Electricity sector in India

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Electricity sector ofIndia

Data
Electricity coverage	99.94% (31 March 2019)[1]
Installed capacity	441,969MW[2]
Production (FY2022)	1719.442TWh[3]
GHGemissions from electricity generation (2018)	2,309.98million metric tonsofCO2[4]
Average electricity use (FY2023)	1,327kWhper capita[5]
Transmission & Distribution losses (FY2022)	15%[3]
Consumption by sector (% of total)
Residential	25.77%[3](FY2022)
Industrial	41.16%[3](FY2022)
Agriculture	17.67%[3](FY2022)
Commercial	8.29%[3](FY2022)
Traction	1.53%[3](FY2022)
Tariffs and financing
Average residential tariff (US$/kW·h, Dec. 2020)	₹5.75(6.9¢ US)[6]
Average commercial tariff (US$/kW·h, Dec. 2020)	₹8.64(10¢ US)[6]
Services
Share of private sector in generation	33.46% (FY2020)[7]
Institutions
Responsibility for policy-setting	Ministry of Power
Responsibility for renewable energy	Ministry of New and Renewable Energy
Responsibility for the environment	Ministry of Environment, Forest and Climate Change
Electricity sector law	Electricity Act, 2003

Indiais the third largest producer of electricity in the world.^[8] During thefiscal year(FY) 2022–23, the total electricity generation in the country was 1,844TWh,of which 1,618 TWh was generated by utilities.^[5]

The gross electricity consumption per capita in FY2023 was 1,327 kWh.^[5]In FY2015,electric energy consumptionin agriculture was recorded as being the highest (17.89%) worldwide.^[7] Theper capita electricity consumptionis low compared to most other countries despite India having a lowelectricity tariff.^[9]

TheIndian national electric gridhas an installed capacity of 442.0GWas of 31 March 2024.^[10]Renewable energyplants, which also include large hydroelectric power plants, constitute 43% of the total installed capacity.

India’s electricity generation is more carbon-intensive (713 grams CO₂per kWh) than the global average (480 gCO₂/kWh), with coal accounting for three quarters of generation in 2023.^{[11][12][13][14]}

The government declared its efforts to increase investment in renewable energy. Under the government's 2023-2027 National Electricity Plan, India will not build any newfossil fuelpower plants in the utility sector, aside from those currently under construction.^[15][16]It is expected that non-fossil fuel generation contribution is likely to reach around 44.7% of the total gross electricity generation by 2029–30.^[17]

The first demonstration ofelectric lightin Calcutta (nowKolkata) was conducted on 24 July 1879 by P.W. Fleury & Co. On 7 January 1897, Kilburn & Co secured the Calcutta electric lighting license as agents of the Indian Electric Co, which was registered inLondonon 15 January 1897. A month later, the company was renamed theCalcutta Electric Supply Corporation.The control of the company was transferred from London to Calcutta only in 1970. The introduction of electricity in Calcutta was a success, and power was next introduced in Bombay (nowMumbai).^[18]The first electric lighting demonstration in Mumbai was in 1882 atCrawford Marketand theBombay Electric Supply & Tramways Company(BEST) set up a generating station in 1905 to provide electricity for the tramway.^[19]

The first hydroelectric installation in India was installed near a tea estate atSidrapongfor theDarjeeling Municipalityin 1897.^[20]The first electricstreet lightinAsiawas lit on 5 August 1905 inBangalore.^[21]The first electric train in the country ran on theHarbour Linebetween Bombay'sChhatrapati Shivaji Maharaj Terminus (then Victoria Terminus)andKurlaon 3 February 1925.^[22]The first high-voltage laboratory of India was established at theGovernment Engineering College, Jabalpurin 1947.^[23]On 18 August 2015,Cochin International Airportbecame the world's first fullysolar poweredairport with the inauguration of a dedicated solar plant (seeCIAL Solar Power Project).^[24][25]

India began using grid management on a regional basis in the 1960s. Individual State grids were interconnected to form 5 regional grids covering mainland India, the Northern, Eastern, Western, North Eastern and Southern Grids. These regional links were established to enable transmission of surplus electricity between states in each region. In the 1990s, the Indian government began planning for a national grid. Regional grids were initially interconnected by asynchronoushigh-voltage direct current(HVDC)back-to-backlinks facilitating the limited exchange of regulated power. The links were subsequently upgraded to high capacity synchronous links.^[26]

The first interconnection of regional grids was established in October 1991 when the North Eastern and Eastern grids were interconnected. The Western Grid was interconnected with these grids in March 2003. The Northern grid was also interconnected in August 2006, forming a Central Grid that was synchronously connected and operating at one frequency.^[26]The sole remaining regional grid, the Southern Grid, was synchronously interconnected to the Central Grid on 31 December 2013 with the commissioning of the 765kVRaichur-Solapur transmission line, establishing theNational Grid.^[26][27]

By the end of the calendar year 2015, despite poor hydroelectricity generation, India had become a power surplus nation with huge power generation capacity idling for want of demand.^[28][29][30]The calendar year 2016 started with steep falls in the international price of energy commodities such as coal, diesel oil,naphtha,bunker fuel,andliquefied natural gas(LNG), which are used in electricity generation in India.^{[31][32][33][34][35]}As a result of the global glut in petroleum products, these fuels became cheap enough to compete with pit head coal-based power generators.^[36]Coal prices have also fallen.^[37]Low demand for coal has led to coal stocks building up at power stations as well as coal mines.^[38]New installations ofrenewable energyin India surpassed installations of fossil fuel for the first time in 2016–17.^[39]

On 29 March 2017, theCentral Electricity Authority (CEA)stated that for the first time India has become a net exporter of electricity. India exported 5,798 GWh to neighboring countries, against a total import of 5,585 GWh.

TheGovernment of Indialaunched a program called "Power for All" in 2016.^[40]The program was accomplished by December 2018 in providing the necessary infrastructure to ensure uninterrupted electricity supply to all households, industries, and commercial establishments.^[41]Funding was made through a collaboration between the Government of India and its constituentstates.^[42][43]

The total installed power generation capacity is the sum of utility capacity, captive power capacity, and other non-utilities which is 495.200 GW as on 31 March 2023.^[3]

Growth of Installed Capacity in India^[7]

Installed Capacity as on	Thermal (MW)				Nuclear (MW)	Renewable (MW)			Total (MW)	% Growth (on yearly basis)
	Coal	Gas	Diesel	Sub-Total Thermal		Hydro	Other Renewable	Sub-Total Renewable
31 December 1947	756	-	98	854	-	508	-	508	1,362	-
31 December 1950	1,004	-	149	1,153	-	560	-	560	1,713	8.59%
31 March 1956	1,597	-	228	1,825	-	1,061	-	1,061	2,886	13.04%
31 March 1961	2,436	-	300	2,736	-	1,917	-	1,917	4,653	12.25%
31 March 1966	4,417	137	352	4,903	-	4,124	-	4,124	9,027	18.80%
31 March 1974	8,652	165	241	9,058	640	6,966	-	6,966	16,664	10.58%
31 March 1979	14,875	168	164	15,207	640	10,833	-	10,833	26,680	12.02%
31 March 1985	26,311	542	177	27,030	1,095	14,460	-	14,460	42,585	9.94%
31 March 1990	41,236	2,343	165	43,764	1,565	18,307	-	18,307	63,636	9.89%
31 March 1997	54,154	6,562	294	61,010	2,225	21,658	902	22,560	85,795	4.94%
31 March 2002	62,131	11,163	1,135	74,429	2,720	26,269	1,628	27,897	105,046	4.49%
31 March 2007	71,121	13,692	1,202	86,015	3,900	34,654	7,760	42,414	132,329	5.19%
31 March 2012	112,022	18,381	1,200	131,603	4,780	38,990	24,503	63,493	199,877	9.00%
31 March 2014	145,273	21,782	1,200	168,255	4,780	40,532	31,692	72,224	245,259	10.77%
31 March 2017	192,163	25,329	838	218,330	6,780	44,478	57,260	101,138	326,841	10.31%
31 March 2018	197,171	24,897	838	222,906	6,780	45,293	69,022	114,315	344,002	5.25%
31 March 2019	200,704	24,937	637	226,279	6,780	45,399	77,641	123,040	356,100	3.52%
31 March 2020[44]	205,135	24,955	510	230,600	6,780	45,699	87,028	132,427	370,106	3.93%
31 March 2021[45]	209,294	24,924	510	234,728	6,780	46,209	94,433	140,642	382,151	3.25%
31 March 2022	210,700	24,899	510	236,109	6,780	46,723	109,885	156,607	399,497	4.53%
31 March 2023[2]	211,855	24,824	589	237,269	6,780	46,850	125,160	172,010	416,059	4.15%
31 March 2024[10]	217,589	25,038	589	243,217	8,180	46,928	143,645	190,573	441,970	6.23%

Nearly 32,285 MW coal thermal power projects are under construction as on 1 April 2021.^[46]

The total installed utility power generation capacity as on 31 March 2023 by type is given below.^[2]

Breakdown of Installed Generation Capacity as on 31/03/2023

Source	Installed Capacity (MW)	% of Share in Total
Fossil Fuels (Total)	237,269	57%
Coal	205,235	49.3%
Lignite	6,620	1.6%
Gas	24,824	6.0%
Diesel	589	0.1%
Non-Fossil Fuels (Total)	178,790	43%
Hydro	46,850	11.3%
Wind	42,633	10.2%
Solar	66,780	16.1%
Bio Mass Power/Cogen	10,248	2.5%
Waste to Energy	554	0.1%
Small Hydro	4,944	1.2%
Nuclear	6,780	1.6%
Total Installed Capacity	416,059	100%

Hydroelectric power plants with ≤ 25 MW generation capacity are included in Renewable category (classified as SHP – Small Hydro Project)

The installedcaptive powergeneration capacity (above 1 MW capacity) associated with industry-owned plants is 79,140 MW as of 31 March 2023.^[5]In the fiscal year 2022–23, captive power generation was 226,000 GWh.^[5][48]Diesel power generation sets of 75,000 MW capacity (excluding sets of size above 1 MW and below 100 kVA) are also installed in the country.^[49][50]In addition, there are a large number of diesel generators of capacity less than 100 kVA to cater to emergency power needs duringpower outagesin all sectors.^[51]

Per capita electricity consumption^[52]

Year	Per capita consumption (in kWh/year)
2010	779
2011	819
2012	884
2013	914
2014	957
2015	1,010
2016	1,075
2017	1,122
2018	1,149
2019	1,181
2020	1,208
2021	1,161
2022	1,255
2023	1,327

Captive Power Sector, FY 2022–23

Source	Captive Power Capacity (MW)	Share	Electricity generated (GWh)	Share
Coal	47,000	59.39%	192,900	85.35%
Hydroelectricity	140	0.18%	400	0.09%
Renewable energy source	7,100	8.97%	8,900	3.94%
Natural Gas	6,700	7.20%	21,500	9.51%
Oil	19,200	24.26%	2,300	1.02%
Total	79,140	100.00%	226,000	100.00%

The major states leading in captive power generation are Odisha, Gujarat, Chhattisgarh, Karnataka, Uttar Pradesh and Rajasthan which are producing nearly 66% of the total.

State Wise Captive Power, FY 2021–22^[53]

State	Captive Power Capacity (MW)	Electricity generated (GWh)
Odisha	12,171	62,587
Gujarat	7,061	19,413
Chhattisgarh	5,787	21,487
Karnataka	6,613	15,169
Uttar Pradesh	4,779	13,957
Rajasthan	3,161	11,585
India	76,733	209,311

State-wise all India installed power generation capacity as of 31 October 2023. ^{[54][55][56][57][58][59][60]}

State/Union Territory	Thermal (inMW)					Nuclear (inMW)	Renewable (inMW)			Total (inMW)	% of National Total	% Renewable
	Coal	Lignite	Gas	Diesel	Sub-Total Thermal		Hydel	Other Renewable	Sub-Total Renewable
Western Region	84236	1400	10806.49	-	96442.49	2540	7392	42755.33	50147.33	149129.82	35.04%	33.63%
Gujarat	14692	1400	7551.41	-	23643.41	1140	1990	21792.75	23782.75	48566.16	11.41%	48.97%
Maharashtra	23856	-	3207.08	-	27063.08	1400	3047	13241.26	16288.26	44751.34	10.52%	36.40%
Madhya Pradesh	22000	-	-	-	22000	-	2235	6270.86	8505.86	30505.86	7.17%	27.88%
Chhattisgarh	23688	-	-	-	23688	-	120	1366.24	1486.24	25174.24	5.92%	5.90%
Goa	-	-	48	-	48	-	-	37.75	37.75	85.75	0.02%	44.02%
Dadra and Nagar Haveli and Daman and Diu	-	-	-	-	-	-	-	46.47	46.47	46.47	0.01%	100%
Southern Region	40557.50	3640	6491.80	460.49	51149.80	3320	11747.15	52331.17	64078.32	118548.12	27.86%	54.05%
Tamil Nadu	10045	3640	1027.18	211.70	14923.88	2440	2178.20	18706.32	20884.52	38248.40	8.99%	54.60%
Karnataka	9480	-	-	25.20	9505.20	880	3689.20	17848.74	21537.94	31923.14	7.50%	67.47%
Andhra Pradesh	12390	-	4898.54	36.80	17325.34	-	1610	9381.55	10991.55	28316.89	6.65%	38.82%
Telangana	8642.50	-	-	-	8642.50	-	2405.60	5152.32	7557.92	16200.42	3.81%	46.65%
Kerala	-	-	533.58	159.96	693.54	-	1864.15	1194.20	3058.35	3751.89	0.88%	81.51%
Puducherry	-	-	32.50	-	32.50	-	-	43.27	43.27	75.77	0.02%	57.11%
Lakshadweep	-	-	-	26.83	26.83	-	-	4.77	4.77	31.60	0.01%	15.09%
Northern Region	44285	1580	5994.96	-	51859.96	1620	19696.27	34540.29	54236.56	107716.52	25.31%	50.35%
Rajasthan	9200	1580	1022.83	-	11802.83	1180	411	23431.56	23842.56	36825.39	8.65%	64.74%
Uttar Pradesh	24075	-	1493.14	-	25568.14	440	501.60	4901.27	5402.87	31411.01	7.38%	17.20%
Himachal Pradesh	-	-	-	-	-	-	10263.02	1091.46	11354.48	11354.48	2.67%	100%
Punjab	5680	-	-	-	5680	-	1096.30	1970.50	3066.80	8746.80	2.05%	35.06%
Haryana	5330	-	431.59	-	5761.59	-	-	1561.75	1561.75	7323.34	1.72%	21.32%
Uttarakhand	-	-	664	-	664	-	3975.35	934.09	4909.44	5573.44	1.31%	88.09%
Jammu and Kashmir	-	-	175	-	175	-	3360	216.41	3576.41	3751.41	0.88%	95.33%
Delhi	-	-	2208.40	-	2208.40	-	-	320.41	320.41	2528.81	0.59%	12.67%
Ladakh	-	-	-	-	-	-	89	48.79	137.79	137.79	0.03%	100%
Chandigarh	-	-	-	-	-	-	-	64.05	64.05	64.05	0.01%	100%
Eastern Region	36997	-	80	92.71	37169.71	-	5987.75	1931.24	7918.99	45088.70	10.59%	17.56%
West Bengal	13487	-	80	-	13567	-	1341.20	636.02	1977.22	15544.22	3.65%	12.72%
Odisha	9540	-	-	-	9540	-	2154.55	640.08	2794.63	12334.63	2.90%	22.66%
Bihar	9060	-	-	-	9060	-	-	420.26	420.26	9480.26	2.23%	4.43%
Jharkhand	4910	-	-	-	4910	-	210	139.92	349.92	5259.92	1.24%	6.65%
Sikkim	-	-	-	-	-	-	2282	59.80	2341.80	2341.80	0.55%	100%
Andaman and Nicobar Islands	-	-	-	92.71	92.71	-	-	35.16	35.16	127.87	0.03%	27.50%
North-Eastern Region	750	-	1664.95	36	2450.95	-	2027	574.41	2601.41	5052.36	1.19%	51.49%
Assam	750	-	597.36	-	1347.36	-	350	191.92	541.92	1889.28	0.44%	28.68%
Arunachal Pradesh	-	-	-	-	-	-	1115	144.90	1259.90	1259.90	0.30%	100%
Tripura	-	-	1067.60	-	1067.60	-	-	34.48	34.48	1102.08	0.26%	3.13%
Meghalaya	-	-	-	-	-	-	322	73.02	395.02	395.02	0.1%	100%
Manipur	-	-	-	36	36	-	105	18.48	123.48	159.48	0.04%	77.43%
Mizoram	-	-	-	-	-	-	60	75.90	135.90	135.90	0.03%	100%
Nagaland	-	-	-	-	-	-	75	35.71	110.71	110.71	0.03%	100%
Total	206825.50	6620	25038.21	589.20	239072.91	7480	46850.17	132132.44	178982.61	425535.52	100.00%	42.06%

Other Renewable Energy sources include SHP (Small Hydro Power - hydel plants ≤ 25 MW), Biomass Power, Urban & Industrial waste, Solar and Wind Energy

The draft national electricity plan 2022 prepared by CEA says that the peak demand and energy demand would be 272 GW and 1,852 billion kWh (excluding rooftop solar generation) respectively in the fiscal year 2026–27.^[61]The peak demand and energy demand would be 363 GW and 2,459 billion kWh (excluding rooftop solar generation) respectively in the fiscal year 2031–32. From the calendar year 2015 onwards, power generation in India has been less of a problem than power distribution.^{[62][29][30][63][64]}

Nearly 0.07% of Indian households (0.2 million) have no access to electricity.^[1]TheInternational Energy Agencyestimates India will add between 600 GW to 1,200 GW of additional new power generation capacity before 2050.^[65]This added new capacity is similar in scale to the 740 GW total power generation capacity of the European Union (EU-27) in 2005. The technologies and fuel sources India adopts as it adds this electricity generation capacity may have a significant impact on global resource usage and environmental issues.^[66]The demand for electricity for cooling (HVAC) is projected to grow rapidly.^[67]

According to the analysis presented in the India Cooling Action Plan (ICAP) released by the Ministry of Environment, Forests and Climate Change, only 8 percent of Indian households own air-conditioning units. The cooling demand across India is projected to rise at a rate of 15-20 percent annually and aggregated cooling demand will grow to around eight times by 2037–38, as compared to the 2017-18 baseline. In India, 45 percent of the country's peak electricity demand in 2050 is expected to come from space cooling alone.^[68]

About 136 million Indians (11%) use traditional fuels –firewood,agricultural waste anddry animal dung fuel– for cooking and general heating needs.^[69]These traditional fuels are burnt in cook stoves, sometimes known aschulahorchulha.^[70]Traditional fuel is an inefficient source of energy, and its burning releases high levels of smoke, PM10 particulate matter,NO_x,SO
_x,PAHs, polyaromatics, formaldehyde, carbon monoxide and otherair pollutants,affecting outdoor air quality, haze and smog, chronic health problems, damage to forests, ecosystems and global climate.^[71][72][73]TheWorld Health Organizationestimates that 300,000 to 400,000 people in India die ofindoor air pollutionand carbon monoxide poisoning every year because of biomass burning and use of chulahs.^[74]Burning traditional fuel in conventional cook stoves is estimated to release 5–15x more pollutants than industrial combustion of coal, and is unlikely to be replaced until electricity or clean-burning fuel and combustion technologies become reliably available and widely adopted in rural and urban India. The growth of the electricity sector in India may help find a sustainable alternative to traditional fuel burning.

In addition to air pollution problems, a 2007 study finds that discharge of untreated sewage is the single most important cause for pollution of surface and groundwater in India. The majority of government-owned sewage treatment plants remain closed most of the time in part because of the lack of a reliable electricity supply to operate the plants. Uncollected waste accumulates in urban areas, causing unhygienic conditions, and release heavy metals and pollutants that leaches to surface and groundwater.^[75][76]A reliable supply of electricity is required to address India's water pollution and associated environmental issues.

The per capita annual domestic electricity consumption in India during the year 2009 was 96 kWh in rural areas and 288 kWh in urban areas for those with access to electricity. Globally the per capita annual average is 2,600 kWh and in the European Union it is 6,200 kWh.^[77]

Adding to it, the recent coal crisis has raised an alarm as over 60 per cent of the electricity produced in the country is derived from thermal power plants, and thus, depend on coal.^[78]

In 2021, electricity consumption in India was dominated by the industrial sector at 43.9%. The residential sector used 25.3%, agriculture and forestry 19.0%, and commercial and public services 6.6%. Transport had the lowest share at 1.6%.^[12]

Growth of Electricity Consumption in India^[79][7]

Year*	Mid-year population (millions)[3][80]	Net consumption (GWh)	% of Total						Gross per-capita generation (inkWh)
			Domestic	Commercial	Industrial	Traction	Agriculture	Misc
1947**	330	4,182	10.11%	4.26%	70.78%	6.62%	2.99%	5.24%	16.3
1950**	376	5,610	9.36%	5.51%	72.32%	5.49%	2.89%	4.44%	18.2
1956	417	10,150	9.20%	5.38%	74.03%	3.99%	3.11%	4.29%	30.9
1961	458	16,804	8.88%	5.05%	74.67%	2.70%	4.96%	3.75%	45.9
1966	508	30,455	7.73%	5.42%	74.19%	3.47%	6.21%	2.97%	73.9
1974	607	55,557	8.36%	5.38%	68.02%	2.76%	11.36%	4.13%	126.2
1979	681	84,005	9.02%	5.15%	64.81%	2.60%	14.32%	4.10%	171.6
1985	781	124,569	12.45%	5.57%	59.02%	2.31%	16.83%	3.83%	228.7
1990	870	195,098	15.16%	4.89%	51.45%	2.09%	22.58%	3.83%	329.2
1997	997	315,294	17.53%	5.56%	44.17%	2.09%	26.65%	4.01%	464.6
2002	1089	374,670	21.27%	6.44%	42.57%	2.16%	21.80%	5.75%	671.9
2007	1179	525,672	21.12%	7.65%	45.89%	2.05%	18.84%	4.45%	559.2
2012	1,220	785,194	22.00%	8.00%	45.00%	2.00%	18.00%	5.00%	883.6
2013	1,236	824,301	22.29%	8.83%	44.40%	1.71%	17.89%	4.88%	914.4
2014	1,252	881,562	22.95%	8.80%	43.17%	1.75%	18.19%	5.14%	957
2015	1,267	938,823	23.53%	8.77%	42.10%	1.79%	18.45%	5.37%	1010
2016	1,284	1,001,191	23.86%	8.59%	42.30%	1.66%	17.30%	6.29%	1075
2017	1,299	1,066,268	24.32%	9.22%	40.01%	1.61%	18.33%	6.50%	1122
2018	1,313	1,130,244	24.20%	8.51%	41.48%	1.27%	18.08%	6.47%	1149
2019	1,328	1,196,309	24.76%	8.24%	41.16%	1.52%	17.69%	6.63%	1181
2020	1,342	1,291,494	24.01%	8.04%	42.69%	1.52%	17.67%	6.07%	1208
2021[81]	1,356	1,227,000	25.67%	8.31%	41.09%	1.51%	17.52%	5.89%	1177
2022[3]	1,370	1,296,300	25.77%	8.29%	41.16%	1.53%	17.67%	5.59%	1255
2023[5]	1,390	1,403,400	25.79%	7.49%	42.40%	1.78%	17.16%	5.38%	1327

* Data from the fiscal year ending on 31 March of each year.
** Refers to the fiscal year ending on 31 December.

Note: Gross per-capita generation=(gross electricity generation by all sources plus net import) / mid-year population. 'Consumption' is 'gross electricity generation by all sources plus net import' after subtracting transmission losses and auxiliary consumption in electricity generation.

India's Ministry of Power launchedDeen Dayal Upadhyaya Gram Jyoti Yojana(DDUGJY) as one of its flagship programs in July 2015 with the objective of providing round-the-clock power to rural areas. The program focused on reforms in the rural power sector by separating feeder lines for rural households from those for agricultural applications and strengthening transmission and distribution infrastructure. A previous scheme for rural electrification,Rajiv Gandhi Grameen Vidyutikaran Yojana(RGGVY) was subsumed into the new scheme.^[82]As of 28 April 2018, 12 days ahead of the target date, all Indian villages (a total of 597,464 census villages) were electrified.^[83]

India has also achieved close to 100% electrification of all rural and urban households. As of 4 January 2019, 211.88 million rural households were provided with electricity, close to 100% of the 212.65 million total rural households.^[1]As of 4 January 2019, 42.937 million urban households are provided with electricity, close to 100% of the 42.941 million total urban households.

Electricity consumptionper capita in 2021–2022^[52][84][85]

State/Union territory	Population (Millions)	Total Consumers (Millions)	Total Connected Load (MW)	Per-capita consumption (kWh)	Total sales (TWh)	Domestic sales (TWh)	Industrial HV sales (TWh)	Industrial MV & LV sales (TWh)	Agriculture sales (TWh)	Commercial sales (TWh)
Dadra and Nagar Haveli	0.64	0.08	1,584	12,250	6.4
Daman and Diu	0.5	0.06	806	5,914	2.13
Goa	1.56	0.66	3,112	3,736	4.02
Gujarat	70.29	19.23	68,994	2,239	124.87	16.51	41.12	14.60	13.79	4.31
Chhattisgarh	29.69	6.03	10,301	2,211	43.96	6.44	7.51	0.60	5.93	1.41
Maharashtra	125.01	33.07	94,336	1,588	149.45	30.19	34.15	9.88	36.25	9.54
Madhya Pradesh	85.12	17.24	31,491	1,232	70.86	16.79	9.24	1.29	26.52	3.37
Western Region	312.80	76.39	210,657	1,736	401.75	71.49	100.49	26.87	82.53	19.15
Puducherry	1.59	0.51	1,568	2,138	2.85	0.81	1.51	0.16	0.06	0.21
Tamil Nadu	76.54	32.45	87,144	1,714	109.24	33.97	35.61	9.89	13.43	10.33
Andhra Pradesh[86]	52.90	20.00	46,633	1,567	71.05	18.19	23.43	3.11	14.11	4.54
Telangana	37.82	16.99	41,703	2,126	65.68	13.32	17.53	1.23	22.15	5.70
Karnataka	67.09	28.83	66,340	1,376	73.18	14.11	19.75	5.05	21.93	5.81
Kerala	35.57	13.82	30,228	844	25.13	12.75	4.70	1.22	0.38	4.83
Lakshadweep	0.07	0.03	93	819	0.05
Southern Region	271.57	112.31	273,713	1,548	347.18	93.19	102.54	20.67	72.09	31.44
Punjab	30.45	10.16	39,918	2,350	56.21	15.32	12.58	3.13	12.57	3.46
Haryana	29.70	7.37	33,713	2,186	49.68	11.97	10.75	2.04	9.12	4.00
Delhi	20.80	6.66	21,503	1,684	27.62	16.43	0.47	2.34	0.03	5.31
Himachal Pradesh	7.42	2.65	8,316	1,742	10.33	2.35	4.68	0.08	0.08	0.51
Uttarakhand	11.47	2.75	7,876	1,520	13.46	3.20	5.44	0.26	0.43	1.33
Chandigarh	1.22	0.26	1,611	1,529	1.41
Jammu and Kashmir	13.76	2.19	4,099	1,475	10.23	4.88	0.92	0.23	0.38	1.70
Rajasthan	79.79	15.98	51,148	1,345	79.52	14.25	11.53	2.11	28.81	4.09
Uttar Pradesh	232.30	31.77	68,284	663	109.57	43.95	10.25	3.98	18.95	6.28
Northern Region	426.90	79.82	236,473	1,137	358.09	113.09	56.76	14.32	70.39	27.06
Odisha	44.11	9.84	16,600	2,264	82.05	8.42	6.02	0.40	0.78	2.15
Sikkim	0.68	0.12	290	1,011	0.441
Jharkhand	38.76	4.17	8,499	867	30.27	6.47	11.83	0.30	0.17	1.03
West Bengal	98.40	24.95	296,158	733	55.11	17.53	15.58	2.14	1.22	5.45
Andaman and Nicobar	0.40	0.01	340	878	0.27
Bihar	124.15	17.65	21,666	329	26.55	15.04	2.76	0.80	1.14	2.39
Eastern Region	306.51	56.89	77,011	807	194.70	47.74	36.45	3.68	3.33	11.12
Arunachal Pradesh	1.54	0.24	244	645	0.51
Meghalaya	3.30	0.59	1,255	751	1.54
Mizoram	1.22	0.27	529	582	0.66
Nagaland	2.20	0.32	205	433	0.70
Tripura	4.09	0.97	780	435	1.05
Assam	35.24	6.13	9,737	384	9.81	3.78	1.57	0.12	0.05	1.09
Manipur	3.18	0.54	1,088	362	0.73
North Eastern Region	50.78	9.08	13,840	426	15.06	6.15	2.35	0.23	0.10	1.52
National	1,368.56	334.51	811,694	1,255	1,316.76	339.78	479.83	76.65	228.51	97.12

Notes: Per capita consumption = (gross electricity generation + captive power generation + net import) / mid-year population. Nearly a 24% difference between sales and gross generation due to auxiliary power consumption of thermal power plants and transmission and distribution (T&D) losses, etc. Maximum peak load (MW) in a year is nearly 25% of the total connected load only.

India has recorded rapid growth in electricity generation since 1985, increasing from 179 TW-hr in 1985 to 1,057 TW-hr in 2012.^[87]The majority of the increase came from coal-fired plants and non-conventionalrenewable energysources (RES), with the contribution from natural gas, oil, and hydro plants decreasing in 2012–2017. The gross utility electricity generation (excluding imports from Bhutan) was 1,484 billion kWh in 2021–22, representing 8.1% annual growth compared to 2020–2021. The contribution from renewable energy sources (including large hydro) was nearly 21.7% of the total. In 2019–20, all the incremental electricity generation is contributed by renewable energy sources as the power generation from fossil fuels decreased.^[88]During the year 2020–2021, the utility power generation decreased by 0.8% (11.3 billion kWh) with a reduction in power generation from fossil fuels by 1% and power generation from non-fossil sources is more or less same of the previous year. In 2020–21, India exported more electricity than it imported from neighboring countries.^[89]Solar power generation in 2020–21, occupied third place after coal and hydropower generations surpassing wind, gas and nuclear power generations.

In 2022–23, renewable power generation was 22.47% of total utility power generation when total utility power generation increased by 8.77% to 1614.70 billion kWh. In 2023-24, renewable electricity generation is nearly 20.76% due to lower contribution from hydropower stations.

Yearly gross electricity generation by source (GWh)

Year	Fossil Fuel			Nuclear	Hydro*	Sub total	RES[90]						Utility and Captive Power
	Coal	Oil	Gas				Mini hydro	Solar	Wind	Bio mass	Other	Sub total	Utility	Captive (seeTable above)	Misc	Total
2011–12	612,497	2,649	93,281	32,286	130,511	871,224	na	na	na	na	na	51,226	922,451	134,387	na	1,056,838
2012–13	691,341	2,449	66,664	32,866	113,720	907,040	na	na	na	na	na	57,449	964,489	144,009	na	1,108,498
2013–14	746,087	1,868	44,522	34,228	134,847	961,552	na	3,350	na	na	na	59,615	1,021,167	156,643	na	1,177,810
2014–15	835,838	1,407	41,075	36,102	129,244	1,043,666	8,060	4,600	28,214	14,944	414	61,780	1,105,446	166,426	na	1,271,872
2015–16[91]	896,260	406	47,122	37,413	121,377	1,102,578	8,355	7,450	28,604	16,681	269	65,781	1,168,359	183,611	na	1,351,970
2016–17[92]	944,861	275	49,094	37,916	122,313	1,154,523	7,673	12,086	46,011	14,159	213	81,869	1,236,392	197,000	na	1,433,392
2017–18[93]	986,591	386	50,208	38,346	126,123	1,201,653	5,056	25,871	52,666	15,252	358	101,839	1,303,493	183,000	na	1,486,493
2018–19[7]	1,021,997	129	49,886	37,706	135,040	1,244,758	8,703	39,268	62,036	16,325	425	126,757	1,371,517	175,000	na	1,546,517
2019–20[79]	994,197	199	48,443	46,472	155,769	1,245,080	9,366	50,103	64,639	13,843	366	138,337[94]	1,383,417	239,567	na	1,622,983
2020–21[81]	981,239	129	51,027	42,949	150,305	1,225,649	10,258	60,402	60,150	14,816	1621	147,247[95]	1,373,187	224,827	na	1,598,014
2021–22[3]	1,078,444	115	36,143	47,019	151,695	1,313,418	10,463	73,483	68,640	16,056	2,268	170,912[96]	1,484,442	209,311	na	1,693,753
2022–23[5]	1,182,096	320	23,885	45,861	162,099	1,414,281	11,170	102,014	71,814	16,024	2,529	203,532	1,617,813	226,000	na	1,843,813
2023–24[10]	1,294,071	401	31,301	47,817	133,972	1,507,555	9,485	115,975	83,385	13,243	2,746	225,835[97]	1,733,390		na

Notes: Coal includes lignite; Misc: includes contributions from emergency diesel generator sets, rooftop solar, captive power generation from below 1 MW capacity plants, etc.;^*Hydro includes pumped storage generation; na = data not available. The above data is excluding net imports from Bhutan.

In April 2024, India's electricity sector has seen a significant shift towards coal due to a shortfall in hydropower generation, driven by lower-than-expected rainfall. As reported by the Grid Controller of India Ltd. in April, coal's share in the total power generation mix increased to 77% in the first week of the month, compared to the previous year. This shift to coal is a strategic response to meet the rising electricity demands anticipated during the summer season and ahead of the upcoming elections. This is despite the fact that India'scoal reserveswere 34% higher than the previous year. The reliance on coal in the short term highlights the tension between India'senergy securityneeds and its clean energy targets.^[98]

In India the Commercial Energy makes 74% of total energy, of which coal based energy production is around 72–75%, as per 2020 data. For utility power generation, India consumed 622.22 million tons of coal during 2019–20 which is less by 1% compared to 628.94 million tons during 2018–19. However coal imports for utility power generation increased by 12.3% during year 2019–20 at 69.22 million tons from 61.66 million tons during 2018–19.^[99]A large part of the Indian coal reserve is similar toGondwana coal:it is of lowcalorific valueand high ash content, with poor fuel value. On average, Indian coal has a gross calorific value (GCV) of about 4500 Kcal/kg, whereas in Australia, for example, the GCV is about 6500 Kcal/kg.^[100]The result is that Indian power plants using India's coal supply consume about 0.7 kg of coal per kWh of power generation, whereas in the United States thermal power plants consume about 0.45 kg of coal per kWh. In 2017, India imported nearly 130Mtoe(nearly 200 million tons) of steam coal and coking coal, 29% of total consumption, to meet the demand in electricity, cement and steel production.^[101][102]

TheCentre for Science and Environmenthas assessed the Indian coal-based power sector as one of the most resource-wasteful and polluting sectors in the world, in part due to the high ash content in India's coal.^[103]India'sMinistry of Environment and Forestshas therefore mandated the use of coals whose ash content has been reduced to 34% (or lower) in power plants in urban, ecologically sensitive and other critically polluted areas. The coal ash reduction industry has grown rapidly in India, with current capacity topping 90 megatonnes.^{[when?][citation needed]}

Before a thermal power plant is approved for construction and commissioning in India it must undergo an extensive review process that includes environmental impact assessment.^[104]TheMinistry of Environment and Forestshas produced a technical guidance manual to help project proposers avoid environmental pollution from thermal power plants.^[105]As of 2016, the existing coal-fired power stations in the utility and captive power sectors were estimated to require nearly 12.5 millionINRper MW capacity to install pollution control equipment to comply with the latest emission norms set out by the Ministry of Environment and Forests.^{[106][107][108][109]}Most of the coal fired stations have not complied installation of flue gas de-sulphurisation units for reducing the pollution.^[110]In April 2020,CPCBdeclared that over 42,000 MW thermal power plants have outlived their lives.^[111]India has also banned imports ofpet cokefor use as fuel.^[112]As a signatory to theParis Agreement,India is also reducing power generation from coal to control the emission ofgreenhouse gases.^[113]The particulate, NO_xand SO_xemissions (excluding particulate emissions in the form of drift fromwet cooling towersand mercury emissions from the flue stacks) of coal, oil and gas fired power stations in utility power sector (excluding captive power plants) are monitored regularly.^[114]

The state and central power generation companies are permitted by the Government of India to minimize the cost of coal transportation using flexible coal linkage swaps from inefficient plants to efficient plants, and from plants situated far from coal mines to plants close to the pit head, leading to a reduction in the cost of power.^[115]Although coal imports for consumption in the utility sector are declining, the overall imports of steam coal are increasing as the local coal production is unable to meet the requirements of coal-fired captive power plants.^[116][117]India is introducing single spot auctions/exchanges for all type of coal consumers.^[118]

In 2021, the majority of CO2 emissions from power generation in India were produced by coal, accounting for 96.7% of the total. Natural gas was responsible for 2.6% of emissions, while oil contributed 0.5%.^[12]

India's coal-fired, oil-fired and natural gas-fired thermal power plants are inefficient and replacing them with cheaper renewable technologies offers significant potential for greenhouse gas (CO₂) emission reduction. India's thermal power plants emit 50% to 120% more CO₂per kWh produced compared to average emissions from their European Union (EU-27) counterparts.^[119]Thecentral governmentplans to retire coal-based plants that are at least 25 years old and contributing excessive pollution, totalling 11,000 MW of capacity.^[120]As of 2018 there is no similar retirement plan for thecaptive powersector. In 2020Carbon Trackerestimated that phasing out 20 years or more old coal-fired plants and the coal fired plants under construction with electricity sale price exceeding INR 4/kWh with new renewables is more economical as these coal fired plants are imposing heavy financial burden on Discoms.^[121]

Some diesel generator plants and gas turbine plants were also decommissioned in 2016 though they are best suitable for cateringancillary services.^[122]

India has committed to install 275,000 MW renewable energy capacity by 2027.^[123]The existing base load coal and gas based power plants need to be flexible enough to accommodate the variable renewable energy. Also ramping up, ramping down, warm start up, hot start up capabilities of existing coal based power stations are critical to accommodate the frequent variations in renewable power generation.^[124][125]It is also examined to use the retired coal based electric generators assynchronous condensersfor improving the grid inertia when it is dominated by static power generation sources like solar and wind power.^[126]As the solar power plants remain idle during the night hours, reactive power capability of the inverters installed as part of the solar power plant can also be used during the night time for solving the problem of very high voltage which occurs due to low loads on the transmission lines.^[127]Wind and solar power plants are also capable to providefast frequency responsein ramping up falling grid frequency.^[128]Grid-forming inverters can also restart a downed grid by providing black start power from inverter-based resources like solar, wind and batteries.^[129]

The installed capacity of natural gas-based power plants (including the plants ready to be commissioned with the commencement of natural gas supply) was nearly 26,765 MW at the end of the financial year 2014–15. These plants were operating at an overallplant load factor(PLF) of 22% due to a severe shortage of natural gas in the country,^[130]and the fact that importedliquid natural gas(LNG) was too expensive for power generation. Many power stations were shut down throughout the year for a lack of natural gas supply.^[131]The natural gas shortage for power sector alone was nearly 100 million cubic metre per day atstandard conditions.^[132]The break-even price for switching from imported coal to LNG in electricity generation was estimated to be approximately US$6 permillion British thermal units($20/MWh) (thermal energy).^[133]The Indian government has taken steps to enhance power generation from gas-based power plants by waiving import duties and taxes.^[134][135]

Gasificationof coal or lignite orpet cokeorbiomassproduces synthesis gas orsyngas(also known ascoal gasorwood gas) which is a mixture of hydrogen, carbon monoxide and carbon dioxide gases.^[136]Coal gas can be converted intosynthetic natural gasby using theFischer–Tropsch processat low pressure and high temperature. Coal gas can also be produced by undergroundcoal gasificationif the coal deposits are located deep in the ground or it is uneconomical to mine the coal.^[137]Synthetic natural gas production technologies promise to dramatically improve India's supply of natural gas.^[138]TheDankunicoal complex produces syngas that is piped to industrial users in Calcutta.^[139]Many coal-based fertiliser plants can also be economically retrofitted to produce synthetic natural gas. It is estimated that the production cost for syngas could be below US$6 per million British thermal units ($20/MWh).^[140][141]

Earlier, natural gas use in power generation was thought to be a bridge fuel as it emits far less CO₂(below 50%) when compared to coal use in power generation until renewable power generation without CO₂emissions become economical.^[142]Renewable power generation is already cheaper than coal and gas fueled power generation in India. Now the bridge fuel concept is no more valid and existing gas-based generation needs to compete with the coal-based generation when there is no adequate renewable power generation (including storage and peaking type hydropower). The problem of stranded assets/capacity is more deep-rooted for gas-based power plants than that of the coal-based power plants as coal is far cheaper than natural gas in India.

As of 31 March 2022, India had 6.78 GW of installed nuclear power generation capacity or nearly 1.7% of the total installed utility power generation capacity. Nuclear plants generated 47,063 million kWh at 79.24% PLF in 2021–22.^[143]

India's nuclear power plant development began in 1964. India signed an agreement withGeneral Electric(United States) for the construction and commissioning of two boiling water reactors at Tarapur. In 1967, this effort was placed under India'sDepartment of Atomic Energy.In 1971, India set up its first pressurized heavy water reactors with Canadian collaboration inRajasthan.

In 1987, India created theNuclear Power Corporation of India Limitedto commercialize nuclear power. The Nuclear Power Corporation of India is a public sector enterprise, wholly owned by the Government of India, under the administrative control of the Department of Atomic Energy. The state-owned company has ambitious plans to establish plants totalling to 63 GW generation capacity by 2032.^[144]

India's nuclear power generation effort is subject to many safeguards and oversights. Its environmental management system is ISO-14001 certified, and it undergoes peer review by theWorld Association of Nuclear Operators,including a pre-start-up peer review. The Nuclear Power Corporation of India Limited commented in its annual report for 2011 that its biggest challenge is to address public and policymaker perceptions about the safety of nuclear power, particularly after theFukushima Daiichi nuclear disasterin Japan.^[145]

In 2011, India had 18 pressurized heavy water reactors in operation, with another four projects launched totaling 2.8 GW capacity. India is in the process of launching its first prototypefast breederreactor usingplutonium-based fuel obtained by reprocessing the spent fuel offirst-stage reactors.The prototype reactor is located inTamil Naduand has a capacity of 500 MW.^[146]

India has nuclear power plants operating in the following states:Maharashtra,Gujarat,Rajasthan,Uttar Pradesh,Tamil NaduandKarnataka.These reactors have an installed electricity generation capacity of between 100 MW and 1000 MW each. TheKudankulam nuclear power plant(KNPP) is the single largest nuclear power station in India. KNPP Unit 1 with a capacity of 1000 MWe was commissioned in July 2013, while Unit 2, also with a capacity of 1000 MWe, attained criticality in 2016. Two additional units are under construction.^[147]The plant has suffered multiple shutdowns, leading to calls for an expert panel to investigate.^[148]First 700 MWePHWRunit under phase II ofKakrapar Atomic Power Stationachieved first criticality in July 2020 and expected to begin commercial operation by December 2022.^[146][149]

In 2011, uranium was discovered in theTummalapalle uranium mine,the country's largest uranium mine and possibly one of the world's largest. The reserves were estimated at 64,000 tonnes, and could be as large as 150,000 tonnes.^[150]The mine began operation in 2012.^[151]

India's share of nuclear power plant generation capacity is 1.2% of worldwide nuclear power production capacity, making it the15th largestnuclear power producer. India aims to supply 9% of its electricity needs with nuclear power by 2032 and 25% by 2050.^[145][152]Jaitapur Nuclear Power Project,India's largest nuclear power plant project, is planned to be implemented in partnership withÉlectricité de Franceunder an agreement signed on 10 March 2018.^[153]

India's government is developing up to 62 additional nuclear reactors, mostly usingthoriumfuel, which it expects to be operational by 2025. It is the "only country in the world with a detailed, funded, government-approved plan" to focus onthorium-based nuclear power.^[152]

On 12 August 2021, India's grid-connected electricity generation capacity reached 100 GW from non-conventional renewable technologies^[44][155]and 46.21 GW from conventional renewable power or major hydroelectric power plants. As of 12 August 2021, there are about 50 GW of projects under development, and 27 GW that are tendered and yet to be auctioned.^[44]

Installed capacity of non-conventional renewable power as of 30 April 2024^[156]

Type	Capacity (inMW)
Wind	46,162
Solar including off grid capacity	82,637
Small Hydro Power Projects	5,005
Biomass Power & GasificationandBagasse Cogeneration	10,355
Waste to Power	591
Total non-conventional renewable Power	144,751

Thehydro-electric powerplants atDarjeelingandShivanasamudrawere among the first in Asia, and were established in 1898 and 1902 respectively.

India's potential for hydropower has been assessed to be about 125,570 MW at a 60% load factor.^[157]India is ranked fourth globally by underutilized hydropower potential. The estimated amount of viable hydropower including off-the-streampumped storage hydroelectricpotential varies with improved technology and the cost of electricity generation from other sources.^[158]In addition, there is an estimated 6,740 MW of potential for small, mini, and micro-hydro generators and 56 sites for pumped storage schemes with an aggregate capacity of 94,000 MW have been identified.^[159][160]In 2020, the power tariff from Solar PV clubbed with pumped storage hydro have fallen below the coal-based power plant tariffs in offering base load and peak load power supply.^[161][162]

The installed hydropower capacity as of 31 March 2024 was 46,928 MW, approximately 10.7% of the total installed utility capacity.^[10]Small, mini, and micro-hydro generators add another 5,005 MW capacity. The share of this sector operated by public companies is 97%.^[163]Companies engaged in the development of hydroelectric power in India include the National Hydroelectric Power Corporation (NHPC), Northeast Electric Power Company (NEEPCO), Satluj Jal Vidyut Nigam (SJVNL), Tehri Hydro Development Corporation, and NTPC-Hydro.

Pumped storageschemes offer the potential for centralized peak power stations for load management in the electricity grid.^[164][165]They also produce secondary /seasonal power at no additional cost when rivers are flooding with excess water. Storing electricity by alternative systems such asbatteries,compressed air storagesystems, etc. is more costly than electricity production bystandby generator.India has already established nearly 4,785 MW pumped storage capacity as part of its installedhydro power plants.^[166][167]

Hydropower is a low-carbon, renewable electricity source. However, its advantages are not limited to power generation. In fact, many of its other services are becoming increasingly important in the context of the energy transition and climate change. Hydropower plants offer a broad range of services to the grid that includes balancing and ancillary services. Additionally, hydropower can provide water services such as flood control, irrigation control, water distribution, recreational facilities, and wastewater control.^[168]

In April 2024, the Grid Controller of India Ltd. noted an 11% drop in March hydropower production from the previous year, leading to a greater dependence on coal to meet energy demands. This highlights hydropower's sensitivity to rainfall and its impact on India's energy mix.^[98]

Thesolar energysector in India offers potentially enormous capacity, though little of this potential has so far been exploited. Solar radiation of about 5,000 trillion kWh per year is incident over India's land mass, with average dailysolar powerpotential of 0.25 kWh/m²of used land area with available commercially proven technologies.^[171]As of 31 March 2024, the installed capacity was 81.813 GW_ACand nearly 6.7% of utility electricity generation.^[155]India is the third largest producer of solar power globally.^[11]

Solar power plants require nearly 2.0 hectares (0.020 km²) land per MW capacity, which is similar to coal-fired power plants when life cycle coal mining, consumptive water storage and ash disposal areas are taken into account, and hydropower plants when the submergence area of the water reservoir is included.^[172]Solar plants with 1.33 million MW capacity could be installed in India on 1% of its land, which is about 32,000 km²(3,200,000 hectares). Large tracts of land that are unproductive, barren and devoid of vegetation exist in all parts of India, exceeding 8% of its total area. These are potentially suitable for solar power.^[173]It has been estimated that if 32,000 square km of these wastelands were used for solar power generation, 2000 billion kWh of electricity could be produced, twice the total power generated in 2013–14. At a price of 2.75 ₹/kWh and 1.8 million kWh/MW yearly generation, this would result in a land annual productivity/yield of₹1.0 million(US$12,000) per acre, which compares favorably with many industrial areas and is many times more than the best productive irrigated agriculture lands.^[174]Building solar power plants on marginally productive lands offers the potential for solar electricity to replace all of India's fossil fuel energy requirements (natural gas, coal, lignite, and crude oil),^[175]and could offer per capitaenergy consumptionat par with USA/Japan for the peak population expected during itsdemographic transition.^[176]

The sale price of power generated by solarphotovoltaicsfell to₹2.00(2.4¢ US) perkWhin November 2020 which is lower than any other type of power generation in India.^[177][178]In 2023, the levelised tariff in US$ for solar electricity fell to 1.62 cents/kWh, far below the solar PV sale tariff in India.^[179][180]In 2020, the power tariff from Solar PV clubbed with pumped storage hydro or battery storage have fallen below the coal based power plant tariffs in offering base load and peak load power supply.^[162]

Land acquisition is a challenge for solar farm projects in India. Some state governments are exploring innovative ways to address land availability, for example, by deploying solar capacity above irrigation canals.^[181][182]This allows solar energy to be harvested while simultaneously reducing the loss of irrigation water by solar evaporation.^[183]The state of Gujarat was first to implement theCanal Solar Power Project,using solar panels on a 19,000 km (12,000 mi) long network of Narmada canals across the state to generate electricity. It was the first such project in India.

Synergy with other types of power generation

A major disadvantage of solar power is that it produces electricity only in daylight, and not during nighttime or cloudy daytime. This disadvantage can be overcome by adding energy storage capacity such aspumped-storage hydroelectricity.^[184]A proposed gigantic-scale multipurpose project tointerlink Indian riversenvisagescoastal reservoirsfor harnessing river waters that would also create adequte pumped-storage hydropower capacity for energy storage on a daily/weekly basis by consuming the surplus solar power available during the day time.^[158][185]Existing and future hydropower stations can also be expanded with additional pumped-storage hydroelectricity units to cater for nighttime electricity consumption. Most of the groundwater pumping power required can be met directly by solar power during the daytime.^[186]

Concentrated solar powerplants with thermal storage are also emerging as cheaper (US 5¢/kWh) and cleanerLoad following power plantsthan fossil fuel power plants.^[187]They can respond to demand round the clock, and work asbase loadpower plants when there is excess solar energy. A mix of solar thermal and solar photovoltaic plants offers the potential to match load fluctuations without requiring costly battery storage.

In 2021, the onshore wind power potential was assessed as 302 GW at 100 meters and 695.50 GW at 120 meters above ground level.^[188]The estimated potential is found on the higher side as the present installed capacity is operating below 20%CUFon average against the minimum 30% CUF considered while assessing the wind potential.^[189]Out of the 695 GW potential at 120 m agl, 132 GW potential is assessed to have more than 32% CUF.^[190]

India has thefourth largest installed wind powercapacity in the world. As of 31 August 2023, the installed capacity of wind power was 44.081GW,spread across many states of India.^[155][191]In 2022–23, wind power accounted for nearly 10% of India's total installed power capacity, and 4.43% of the country's power output. The wind power tariff of around 2.5 INR/kWh is the cheapest of all power generation sources in India.^[192]Wind turbine towers and blades can also be made of wood to make them even greener and can surpass the hub height above the local ground level that is economically feasible with steel towers.^[193][194]

The offshore wind power potential of India is nearly 112 GW up to 50 meters water depth and nearly 195 GW up to 1000 meters water depth.^[195]India has announced tentative schedule for callingrequest for quotation(RfQ) to establish offshore wind power projects.^[196]The levelised cost of electricity (LCOE) has fallen to US$50 per MWh for offshore wind power plants.^[195]

Biomassisorganic matterfrom living organisms. As arenewable energysource, biomass can either be used directly via combustion to produce heat, or indirectly after converting it to various forms ofbiofuelusing a range of methods which are broadly classified into thermal, chemical, and biochemical methods.^[197]Biomass,bagasse,forestry, domestic organic wastes, industrial organic wastes, organic residue from biogas plants, and agricultural residue and waste can all be used as fuel to produce electricity.^[198][199]Nearly 750 million tons of biomass that is not edible by cattle is available annually in India.^[200][201]

The total use of biomass to produce heat in India was nearly 177Mtoein 2013.^[202]20% of households in India use biomass and charcoal for cooking purposes. This traditional use of biomass is being replaced byliquefied petroleum gasin rural areas, resulting in increased burning of biomass in fields, This has become a major source of air pollution in nearby towns and cities.^[203][200]

Torrefied biomass

Large quantities of imported coal are being used inpulverised coal-fired power stations.Raw biomass cannot be used directly in the pulverised coal mills as it is difficult togrindinto fine powder due tocaking.However,torrefactionmakes it possible for biomass to replace coal.^[204]The hot flue gas of existing coal-fired power stations can be used as a heat source for torrefaction, so that biomass can becofiredwith coal.^[205][206]Surplus agriculture/crop residue biomass is beginning to be used for this purpose.^[207][208]Instead of shutting down/ retirement of coal-fired power plants due to concerns over pollution, it has been argued that these units can be retrofitted economically to produce electricity from biomass.^[209][210]Biomass contains substantial oxygen and lesser ash to make retrofitting of old units less capital intensive. Biomass power plants can also sell Renewable Energy Certificates, increasing their profitability.^[211][212]Cofiring of biomass up to 10% with coal in existing pulverised coal-fired power stations is successfully implemented in India.^[213][214]Central Government has made cofiring (minimum 5%) of biomass mandatary from October 2022 in all coal fired plants.^[215][216]

Biogas

In 2011, India started a new initiative to demonstrate the utility of medium-size mixed feedbiogas-fertilizer pilot plants. The government approved 21 projects with an aggregate capacity of 37,016 cubic meters per day, of which 2 projects were successfully commissioned by December 2011.^[217]India commissioned a further 158 projects under its Biogas-based Distributed/Grid Power Generation program, with a total installed capacity of about 2 MW. In 2018, India has set a target of producing 15 million tons of biogas/bio-CNG by installing 5,000 large-scale commercial-type biogas plants which can produce daily 12.5 tons of bio-CNG by each plant.^[218]As of May 2022, nearly 35 such plants are in operation.^[219]Rejected organic solids from biogas plants can be used in coal plants aftertorrefaction.

Biogas is primarily methane, and can also be used to generate protein-rich feed for cattle, poultry and fish by growingMethylococcus capsulatus,a bacterium that grows directly on methane. This can be done economically in villages with low requirements for land and water.^{[220][221][222]}The carbon dioxide gas produced as a by-product from these units can be used in cheaper production ofalgae oilorspirulinafromalgae cultivation,which may eventually substitute for crude oil.^[223][224]Using biogas for protein-rich feed production is also eligible for carbon credits as thissequesters carbonfrom the atmosphere.^[225]There is significant potential to extract useful biomass from breweries, textile mills, fertilizer plants, the paper, and pulp industry, solvent extraction units, rice mills, petrochemical plants and other industries.^[226]

The government is exploring several ways to use agro waste or biomass in rural areas to improve the rural economy.^[227][228]For example, biomass gasifier technologies are being explored to produce power from surplus biomass resources such as rice husk, crop stalks, small wood chips and other agro-residues in rural areas. The largest biomass-based power plant in India at Sirohi, Rajasthan has a capacity of 20 MW. During 2011, India installed 25 rice husk based gasifier systems for distributed power generation in 70 remote villages ofBihar,including a total of 1.20 MW in Gujarat and 0.5 MW in Tamil Nadu. In addition, gasifier systems were installed at 60 rice mills in India.^[217]The green hydrogen roadmap is constantly evolving in India by consolidating various capabilities at institutional and research centers.^[229][230]

This sectionmay contain an excessive amount of intricate detail that may interest only a particular audience.Specifically, not all springs are hot enough to generate electricity.Please help by removing excessive detail that may be againstWikipedia's inclusion policy.(August 2023)(Learn how and when to remove this message)

India'sgeothermal energyinstalled capacity is experimental, and commercial use is insignificant. According to some estimates, India has 10,600 MW of geothermal energy available.^[231]The resource map for India has been grouped into six geothermal provinces:^[232]

• Himalayan Province–Tertiaryorogenicbelt with tertiarymagmatism
• Faulted blocks province – theAravalli range,Naga-Lushi, the west coast regions, and theNarmada-Sonlineament.
• Volcanic arc province – theAndaman and Nicobararc.
• Deep sedimentary basins of Tertiary age such as theCambaybasin.
• Radioactive province –Surajkund,HazaribaghandJharkhand.
• Dharwar Cratonicprovince – Peninsular India

India has about 340 hot springs spread over the country. Of these, 62 are distributed along the northwest Himalaya, in the states ofJammu and Kashmir,Himachal PradeshandUttarakhand.They are found concentrated in a 30-50-km wide thermal band mostly along the river valleys. The Naga-Lusai and West Coast Provinces also manifest a series of thermal springs. The Andaman and Nicobar arc is the only place in India where volcanic activity continues, potentially a good site for geothermal energy. The Cambay geothermal belt is 200 km long and 50 km wide, with Tertiary sediments. Thermal springs have been reported from the belt although they are not of very high temperature or flow levels. High subsurface temperature and thermal fluid have been reported in deep drill wells in depth ranges of 1.7 to 1.9 km during drilling in this area. Steam blowout has also been reported in drill holes in a depth range of 1.5 to 3.4 km. The thermal springs in India's peninsular region are more related to the faults, which allow water to circulate to considerable depths. The circulating water acquires heat from the normal thermal gradient in the area, and can emerge at a high temperature.^[232]

In a December 2011 report, India identified six promising geothermal sites for the development of geothermal energy. In decreasing order of potential, these are:

• Tattapani (Chhattisgarh)
• Puga (Jammu & Kashmir)
• Cambay Graben (Gujarat)
• Manikaran (Himachal Pradesh)
• Surajkund (Haryana)
• Chhumathang (Jammu & Kashmir)

Puga and Chumathang area in Ladakh are deemed as the most promising geothermal fields in India. These areas were discovered in the 1970s and initial exploratory efforts were made in the 1980s byGeological Survey of India(GSI). On 6 February 2021, theONGCEnergy Center (OEC) signed a Memorandum of Understanding (MoU) with Ladakh and the Ladakh Autonomous Hill Development Council, Leh in the presence of current Lieutenant governorRadha Krishna Mathur.^[233]

In 2011, the Ministry of New & Renewable Energy, Government of India and the Renewable Energy Development Agency of West Bengal jointly approved and agreed to implement India's first 3.75 MW Durgaduani minitidal powerproject.^[234]

Another tidal wave technology harvests energy from surface waves or from pressure fluctuations below the sea surface. A report from the Ocean Engineering Centre, at theIndian Institute of Technology Madrasestimated the annual wave energy potential along the Indian coast is 5 to 15 MW/metre, suggesting a theoretical maximum potential for electricity harvesting along India's 7500-kilometer coastline of about 40 GW.^[235]However, the realistic economical potential is likely to be considerably less than this.^[235]

The third approach to harvesting tidal energy is ocean thermal energy technology. This approach harvests the solar energy trapped in ocean waters. Oceans have a thermal gradient, the surface being much warmer than the deeper levels of the ocean. This thermal gradient may be harvested using the modifiedRankine cycle.India'sNational Institute of Ocean Technology(NIOT) has attempted this approach without success. In 2003, NIOT attempted to build and deploy a 1 MW demonstration plant with Saga University of Japan,^[236]but mechanical problems prevented success.^{[citation needed]}

As of 2013, India has a singlewide area synchronous gridthat covers the entire country except distant islands.^[237]

Installed transmission lines and distribution capacity (MVA) as of 31 July 2018^[238][239]

Capacity	Substations (MVA)	Transmission lines (circuit km)	c.km / MVA ratio[240]
HVDC± 220 kV & above	22,500	15,556	0.691
765 kV	197,500	36,673	0.185
400 kV	292,292	173,172	0.707
220 kV	335,696	170,748	0.592
220 kV & above	847,988	396,149	0.467

The total length of high voltage (HV) transmission lines (220kV and above) would be enough to form a square matrix of area 266 km²(i.e. a square grid 16.3 km on a side, so that on average there is at least one HV line within a distance of 8.15 km) over the entire area of the country. This represents a total of almost 20% more HV transmission lines than that of the United States (322,000 km (200,000 mi) of 230 kV and above). However the Indian grid transmits far less electricity.^[241]The installed length of transmission lines of 66 kV and above is 649,833 km (403,788 mi) (on average, there is at least one ≥66 kV transmission line within 4.95 km across the country).^[7]The length of secondary transmission lines (400 V and above) is 10,381,226 km (6,450,595 mi) as of 31 March 2018.^[7]The spread of total transmission lines (≥400 V) would be sufficient to form a square matrix of area 0.36 km²(i.e. on average, at least one transmission line within 0.31 km distance) over the entire area of the country. In a future grid dominated by decentralized power generation like solar and wind power, unscientific expansion of the electrical grid would yield negative results due toBraess's paradox.^[242]

The all-time maximum peak load met was 182,610 MW on 30 May 2019.^[243]The maximum achieveddemand factorof substations is nearly 60% at the 220 kV level. However, theoperational performanceof the system is not satisfactory in meeting peak electricity loads.^[244][245]This has led to the initiation of detailedforensic engineeringstudies, with a plan to make capital investments in asmart gridthat maximizes the utility of the existing transmission infrastructure.^[246][50]

The introduction of anavailability based tariff(ABT) originally helped to stabilize the Indian transmission grids.^{[citation needed]}However, as the grid transitions to power surplus the ABT has become less useful. TheJuly 2012 blackout,affecting the north of the country, was the largest power grid failure in history as measured by the number of people affected.^{[citation needed]}

India's aggregate transmission and commercial (ATC) losses were nearly 21.35% in 2017–18.^{[247][7][248]}This compares unfavorably to the total ATC loss in theelectricity sector of the United States,which was only 6.6% out of 4,404 billion kWh electricity supplied during the year 2018.^[249]The Indian government set a target of reducing losses to 17.1% by 2017 and to 14.1% by 2022. A high proportion of non-technical losses are caused by illegal tapping of lines, faulty electric meters and fictitious power generation that underestimates actual consumption and also contributes to reduced payment collection. A case study in Kerala estimated that replacing faulty meters could reduce distribution losses from 34% to 29%.^[65]

India'sNational Gridis synchronously interconnected to Bhutan, and asynchronously linked withBangladesh,MyanmarandNepal.^[250]Anundersea interconnectortoSri Lanka(India–Sri Lanka HVDC Interconnection) have been proposed.^[251]Singapore and UAE are interested to import electricity from India by establishing undersea cable link to reduce carbon emissions as imported electricity would not contribute to carbon emissions upon its use whether it is generated from renewable resources or not in the exporting country.^[252]

India has been exporting electricity toBangladesh,Myanmar and Nepal and importing excess electricity from Bhutan.^[253][254]Since 2016–17, India has been a net exporter of electricity with 9,232 Gwh exports and 7,597 Gwh imports, mainly from Bhutan, in 2021–22.^{[3][255][256]}In 2018, Bangladesh proposed importing 10,000 MW power from India.^[257]

Electricity (Million kWh) Trade by India. ^[258]

Fiscal year	Bhutan	Nepal	Bangladesh	Myanmar	Total
2023-24	+3,763	-154	-8,413	-8	-4,812

Net exports (-) and Net imports (+). The above exports to Bangladesh are excluding the exports from the 1600 MWGodda Thermal Power Stationwhich is located in India but not connected to Indian electric grid.

To encourage the carbon neutral solar power generation, plans are made to transform the Indian national grid into atransnational gridexpanding up toVietnamtowards east andSaudi Arabiatowards west spanning nearly 7,000 km wide.^[259][260]Being at the central location of the widened grid, India will be able to import the excess solar power available outside its territory at cheaper prices to meet the morning and evening peak load power demands without much costly energy storage.^[261]

TheMinistry of Poweris India's top union government body regulating the electrical energy sector in India. The ministry was created on 2 July 1992. It is responsible for planning, policy formulation, processing of projects for investment decisions, monitoring project implementation, training and manpower development, and the administration and enactment of legislation in regard to power generation, transmission and distribution.^[262]It is also responsible for the administration of India'sElectricity Act (2003),the Energy Conservation Act (2001) and has the responsibility of undertaking amendments to these Acts when necessary to meet the union government's policy objectives.

Electricity is a concurrent list subject at Entry 38 in List III of the Seventh Schedule of theConstitution of India.In India's federal governance structure, this means that both the union government and India's state governments are involved in establishing policies and laws for the electricity sector. This requires the union government and individual state governments to enter intomemoranda of understandingto help expedite projects in the individual states.^[263]To disseminate information to the public on power purchases by the distribution companies (discoms), the government of India recently started posting data on its website on a daily basis.^[264]

Bulk power purchasers can buy electricity on a daily basis for short, medium, and long-term durations from a reverse e-auction facility.^[265]The electricity prices transacted by the reverse e-auction facility are far less than the prices agreed under bilateral agreements.^[266]The commodity derivative exchangeMulti Commodity Exchangehas sought permission to offer electricity futures markets in India.^[267]The union government of India is also planning reverse procurement process in which generators and discoms with surplus power can seek e-bids for power supply for up to a one-year period, to put an end to bilateral contracts and determine the market-based price for electricity.^[268]

Energy saving certificates (PAT), various renewable purchase obligations (RPO), and renewable energy certificates (REC) are also traded on the power exchanges regularly.^[269][270]

India's Ministry of Power administers central government-owned companies involved in the generation of electricity in India. These include theNational Thermal Power Corporation,Neyveli Lignite Corporation,the SJVN, theDamodar Valley Corporation,theNational Hydroelectric Power Corporationand theNuclear Power Corporation of India.ThePower Grid Corporation of Indiais also administered by the Ministry; it is responsible for the inter-state transmission of electricity and the development of the national grid.

The Ministry works with state governments on matters related to state government-owned corporations in India's electricity sector. Examples of state corporations include theTelangana Power Generation Corporation,theAndhra Pradesh Power Generation Corporation Limited,theAssam Power Generation Corporation Limited,theTamil Nadu Electricity Board,theMaharashtra State Electricity Board,theKerala State Electricity Board,theWest Bengal State Electricity Distribution CompanyandGujarat Urja Vikas NigamLimited.

India's Ministry of Power administers theRural Electrification Corporation Limitedand thePower Finance CorporationLimited. These central-government-owned public sector enterprises provide loans and guarantees for public and private electricity sector infrastructure projects in India. Excessive plant construction loans at 75% of overestimated costs on overrated plant capacities have led tostranded assetsof US$40 to 60 billion.^[271][272]The central and state-owned power generators escaped this crisis as they had enteredPPAswith state-ownedmonopolisticdiscoms on a cost-plus basis at higher than prevailing market power tariffs, without undergoing competitive bidding process. Many direct and indirect subsidies are given to various sectors.^[273]

After the enactment of Electricity Act 2003 budgetary support to the power sector is negligible.^[274]Many State Electricity Boards were separated into their component parts after the act came into force, creating separate entities for generating, transmitting and distributing power.^[275]

The rapid growth of the electricity sector in India has generated high demand for trained personnel. India is making efforts to expand energy education and to enable existing educational institutions to introduce courses related to energy capacity addition, production, operations and maintenance. This initiative includes conventional andrenewable energy.

TheMinistry of New and Renewable Energyannounced that State Renewable Energy Agencies are being supported to organize short-term training programs for installation, operation and maintenance, and repair ofrenewable energysystems in locations where intensive renewable energy programs are being implemented. Renewable Energy Chairs have been established at theIndian Institute of Technology Roorkeeand theIndian Institute of Technology Kharagpur.^[217]TheCentral Training Institute Jabalpuris a training institute for power distribution engineering and management.^{[citation needed]}The NTPC School of Business Noida has initiated an energy-centered two-year post-graduate diploma in the management program and a one-year post-graduate diploma in management (executive) program, to cater to the growing need for management professionals in this area.^{[citation needed]}Education and availability of skilled workers are expected to be a key challenge in India's effort to expand its electricity sector.

India's electricity sector faces many issues, including:

1. Inadequate last mile connectivity.The country already has adequate generation and transmission capacity to meet the full consumer demand, both temporally and spatially.^[7]However, due to the lack of last-mile link-up between all electricity consumers and a reliable power supply (to exceed 99%), many consumers depend ondiesel generators.^[50]Nearly 80 billion kWh of electricity is generated annually in India by diesel generator sets that consume nearly 15 million tons of diesel oil. Over 10 million households use battery storageUPSas back-ups in case ofload shedding.^[276]India imports nearly US$2 billion worth of battery storage UPS every year.^[277]As overhead lines cause distribution problems during rain and wind storms, there is a plan to lay buried cables from low voltage substations to supply cheaper emergency power in cities and towns and thus reduce diesel oil consumption by diesel generator sets and the installation of UPS systems.^{[citation needed]}
2. Demand build up measures.Electricity-intensive industries consume the cheaper electricity (average price Rs 2.5 perkWhr) available from the grid instead of running their own coal/gas/oil fired captive power plants.^[278][279]The captive power generation capacity by such plants is nearly 53,000 MW, and they are mainly established in steel, fertilizer, aluminium, cement, etc. industries.^[280][7]These plants can draw cheaper electricity from the grid on short term open access (STOA) basis, avoiding their own higher cost of electricity generation and diverting power from other consumers.^[281][282]Some of these idling captive power plants can be used forancillary servicesorgrid reserve serviceand earn extra revenue.^[283][284]
3. Unequal electricity distribution.Almost all households have access to electricity.^[1]However, most households find the electricity supply intermittent and unreliable.^[285]At the same time, many power stations are idling for lack of electricity demand and the idling generation capacity is sufficient to supply the needs of households lacking electricity three times over.
4. Erratic power pricing.In general, industrial and commercial consumers subsidize domestic and agricultural consumers.^[286][287]Government giveaways such as free electricity for farmers, created partly to curry political favor, have depleted the cash reserves of state-run electricity-distribution system and led to debts of₹2.5 trillion(US$30 billion).^[288]This has financially crippled the distribution network, and its ability to pay to purchase power in the absence of subsidies from state governments.^[289]This situation has been worsened by state government departments that do not pay their electricity bills.
5. Over-rated capacity.Many coal-fired plants are overrated above the actualmaximum continuous rating(MCR) capacity.^[290]to allow the plant cost to be inflated.^[291]These plants operate 15 to 10% below theirdeclared capacityon a daily basis and rarely operate at declared capacity, undermining grid stability.
6. Lack of timely information on load and demand.Intraday graphs at 15-minute or more frequent intervals are required to understand the shortcomings of the power grid with respect to grid frequency, including comprehensive data collected fromSCADAfor all grid-connected generating stations (≥ 100 KW) and load data from all substations.^[292]
7. Lack of adequate coal supply:Despite abundant reserves of coal, power plants are frequently under-supplied. India's monopoly coal producer, state-controlledCoal India,is constrained by primitive mining techniques and is rife with theft and corruption.^{[citation needed]}Poor coal transport infrastructure has worsened these problems. Most of India's coal lies under protected forests or designated tribal lands and efforts to mine additional deposits have been resisted.
8. Poor gas pipeline connectivity and infrastructure.India has abundant coal bed methane and natural gas potential. However agiant new offshore natural gas fieldhas delivered far less gas than claimed, causing a shortage of natural gas.
9. Transmission, distribution and consumer-level losses.Losses exceed 30%, including the auxiliary power consumption of thermal power stations and fictitious electricity generation by wind generators, solar power plants & independent power producers (IPPs), etc.
10. Resistance toenergy efficiencyin the residential building sector.Continuous urbanization and the growth of population result in increased power consumption in buildings. The belief still predominates among stakeholders that energy-efficient buildings are more expensive than conventional buildings, adversely affecting the "greening" of the building sector.^[293]
11. Resistance to hydroelectric power projects.Hydroelectric power projects in India's mountainous north and northeast regions have been slowed down by ecological, environmental and rehabilitation controversies, coupled with public interest litigation.
12. Resistance to nuclear power generation.Political activism since theFukushima disasterhas reduced progress in this sector. The track record of executing nuclear power plants is also very poor in India.^[294][149]
13. Theft of power.The financial loss due totheft of electricityis estimated at $16 billion yearly.^{[citation needed]}

Key implementation challenges for India's electricity sector include efficient performance of new project management and execution, ensuring availability and appropriate quality of fuel, developing the large coal and natural gas resources available in India, land acquisition, obtaining environmental clearances at state and central government level, and training skilled manpower.^[295]

India's net import ofliquefied petroleum gas(LPG) is 16.607 million tons and the domestic consumption is 25.502 million tons which is 90% of total consumption in 2021–22.^[296]The LPG import content is nearly 57% of total consumption in 2021–22.^[297]The affordable electricity retail tariff (860 Kcal/kWh at 74% heating efficiency) to replace LPG (net calorific value 11,000 Kcal/Kg at 40% heating efficiency) in domestic cooking is up to 10.2 ₹/kWh when the retail price of LPG cylinder is ₹1000 (without subsidy) with 14.2 kg LPG content.^[298]Replacing LPG consumption with electricity would reduce imports substantially.^[299]

India'spiped natural gas(PNG) for domestic cooking needs was 12,175 million standard cubic meters (mmscm) which is nearly 19% of total natural gas consumption in 2021–22.^[296]Natural gas/ LNG import content is nearly 56% of total consumption in 2021–22.^[296]The affordable electricity retail tariff (860 Kcal/kWh at 74% heating efficiency) to replace PNG (net calorific value 8,500 Kcal/scm at 40% heating efficiency) in domestic cooking is up to 9 ₹/kWh when the retail price of PNG is ₹47.59 per scm.^[300][301]Replacing PNG consumption with electricity would reduce costly LNG imports substantially.

The domestic consumption ofkeroseneis 1.291 million tons out of 1.493 million tons total consumption in 2021–22. The subsidized retail price of kerosene is 15 ₹/liter whereas the export/import price is 79 ₹/liter. The affordable electricity retail tariff (860 Kcal/kWh at 74% heating efficiency) to replace kerosene (net calorific value 8240 Kcal/liter at 40% heating efficiency) in domestic cooking is up to 15.22 ₹/kWh when the kerosene retail price is 79 ₹/liter.

In 2022–23, theplant load factor(PLF) of coal-fired thermal power stations (nearly 212 GW) was only 64.15%.^[5]These stations can run above 85% PLF if there is adequate electricity demand. The possible additional net electricity generation at 85% PLF is nearly 450 billion kWh which is enough to replace all the LPG, PNG, and kerosene consumption in the domestic sector.^[302]The incremental cost of generating additional electricity is only the coal fuel cost, less than 3 ₹/kWh. Enhancing the PLF of coal-fired stations and encouraging domestic electricity consumers to substitute electricity in place of LPG, PNG, and kerosene in household cooking would reduce government subsidies. It has been proposed that domestic consumers who are willing to surrender subsidized LPG/kerosene permits should be given a free electricity connection and a subsidized electricity tariff.^[303][304]To avoid the possibility of fatal electric shocks and improve the safety standard more than that of LPG cooking, power is supplied to the electric cook stove through aresidual-current circuit breaker.

The power demand in India, peaks during the morning and evening hours mainly due to electricity consumption for water heating. To moderate the peak power demand,heat pumpwater heaters are available which consume 2 to 3 times less electricity for the same heat load.^[305]

Substantial scope is also present in micro, small, and medium enterprises (MSME) to switch over to electricity from fossil fuels to reduce the cost of production provided uninterrupted power supply is ensured.^[306]Since 2017,IPPshave been offering to sell solar and wind power below 3.00 ₹/kWh to feed into the high voltage grid. After considering distribution costs and losses, solar power appears to be a viable economic option for replacing the LPG, PNG, kerosene, etc. used in the domestic and MSME sectors. In 2024, renewable power producers are offering firm and dispatchable renewable electricity below 5.60 ₹/kWh (0.0677 $/kWh) which is economical to replace fossil fuels in above applications.^[307]

The retail prices ofpetrolanddieselare high enough in India to makeelectricity driven vehiclesrelatively economical.^[308]The retail price of diesel was 101.00 ₹/liter in 2021–22, and the retail price of petrol was 110.00 ₹/liter. The affordable retail electricity price to replace diesel would be up to 19 ₹/kWh (860 Kcal/kWh at 75% input electricity to shaft power efficiency versus diesel's net calorific value of 8572 Kcal/liter at 40%fuel energy to crankshaft power efficiency), and the comparable number to replace petrol would be up to 28 ₹/kWh (860 Kcal/kWh at 75% input electricity to shaft power efficiency versus petrol's net calorific value at 7693 Kcal/liter at 33% fuel energy to crankshaft power efficiency). In 2021–22, India consumed 30.849 million tons of petrol and 76.687 million tons of diesel, both mainly produced from imported crude oil.^[296]To spread the use of electric vehicles rapidly and reduce the consumption of imported fossil fuels, electricity sale prices at fast charging centers could be subsidized to below 5 ₹/kWh. Thus owners of commercial passenger and goods vehicles can be attracted to switch to costly electric vehicles which do not contribute to surface air pollution.^[309]

Electricity-driven vehicles are expected to become popular in India when energy storage/batterytechnology offers improved range, longer life, and lower maintenance.^[310][311]Conversion of old petrol and diesel vehiclesto battery electric vehicles is also feasible as the battery pack prices become affordable.Vehicle to gridoptions are also attractive, potentially allowing electric vehicles to help to mitigate peak loads in the electricity grid.^[312]Discarded batteries of electric vehicles are also used as energy storage systems economically.^[313]The potential for continuous charging of electric vehicles throughwireless electricity transmissiontechnology is being explored by Indian companies and others.^{[314][315][316]}

India has abundant solar, wind, hydro (including pumped storage) and biomass power potential. In addition, as of January 2011 India had approximately 38 trillion cubic feet (Tcf) of proven natural gas reserves, the world's 26th largest reserve.^[317]The United StatesEnergy Information Administrationestimates that India produced approximately 1.8 Tcf of natural gas in 2010 while consuming roughly 2.3 Tcf of natural gas. India already producescoalbed methane.

• National electricity Plan – 2012, CEA, Government of India
• Electricity grid maps of the southern regionArchived31 July 2021 at theWayback Machine
• India's Energy Policy and Electricity Production
• [2]Archived6 April 2019 at theWayback Machine