This is the last decent version of Atomically Precise Manufacturing on Wikipedia before it was butchered by User:Fahmed02 in November 2020 Atomically precise manufacturing (APM),[1][2][3] is the production of materials, structures, devices, and finished goods in a manner such that every atom has a specified location relative to the other atoms, and in which there are no defects, missing atoms, extra atoms, or incorrect (impurity) atoms. Molecules are atomically precise objects and, as such, are essential building blocks in atomically precise manufacturing. Novel molecular designs can, themselves, be considered atomically precise products; for example, enzyme-like catalysts can be crafted to accelerate chemical reactions.[5] Beyond synthesis techniques to create single molecules, the key challenge of atomically precise manufacturing is in the assembly of molecular building blocks into larger and more complex objects that are also atomically precise. The two known methods for doing this are self-assembly and positional assembly. Molecules that have been designed or have evolved to bind together, typically along conformal surfaces, will self-assemble under the right conditions. In the production of atomically precise membranes, molecules can arrange themselves on the surface of a liquid and then be chemically bound to each other.[6] Complex atomically precise self-assembled objects are also possible: striking examples include the robot-like Enterobacteria phage T4 and the bacterial flagellar motor.[7] In these cases, free-floating "parts" (proteins) in solution self-assemble into three-dimensional objects. Self-assembly APM is experimentally accessible today. In non-biological systems, the positional assembly (that is, the chemical binding) of a single atom to a single molecule was first demonstrated by Ho and Lee at Cornell University in 1999 using a scanning tunneling microscope (STM).[8] In this seminal work, a single carbon monoxide molecule on the tip of an STM was moved to a single iron atom sitting on the surface of a crystal and chemically bound by applying electric current. In August 2015, the United States Department of Energy (DOE) Advanced Manufacturing Office (AMO) invited researchers to their Workshop on Integrated Nanosystems for Atomically Precise Manufacturing (INFAPM) to gather information for accelerating the development of APM. "A fundamentally new approach to INFAPM structures and applications, tools, and demonstration is needed to realize the enormous savings potential of atomic-scale, defect-free manufacturing."[9] There are two assembly approaches for achieving an atomic precision. The first approach is tip-based positional assembly using scanning probe microscopes, which would also include Joseph W. Lyding's selective deprotection and atomic layer epitaxial deposition. The second approach is an integrated nanosystem using molecular machine components. Both approaches have considerable challenges to implementation, including positional accuracy (which is influenced by factors such as component stiffness and thermal vibration), repeatability, working tip design and synthesis, suitable building block design, transport of molecules to the working tip, and scalability."[10] References[1] "Atomically Precise Manufacturing using STM Based Patterning". University of Texas-Arlington, ZyVex Labs. 2015-10-06. Retrieved 2016-05-18.[2] "Atomically precise manufacturing as the future of nanotechnology". foresight.org. 2015-03-08. Retrieved 2016-05-18. [3] "Nanotechnology's Revolutionary Next Phase". Forbes.com. 2013-02-26. Retrieved 2016-05-18. [4] "Atomic Precision Advanced Manufacturing for Digital Electronics" (PDF). Electronic Device Failure Analysis. 2020-02-25. Retrieved 2020-10-30. [5] "Small Businesses Selected for Research Awards in New Topic Focused on Mimicking Nature's Catalysts | Department of Energy". www.energy.gov. Retrieved 2018-07-11. [6] Han, Daehoon; Park, Yongkuk; Kim, Hyejin; Lee, Jong Bum (2014). "Self-Assembly of Free Standing RNA Membranes | Nature Communications". Nature Communications. 5: 4367. doi:10.1038/ncomms5367. PMID 24994070. [7] "Structure and Function of the Bi-Directional Bacterial Flagellar Motor | Researchgate". www.researchgate.com. Retrieved 2018-07-11. [8] Single-Bond Formation and Characterization with a Scanning Tunneling Microscope | Researchgate". www.researchgate.com. Retrieved 2018-07-11. [9] "Integrated Nanosystems for Atomically Precise Manufacturing Workshop – August 5-6, 2015 | Department of Energy". www.energy.gov. Retrieved 2018-06-05 [10]"DOE: Atomically Precise Manufacturing FY 2018 | Nano". www.nano.gov. Retrieved 2018-06-05. Last Updated 19 February 2021 Back to David Forrest's home page. |