((p-Chlorobenzyl)oxy)guanidine nitrate (CAS 1020-92-4)
((p-Chlorobenzyl)oxy)guanidine nitrate (CAS:
1020-92-4) has molecular formula C8H11ClN4O4 and molecular weight 262.65 g/mol. This compound has been the subject of numerous scientific investigations due to its structural features and practical utility in synthetic chemistry and industrial processes. View product details →
Product Background
This comprehensive research profile examines the scientific literature surrounding ((p-Chlorobenzyl)oxy)guanidine nitrate.
Key Research Findings
- The nucleation model is used in combination with the measurements of crystallisation events to infer nucleation rates at varying equilibrium state points, showing that classical nu
Detailed Literature Analysis
Below are the top-ranked research papers for ((p-Chlorobenzyl)oxy)guanidine nitrate, presented with bibliographic details and scientific abstracts.
Synthetic Chemistry
1. Properties of Confined Ammonium Nitrate Ionic Liquids
Ethylammonium nitrate (EAN) and propylammonium nitrate ionic liquids confined between polar glass plates and exposed to a strong magnetic field demonstrate gradually slowing diffusivity, a process that can be reversed by removing the sample from the magnetic field. The process can be described well by the Avrami equation, which is typical for autoc
🔑 Key Finding: Ethylammonium nitrate and propylammonium nitrate ionic liquids confined between polar glass plates and exposed to a strong magnetic field demonstrate gradually slowing diffusivity
2. Properties of Confined Ammonium Nitrate Ionic Liquids
Ethylammonium nitrate (EAN) and propylammonium nitrate ionic liquids confined between polar glass plates and exposed to a strong magnetic field demonstrate gradually slowing diffusivity, a process that can be reversed by removing the sample from the magnetic field. The process can be described well by the Avrami equation, which is typical for autoc
Biological & Pharmacological Studies
3. Autonomous Sensor Exchange and Calibration for Cornstalk Nitrate Monitoring Robot
Interactive sensors are an important component of robotic systems but often require manual replacement due to wear and tear. Automating this process can enhance system autonomy and facilitate long-term deployment. We developed an autonomous sensor exchange and calibration system for an agriculture crop monitoring robot that inserts a nitrate sensor
4. Autonomous Sensor Exchange and Calibration for Cornstalk Nitrate Monitoring Robot
Interactive sensors are an important component of robotic systems but often require manual replacement due to wear and tear. Automating this process can enhance system autonomy and facilitate long-term deployment. We developed an autonomous sensor exchange and calibration system for an agriculture crop monitoring robot that inserts a nitrate sensor
5. Hyperspectral in situ remote sensing of water surface nitrate in the Fitzroy River estuary, Queensland, Australia, using deep learning
Nitrate () is a form of dissolved inorganic nitrogen derived primarily from anthropogenic sources. The recent increase in river-discharged nitrate poses a major risk for coral bleaching in the Great Barrier Reef (GBR) lagoon. Although nitrate is an optically inactive (i.e., colourless) constituent, previous studies have demonstrated there is an ind
6. Hyperspectral in situ remote sensing of water surface nitrate in the Fitzroy River estuary, Queensland, Australia, using deep learning
Nitrate () is a form of dissolved inorganic nitrogen derived primarily from anthropogenic sources. The recent increase in river-discharged nitrate poses a major risk for coral bleaching in the Great Barrier Reef (GBR) lagoon. Although nitrate is an optically inactive (i.e., colourless) constituent, previous studies have demonstrated there is an ind
Other Research
7. Nucleation kinetics in drying sodium nitrate aerosols
A quantitative understanding of the evaporative drying kinetics and nucleation rates of aqueous based aerosol droplets is important for a wide range of applications, from atmospheric aerosols to industrial processes such as spray drying. Here, we introduce a numerical model for interpreting measurements of the evaporation rate and phase change of d
8. Nucleation kinetics in drying sodium nitrate aerosols
A quantitative understanding of the evaporative drying kinetics and nucleation rates of aqueous based aerosol droplets is important for a wide range of applications, from atmospheric aerosols to industrial processes such as spray drying. Here, we introduce a numerical model for interpreting measurements of the evaporation rate and phase change of d
Conclusion
The research literature on ((p-Chlorobenzyl)oxy)guanidine nitrate demonstrates sustained scientific interest, with publications continuing through 0. The compound serves as an important building block in synthetic chemistry and has been explored for various applications. Researchers and industrial users can view detailed specifications or submit an inquiry for pricing and availability.
Data Sources: PubMed/MEDLINE, CrossRef. 8 papers analyzed. Last updated: 2026-05-25. This article is automatically generated from peer-reviewed research data.