High stability of charged particle clusters in protoplanetary disks

IF 5.4 2区 物理与天体物理 Q1 ASTRONOMY & ASTROPHYSICS
J. Schwaak, F. Führer, D. E. Wolf, L. Posorski, L. Brendel, J. Teiser, G. Wurm
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引用次数: 0

Abstract

Context. The initial particle growth in protoplanetary disks is limited by a bouncing barrier at submillimeter wavelengths. Bouncing leads to tribocharging and the electrostatic attraction of tribocharged aggregates may eventually draw them into large clusters. A charge- mediated growth phase allows for the formation of larger entities, namely, clusters of aggregates that are more prone to further particle concentrations, such as the streaming instability.Aims. We aim to quantify the strength of the electrostatic forces.Methods. In laboratory experiments, we used an acoustic trap to levitate small aggregates of tribocharged submm grains. These aggregates spin up within the trap until they lose grains. Thus, we used the centrifugal force as a measure of the local force.Results. Grains are regularly bound strongly to their neighbors. In comparison, the force at ejection can be stronger than the attractive scattering forces of the trap and can therefore be several orders of magnitude larger than expected. We note that these forces are long- ranging, compared to van der Waals forces. Thus, charged aggregates are much more stable than uncharged ones.Conclusions. Particle aggregates in disks might grow to centimeter clusters or larger as tribocharging increases the effective binding forces. This allows for hydrodynamic concentration and planetesimal formation to eventually take place throughout a wide part of the disk.
原行星盘中带电粒子群的高度稳定性
背景。原行星盘中最初的粒子生长受到亚毫米波长反弹屏障的限制。弹跳会导致三电荷,三电荷聚集体的静电吸引力最终会将它们吸引成大的团块。电荷介导的生长阶段可以形成更大的实体,即更容易进一步造成粒子聚集的聚集簇,如流变不稳定性。我们旨在量化静电力的强度。在实验室实验中,我们使用声学陷阱来悬浮三电荷亚毫米晶粒的小聚集体。这些聚集体在捕集器内旋转,直到失去晶粒。因此,我们用离心力来衡量局部力。晶粒有规律地与相邻晶粒紧密结合。相比之下,弹射时的力可能比陷阱的吸引力散射力更强,因此可能比预期的大几个数量级。我们注意到,与范德华力相比,这些力的作用范围更大。因此,带电的聚集体要比不带电的稳定得多。由于三电荷增加了有效结合力,磁盘中的粒子聚集体可能会增长到厘米级或更大。这使得流体动力聚集和行星小体的形成最终会在整个星盘的大部分区域发生。
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来源期刊
Astronomy & Astrophysics
Astronomy & Astrophysics 地学天文-天文与天体物理
CiteScore
10.20
自引率
27.70%
发文量
2105
审稿时长
1-2 weeks
期刊介绍: Astronomy & Astrophysics is an international Journal that publishes papers on all aspects of astronomy and astrophysics (theoretical, observational, and instrumental) independently of the techniques used to obtain the results.
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