National Physical Laboratory of India

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National Physical Laboratory
Logo NPL india.svg
Agency overview
Formed4 January 1947
Headquarters New Delhi
Agency executive
Parent agency Council of Scientific and Industrial Research
Website nplindia.org

The CSIR- National Physical Laboratory of India, situated in New Delhi, is the measurement standards laboratory of India. It maintains standards of SI units in India and calibrates the national standards of weights and measures.

Contents

National physical laboratory in Delhi. National physical laboratories in Delhi..jpg
National physical laboratory in Delhi.

History of measurement systems in India

In the Harappan era, which is nearly 5000 years old, one finds excellent examples of town planning and architecture. The sizes of the bricks were the same all over the region. In the time of Chandragupta Maurya, some 2400 years ago, there was a well - defined system of weights and measures. The government of that time ensured that everybody used the same system. In the Indian medical system, Ayurveda, the units of mass and volume were well defined.

The measurement system during the time of the Mughal emperor, Akbar, the guz was the measure of length. The guz was widely used till the introduction of the metric system in India in 1956. During the British period, efforts were made to achieve uniformity in weights and measures. A compromise was reached in the system of measurements which continued till India's independence in 1947. After independence in 1947, it was realized that for fast industrial growth of the country, it would be necessary to establish a modern measurement system in the country. The Lok Sabha in April 1955 resolved : This house is of the opinion that the Government of India should take necessary steps to introduce uniform weights and measures throughout the country based on metric system [1] [ circular reference ]

Key Functions of NPL:

Maintaining SI Units: NPL establishes and maintains the Indian standards for the International System of Units (SI), which includes units like meter, kilogram, second, ampere, kelvin, candela, and mole.

Calibrating National Standards: NPL calibrates the national standards of weights and measures to ensure their accuracy and traceability to international standards.

Conducting Research: NPL conducts research in various fields of physics, including metrology, materials science, and nanotechnology.

Providing Calibration and Testing Services: NPL offers calibration and testing services to industries and other organizations to help them maintain product quality and comply with regulatory standards.

Disseminating Time and Frequency: NPL provides accurate time and frequency signals to various users through satellite, radio, and television broadcasts.

History of the National Physical Laboratory, India

The National Physical Laboratory, India was one of the earliest national laboratories set up under the Council of Scientific & Industrial Research. Jawaharlal Nehru laid the foundation stone of NPL on 4 January 1947. Dr. K. S. Krishnan was the first Director of the laboratory. The main building of the laboratory was formally opened by Former Deputy Prime Minister Sardar Vallabhbhai Patel on 21 January 1950. Former Prime Minister Indira Gandhi, inaugurated the Silver Jubilee Celebration of the Laboratory on 23 December 1975.

NPL Charter:-

The main aim of the laboratory is to strengthen and advance physics-based research and development for the overall development of science and technology in the country. In particular its objectives are:

To establish, maintain and improve continuously by research, for the benefit of the nation, National Standards of Measurements and to realize the Units based on International System (Under the subordinate Legislations of Weights and Measures Act 1956, reissued in 1988 under the 1976 Act). To identify and conduct after due consideration, research in areas of physics which are most appropriate to the needsof the nation and for advancement of field

To assist industries, national and other agencies in their developmental tasks by precision measurements, calibration, development of devices, processes, and other allied problems related to physics.

To keep itself informed of and study critically the status of physics.

Newly established structures at NPL campus Traceability Pyramid at NPL.png
Newly established structures at NPL campus

In 1957, India became member of the General Conference of Weight and Measures (CGPM), BIPM, an International Intergovernmental organization constituted by diplomatic treaty, i.e. ‘The Metre Convention’. Being NMI of India and to fulfil the mandate, Dr. K. S. Krishnan, the then Director, CSIR-NPL signed the ‘Metre Convention’ on behalf of Government of India. In 1958, BIPM provided CSIR-NPL the Copies No. 57 (NPK) and No. 4 of International Prototypes of the Kilogram (IPK) and the platinum-iridium (Pt–Ir) Metre bar, respectively, to realize the SI base units ‘kilogram’ and ‘metre’. This was the milestone in the foundation of quality infrastructure in independent India.

In 1960, when the metric system was officially adopted as the basis for SI units, the number of base units being maintained at the NPL increased. However, in 1963 on the recommendation of Nobel Laureate P.M.S. Blackett, these groups were brought together under a single umbrella. The objective was to bring greater coordination between the various groups and to give the standards activity a programme-based approach on a bigger scale and enable the Laboratory to play its role more effectively. Other physical standards in the form of standard cells, standard resistance coils, standard lamps, etc. were acquired and calibration and testing work were started in these areas also. It has since been maintaining six SI base units; namely, metre (for length), kilogram (for mass), second (for time), kelvin (for temperature), ampere (for current) and candela (for luminous intensity).

Maintenance of standards of measurements in India

Each modernized country, including India has a National Metrological Institute (NMI), which maintains the standards of measurements. This responsibility has been given to the National Physical Laboratory, New Delhi.

Metre

The standard unit of length, metre, is realized by employing a stabilized helium-neon laser as a source of light. Its frequency is measured experimentally. From this value of frequency and the internationally accepted value of the speed of light (299792458 m/s), the wavelength is determined using the relation:

The nominal value of wavelength, employed at NPL is 633 nanometer. By a sophisticated instrument, known as an optical interferometer, any length can be measured in terms of the wavelength of laser light.

The present level of uncertainty attained at NPL in length measurements is ±3 × 10−9. However, in most measurements, an uncertainty of ±1 × 10−6 is adequate.

Kilogramme

The Indian national standard of mass, kilogramme, is copy number 57 of the international prototype of the kilogram supplied by the International Bureau of Weights and Measures (BIPM: French – Bureau International des Poids et Mesures), Paris. This is a platinum-iridium cylinder whose mass is measured against the international prototype at BIPM. The NPL also maintains a group of transfer standard kilograms made of non-magnetic stainless steel and nickel-chromium alloy.

The uncertainty in mass measurements at NPL is ±4.6 × 10−9.

Second

The national standard of time interval, second as well as frequency, is maintained through four parameters, which can be measured most accurately. Therefore, attempts are made to link other physical quantities to time and frequency. The standard maintained at NPL has to be linked to different users. This process, known as dissemination, is carried out in a number of ways. For applications requiring low levels of uncertainty, there is satellite based dissemination service, which utilizes the Indian national satellite, INSAT. Time is also disseminated through TV, radio, and special telephone services. The caesium atomic clocks maintained at NPL are linked to other such instituted all over the world through a set of global positioning satellites.

Ampere

The unit of electric current, ampere, is realized at NPL by measuring the volt and the ohm separately.

The uncertainty in measurement of ampere is ± 1 × 10−6.

Kelvin

The standard of temperature is based on the International Temperature Scale of 1990 (ITS-90). This is based on the assigned temperatures to several fixed points. One of the most fundamental temperatures of these is the triple point of water. At this temperature, ice, water and steam are at equilibrium with each other. This temperature has been assigned the value of 273.16 kelvins. This temperature can be realized, maintained and measured in the laboratory. At present temperature standards maintained at NPL cover a range of 54 to 2,473 kelvins.

The uncertainty in its measure is ± 2.5 × 10−4.

Candela

The unit of luminous intensity, candela, is realized by using an absolute radiometer. For practical work, a group of tungsten incandescent lamps are used.

The level of uncertainty is ± 1.3 × 10−2.

Mole

Experimental work has been initiated to realize mole, the SI unit for amount of substance

Radiation

The NPL does not maintain standards of measurements for ionizing radiations. This is the responsibility of the Bhabha Atomic Research Centre, Mumbai.

Calibrator of weights and measures

The standards maintained at NPL are periodically compared with standards maintained at other National Metrological Institutes in the world as well as the BIPM in Paris. This exercise ensures that Indian national standards are equivalent to those of the rest of the world.

Any measurement made in a country should be directly or indirectly linked to the national standards of the country, For this purpose, a chain of laboratories are set up in different states of the country. The weights and measures used in daily life are tested in the laboratories and certified. It is the responsibility of the NPL to calibrate the measurement standards in these laboratories at different levels. In this manner, the measurements made in any part of the country are linked to the national standards and through them to the international standards.

The weights and balances used in local markets and other areas are expected to be certified by the Department of Weights and Measures of the local government. Working standards of these local departments should, in turn, be calibrated against the state level standards or any other laboratory which is entitled to do so. The state level laboratories are required to get their standards calibrated from the NPL at the national level which is equivalent to the international standards.

Bharatiya Nirdeshak Dravya (BND) or Indian Reference Materials

Bharatiya Nirdeshak Dravya (BND) or Indian reference materials are reference materials developed by NPL which derive their traceability from National Standards.

Research programs

NPL is also involved in research. One of the important research activities undertaken by NPL is to devise the chemical formula for the indelible ink which is being used in the Indian elections to prevent fraudulent voting. This ink, manufactured by the Mysore Paints and Varnish Limited is applied on the finger nail of the voter as an indicator that the voter has already cast his vote.

NPL also have section working on development of biosensors. Currently the division is headed by Dr. C. Sharma and section is primarily focusing on development of sensor for cholesterol, measurement and microfluidic based biosensors. Section is also developing biosensors for Uric acid detection.

India’s polar research program

During the 28th Indian Scientific Expeditions to Antarctica (ISEA) (2008-2009), CSIR-NPL established a state of art Indian Polar Space Physics Laboratory (IPSPL) at Indian Permanent Research Base Maitri (70 0 46’ S, 110 43’ E), Antarctica on the occasion of International Polar Year (IPY) for continuous and real time monitoring of high latitude ionosphere to address the scientific interest of high latitudinal ionospheric consequences caused by the modulation of near-earth space environmental conditions. In 2011 CSIR-NPL provided leadership to the Antarctic expedition to India's newly constructed 3rd permanent scientific base “Bharati” (69° 24’ S, 76 ° 11’) to test & validate its facilities during extreme winter conditions. CSIR NPL is also the part of India's arctic expeditions. Himadri is India's first permanent Arctic research station located at the International Arctic Research base, Ny-Ålesund at Spitsbergen, Svalbard Norway. It was set up during India's second Arctic expedition in June 2008. It is located 1200 km from the North Pole.

NPL's contributions

The indelible mark/ink

During general election, nearly 40 million people wear a CSIR mark on their fingers. The indelible ink used to mark the fingernail of a voter during general elections is a time-tested gift of CSIR to the spirit of democracy. Developed in 1952, it was first produced in-campus. Subsequently, industry has been manufacturing the Ink. It is also exported to Sri Lanka, Indonesia, Turkey and other democracies.

Pristine air-quality monitoring station at Palampur

National Physical Laboratory (NPL) has established an atmospheric monitoring station in the campus of Institute of Himalayan Bioresource Technology (IHBT) at Palampur (H.P.) at an altitude of 1391 m for generating the base data for atmospheric trace species & properties to serve as reference for comparison of polluted atmosphere in India. At this station, NPL has installed state of art air monitoring system, greenhouse gas measurement system and Raman Lidar. A number of parameters like CO, NO, NO2, NH3, SO2, O
3
, PM, HC & BC besides CO2 & CH4 are being currently monitored at this station which is also equipped with weather station (AWS) for measurement of weather parameters. [2] [3]

Gold standard (BND-4201)

The BND-4201 is first Indian reference material for gold of ‘9999’ fineness (gold that is 99.99% pure with impurities of only 100 parts-per-million).

Honors and awards bestowed upon CSIR-NPL Staff

Padma Bhushan

Dr. K.S. Krishnan - 1954 Dr. A.R. Verma – 1982 Dr. A.P. Mitra - 1989 Dr. S.K. Joshi - 2003

Padma Shri

Dr. S.K. Joshi – 1991

Shanti Swarup Bhatnagar Prize

Dr. K.S. Krishnan - 1958 Dr. A.P. Mitra – 1968 Dr. Vinay Gupta - 2017

Other awards

Contributors to Nobel Peace Prize-winning team for Intergovernmental Panel on Climate Change IPCC Dr. A.P. Mitra & Dr. Chhemmendra Sharma – 2007

See also

Related Research Articles

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<span class="mw-page-title-main">Metre Convention</span> 1875 international treaty

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<span class="mw-page-title-main">Kibble balance</span> Electromechanical weight measuring instrument

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<span class="mw-page-title-main">International Prototype of the Kilogram</span> Physical artifact that formerly defined the kilogram

The International Prototype of the Kilogram is an object whose mass was used to define the kilogram from 1889, when it replaced the Kilogramme des Archives, until 2019, when it was replaced by a new definition of the kilogram based entirely on physical constants. During that time, the IPK and its duplicates were used to calibrate all other kilogram mass standards on Earth.

<span class="mw-page-title-main">Atomic clock</span> Clock that monitors the resonant frequency of atoms

An atomic clock is a clock that measures time by monitoring the resonant frequency of atoms. It is based on atoms having different energy levels. Electron states in an atom are associated with different energy levels, and in transitions between such states they interact with a very specific frequency of electromagnetic radiation. This phenomenon serves as the basis for the International System of Units' (SI) definition of a second:

The second, symbol s, is the SI unit of time. It is defined by taking the fixed numerical value of the caesium frequency, , the unperturbed ground-state hyperfine transition frequency of the caesium-133 atom, to be 9192631770 when expressed in the unit Hz, which is equal to s−1.

<span class="mw-page-title-main">Standard (metrology)</span> Object, system, or experiment which relates to a unit of measurement of a physical quantity

In metrology, a standard is an object, system, or experiment that bears a defined relationship to a unit of measurement of a physical quantity. Standards are the fundamental reference for a system of weights and measures, against which all other measuring devices are compared. Historical standards for length, volume, and mass were defined by many different authorities, which resulted in confusion and inaccuracy of measurements. Modern measurements are defined in relationship to internationally standardized reference objects, which are used under carefully controlled laboratory conditions to define the units of length, mass, electrical potential, and other physical quantities.

<span class="mw-page-title-main">2019 revision of the SI</span> Definition of the units kg, A, K and mol

In 2019, four of the seven SI base units specified in the International System of Quantities were redefined in terms of natural physical constants, rather than human artefacts such as the standard kilogram. Effective 20 May 2019, the 144th anniversary of the Metre Convention, the kilogram, ampere, kelvin, and mole are now defined by setting exact numerical values, when expressed in SI units, for the Planck constant, the elementary electric charge, the Boltzmann constant, and the Avogadro constant, respectively. The second, metre, and candela had previously been redefined using physical constants. The four new definitions aimed to improve the SI without changing the value of any units, ensuring continuity with existing measurements. In November 2018, the 26th General Conference on Weights and Measures (CGPM) unanimously approved these changes, which the International Committee for Weights and Measures (CIPM) had proposed earlier that year after determining that previously agreed conditions for the change had been met. These conditions were satisfied by a series of experiments that measured the constants to high accuracy relative to the old SI definitions, and were the culmination of decades of research.

<span class="mw-page-title-main">History of the metric system</span>

The history of the metric system began during the Age of Enlightenment with measures of length and weight derived from nature, along with their decimal multiples and fractions. The system became the standard of France and Europe within half a century. Other measures with unity ratios were added, and the system went on to be adopted across the world.

Bryan Peter Kibble was a British physicist and a pioneering metrologist. He was the inventor of the Kibble balance, an improved version of the current balance, developed for the realisation of the S.I. unit of mass, the kilogram.

<span class="mw-page-title-main">Alternative approaches to redefining the kilogram</span>

The scientific community examined several approaches to redefining the kilogram before deciding on a revision of the SI in November 2018. Each approach had advantages and disadvantages.

References

  1. Indian units of measurement
  2. "National Physical Laboratory(NPL)- CSIR dedicates the first "Pristine air-quality monitoring station at Palampur" to the Nation". pib.nic.in.
  3. "CSIR-NPL launches India's First Pristine Air-Quality Monitoring Station at Palampur". MyGov Blogs. 25 March 2017.