Nanomanufacturing involves designing, fabricating, and assembling materials or devices at the nanoscale, essential for advancing nanotechnology applications across engineering and science. This field focuses on methods that enable precise control over structures measured in billionths of a meter, impacting electronics, medicine, and materials science. As a subfield of ENGINEERING > Nanotechnology, nanomanufacturing research explores innovative ways to produce nanoscale components efficiently. JoVE Visualize enhances the learning experience by pairing PubMed articles with JoVE’s experiment videos, offering readers a clearer understanding of the research techniques and outcomes involved.
Established nanomanufacturing methods include top-down and bottom-up approaches, the two fundamental strategies driving the field. Top-down methods, like lithography and etching, carve nanoscale features from bulk materials, widely used in semiconductor fabrication. Bottom-up techniques, such as self-assembly and chemical vapor deposition, build structures atom-by-atom or molecule-by-molecule, enabling precise material customization. Other common techniques include nanoimprint lithography and focused ion beam processing. Understanding these nanomanufacturing examples reveals how researchers achieve structural control and functional integration at the nanoscale.
Recent advances in nanomanufacturing emphasize scalable, cost-effective methods and integration with biological systems. Emerging trends include advanced 3D nanoprinting, which allows complex architectures beyond conventional fabrication limits. Techniques like atomic layer deposition and novel self-assembly strategies improve material uniformity and device performance. Additionally, hybrid approaches combining top-down and bottom-up methods aim to overcome limitations of each. As the field evolves, the impact factors seen in leading nanomanufacturing journals reflect rapid progress. These developments are vital for translating laboratory discoveries into commercial nanotechnology products.
Antonio J Santos, Marta Escanciano, Alfonso Suárez-Llorens, M Pilar Yeste, Francisco M Morales
Vincenzo Caligiuri, Aniket Patra, Maria P De Santo, Agostino Forestiero, Giuseppe Papuzzo, Dante M Aceti, Giuseppe E Lio, Riccardo Barberi, Antonio De Luca
Victória Vieira Kopp, Caroline Borges Agustini, Mariliz Gutterres, João Henrique Zimnoch Dos Santos
Henry Seligman, Sameer Zaman, David S Pitcher, Matthew J Shun-Shin, Freya Hepworth Lloyd, Vitaliy Androshchuk, Sayan Sen, Rasha Al-Lamee, David M Miller, Harry W Barnett, Gulam S Haji, Luke S Howard, Sukhjinder Nijjer, Jamil Mayet, Darrel P Francis, Oscar Ces, Nicholas W F Linton, Nicholas S Peters, Ricardo Petraco
Pei-Hsiang Hsu, Chien-Chun Chang, Tsu-Hao Wang, Phuc Khanh Lam, Ming-Yu Wei, Ching-Tien Chen, Chin-Yu Chen, Lien-Yang Chou, Fa-Kuen Shieh
Mohammad Kalantari, Meihua Yu, Owen Noonan, Hao Song, Chun Xu, Xiaodan Huang, Feixiang Xiang, Xiaolin Wang, Chengzhong Yu
Sanjay Kumar, Pramila Sharma, Poonam Ratrey, Bhaskar Datta