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Our Go Direct package is great way to get started. It includes most of the sensors needed for the experiments in the lab book.
£1,756.00 ex VAT | £2,107.20 Inc VAT Add to basket
The Go Direct Temperature Probe is a rugged, general-purpose temperature sensor that students can use to monitor temperature. It directly connects wirelessly via Bluetooth® or wired via USB to your platform.
£111.00 ex VAT | £133.20 Inc VAT Add to basket
The Go Direct pH Sensor is a general-purpose pH sensor used to monitor pH of aqueous solutions. It directly connects wirelessly via Bluetooth® or wired via USB to your platform.
£155.00 ex VAT | £186.00 Inc VAT Add to basket
The Go Direct Gas Pressure Sensor measures the absolute pressure of a gas. It directly connects wirelessly via Bluetooth® or wired via USB to your platform.
£141.00 ex VAT | £169.20 Inc VAT Add to basket
The Go Direct Voltage Probe combines a wide input voltage range and high precision, making it an excellent choice for investigations of both AC/DC circuits and electromagnetism. It directly connects wirelessly via Bluetooth® or wired via USB to your platform.
£113.00 ex VAT | £135.60 Inc VAT Add to basket
The Go Direct Constant Current System is a DC power source with a built-in current probe designed for use in electrochemistry experiments. It directly connects wirelessly via Bluetooth® or wired via USB to your platform.
£121.00 ex VAT | £145.20 Inc VAT Add to basket
The Go Direct Conductivity Probe determines the ionic content of an aqueous solution by measuring its electrical conductivity. It directly connects wirelessly via Bluetooth® or wired via USB to your platform.
£169.00 ex VAT | £202.80 Inc VAT Add to basket
The Go Direct Drop Counter precisely records the number of drops of titrant added during a titration and then automatically converts it to volume. It directly connects wirelessly via Bluetooth® or wired via USB to your platform.
£155.00 ex VAT | £186.00 Inc VAT Add to basket
The Go Direct ORP (Oxidation-Reduction Potential) Sensor measures the ability of a solution to act as an oxidizing or reducing agent. It directly connects wirelessly via Bluetooth® or wired via USB to your platform.
£168.00 ex VAT | £201.60 Inc VAT Add to basket
The Go Direct SpectroVis Plus Spectrophotometer quickly measures a full wavelength spectrum. It directly connects wirelessly via Bluetooth® or wired via USB to your platform.
Use with the Vernier Spectrophotometer Optical Fiber.
£643.00 ex VAT | £771.60 Inc VAT Add to basketFree Software
Graphical Analysis™ for Chrome™, iOS®, Android™, Windows®, and macOS®
Collect, share, and analyze sensor data with our free software. Graphical Analysis 4 app facilitates student understanding with real-time graphs of experimental data and intuitive analysis tools.
Learn more about Graphical Analysis
Spectral Analysis 4 App
Collect, share, and analyze spectrometer data with our free software for Chrome™, iOS, Android™, Windows®, and macOS™. Using the app, students can collect a full spectrum and explore topics such as Beer’s law, enzyme kinetics, and plant pigments.
Lab Book
Advanced Chemistry with Vernier
Advanced Chemistry with Vernier contains 35 experiments appropriate for AP* Chemistry or college general chemistry. Use it in addition to Vernier Chemistry Investigations for Use with AP* Chemistry for a comprehensive set of topics.
The electronic version of the lab book includes a searchable PDF of the entire book, word-processing files for student experiments, teacher information files including sample data and graphs, a complete materials and supplies list, and other supplemental resources. The printed lab book includes everything in the electronic version, plus a printed copy of the book.
A site license is included. You only need one copy of either the electronic version or printed lab book for your entire school or college department.
Advanced Chemistry with Vernier lab book contains the following Experiments:
- The Molar Mass of a Volatile Liquid
- Using Freezing-Point Depression to Find Molecular Weight
- The Molar Volume of a Gas
- Determining the Mole Ratios in a Chemical Reaction
- The Decomposition of Hydrogen Peroxide
- Determining the Enthalpy of a Chemical Reaction
- The Synthesis of Alum
- The Analysis of Alum
- The Synthesis and Analysis of Aspirin
- The Enthalpy of Neutralization of Phosphoric Acid
- The Base Hydrolysis of Ethyl Acetate
- Exploring the Properties of Gases
- Vapor Pressure and Heat of Vaporization
- Rate Determination and Activation Energy
Stainless Steel Temperature Probe
- The Molar Mass of a Volatile Liquid
- Using Freezing-Point Depression to Find Molecular Weight
- The Molar Volume of a Gas
- Determining the Mole Ratios in a Chemical Reaction
- The Decomposition of Hydrogen Peroxide
- Determining the Enthalpy of a Chemical Reaction
- The Synthesis of Alum
- The Analysis of Alum
- The Synthesis and Analysis of Aspirin
- The Enthalpy of Neutralization of Phosphoric Acid
- The Base Hydrolysis of Ethyl Acetate
- Exploring the Properties of Gases
- Vapor Pressure and Heat of Vaporization
- Rate Determination and Activation Energy
- The Molar Mass of a Volatile Liquid
- The Molar Volume of a Gas
- The Decomposition of Hydrogen Peroxide
- Exploring the Properties of Gases
- Vapor Pressure and Heat of Vaporization
- The Molar Mass of a Volatile Liquid
- The Molar Volume of a Gas
- The Decomposition of Hydrogen Peroxide
- Exploring the Properties of Gases
- Vapor Pressure and Heat of Vaporization
- Standardizing a Solution of Sodium Hydroxide
- Acid-Base Titration
- Investigating Indicators
- Separation and Qualitative Analysis of Cations
- Separation and Qualitative Analysis of Anions
- Buffers
- Determining the Ksp of Calcium Hydroxide
- Determining Ka by the Half-Titration of a Weak Acid
- Standardizing a Solution of Sodium Hydroxide
- Acid-Base Titration
- Investigating Indicators
- Separation and Qualitative Analysis of Cations
- Separation and Qualitative Analysis of Anions
- Buffers
- Determining the Ksp of Calcium Hydroxide
- Determining Ka by the Half-Titration of a Weak Acid
- Standardizing a Solution of Sodium Hydroxide
- Acid-Base Titration
- An Oxidation-Reduction Titration: The Reaction of Fe2+ and Ce4+
- Investigating Indicators
- Conductimetric Titration and Gravimetric Determination of a Precipitate
- Potentiometric Titration of Hydrogen Peroxide
- Standardizing a Solution of Sodium Hydroxide
- Acid-Base Titration
- An Oxidation-Reduction Titration: The Reaction of Fe2+ and Ce4+
- Investigating Indicators
- Conductimetric Titration and Gravimetric Determination of a Precipitate
- Potentiometric Titration of Hydrogen Peroxide
- An Oxidation-Reduction Titration: The Reaction of Fe2+ and Ce4+
- Potentiometric Titration of Hydrogen Peroxide
- An Oxidation-Reduction Titration: The Reaction of Fe2+ and Ce4+
- Potentiometric Titration of Hydrogen Peroxide
Go Direct SpectroVis Plus Spectrometer
- The Determination of an Equilibrium Constant
- Determining the Concentration of a Solution: Beer’s Law
- The Synthesis and Analysis of Aspirin
- The Rate and Order of a Chemical Reaction
- Rate Determination and Activation Energy
- The Determination of an Equilibrium Constant
- Determining the Concentration of a Solution: Beer’s Law
- The Synthesis and Analysis of Aspirin
- The Rate and Order of a Chemical Reaction
- Rate Determination and Activation Energy
- The Determination of an Equilibrium Constant
- Determining the Concentration of a Solution: Beer’s Law
- The Synthesis and Analysis of Aspirin
- The Rate and Order of a Chemical Reaction
- Rate Determination and Activation Energy
- Conductimetric Titration and Gravimetric Determination of a Precipitate
- Conductimetric Titration and Gravimetric Determination of a Precipitate
- Electrochemistry: Voltaic Cells
- Electrochemistry: Voltaic Cells
Go Direct Constant Current System
- Electroplating
- Determining Avogadro’s Number
- Electroplating
- Determining Avogadro’s Number
- Determining the Half Life of an Isotope
- α, β, and γ
- Radiation Shielding
- Determining the Half-Life of an Isotope
No Probeware Used
- The Determination of a Chemical Formula
- The Determination of the Percent Water in a Compound
- Liquid Chromatography
