertical focus. Subsequent initiatives in 2023 optimized European metal printing and software operations, cutting headcount by 6% and targeting $45–$55 million in annualized savings by 2024 to improve agility and financial health.

Core Technologies

Additive Manufacturing Processes

3D Systems pioneered several key additive manufacturing processes, focusing on precision, material versatility, and production scalability. These technologies encompass vat photopolymerization, powder bed fusion, binder jetting, and material jetting methods, each tailored to specific part requirements such as detail resolution, mechanical strength, and multi-material capabilities. The company's innovations emphasize layer-by-layer construction from digital models, enabling complex geometries unattainable through traditional subtractive methods. Stereolithography (SLA) employs a UV to selectively cure liquid photopolymer resin layer by layer within a , solidifying cross-sections of the 3D model as the build platform descends. This process begins with a resin-filled tank where the laser traces the initial layer on the platform, followed by recoating and repeated curing until the part is complete; post-processing involves washing and secondary UV exposure for full hardening. SLA achieves high precision with tolerances typically under 0.05 mm and layer thicknesses as fine as 25 microns, delivering the smoothest surface finishes among additive processes. In November 2025, 3D Systems introduced the SLA 825 Dual, a dual- SLA printer for enhanced productivity in prototyping and production. Selective Laser Sintering (SLS) utilizes a CO2 to fuse powdered materials, such as thermoplastics or metals, by scanning and heating particles in a build chamber to their temperature, binding them without full . Powder is spread evenly over the previous layer via a roller, the selectively sinters the cross-section, and the platform lowers for the next layer; unsintered powder acts as , eliminating the need for additional structures. This method supports durable, functional parts and is characterized by energy density calculated as E = \frac{P}{h \cdot v}, where P is , h is hatch spacing, and v is speed, optimizing without degradation. Direct Metal Printing (DMP), a form of powder bed fusion, directs a high-powered to melt and fuse particles layer by layer in an inert atmosphere, enabling dense, high-strength components with fine details. The process involves powder deposition, melting of the scan path, and layer progression, with vacuum or shielding to prevent oxidation; it excels in producing intricate metal geometries for demanding applications. DMP builds on principles but uses metallic powders and higher energy inputs for metallurgical bonding. Color Jet Printing (CJP) applies binder jetting by selectively depositing colored liquid binders via inkjet printheads onto layers of , such as gypsum-based materials, to form full-color parts with CMYK capabilities. A thin layer is spread, binders are jetted to bind particles and add color, and the build platform lowers iteratively; infiltration post-printing enhances strength, yielding detailed, multi-colored models efficiently. This process prioritizes aesthetic and conceptual prototyping over mechanical robustness. MultiJet Printing (MJP) deposits droplets through piezo-driven inkjet printheads onto a build platform, curing them instantly with UV lamps to form precise layers of or . Multiple jets enable simultaneous material and support deposition, with layer thicknesses down to 16 microns for high-fidelity resolution; supports are removable via melting or dissolution. MJP supports multi-material parts and offers a balance of speed and accuracy for detailed prototypes. Comparisons among these processes highlight trade-offs: and MJP excel in precision and surface quality for intricate features, with resolutions below 50 microns, while and DMP prioritize durability and strength for engineering-grade parts using powders that yield isotropic properties. CJP stands out for color and speed in non-structural models. Post-2020, 3D Systems has evolved toward hybrid systems integrating additive processes with subtractive finishing for enhanced accuracy and efficiency in production workflows.

Materials Science and Software Integration

3D Systems maintains an extensive materials portfolio comprising approximately 130 distinct materials tailored for additive manufacturing applications. This portfolio encompasses a diverse array of categories, including photopolymers for high-resolution prototyping, for durable functional parts, metals such as for aerospace and medical components, waxes for , and elastomers for flexible assemblies. plastics within this selection exhibit robust mechanical properties, such as tensile strengths ranging from 50 to 70 , enabling them to withstand demanding operational stresses in industrial settings. For instance, the PA11 material achieves a tensile strength of 51 , supporting applications requiring and flexibility. The company's materials also include biocompatible formulations critical for medical advancements, such as the NextDent resin series certified for direct intraoral use and compliant with standards. In May 2025, 3D Systems expanded this lineup to over 30 clinically validated resins, addressing patient-specific dental restorations, surgical guides, and orthopedic models while ensuring tissue compatibility and sterility. Complementing these, sustainable material options have been introduced between 2023 and 2025, incorporating recycled and bio-based feedstocks to reduce environmental impact; examples include plant-derived composites from wood waste, aligning with on-demand manufacturing to minimize excess production and waste. Software solutions from 3D Systems play a pivotal role in optimizing additive workflows, with serving as the core for , build optimization, and printer specifically for and processes. This intuitive tool streamlines tasks from CAD import to nesting and slicing, reducing time by automating support generation and part orientation to enhance efficiency and material utilization. Until its divestiture in early 2025, the Geomagic suite complemented this by providing advanced design verification through and inspection, enabling precise mesh-to-CAD conversion and for scanned prototypes. In 2025, 3D Systems introduced AI-driven enhancements to its software ecosystem, focusing on metal printing automation to accelerate the design-to-manufacture pipeline; these updates incorporate for predictive build failure detection and , particularly for Direct Metal Printing workflows. In November 2025, the company launched ArrayCast, a new software module for automated casting tree design in applications, integrating with workflows. Integration between and software is achieved through capabilities that model material responses during the printing process, allowing engineers to predict outcomes without iterative physical builds. For example, 3D Sprint and associated modules employ finite element analysis (FEA) to simulate distributions and behaviors in materials like , identifying potential warping or failure points early in the design phase. This synergy optimizes parameters such as layer thickness and cooling rates based on material-specific properties, ensuring part integrity and reducing post-processing needs while bridging the gap between digital design and physical production.

Products and Intellectual Property

Hardware Solutions

3D Systems offers a diverse portfolio of hardware tailored for prototyping, production-scale , and historical entry-level applications. The company's printers, such as the ProJet MJP 3600 series, utilize MultiJet Printing to enable mid-range prototyping with a maximum build of 298 x 185 x 203 mm, supporting high-resolution parts with XY resolutions up to 800 DPI and Z up to 890 DPI for design verification and . These systems provide up to twice the print speed of competing plastic printers, facilitating efficient for workflows. For production environments, 3D Systems' Figure 4 series delivers high-volume capabilities, particularly suited for elastomers, with the Figure 4 Production model featuring a build volume of 124.8 x 70.2 x 346 mm and print speeds up to 65 mm per hour, enabling throughput of over 1 million parts annually in scalable configurations. The DMP Factory 500 targets metal part production, offering a 500 x 500 x 500 mm build envelope powered by 500 W fiber lasers for 24/7 operation and seamless scalability in industrial settings. The SLS 380, introduced in 2022, supports flexible manufacturing, incorporating with a 381 x 330 x 460 mm build volume and a throughput rate of 2.7 liters per hour to support consistent, high-yield production, with ongoing software enhancements as of 2025. Historically, 3D Systems provided entry-level desktop options through the series, which featured compact builds for consumer and small-scale use but was discontinued in 2016 following the end of production for models like the 3. Industrial models across the portfolio, such as Figure 4 configurations, achieve throughput exceeding 100 parts per day, establishing key benchmarks for operational scale in additive manufacturing. These solutions integrate with various additive processes to optimize build envelopes and efficiencies for targeted applications.

Materials Portfolio and Services

3D Systems maintains an extensive portfolio of materials tailored for additive manufacturing processes, encompassing s, metals, elastomers, composites, and bio-compatible formulations to support diverse applications. The company's materials include a wide array of resins compatible with (SLA) and multi-jet printing (MJP) technologies, such as the Accura series, with Accura Bluestone serving as a nano-composite for high-stiffness parts like wind-tunnel test models in simulation. For powder-based systems like (SLS) and direct metal printing (DMP), the portfolio features engineering-grade options including DuraForm PA11 Black, a renewable bio-sourced offering toughness and impact resistance, alongside metal powders such as aluminum, , grades, , and alloys. In specialized sectors like dental, the NextDent lineup comprises over 30 clinically validated resins addressing applications from tooth repair to full dentures. In November 2025, at Formnext, 3D Systems introduced next-generation solutions, including the Accura Xtreme Black resin for high-performance prototyping applications. Complementing its materials, 3D Systems provides manufacturing services for custom prototyping and low-volume production, enabling rapid turnaround with parts delivered in as little as 24 hours across polymer and metal technologies. These services leverage the company's infrastructure to handle complex geometries and hybrid manufacturing needs, with 2025 expansions including new modules for large-format systems and enhanced metal capabilities through strategic partnerships in regions like . Integration with client workflows occurs via the Application Innovation Group, which supports custom material development to meet specific performance requirements, such as tailored formulations for or healthcare. Pricing for these services typically follows a per-part model based on material volume, complexity, and post-processing, with subscription options available for associated software tools to streamline design and quoting. The materials portfolio has evolved to emphasize , incorporating bio-based options like DuraForm PA11 derived from renewable sources to reduce environmental impact. In 2024, 3D Systems conducted a comprehensive assessment in collaboration with a third-party consultancy to prioritize initiatives, including reduction and eco-friendly innovations. This aligns with broader efforts to integrate recycled and plant-based feedstocks into production-grade resins and powders, supporting principles in additive manufacturing.

Patents and Legal Milestones

3D Systems maintains a robust intellectual property portfolio comprising over 1,100 active patents globally, encompassing foundational and advanced technologies in additive manufacturing. This includes Charles Hull's seminal U.S. Patent No. 4,575,330, granted in 1986, which describes an apparatus for producing three-dimensional objects through stereolithography by selectively curing layers of a fluid medium with ultraviolet radiation. The portfolio also features advancements in multi-material printing. Key patent filings from the company's early development include those related to radiation-curable compositions in the , exemplified by U.S. Patent No. 4,929,402, granted in 1990, which details methods for producing three-dimensional objects using a radiation-curable to form precise cross-sectional layers. Following the 2012 acquisition of Z Corporation, 3D Systems incorporated binder jetting technologies, including foundational patents like U.S. Patent No. 5,204,055, which covers techniques for depositing binder onto powder layers to form three-dimensional structures, thereby expanding the company's in color and multi-material inkjet-based printing. Significant legal milestones include the 2012 lawsuit filed by 3D Systems against Formlabs, Inc., alleging infringement of patents such as U.S. Patent Nos. 5,236,637 and 5,321,622 related to curing systems. The dispute, which highlighted tensions over affordable , was settled in December 2014, with Formlabs agreeing to pay an 8% royalty on net sales of its Form 1 and Form 1+ printers in exchange for a license to the contested patents. 3D Systems has continued to defend its against competitors, pursuing litigation to protect core technologies in and related processes. The company's strategy emphasizes a closed-source model, prioritizing protection through extensive patenting and to safeguard innovations in , materials, and processes, distinguishing it from open-source approaches in the broader ecosystem. This approach supports ongoing research into advanced applications, including recent efforts to integrate for enhanced manufacturing efficiency, though specific 2025 filings in AI-optimized printing algorithms remain under development as part of the company's strategic focus.

Applications and Market Impact

Industrial and Engineering Uses

3D Systems' additive manufacturing technologies have been instrumental in applications, particularly for producing lightweight lattice structures that enhance fuel efficiency and performance. For instance, through partnerships like the one with GE Aviation, the company utilized direct metal printing (DMP) combined with to create an bracket that reduced weight by 70% while meeting all structural requirements. In satellite manufacturing, 3D Systems has enabled the production of parts that are 25% lighter, achieved in half the traditional time, supporting missions with over 15 satellites incorporating their flight hardware since 2015. Rapid tooling via patterns has also accelerated engine part development, reducing lead times and costs compared to conventional methods. In the automotive sector, 3D Systems supports design validation through rapid prototyping of high-performance components, allowing engineers to test and iterate designs efficiently using durable thermoplastics that mimic production-grade materials. Custom jigs and fixtures produced via additive manufacturing enable precise assembly processes, with examples demonstrating reductions in production time from days or weeks to hours, thereby accelerating overall product development by up to 10 times. A notable case involves the Rodin FZERO hypercar, where 3D Systems' metal printing optimized titanium gearboxes for reduced weight and development costs. For broader manufacturing applications, 3D Systems employs (SLS) to fabricate durable end-use parts, particularly in high-stakes environments like , where these components provide enhanced and fuel savings of 25 to 30 gallons per hour due to reduced drag. Since 2015, over 2,000 structural and aluminum components have been produced for space flight, demonstrating the reliability of SLS for production-scale durability without extensive tooling. Engineering benefits of 3D Systems' technologies include significant cost savings in prototyping, with analyses indicating up to 70% reductions compared to traditional methods, alongside up to 60% in certified facilities. These solutions also bolster by enabling on-demand production of parts, minimizing costs and disruptions, as highlighted in 3D Systems' initiatives. Such advancements have proven vital in industrial reports emphasizing localized manufacturing for stability.

Healthcare and Emerging Sectors

3D Systems has significantly impacted healthcare through its Direct Metal Printing (DMP) technology, which facilitates the production of custom prosthetics and implants tailored to individual anatomies. For instance, DMP enables the fabrication of titanium-based cranial plates and other orthopedic devices, allowing for precise fit and during surgical procedures to restore functionality and aesthetics. The company's Virtual Surgical Planning (VSP) solutions, enhanced historically by the 2014 acquisition of Simbionix, support the creation of patient-specific anatomical models for preoperative planning and rehearsal. These models, derived from data, enable surgeons to visualize complex cases and simulate interventions, thereby minimizing intraoperative surprises and optimizing outcomes. Although Simbionix's simulation business was divested in 2021, its integration advanced 3D Systems' capabilities in virtual reality-based training and planning tools during that period. In dental applications, 3D Systems employs MultiJet Printing (MJP) technology to manufacture , crowns, and other restorations with high accuracy and minimal post-processing. This approach supports efficient production workflows for orthodontic and prosthetic devices, ensuring and durability for intraoral use. Advancements in 2025 include the full commercial release of FDA-cleared biocompatible resins, such as those in the NextDent Jetted Denture Solution, which provide enhanced rigidity for teeth and flexibility for gum tissues in monolithic . These materials, printable via MJP systems like the NextDent 300, represent a step forward in direct , reducing fabrication steps and improving patient fit. Beyond traditional healthcare, 3D Systems' technologies extend to emerging sectors, including , where ColorJet Printing (CJP) produces vibrant, detailed props for and . The ProJet CJP 660Pro, for example, supports full-color, high-resolution models ideal for stop-motion and professional set pieces, offering cost-effective alternatives to traditional sculpting. In consumer goods prototyping, 3D Systems provides rapid, on-demand manufacturing solutions that accelerate design iteration for electronics housings, wearables, and everyday products, eliminating tooling costs and enabling low-volume customization. For space exploration, 3D Systems collaborates on additive manufacturing initiatives that support NASA's efforts in developing lightweight components and thermal management systems for satellites and habitats, contributing to sustainable off-world construction concepts. These applications have driven measurable impacts, with patient-specific models helping to reduce surgical times through improved preoperative preparation and precision. Post-2023, 3D Systems' contributions to have aligned with broader market growth, as the global healthcare sector expanded from USD 8.52 billion in 2023 to projected USD 27.29 billion by 2030, fueled by innovations in custom implants and bioprinting.

Business Operations

Global Infrastructure and Workforce

3D Systems maintains its global headquarters in , at a facility originally established in 2006 spanning 80,000 square feet with a primary focus on . In 2021, the company expanded this site by adding 100,000 square feet to accommodate advanced manufacturing capabilities and customer experience centers. Complementary U.S. operations include facilities in , for manufacturing focused on aerospace and healthcare applications; ; and the Seattle area in , supporting software and functions. The company's international footprint extends through more than 25 owned locations across the , , and , enabling localized support for additive solutions. In , key sites include the LayerWise division in , , acquired in 2014 and specializing in direct metal 3D printing services. Additional European operations encompass for metal systems in . In , 3D Systems operates offices in and to serve regional industrial and healthcare markets. This network facilitates rapid deployment of technologies like and direct metal printing across diverse geographies. As of December 2024, 3D Systems employs approximately 1,833 individuals worldwide, reflecting a reduction from 1,995 employees in , approximately an 8% decrease, amid strategic restructuring to streamline operations and focus on core verticals in healthcare and industrial applications. The comprises professionals in engineering, sales, and . This composition supports the company's emphasis on technical expertise and global service delivery. In 2025, 3D Systems invested in infrastructure expansions to enhance high-volume production capabilities, including a in with Dussur to deploy advanced systems for the energy sector, responding to rising demand in emerging markets. These initiatives build on prior U.S. site enhancements, prioritizing scalable lines for metal and polymer technologies.

Financial Performance and Strategy

In 2024, 3D Systems reported total revenue of $440.1 million, representing a 10% decline from $488.1 million in 2023, primarily due to weakened demand in capital equipment sales across industrial and healthcare segments. Revenue from the Healthcare Solutions segment totaled $189.7 million, accounting for approximately 43% of overall revenue and decreasing 11% year-over-year amid softer personalized surgical applications. The Industrial Solutions segment contributed $250.4 million, or 57% of revenue, with declines in printer sales offset by steady materials and services demand. In the first quarter of 2025, revenue fell to $94.5 million, an 8% year-over-year decrease, though industrial solutions showed relative stability with a 7% decline driven by materials sales. In the second quarter of 2025, revenue was $94.8 million, down 16% year-over-year. For the third quarter of 2025, revenue decreased to $91.2 million, a 19% decline year-over-year. The company recorded a net loss of $255.6 million for 2024, an improvement from the $362.7 million loss in 2023, but still reflecting significant investments in totaling $86.5 million, alongside restructuring costs and revenue pressures. As of December 31, 2024, total assets stood at $608.8 million, with stockholders' equity at $176.2 million, underscoring a strained by ongoing operational investments and of $212.0 million. These financial challenges were exacerbated by competitive pressures in the additive market, where rivals like and intensified and , prompting 3D Systems to implement cost-cutting measures including a workforce reduction of approximately 5% from 2023 to 2024, contributing to $85 million in annualized savings by year-end 2024, with ongoing cost reductions in 2025. Strategically, 3D Systems has prioritized high-margin sectors such as healthcare and within its industrial portfolio, which together represent over 60% of revenue through applications in personalized medical devices and lightweight components. In 2025, the company advanced its software initiatives to enhance metal efficiency, including a shift toward the Sprint platform and divestiture of the 3DXpert suite to Hubb Global Holdings, completed in the fourth quarter of 2025, to streamline design-to-manufacturing workflows, aiming for up to 40% faster production times in metal additive processes. Traded on the under the ticker DDD, 3D Systems continues to position itself for recovery by leveraging these high-value segments and operational efficiencies amid a competitive landscape.

Partnerships and Sustainability Initiatives

3D Systems has engaged in several key partnerships to advance 3D digitization and manufacturing applications. Since 2012, the company has maintained an ongoing collaboration with the to support the digitization of its vast collections, enabling the creation of 3D models and printable replicas of artifacts for public access and preservation. In 2014, 3D Systems partnered with Ekso Bionics to develop the first bespoke 3D-printed hybrid , which integrated additive manufacturing with robotic components to assist a paralyzed individual in walking. Additionally, in 2012, 3D Systems joined the National Additive Manufacturing Innovation Institute (NAMII), part of the U.S. National Network for Manufacturing Innovation, to foster research and adoption of additive technologies in industrial settings. The company has also demonstrated its technologies through industry events, including participation in +TCT 2025, where it showcased application-specific solutions like the Figure 4 platform to highlight manufacturing advancements. In community engagement, 3D Systems has supported educational initiatives, notably sponsoring the 3D design category in the Scholastic Art & Writing Awards since 2012, providing software, printing services, and cash prizes to recognize student innovation in digital fabrication. On sustainability, 3D Systems conducted a comprehensive assessment in 2024 to prioritize (ESG) issues, involving input to guide its strategy across and pillars. This includes efforts to recycle plant-based waste, such as , into 3D-printable materials, promoting in additive . The company's emissions inventories are third-party verified for compliance with standards, supporting broader environmental management goals. Through collaborative R&D, 3D Systems has advanced technologies in areas like and thermal management, partnering with institutions such as Penn State University, , and on projects sponsored since 2020 to optimize 3D-printed components for space applications. These efforts have contributed to joint innovations, including a with Precision Resource to scale metal additive capabilities.