Webinar

The Webinar topic is dedicated to the electrochemistry of nanomaterials and electromagnetic technologies. These intersections allow us to explore the frontiers of innovation and research, delving into fundamental topics in the field of materials science and emerging technologies.

In the realm of electrochemistry, we examine methods and technologies to efficiently and creatively utilize processes, paving the way for new operational approaches previously unseen.

In the Nanomaterials section, we explore the world of nanomaterials from an electrochemical and magnetic perspective, analyzing their plasmatic nature and their ability to assume different forms through interactions with other forces.

Through the Electromagnetic Technologies section, we explore the interaction of electromagnetic fields with the support of nanomaterials and their practical applications, opening the door to new innovative solutions and advancements in science and technology.

If you wish to delve deeper into these topics or request our services, please contact us. We are here to answer all your questions and provide the necessary support. You can reach us through the contact form or by sending an email to .

Available Topics

Electrochemistry Section

Introduction to Resonance Electrolysis Technology
1.1 Advantages and quality of gases obtained without the use of chemical electrolytes
1.2 Creation of nanotubes in electrolytic reactors
1.3 Principles of coherence and creation of almost free electrons
1.4 Overview of the implosive nature of oxyhydrogen
1.5 Introduction to civil, industrial, and medical applications

Approach to Installing Electrolytic Reactors on Internal Combustion Engines
2.1 General overview of the assembly scheme
2.2 Operating principle and key points on installations
2.3 Configuration as a motor additive and configuration with professional injection systems
2.4 Complete overview of settings, alarms, and steady-state operation of the system
2.5 Extraordinary maintenance

Implementations of Installing Electrolytic Reactors on Internal Combustion Engines
3.1 Chemical treatments on mechanical parts to protect metal parts from hydrogen
3.2 Modifications to engine operation principles to adapt to hydrogen
3.3 Configuration of the ECU and sensor parameters for engineering retrofit from fossil fuel to hydrogen

Approach to Installing Electrolytic Reactors on Residential Heating
4.1 General overview of the assembly scheme
4.2 Operating principle and key points on installations
4.3 Configuration as a motor additive and configuration with professional injection systems
4.4 Complete overview of settings, alarms, and steady-state operation of the system
4.5 Ordinary and extraordinary maintenance

Introduction to Resonance Electrolysis Technology Applied to Catalytic Conversion
5.1 General operating principle of the catalytic reaction of oxyhydrogen to pure water
5.2 Initiation of the reaction, catalysts, and types of catalytic converter supports
5.3 Available technologies and methods for depositing metallic supports for catalytic reactions
5.4 General overview of approaches and safety procedures for testing
5.5 Introduction to the operating scheme of the Catalytic Heating Reactor
5.6 Control of the catalytic reaction through proportional-integral-derivative (PID) control, useful for making the system stable, safe, and efficient

Introduction to Resonance Electrolysis Technology Applied to Catalytic Conversion
6.1 Operation of the catalytic converter
6.2 Highly exothermic reaction principle of oxyhydrogen on catalyst supports
6.3 Specific treatments of catalytic converters to achieve the reaction
6.4 How to use the heat produced by the catalytic reactor for heating air, water, and floors

Deepening Resonance Electrolysis Technology Applied to Catalytic Conversion
7.1 General operating principle of the catalytic reaction of oxyhydrogen to pure water
7.2 Initiation of the reaction, catalysts, and types of catalytic converter supports
7.3 Available technologies and methods for depositing metallic supports for catalytic reactions
7.4 General overview of approaches and safety procedures for testing
7.5 Introduction to the operating scheme of the Catalytic Heating Reactor
7.6 Control of the catalytic reaction through proportional-integral-derivative (PID) control, useful for making the system stable, safe, and efficient

Nanomaterials Section

Introduction to Transition Metal Technology
8.1 General overview of the nature and composition of platinum group elements
8.2 Literature citations on platinum group transition elements
8.3 Overview of platinum group transition elements applications in agriculture
8.4 Overview of platinum group transition elements applications in human use
8.5 Overview of platinum group transition elements applications in energy

Guide to Extracting Transition Metals of the Platinum Group
9.1 General overview of material selection and necessary equipment
9.2 Method of extracting platinum group elements
9.3 Preparation of the base and reagent, pH meter calibration and standards
9.4 Reaction process, peaks, sub-reactions, safety windows
9.5 Protection of the precipitate from electromagnetic sources
9.6 Base purification according to the intended use
9.7 Coupling/rearrangement of transition metals with organic nanomaterials
9.8 General overview of applications: biocellular, biovegetal, cosmetic, and energy storage
9.9 Drying and pulverization
9.10 Types of analyses to be performed

Use of Transition Metals as Cellular Bioactivators
10.1 General overview of the use of transition metals as cellular bioactivators
10.2 Overview of the quantum state of transition elements in morphogenetics, effect on morphogenetic fields, and higher states of consciousness
10.3 Application methods to influence and stimulate the biological system
10.4 Identification of discomfort and solution through quantum transfer onto water, quantum porting, and water intake
10.5 Effects on biology, duration, and preservation

Use of Transition Metals as Plant Bioactivators
11.1 Overview of the use of transition metals as plant bioactivators
11.2 Effects on photorespiration reactions and optimal plant growth
11.3 Types of formulations, dilutions, and dosages
11.4 Application of the product to soil and foliar surfaces
11.5 Methods for soil irrigation and foliar deposition
11.6 Seed coating, basic treatment, complete treatment, co-application
11.7 Duration, preservation, and warnings