Zheng Lu scite author profile

Social instant messaging services are emerging as a transformative form with which people connect, communicate with friends in their daily life -they catalyze the formation of social groups, and they bring people stronger sense of community and connection. However, research community still knows little about the formation and evolution of groups in the context of social messaging -their lifecycles, the change in their underlying structures over time, and the diffusion processes by which they develop new members.In this paper, we analyze the daily usage logs from WeChat group messaging platform -the largest standalone messaging communication service in China -with the goal of understanding the processes by which social messaging groups come together, grow new members, and evolve over time. Specifically, we discover a strong dichotomy among groups in terms of their lifecycle, and develop a separability model by taking into account a broad range of group-level features, showing that long-term and shortterm groups are inherently distinct. We also found that the lifecycle of messaging groups is largely dependent on their social roles and functions in users' daily social experiences and specific purposes. Given the strong separability between the long-term and short-term groups, we further address the problem concerning the early prediction of successful communities.In addition to modeling the growth and evolution from grouplevel perspective, we investigate the individual-level attributes of group members and study the diffusion process by which groups gain new members. By considering members' historical engagement behavior as well as the local social network structure that they embedded in, we develop a membership cascade model and demonstrate the effectiveness by achieving AUC of 95.31% in predicting inviter, and an AUC of 98.66% in predicting invitee.

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A novel probabilistic graphic model to detect product defects from social media data

2020

Decision Support Systems

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An integrated probabilistic graphic model and FMEA approach to identify product defects from social media data

2021

Expert Systems with Applications

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A Unique Ruthenium Carbyne Complex: A Highly Thermo‐endurable Catalyst for Olefin Metathesis

Shao¹,

Lu²,

Qiao³

et al. 2012

Adv Synth Catal

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A cationic ruthenium carbyne complex was prepared and was found to initiate olefin metathesis reactions with good activities, which throws a new light on the design of a new type of ruthenium catalyst for RCM reactions. More importantly, no double bond isomerized by-product was observed even at elevated temperatures in reactions catalyzed by the new carbyne complex. A mechanism involving the in situ conversion of the ruthenium carbyne to a ruthenium carbene complex via addition of an iodide to the carbyne carbon was also proposed.

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Zheng Lu

Social Network Analysis: Methods and Examples

The Lifecycle and Cascade of WeChat Social Messaging Groups

A novel probabilistic graphic model to detect product defects from social media data

An integrated probabilistic graphic model and FMEA approach to identify product defects from social media data

A Unique Ruthenium Carbyne Complex: A Highly Thermo‐endurable Catalyst for Olefin Metathesis

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