Synergetic chemical coupling controls the uniformity of carbon nanotube microstructure growth.

Control of the uniformity of vertically aligned carbon nanotube structures (CNT "forests"), in terms of both geometry and nanoscale morphology (density, diameter, and alignment), is crucial for applications. Many studies report complex and sometimes unexplained spatial variations of the height of macroscopic CNT forests, as well as variations among micropillars grown from lithographically patterned catalyst arrays. We present a model for chemically coupled CNT growth, which describes the origins of synergetic growth effects among CNT micropillars in proximity. Via this model, we propose that growth of CNTs is locally enhanced by active species that are catalytically produced at the substrate-bound nanoparticles. The local concentration of these active species modulates the growth rate of CNTs, in a spatially dependent manner driven by diffusion and local generation/consumption at the catalyst sites. Through experiments and numerical simulations, we study how the uniformity of CNT micropillars can be influenced by their size and spacing within arrays and predict the widely observed abrupt transition between tangled and vertical CNT growth by assigning a threshold concentration of active species. This mathematical framework enables predictive modeling of spatially dependent CNT growth, as well as design of catalyst patterns to achieve engineered uniformity.

[1]  Gyula Eres,et al.  Flux-dependent growth kinetics and diameter selectivity in single-wall carbon nanotube arrays. , 2011, ACS nano.

[2]  Mostafa Bedewy,et al.  Collective mechanism for the evolution and self-termination of vertically aligned carbon nanotube growth , 2009 .

[3]  J. Robertson,et al.  Diffusion- and reaction-limited growth of carbon nanotube forests. , 2009, ACS nano.

[4]  K. Goodson,et al.  Heat Capacity, Thermal Conductivity, and Interface Resistance Extraction for Single-Walled Carbon Nanotube Films Using Frequency-Domain Thermoreflectance , 2013, IEEE Transactions on Components, Packaging and Manufacturing Technology.

[5]  A. Hart,et al.  Diameter-dependent kinetics of activation and deactivation in carbon nanotube population growth , 2012 .

[6]  P. Ajayan,et al.  Reliability and current carrying capacity of carbon nanotubes , 2001 .

[7]  R. Baughman,et al.  Carbon Nanotubes: Present and Future Commercial Applications , 2013, Science.

[8]  H. Jiang,et al.  An essential role of CO2 and H2O during single-walled CNT synthesis from carbon monoxide , 2006 .

[9]  Robert C. Davis,et al.  Effect of iron catalyst thickness on vertically aligned carbon nanotube forest straightness for CNT-MEMS , 2012 .

[10]  M. Strano,et al.  A mechanochemical model of growth termination in vertical carbon nanotube forests. , 2008, ACS nano.

[11]  K. Hata,et al.  Unexpectedly high yield carbon nanotube synthesis from low-activity carbon feedstocks at high concentrations. , 2013, ACS nano.

[12]  A John Hart,et al.  Multiple alkynes react with ethylene to enhance carbon nanotube synthesis, suggesting a polymerization-like formation mechanism. , 2010, ACS nano.

[13]  A. John Hart,et al.  Visualizing Strain Evolution and Coordinated Buckling within CNT Arrays by In Situ Digital Image Correlation , 2012 .

[14]  Antonio Monzón,et al.  Carbon Nanotube Growth by Catalytic Chemical Vapor Deposition: A Phenomenological Kinetic Model , 2010 .

[15]  O. S. Nakagawa,et al.  Rapid characterization and modeling of pattern-dependent variation in chemical-mechanical polishing , 1998 .

[16]  L. Forró,et al.  Evidence of an equimolar C2H2-CO2 reaction in the synthesis of carbon nanotubes. , 2007, Angewandte Chemie.

[17]  C. Thompson,et al.  Precursor gas chemistry determines the crystallinity of carbon nanotubes synthesized at low temperature , 2011 .

[18]  K. Jiang,et al.  Effect of carbon deposits on the reactor wall during the growth of multi-walled carbon nanotube arrays , 2007 .

[19]  A. Hart,et al.  Measurement of carbon nanotube microstructure relative density by optical attenuation and observation of size-dependent variations. , 2013, Physical chemistry chemical physics : PCCP.

[20]  J. Lefebvre,et al.  Origin of periodic rippling during chemical vapor deposition growth of carbon nanotube forests , 2011 .

[21]  Lingbo Zhu,et al.  Monitoring carbon nanotube growth by formation of nanotube stacks and investigation of the diffusion-controlled kinetics. , 2006, The journal of physical chemistry. B.

[22]  A John Hart,et al.  Early evaluation of potential environmental impacts of carbon nanotube synthesis by chemical vapor deposition. , 2009, Environmental science & technology.

[23]  L. Forró,et al.  Striking influence of the catalyst support and its acid-base properties: new insight into the growth mechanism of carbon nanotubes. , 2011, ACS nano.

[24]  J. Robertson,et al.  Growth kinetics of 0.5 cm vertically aligned single-walled carbon nanotubes. , 2007, The journal of physical chemistry. B.

[25]  Bas Ketelaars,et al.  Synergetic nanowire growth. , 2007, Nature nanotechnology.

[26]  K. Hata,et al.  Water-Assisted Highly Efficient Synthesis of Impurity-Free Single-Walled Carbon Nanotubes , 2004, Science.

[27]  Kwon,et al.  Unusually high thermal conductivity of carbon nanotubes , 2000, Physical review letters.

[28]  Stephen Jesse,et al.  In situ measurements and modeling of carbon nanotube array growth kinetics during chemical vapor deposition , 2005 .

[29]  Sameh H Tawfick,et al.  Self-similar organization of arrays of individual carbon nanotubes and carbon nanotube micropillars , 2010 .

[30]  A. Hart,et al.  Flexible high-conductivity carbon-nanotube interconnects made by rolling and printing. , 2009, Small.

[31]  J. Robertson,et al.  The Phase of Iron Catalyst Nanoparticles during Carbon Nanotube Growth , 2012 .

[32]  Benji Maruyama,et al.  In situ evidence for chirality-dependent growth rates of individual carbon nanotubes. , 2012, Nature materials.

[33]  N. Olofsson,et al.  Effect of catalyst pattern geometry on the growth of vertically aligned carbon nanotube arrays , 2009 .

[34]  P.R. Chidambaram,et al.  Pattern Based Prediction for Plasma Etch , 2007, IEEE Transactions on Semiconductor Manufacturing.

[35]  Gyula Eres,et al.  Molecular beam-controlled nucleation and growth of vertically aligned single-wall carbon nanotube arrays. , 2005, The journal of physical chemistry. B.

[36]  H. Wong,et al.  Synergetic carbon nanotube growth , 2013 .

[37]  Mostafa Bedewy,et al.  Mechanical coupling limits the density and quality of self-organized carbon nanotube growth. , 2013, Nanoscale.

[38]  J. Greer,et al.  In situ Mechanical Testing Reveals Periodic Buckle Nucleation and Propagation in Carbon Nanotube Bundles , 2010 .

[39]  M. Bronikowski CVD growth of carbon nanotube bundle arrays , 2006 .

[40]  Gábor Csányi,et al.  Dynamic catalyst restructuring during carbon nanotube growth. , 2010, ACS nano.

[41]  A. Harutyunyan,et al.  Dislocation theory of chirality-controlled nanotube growth , 2009, Proceedings of the National Academy of Sciences.

[42]  H. Dai,et al.  Ultra-high-yield growth of vertical single-walled carbon nanotubes: Hidden roles of hydrogen and oxygen. , 2005, Proceedings of the National Academy of Sciences of the United States of America.

[43]  Eric Verploegen,et al.  Engineering vertically aligned carbon nanotube growth by decoupled thermal treatment of precursor and catalyst. , 2009, ACS nano.

[44]  J. Robertson,et al.  In situ observations of catalyst dynamics during surface-bound carbon nanotube nucleation. , 2007, Nano letters.

[45]  Mostafa Bedewy,et al.  Population growth dynamics of carbon nanotubes. , 2011, ACS nano.