3D Printed Devices for Catalytic Systems

Saggiomo, Vittorio

doi:10.1002/9783527817290.ch11

Cited by 8 publications

(4 citation statements)

References 72 publications

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“…“Why do I need a 3- D printer in my laboratory”? This is a likely response you will receive from a fellow researcher in chemistry when asking if they have a 3- D printer in their laboratory [ 17 ]. The 3- D printer is still perceived by most people as a device intended to create amusement, attention, trick, or a device for printing random tools.…”

Section: Role Of 3-d Printing In Chemistry and Associated Fieldsmentioning

confidence: 99%

Current and future trends of additive manufacturing for chemistry applications: a review

Alimi

Meijboom

2021

J Mater Sci

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Graphical abstract Three-dimensional (3- D ) printing, also known as additive manufacturing, refers to a method used to generate a physical object by joining materials in a layer-by-layer process from a three-dimensional virtual model. 3- D printing technology has been traditionally employed in rapid prototyping, engineering, and industrial design. More recently, new applications continue to emerge; this is because of its exceptional advantage and flexibility over the traditional manufacturing process. Unlike other conventional manufacturing methods, which are fundamentally subtractive, 3 -D printing is additive and, therefore, produces less waste. This review comprehensively summarises the application of additive manufacturing technologies in chemistry, chemical synthesis, and catalysis with particular attention to the production of general laboratory hardware, analytical facilities, reaction devices, and catalytically active substances. It also focuses on new and upcoming applications such as digital chemical synthesis, automation, and robotics in a synthetic environment. While discussing the contribution of this research area in the last decade, the current, future, and economic opportunities of additive manufacturing in chemical research and material development were fully covered.

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Section: Role Of 3-d Printing In Chemistry and Associated Fieldsmentioning

confidence: 99%

Current and future trends of additive manufacturing for chemistry applications: a review

Alimi

Meijboom

2021

J Mater Sci

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“…For almost all powder-based technologies, it is challenging to remove the unsintered/unmolten powder after the process is finished. SLM can play an important role in using 3D printing materials such as stainless steel [100,101], whereas SLS has been used in printing titanium alloys [102,103]. Selective laser sintering is a 3D printing technique using a powder bed and a laser source to sinter the polymeric or metal powder into solid structures according to a 3D design [90].…”

Section: Selective Laser Sintering (Sls)/ Selective Laser Melting (Slm)mentioning

confidence: 99%

A Review on New 3-D Printed Materials’ Geometries for Catalysis and Adsorption: Paradigms from Reforming Reactions and CO2 Capture

et al. 2020

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“Bottom-up” additive manufacturing (AM) is the technology whereby a digitally designed structure is built layer-by-layer, i.e., differently than by traditional manufacturing techniques based on subtractive manufacturing. AM, as exemplified by 3D printing, has gained significant importance for scientists, among others, in the fields of catalysis and separation. Undoubtedly, it constitutes an enabling pathway by which new complex, promising and innovative structures can be built. According to recent studies, 3D printing technologies have been utilized in enhancing the heat, mass transfer, adsorption capacity and surface area in CO2 adsorption and separation applications and catalytic reactions. However, intense work is needed in the field to address further challenges in dealing with the materials and metrological features of the structures involved. Although few studies have been performed, the promise is there for future research to decrease carbon emissions and footprint. This review provides an overview on how AM is linked to the chemistry of catalysis and separation with particular emphasis on reforming reactions and carbon adsorption and how efficient it could be in enhancing their performance.

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“…23 3DP allows the production of reactor geometries that improve mass transfer during flow reactions, 24 and the development of tailored formulations for 3DP to use in specific applications, such as catalysis or materials, is a growing and attractive area. [25][26][27][28][29][30][31] In this regard, recently, we have demonstrated the application of a 3D-printed catalytic reactor in a flow system to convert CO 2 into a cyclic carbonate using an epoxide as the starting point. 28 In this work, we successfully demonstrate the oxidative carboxylation of olefins with CO 2 to produce cyclic carbonates under continuous flow.…”

Section: Introductionmentioning

confidence: 99%

Multi-step oxidative carboxylation of olefins with carbon dioxide by combining electrochemical and 3D-printed flow reactors

Iglesias,

Tinajero,

Marchetti

et al. 2023

Green Chem.

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3D Printed Devices for Catalytic Systems

Cited by 8 publications

References 72 publications

Current and future trends of additive manufacturing for chemistry applications: a review

Current and future trends of additive manufacturing for chemistry applications: a review

A Review on New 3-D Printed Materials’ Geometries for Catalysis and Adsorption: Paradigms from Reforming Reactions and CO2 Capture

Multi-step oxidative carboxylation of olefins with carbon dioxide by combining electrochemical and 3D-printed flow reactors

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