Anna B. Baker
University of Bristol
11 Papers
28 Citations
Anna B. Baker is an academic researcher from University of Bristol. The author has contributed to research in topics: Masking (art) & Self-healing hydrogels. The author has an hindex of 5, co-authored 11 publications. Previous affiliations of Anna B. Baker include Engineering and Physical Sciences Research Council.
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Papers
Green composites: A review of material attributes and complementary applications
Michael P. M. Dicker,Michael P. M. Dicker,Peter F. Duckworth,Anna B. Baker,Guillaume Francois,Guillaume Francois,Mark K. Hazzard,Mark K. Hazzard,Paul M. Weaver +8 more
TL;DR: In this article, the authors provide guidelines for engineers and designers on the appropriate application of green composites and provide a concise summary of the major material attributes of green composite materials accompanied by graphical comparisons of their relative properties.
572
4D sequential actuation: Combining ionoprinting and redox chemistry in hydrogels
TL;DR: In this paper, a soft actuator which utilizes ionoprinting of iron and vanadium, with the selective reduction of iron through a mild reducing agent, is presented to achieve chemically controlled sequential folding.
4D printing with robust thermoplastic polyurethane hydrogel-elastomer trilayers
Anna B. Baker,Simon R.G. Bates,Thomas M. Llewellyn-Jones,Laurie P.B. Valori,Michael P. M. Dicker,Richard S. Trask +5 more
TL;DR: In this paper, a new 4D printing technique capable of producing a diverse range of trilayer constructs using commercial low-cost desktop 3D printers is presented, which enables the viable construction of dynamically robust and complex origami architectures for a new generation of active structures.
116
Light-Triggered Soft Artificial Muscles: Molecular-Level Amplification of Actuation Control Signals
Michael P. M. Dicker,Anna B. Baker,Robert J. Iredale,Sina Naficy,Sina Naficy,Ian P Bond,Charl F. J. Faul,Jonathan Rossiter,Jonathan Rossiter,Geoffrey M. Spinks,Paul M. Weaver +10 more
TL;DR: A biomimetic molecular-level approach is developed that employs light, with its excellent spatial and temporal control properties, to actuate soft, pH-responsive hydrogel artificial muscles, realising a new strategy for the creation of highly functional soft actuating systems.
Thermally induced reversible and reprogrammable actuation of tough hydrogels utilising ionoprinting and iron coordination chemistry
TL;DR: In this paper, the authors combined ionoprinting with a tougher interpenetrating network polymer (IPN) hydrogel with dual pH and temperature responsiveness, enabling the realisation of more highly strained and complex shape formation.